LIBRARY

OF THE

UNIVERSITY OF CALIFORNIA.

BIOLOGY

LIBRARY

G

Ocular or Eye piece

Draw-Tube

Rack and Pinion for
coarse adjustment

Micrometer
Screw for

fine adjustment

Abbe Condenser
Iris Diaphragm

DIRECTIONS

FOR

LABORATORY WORK

IN

BACTERIOLOGY

FOR THE USE OF THE MEDICAL CLASSES
IN THE UNIVERSITY OF MICHIGAN.

FREDERICK G. NOVY, Se.D., M.D.,

JUNIOR PROFESSOR OF HYGIENE AND PHYSIOLOGICAL CHEMISTRY.

GEORGE WAHR:

PUBLISHER AND BOOKSELLER,

ANN ARBOR, MICH.

: / 7

Li!-' -

Copyrighted 1894.

GEORGE \VAHK.

ANN ARBOR COURIER,

PRINTERS AND BINDERS.

PREFACE.

No attempt has been made in the following pages at a formal,
systematic presentation of Bacteriology. The subject-matter has
been arranged entirely with reference to progressive work in the
laboratory and, more especially, corresponds with the work as
carried on in the Hygienic Laboratory of the University of Michigan.
The course covers a period of twelve weeks of daily afternoon work.
Illustrations of the various bacteria and of their cultural character-
istics have been expressly omitted, as the student is expected to
sketch from observation the form of .each organism and its peculiar-
ities of growth in the colony, and in tube culture. Blank pages are
provided for this purpose and for such additional notes as may bo
desirable.

The works that have been drawn upon freely in the preparation
of these pages are Fraeukel's Grundriss der Bakterienkunde,
Eisenberg's Bakteriologische Diagnostik, and Fliigge's Die Mikro-
organisnien. The larger works of Baumgarten and of Sternberg were
likewise frequently consulted, and in many instances recourse was
had to the original sources.

For the frontispiece plate, which is intended to show the com-
ponent parts of the microscope, I am indebted to the firm of E.
Leitz, of Wetzlar.

F. G. NOVY.
ANN ARBOR, April, 1894.

132699

LABORATORY Y/ORK IN BACTERIOLOGY.

i.

FORM AND CLASSIFICATION.

Bacteria as single-celled microscopic plants.

.Relation to algae — to fungi — to yeasts.
Classified according to external form into —
Micrococcus — spherical.
Bacillus — rod-shaped.
Spirillum — screw-shaped.

The term bacterium still used occasionally to desig-
nate a very short bacillus.

Vibrio — is the term applied to organisms which
may form spirals, but commonly grow in seg-
ments of a spiral giving rise to comma — or
^— N shaped forms.

Lack of a natural classification of bacteria.
Variation in form as a result of natural conditions —
environment.

Young and fully developed cells.

Nature of the medium on whhh the growth occurs.

Solid and liquid media.

Temperature.

Unfavorable media give rise to involution forms

— degenerations.

Variations resulting from artificial conditions —
methods of examination.

Deposition of aniline dyes. Simple and double
stains, as of tubercle and of leprosy bacillus.
Contraction of protoplasm by alcohol — by iodine.
Action of heat.

Constancy of form and of species.
Demonstration of, Micrococcup,
Bacillus,
Spirillum.

PREPARATION OF NUTRIENT GELATIN.

LABORATORY WORK. — Place 500 g. of chopped lean beef
into a clean 1^-2 litre flask; add 1000 c. c. of tap-water
and insert a cotton plug into the mouth of the flask. Shake
the flask repeatedly during the next 15-30 rain., and then
immerse in boiling water in a water-bath and heat for
15-30 min. Filter through muslin and to the filtrate or
meat extract thus obtained add,

100 g. of gelatin
10 g. of dry peptone
5 g. of common salt.

Warm in the water-bath until the gelatin melts, then
neutralize or render slightly alkaline by cautious addi-
tions of a saturated sodium carbonate solution (avoid
excess of alkali). Continue heating in a water-bath, with
occasional shaking, for f to 1 hr. Filter through a plaited
filter. The filtrate should be, (1) perfectly clear, (2)
should be neutral or slightly alkaline in reaction, (3)
should not become cloudy or coagulate when boiled in a
test tube for 1 to 2 minutes, (4) should solidify when
cooled.

If the filtrate is cloudy and strongly alkaline correct
the reaction by the addition of dilute acetic acid. If it
becomes cloudy or coagulates when warmed, continue
heating in the water-bath.

If the filtered gelatin answers the above requirements
then fill, with the aid of a small funnel, into test-tubes to
a depth of 1 to 1^ inches. Avoid touching the neck of
the tube with gelatin. These test-tubes are first
thoroughly cleansed, allowed to dry, then plugged with
cotton, placed upright in a wire basket and sterilized in a
dry heat oven at 150 to 175° C. for 1 hour.

After the tubes have been filled with gelatin they are
again sterilized by heating in the steam sterilizer, (100°
C.) for 15 minutes, each day, for the next consecutive
three days.

MEMORANDA.

MEMORANDA.

II.

STRUCTURE OF THE BACTERIAL CELL.

The cell- wall possibly composed of cellulose or woody-
fibre

Difficultly seen — its demonstration by icdine.

Capsulated bacteria.
ZoOgloea — the result of fusion of the cell-walls of

many bacteria.

The cell contents — protoplasm — existence of a nucleus.
Homogeneous — granular.
As a rule the cell is colorless. A few are slightly

colored.
Chlorophyll, the green coloring matter of plants,

is present in a siunll number.
The granulose reaction given by some — blue
color with iodine, same as with boiled starch.
Motion — Brownian, or molecular movement. Real
motion.

Actual motion observed in many bacilli, in spi-
rilla and in two micrococci.
Whips or flagella. Their arrangement on the

bacillus, spirillum, vibrios, micrococciis.
Giant whip-.
Demonstration of,

Action of iodine on protoplasm,

Capsules,

Whips.

PREPARATION OF POTATO CULTURES.

Select three sound potatoes and then clean them
thoroughly, under the tap, with the aid of a brush. By
means of a knife remove any bad spots or depressions that

— 8 —

may exist, since these frequently harbor bacteria which
are highly resistant to destruction. Place the potatoes,
thus prepared, in a solution of mercuric chloride (1-1000)
for | to 1 hour; transfer to a tin pail with a perforated
bottom, and then place tin's in a steam sterilizer. Heat
for f to 1 hour, — the potatoes should be well cooked.
Remove the pail and allow the potatoes to partially cool.

A "moist chamber" is prepared by placing around
filter paper on the bottom of the lower dish and moisten-
ing it with mercuric chloride, allowing any excess of the
solution to drain off. Three potato knives are sterilized
by heating in the flame till the edge begins to redden.
They are then set aside to cool, with the edge up, on a
block or over the edge of the table so that the blade does
not touch anything.

The partially cooled potato is now picked up with the
left hand, which previously has been dipped in mercuric
chloride, and cut into halves by a horizontal section with
a sterilized knife. Each half of the potato is carefully
placed in the moist chamber with the cut surface turned
upwards. Contact with the cut surface must be avoided.

To inoculate, transfer a small portion of the bacterial
growth by means of a sterilized and cooled wire or knife
to the potato, and then thoroughly spread this material
over the surface avoiding the outer £ inch. The potato
is held in the fingers of the left hand, which has been
dipped in mercuric chloride. The number of bacteria
which is thus transferred to the surface of the potato is
usually so great that when they develop the entire surface
is covered with a continuous growth. To isolate bac-
teria, therefore, it is necessary to resort to dilution cul-
ture.

For this purpose a small amount of material is taken
from the surface of the inoculated potato, or No. 1, by
means of a sterilized knife, and transferred in the same
manner as before to the surface of potato No. 2, where it is
likewise spread thoroughly, and evenly, over the surface.
The number of bacteria transplanted to the second potato

MEMORANDA.

MEMORANDA.

-9-

is still, as a rule, too great. Hence, with a sterilized knife
a minute amount of material is taken from the surface of
potato No. 2 and transferred to that of potato No. 3, where
it is spread as before.

If the inoculation is properly carried out the third
potato will have-but a few bn.cteria scattered over the sur-
face, and separated by £ inch or more. Each germ thus
isolated from its neighbor soon multiplies so that in 24 to
36 hours a small growth of about the size of a pin head
becomes visible. This isolated growth is known as a
colony, and inasmuch as it is derived from a single cell it
is &pure culture of that organism.

In this and all subsequent work successful results and
freedom from danger depend upon the rigid sterilization
of all articles used. Hence, sterilize all instruments,
wires, etc., immediately before use, and immediately after
use, before placing them back on the table or in the
tumbler.

LABORATORY WORK. — Make dilution culture (on three
potatoes) of the Micrococcus prodigiosus.

Mass culture (single potato) of Orange sarcine.
Red bacillus of water.
Violet bacillus of water.

— 10 —

III.

LIFE HISTORY OF A BACTERIAL CELL.

Young cells grow, attain full size, multiply.
Spore formation, analogy of spores to seeds of higher
plants.

Observed in many bacilli, few spirals, but not in

micrococci.

Sporogenic granules — their coalescence — the spore.
Spore germination observed in but few instances.

Bacillus snbtilis, Cohn ; Bacillus butyricus, Praz-

movski.
Bacillus anthraci?, Koch ; Bacillus megaterium,

DeBary.

Each spore gives rise to but one bacterial cell, and a
cell develops but one spore. Spore formation, therefore,
a means of reproduction, not of multiplication.

Structure of a spore— dense, highly resistant cell- wall
— the contents.

Behavior of aniline dyes. Action of heat, cold,

desiccation, chemicals.

Their importance as resting or permanent forms.
Position of the spore in the cell — median or termi-
nal— with or without enlargment. Clostridium form —
Drumstick or u Kopchen v form.

Attempts at classification — Endospore and arthro-
spore bacteria.

Spore formation not the result of exhaustion of soil,
but like the flower and fruit of plants represents the high-
est stage of development. It occurs only under favorable
conditions— medium, temperature, oxygen.

Asporogenic bacteria, result of unfavorable environ-
ment— influence of calcium.

MEMORANDA.

MEMORANDA.

— 11 —

Multiplication of bacteria always takes place by
division — one cell forms two and only two new cells.

Threads — result from division of bacilli which
remain adherent end to end by the undivided
cell membrane.

Diplocoocus — Streptococcus — Staphylococcus.
Division in two directions results in Tetrads.
Division in three directions results in sarcines.

Demonstration of,

Sporogenic granules, threads, diplococci, Staphyl-

ococci, streptococci, tetrads, sarcines.
Spores, median and terminal.

— 12 —

IV.
THE MICROSCOPE AND ITS COMPONENT PARTS.

The stand — Coarse adjustment by rack and pinion.

Fine adjustment by micrometer screw.
The optical part— mirror, Abbe condenser with iris
diaphragm, objectives, eye-pieces.

(Structure of the Abbe condenser — its object.

In examining unstained specimens contract

the diaphragm.
In examining stained specimens open the

diaphragm.
Requirements of good objectives :

Magnification, defining power, resolving power.
Achromatic and apochromatic objectives.
Homogeneous oil-immersion objectives — advant-
ages.

The cedar oil must be removed at the close of the
day's work by touching the lens carefully with soft filter
paper.

Slides and cover-glasses for microscopic work must be
rigidly clean. The cover-glasses should be kept in alco-
hol and wiped dry when needed. If surface is at all
greasy, heat the cover-glasses with sulphuric acid and
potassium bichromate, wash well with water and transfer
to alcohol.

EXAMINATION OF BACTERIA IN HANGING

DROPS.

This is intended to show the bacteria in the living
condition — their form and arrangement, presence or
absence of motion, the appearance of the protoplasm,
division of the cells, sporogenic granules, spores, etc.

MEMORANDA.

MEMORANDA.

— 13 —

Place a small drop of water in the center of a clean
cover glass. With a sterilized and cooled platinum wire,
which is fused into the end of a glass rod, 6 or 7 inches
long, transfer a minute amount of the bacterial growth
from the surface of one of the potato cultures, to this drop
of water. Place the cover-glass on a table or on a
block. Select a clean " concave slide " and apply a ring
of vaseline with a brush or stick to the edge of the
cavity. Invert the slide thus prepared over the cover-
glass with the drop and gently press down till the little
chamber is sealed air tight. The slide is now ready for
microscopic examination, and if properly made the drop
of water will be flat, and will not run when the slide is
placed on its edge.

Place the slide, with the cover-glass uppermost, on
the stage of the microscope, .and first find the edge of the
drop with a low power — No. 3 objective. If too much
light is present, constrict the diaphragm. The edge of the
drop should be seen as a sharp line passing through the
field of the microscope. Holding the slide between the
thumb and forefinger of the left hand, slowly move it so
that the edge of the drop constantly remains in the field.
In this way the entire edge or circumference of the drop
should be examined, chiefly for the purpose of practice in
moving a slide under the microscope. Owing to the min-
ute size of bacteria they cannot be seen under this mag-
nification. To observe the individual cells, therefore,
recourse must be had to the higher powers — No. 7 objec-
tive, or the -iV inch homogeneous oil-immersion objective.

Examination with No. 7 objective. — Having found the
edge of the drop with No. 3 objective, replace this by No.
7, by rotating the nose-piece. Then lower the tube of the
microscope by the coarse adjustment till the objective
almost touches the cover-glass. The field of the micro-
scope now is usually very dark, hence open the diaphragm
a trifle to admit enough light to see distinctly. With the
fine adjustment now raise the microscope tube till the
edge of the drop is brought out distinctly. By focussing

— 14 —

the edge carefully the bacteria will be readily detected.
Now move the slide as mentioned above, so as to examine
the entire edge of the drop, and also the center. Study the
characteristics of the microorganisms present.

In working with high powers, while focussing, it is
desirable to constantly hold the slide between the thumb
and forefinger of the left hand, imparting to it a slight
motion. If this motion is arrested it is due to pressure of
the objective, which has been lowered too far, and unless
the pressure is promptly relieved, damage may result.

Examination with A- homogeneous oil immersion
objective. — Having studied the bacteria in the hanging
drop with the No. 7 objective, replace No. 3 objective and
again find the edge of the drop. Now raise the tube of
the microscope, bring the iV objective into position.
Place a drop of cedar oil on the center of the cover-glass,
and lower the tube till the objective touches the oil. As
the field is now very dark open the diaphragm slightly.
Focus the edge of the drop with the fine adjustment,
holding the slide between the fingers of the left hand.
Examine carefully the bacteria present, their motion,
structure, etc., and also different parts of the drop in the
manner already indicated.

LABORATORY WORK. — Make hanging drops of the four
kinds of bacteria growing on the potatoes, and examine as
above. Too much time cannot be devoted to the work at
this point, as the practice thus obtained is indispensable
to the easy and successful manipulation of the microscope.

MEMORANDA.

MEMORANDA.

V.

REQUIREMENTS OF BACTERIA.

Bacteria, like all living cells, require certain nourish-
ing substances.

Absence of chlorophyll — inability to acquire carbon
from carbonic acid. Carbon, therefore, derived from pre-
formed carbon compounds — sugar, proteids, etc.

Nitrogen derived from organic and inorganic sources
--proteids, nitrates, nitrites, ammonia.

Presence of moisture necessary for growth.

Suitable reaction of medium — neutral or slightly alka-
line.

These conditions — solutions of organic nitrogenous
substances — widely distributed in nature. Hence the
occurrence of bacteria almost everywhere on the surface
of the ear tli.

Almost total absence of bacteria at high altitudes, in
air of mid ocean, and in deeper layers of the earth.

Absence of bacteria in organs and circulating fluids
of the healthy normal body.

Theory of spontaneous generation, the outcome of the
wide distribution of bacteria and lack of knowledge con-
cerning the resistance of bacteria and their spores. Its
overthrow.

Classification of bacteria according to habitat — sapro-
phytic and parasitic. No sharp line of distinction to be
drawn — facultative and obligative.

Temperature requirements. Each organism has its
minimum, optimum and maximum temperature for
growth.

In general the minimum temperature is about
15° C.; the maximum about 40°.

— 16 —

Optimum temperature of saprophytic bacteria,

that of the room, or summer, 25° to 30° C.
Optimum temperature of parasitic bacteria, that of

the body, about 37.5° 0.
Influence of cold — of heat, 70° and above.
Growth of some bacteria at 0°. At 50°, 60°, 70° C.
Injurious action of diffuse light, and especially of
sunlight.

LABORATORY WORK. — Continuation of that of preceding
day.

MEMORANDA.

MEMORANDA.

VI.
CHEMISTRY OF BACTERIA.

All living cells take in food, elaborate certain pro-
ducts and give off waste or metabolic products.
Production of,

Gases — Carbonic acid, hydrogen sulphide, nitro-
gen, etc.

Acids — Acetic, lactic, butyric, phenyl-propionic,
etc. Amido acids. Nitrous and nitric acids.

Alkalies — Ammonia, and its substitution com-
pounds, the amines.

Ptomaines — Alkaloidal compounds like the vege-
table alkaloids. May be poisonous (toxines)
and non-poisonous.

Proteids — Bacterial proteids may be highly
poisonous. Compare with the phytalbumoses
of plants, and the proteids in venom of ser-
pents.

Soluble ferments or enzymes — Analogy to the
soluble ferments of the animal body and of
certain plants.

Alcohols — Ethyl, propyl, butyl; phenol, etc.
Reducing powers — oxidizing powers.

Classification of bacteria according to function.
Zymogenic — fermentation bacteria.
Saprogenic — putrefaction bacteria.
Chromogenic — pigment producing bacteria.
A erogenic — gas producing bacteria.
Photogenic — light producing or phosphorescing

bacteria.

Fermentations as vital phenomena, the result of
activity of microorganisms, so-called organized ferments,

— 18 —

bacteria, yeasts, moulds, etc. ; unorganized or soluble fer-
ments (enzymes) produced by bacteria.

Alcoholic, acetic, butyric acid, etc., fermentations.

Ferment changes in the mouth — dental caries.

Abnormal fermentation in the stomach — in the intes-
tines, Summer diarrhoea of infants.

Ammoniacal fermentation of urine — Hydrothionuria.

Putrefaction is putrid fermentation — Proteids acted
upon whereas in true fermentations, starches, sugars, and
cellulose are acted upon.

Poisonous foods.

Liquefaction of albumin, gelatin, etc., by bacteria due
to soluble peptonizing ferments.

Liquefying and non-liquefying bacteria.

Inversion of starch by bacteria — coagulation of milk.

Nitrification in the soil.

Production of pigment, as a rule, is a secondary process,
taking place outside of the cell. The oxygen of the air
acts on a colorless or leuco-product.

Sometimes the pigment may be formed directly by
the cell — primary product.

Phosphorescence — the result of intracellular activities.

In fermentation and putrefaction more or less com-
plex, dead animal and vegetable substances are acted
upon by microorganisms; transformed into relatively simp-
ler compounds, and eventually into inorganic forms, as
carbonic acid, ammonia, nitrates, nitrites, etc., which are
now utilizable by living plants. Thus, lifeless remains
become indispensable to new life, and bacteria, in their
role of scavengers of nature, prove beneficial.

Certain bacteria may live on living matter in the ani-
mal body, and in plants, not only at their expense, but
even to their injury, producing changes which may result
in disease and death.

Division of bacteria into pathogenic and non-patho-
genic,—toxicogenic and non-toxicogenic.

MEMORANDA.

MEMORANDA,

l/U

— 19 —

STAINING OF BACTERIA.

Aniline dyes are commonly employed for this purpose,
and those which are used most frequently are fuchsine,
gentian violet, methyl violet, methylene blue, and vesuvin
or Bismarck brown. The first two are quite permanent,
stain rapidly and deeply and as a rule are to be preferred.
Methylene blue stains slowly and is excellent for special
purposes.

Saturated solutions in absolute or strong alcohol are
first prepared and serve as stock. These concentrated
solutions are only very rarely used as such. Ordinarily
they are diluted with water. For this purpose pour into
the small staining bottle (1 oz.), which is provided with a
pipette, some of the concentrated solution to a depth of
about i inch, then fill the bottle with water. This dilute
stain must be perfectly clear from cloud or precipitate,
and should not be transparent. The dilute stains do
not keep for any length of time owing to the deposit of
the dye. In such cases a fresh solution should be made.

SIMPLE STAINING OF COYER-GLASS PREPARATIONS.

Place a small drop of water on a cover-glass which is
held between the thumb and forefinger of the left hand.
The cover-glass must be perfectly clean so that when the
drop is subsequently spread over the surface with a plat-
inum wire, it will spread in a thin film and not gather into
minute globules. The drop of water taken should prefer-
ably be so small that when spread in a thin film over the
cover-glass, it will dry almost immediately, and thus
evenly cover the whole surface. Large drops of water by
drying slowly, tend to leave unsightly " shore-lines."

With a sterilized platinum wire pick up a minute
amount of the growth from one of the potato cultures and
touch the drop of water cautiously once or twice. Then
sterilize the wire, and when cool, spread the drop of water
evenly over the whole surface of the cover glass, avoiding,
however, contact with the fingers. In a few minutes the
water evaporates, and if desired, this may be hastened by
3

— 20 —

waving the cover glass, to and fro, over a flame, at a height
of 6 or 8 inches. Care must be taken not to transfer too
much material to the drop of water, for in such cases the
cover-glass on subsequent staining will be found to be one
mass of bacteria.

The cover-glass prepartion which has now been dried
in the air or over a flame, must be u fixed" before apply-
ing the staining solution. For this purpose, take hold of
the cover-glass with a narrow-pointed pair of forceps,
and pass it rapidly through the flame, from above down-
ward, keeping the specimen side up, away from direct
contact with the flame. If the exposure to the flame is
too long the bacteria may be so altered as to refuse to take
the stain subsequently, or at most poorly. On the other
hand, if not heated enough, the bacteria will readily wash
away on treatment with the dye, or with water.

As soon as the fixed cover-glass is cool, and while still
holding it in the forceps, cover the specimens with the
dilute aniline stain. Allow this to act for the necessary
length of time (i — ^— 1 min.) and then wash off com-
pletely by means of a syphon or bulb wash-bottle. Place
the cover-glass now on a piece of filter-paper, resting on
the right index finger, and rotate carefully till the lower
side is perfectly clean and dry. Now invert the specimen,
with the moist specimen side downward, onto a clean glass
slide. Sufficient water should be present to fill in the
space between the cover-glass and slide. Specimens
should never be examined dry.

Place the slide thus prepared on the stage of the
microscope and first examine with the No. 7 objective and
subsequently with the ^ homogeneous oil-immersion
objective, in the same way as was done in examining
hanging drops.

A good cover-glass should show the bacteria well
stained, not in masses, but separated from each other, and
evenly distributed over the entire cover-glass. If the
stained bacteria are seen to move about it is due to insuf-
ficient fixing in the flame.

MEMORANDA.

— 21 —

LABORATORY WORK. — Practice staining cover-glass
preparations made from the different potato cultures, em-
ploying the five aniline dyes mentioned above. Also
stain preparations made from the white matter on the
teeth, near the edge of the gums, and look for comma
bacilli, spirilla, and leptothrix threads.

To make permanent stained preparations, the speci-
men which has proven satisfactory on preliminary exam-
ination in water as above, can be floated off the slide by
first bringing a drop or two of water near the edge of the
cover-glass. If any oil is on the upper side it should be
carefully removed by rotating the cover-glass on a piece
of filter-paper. The specimen is then allowed to dry in
the air, or by gently waving over aflame. A clean glass
slide is then selected and a suitable drop of Canada bal-
sam placed in the center. The dry cover-glass is then
inverted, specimen side down, and carefully lowered until
it touches the balsam. If necessary, gentle pressure is
applied so as to cause the balsam to spread out under the
cover-glass.

The following synopsis will be of service :

Simple Stain. — Cover-glass preparation.
Air- dried.
3 x through flame.
Dilute stain (^ — 1 min.).
Water (and examine).
Air-dried.
Canada balsam.

GELATIN PLATE CULTURE.

Tha- object of this method, as with the dilution potato
culture already made, is to isolate the several kinds of
bacteria that may be present. The isolated organisms
developing in a solid, transparent medium, form colonies
which are easily perceived and from which transplan-
tations can be readily made. Pure cultures of the differ-
ent kinds of bacteria 'are thus obtained.

— 22 —

First, sterilize six glass plates by placing them in an
iron box and heating this in the dry heat sterilizer, at a
temperature of 150-175° 0., for one hour. Then remove the
box and allow it to cool.

PJace three of the sterilized gelatin tubes in a water-
bath which has been warmed to about 30-35° 0. When
the gelatin melts the tubes are ready for inoculation.
With a sterilized, cooled platinum wire pick up a minute
amount of the growth of the potato culture of Micrococcus
prodigiosus. Place one of the liquefied gelatin tubes
between the thumb and index finger of the left hand, so
that it is almost horizontal. The neck of the tube with
its plug, as well as the palm of the left hand, is turned to
the right. While still holding the platinum wire in the
right hand, grasp the cotton plug with the little finger of
that hand, and remove it by slight rotation. Now pass
the inoculated wire into the tube and thoroughly mix the
bacteria, thus introduced, with the gelatin. Then with-
draw the wire, replace the cotton plug, and sterilize the
platinum wire in a flame.

With a colored wax pencil mark the tube thus inocu-
lated with J. Likewise mark another liquefied gelatin
tube with 2. Place tube 1 in the left hand in the same
position as before, and then next to it, tube 2. Remove
the cotton plug of tube 2 and place it between the adjoin-
ing index and middle fingers. Then remove the cotton
plug of tube 1 and place it between the ring and little
finger. Now, with a sterilized cooled platinum wire, the
end of which is provided with a small loop, transfer a
loopful of gelatin from tube 1 to tube 2 and mix well.
Return the platinum wire to tube 1 and again transfer a
loopful of gelatin to tube 2. Repeat this once more, so
that all told, three transfers of inoculated gelatin have
been made. Replace the cotton plugs into their respect-
ive tubes, sterilize the platinum wire and set the tubes in
a tumbler having a layer of cotton on the bottom.

Mark a new liquefied gelatin tube with 3. Then place
2 in the same position in which No. 1 was just held, and

MEMORANDA.

MEMORANDA,

— 23 —

next to it place tube 3. Remove the cotton plugs and
place in their respective places as before. With the ster-
ilized cool platinum wire make three successive transfers
of gelatin from tube 2 to tube 3. Return the cotton
plugs to their tubes, sterilize the wire, and set the tubes
aside in the tumbler.

Each of the three gelatin tubes has now been inocu-
lated. Tube 1 usually has a very large number of bac-
teria, while tube 2 has less and tube 3 should have but a
small number, so that subsequently when colonies develop
these should be separated from one another by an appre-
ciable distance. It is necessary therefore, to take a very
minute amount of material for the inoculation of tube 1
in order to obtain good dilutions. In transferring gelatin
from one tube to another care must be taken to prevent
the wire from coming in contact with the neck or walls of
the tubes.

Prepare the ice plating apparatus for use and then
level it. Remove a sterilized glass plate from the iron
box by grasping the edges with two fingers ; place it upon
the ground plate of the ice apparatus and cover with the
bell jar. As soon as the plate is cool it is ready to receive
the gelatin. Before pouring the contents of the tubes
upon the plates it is necessary, as a matter of precaution,
to sterilize the neckof the tube. To accomplish this, cut
off the cotton which projects from the tube, push in the
plug a trifle, and then rotate the neck of the tube in a
flame till the cotton begins to turn yellow. As soon as
the neck oi the tube cools the gelatin can be poured. To
do this remove the cotton plug with a pair of forceps, ster-
ilized in the flame, and place it between the fingers of the
left hand. Transfer the tube to the right hand, raise the
bell jar somewhat and pour the gelatin onto the centre of
the plate. With the lip of the tube spread out the gela-
tin as rapidly and as fully as possible, avoiding, however,
the edges of the plate. Allow the gelatin to solidify
under cover of the bell-jar.

— 24 —

Prepare a " moist chamber" in the same way as for
potato cultures except that tap water may be used for
moistening instead of mercuric chloride. On three small
pieces of paper write the name of the germ or material,
the number of the plate and date. Now place a glass bench
on the bottom of the moist chamber and on it the label
for plate 1. Transfer the gelatin plate from the ice appa-
ratus to the bench. Pour the remaining gelatin tubes on
plates in the same manner as described and when cool
transfer to the benches which are arranged one above the
other, in the moist chamber. Each chamber can hold a
stack of six plates.

The moist chamber containing the plates is now set
aside for 1-2-3 days, during which time colonies will
develop and be ready for further examination.

LABORATORY WORK.— Make plate cultures of Micrococ-
cus prodigiosus and of Bacillus Indicus.

MEMORANDA.

MEMORANDA.

— 25 —

YJII.

EXAMINATION OF COLONIES.

In a greater or less period of time, varying usually
from 1 to 3 days, colonies develop on the plates, and as
soon as they become of suitable size they are ready for
examination. A careful study of the colonies on a plate
should first be made with the unaided eye. Several char-
acteristics of growth can often thus be recognized quite
early. Especial attention should be given to the form
and appearance of the colonies; the presence or absence
of pigment; liquefaction or non-liquefaction of gelatin,
etc. It should be remembered, however, that a given
organism may give rise to at least two kinds of colonies
which sometimes are quite different in appearance. Thus,
we may have surface colonies, and also deep colonies.
The former developing on the surface of the gelatin are
unhindered in their development, and may, therefore,
spread out and thus acquire peculiar characteristics, more-
over, having ready access to oxygen, pigment formation
and liquefaction will be first seen in connection with these
surface colonies. The deep colonies, on the other hand,
are surrounded on all sides by solid gelatin, and hence,
much the same resistance to growth will exist in all direc-
tions. The result is that deep colonies, as a rule, are
much alike in appearance. Thus, the form is usually
round or oval, with sharp edges, and the contents are
slightly granular and yellowish.

The plate should now be placed upon the stage of the
microscope and the colonies carefully examined with a
low-power — No. 3 objective. Further characteristics can
thus be brought out which have escaped the eye.

The study of the micro-organisms which compose the

— 26 —

colonies should now be made. This is done by making
hanging drop examinations and stained preparation accord-
ing to the directions already given.

The object in making plate cultures is to obtain colo-
nies which, since they are derived from a single cell, are
pure cultures of that organism. To perpetuate and keep
up the pure culture thus obtained, it is necessary to resort
to transplantation. For this purpose the colony to be
transplanted is touched with a sterilized and cooled,
straight platinum wire. A portion of the colony will
adhere to the end of the wire and can be transferred
to a tube of sterilized gelatin. The wire is usually pushed
down the centre of the tube, in which case we have what
is known as a stich or stab culture. The operation of
touching the colony is one that requires the greatest care
to prevent contamination with foreign colonies, or other
material, thus vitiating the pure culture. For this reason
it is always carried out under a microscope, and so far as
patience is concerned it certainly is not inaptly called
"fishing."

The gelatin plate is placed on the stage of the micro-
scope and, with the No. 3 objective, a suitable colony for
transplantation is selected. It is desirable to have but one
colony in the field of the microscope. A straight platinum
wire, previously sterilized and cooled, is held in the right
hand in the pen position. The hand is supported by rest-
ing the little finger on the right corner of the stage. The
platinum wire is then inserted about midway between the
front lens of the objective and the surface of the gelatin.
It is held steadily in this position, and on looking into the
microscope an indistinct shadow is seen. The wire is
slowly drawn back till the end of the shadow or indistinct
wire is directly over the colony. Should the wire in doing
this touch the objective or the gelatin it must be sterilized
at once and the operation repeated. When the end of the
wire has been brought over the colony, gradually lower
the point till it touches the colony or cuts it into two.

MEMORANDA.

MEMORANDA.

— 27 —

Now carefully remove the wire without touching the
microscope or some other portion of the gelatin. A tube
of solid gelatin is held in the left hand in an almost hori-
zontal position, the plug is then removed by grasping it
with the little finger of the right hand, and the platinum
wire, which has a small portion of the colony attached to
it, is slowly forced down the centre of the gelatin to the
bottom of the tube. The cotton plug is at once replaced,
the wire sterilized and the tube set aside.

The stich culture thus made is a pure culture and is
now labelled with the name of the organism and date and
set aside to develop. In a few days development takes
place along the line of inoculation and more or less char-
acteristic growth results.

The manner of growth should be daily observed.
Hanging-drop and stained preparations can, of course, be
made if desired, from tube cultures. When the gelatin
is very old, and hence too solid, it tends to split as soon as
the platinum wire is forced into it. This is remedied by
melting the gelatin and allowing it to re-solidify.

LABORATORY WORK. — Examine carefully the colonies
with the eye and under the microscope. Make hanging-
drop and stained preparations from the colonies. Prac-
tice "fishing" and make stich cultures from each of the-
different colonies.

The line of study of the Micrococcus prodigiosus and
Bacillus Indicus and of the various bacteria to be pres-
ently taken up, consists first, in making plate cultures.
Colonies are thus obtained, the characteristics of which
are to be thoroughly studied. Hanging-drop examination!
and stained preparation are next made, thus becoming;
familiar with the organism itself. Stich cultures in gela
tin are then made and also streak cultures on potato or
agar which will be presently described. Finally drawings
should be made showing the form of the colony, the form
of the organism, the appearance of the stich culture, etc.

4

— 28 —

Summarized then, each organism, subsequently de-
scribed, is to be studied by making —
Plates,

Colonies,

Hanging-drop examination.
Stained preparation,
Stich culture in gelatin,
Streak culture on potato, or agar, or both.
Drawings.

MEMORANDA.

MEMORANDA.

— 29 —

IX.
MODIFIED GELATIN PLATE CULTURES.

Several modifications of the Koch plate method as
just described have been introduced whereby the same, if
not better results are obtained with less apparatus. In
the plate method contamination not infrequently results
from exposure to the air while on the ice apparatus, or
subsequently when kept in the large, moist chamber. An
examination of one plate necessitates the exposure of the
remaining plates to contamination with the organisms in
the air. Furthermore, it not infrequently happens that
the gelatin on an upper plate undergoes liquefaction and
then drips over the edges of the plates on those below it.
To overcome these difficulties Petri introduced the use of
shallow dishes which are about 10 cm. in diameter.

Petri Dish Culture. — Place the Petri dishes in a wire
basket and sterilize in the diy-heat oven by heating I
hour at a temperature of 150-175° C., then allow to cool.
Inoculate three gelatin tubes with the organism to be
plated in the same manner as for ordinary plates. Cut off
the projecting cotton, sterilize the lip of the tube as before,
then pour the contents of each tube into one of the cool,
sterilized Petri dishes, properly labeled. Replace the
cover and gently tilt the dish from side to side so as to
cause the gelatin to spread evenly over the bottom. Allow
the gelatin to solidify, then set the dishes aside for colo-
nies to develop. When the colonies develop examine on
the stage of the microscope and transplant as with ordi-
nary plates.

In this method each dish constitutes a plate by itself.
It can be readily examined and the risk of contamination
is reduced to a minimum. In addition to that the use of

— 30 —

the ice-machine, plates, benches, plate boxes, etc., is done
away with.

Esmarck Roll- Tube Cultures. — In this method the
advantages of the plate method are secured without the
use of any extra apparatus, as plates or dishes. The
inoculated gelatin instead of being poured out onto steril-
ized plates or into dishes is solidified in a thin film on the
inside wall of the test-tube. Another advantage of this
method is that it is well adapted for those organisms
which grow very slowly, and require a week or two to
form distinct colonies. Desiccation of the gelatin can be
readily prevented in the roll- tube, whereas it is much
more difficult in plate or dish cultures.

Inoculate three gelatin tubes with the material to be
plated, in the usual manner. Then cut off the cotton
plug on each tube and cover the end with a rubber cap.
Place the tube in a horizontal position, or nearly so, in a
dish of cold, or ice-water and rotate it carefully until the
gelatin solidifies in an even thin layer over the inside wall
of the tube. Avoid contact of the gelatin with the cotton
plug. Now set aside in a cool place to develop and then
examine the colonies under a microscope and make trans-
plantations. The operation of fishing in this case will, of
course, require special care.

LABORATORY WORK. — Make Esmarch roll-tubes of
saliva (1 loopful); and of the Violet bacillus of water.

Make Petri dishes of the Red bacillus of water.

MODIFIED POTATO CULTURES.

The method of making potato cultures of bacteria is
open to much the same objections as the ordinary gelatin
plate method. Two modifications, analogous to the two
modified gelatin plate cultures, are commonly employed
and are excellently adapted for their purpose.
. . Esmarch Potato Cultures.— The Esmarch dishes,
which are about 6 cm. in diameter and 2cm. high, are ster-
ilized in the dry heat oven in the usual manner, and then
allowed to cool. A small, sound potato is selected and

MEMORANDA.

MEMORANDA.

rcKSIl

— 31 —

held with the thumb and forefinger of the left hand.
With a potato knife held vertically, the outer edge of the
potato is pared circularly. Two horizontal sections, one
upper and a lower one, are now made and the clean,
sound core of the potato thus obtained is slipped into a
sterilized Esmarch dish. Each dish is thus supplied with
a clean potato section. The dishes are then placed in a
steam sterilizer and steamed for f to 1 hour. The pota-
toes will then be sterilized and cooked.

The inoculation of the cold sterilized potato is made
in essentially the same way as in the ordinary potato
culture?. As each potato is in a small sterilized dish by
itself the risk of contamination is very small under care-
ful and rapid manipulation.

LABORATORY WORK. — Make dilution cultures of Micro-
coccus prodigiosus, using three of the Esmarch potato
dishes.

Test-Tube Potato Cultures. — These were introduced
independently and almost simultaneously by Bolton of
this country, Globig, of Germany and Roux of France.
In convenience and reliability of cultures, the method
leaves nothing to be desired.

Clean, plug and sterilize about 6 or 8 large test-tubes
(| x (> inches). Also clean several large potatoes and
place them in boiling water or in steam sterilizer for about
j of an hour. By means of a cork-borer, having nearly
the diameter of the test tubes, punch out a number of
cylinders from the cooled potatoes. Place these cylinders
on a clean piece of paper, trim off the ends and then cut
each cylinder diagonally into two pieces. Into each of
the sterilized test-tubes place one of these pieces of pota-
toes with the circular end lowermost. Each tube then
contains a piece of potato having an inclined surface.
Now sterilize again in a steam sterilizer for about f to 1
hour.

Instead of a cork borer an excellent substitute may
be obtained by cutting a test tube in two. By making
cylinders from previously boiled potatoes, the pieces in

— 32 —

the tubes remain perfectly white, whereas cylinders made
direct from the raw potato will frequently become discol-
ored by the subsequent heating.

The inoculation of the sterilized potato tubes is easily
done. If it is desired to obtain dilution cultures, that is,
colonies, this can best be accomplished by making several
parallel streaks on the surface of the potato with the end
of the platinum wire, if necessary repeating the inocula-
tion in two or three tubes, using the same wire.

When transplanting a pure culture, as a portion of a
colony, a single streak should be made along the middle
of the inclined potato.

LABORATORY WORK. — Make^streak cultures from the
colonies of the bacteria which have been studiedthus far.

MEMORANDA.

— 34 —
BACILLUS PRODIGIOSUS.

MONAS PRODIGIOSA OF EHRENBERG. MICROCOCCUS PRODIGIOSUS
OF OLDER WRITERS.

Origin. — Found on starchy substances, rice, potatoes,
moist-bread ; also on meat, albumin, milk, etc. May form
at times local epidemics, infecting foods as bread, meat,
sausages, with production of pink or red color. " Bleed-
ing" bread or wafers.

Form. — Short rod, slightly longer than its width.
May form short threads, especially in slightly acid media.
Usually sinirle or in pairs.

Motility. — Ordinarily shows no motion, except a
marked Brownian movement. In acid or very dilute media
appears to have slight motion.

Sporulation. — Has not been observed. Possesses
marked resistance to desiccation.

Anilin Dyes.— Stain readily.

Growth. — Very rapid.

Gelatin Plates.— Deep colonies, round or oval, with sharp border and
light brown color. Surface colonies irregular, rough border, granular, with
reddish centre, and surrounded by clear, liquefied gelatin.

Stich Cultures.— Rapid, funnel-shaped liquefaction, extending along
entire line of inoculation. Red scum forms on surface of liquid, eventually
settles and entire contents of tube colored bright red.

Streak Cultures.— On agar, forms abundant, moist, spreading growth,
having an intense red color which is non-diffusible. On potatoes, especially
rapid, slimy growth, with marked pigment production. The pigment, when
old, has a metallic fuchsine-like lustre. Odor of trimethylamine. On blood
serum, growth as on agar, with liquefaction.

Milk, — Growth takes place and the pigment is held in solution by the fat
globules.

Oxygen requirements. — Is a facultative anaerobe.
Pigment is formed only in presence of oxygen.

Temperature.— Grows best at ordinary room tem-
perature. In incubator ceases to form pigment, and may
temporarily lose this property, i. e., becomes attenuated.

Behavior to Gelatin.— Rapidly liqueties as result
of formation of soluble ferment. This liquefying property
may be diminished or temporarily lost by growth in acid
media.

Aerogenesis.— Strong odor of trimethylamine on
potatoes.

Pathogenesis. — No pathogenic power. Its soluble
products in large amounts may have a toxic action. The
cellular proteids may induce suppuration. Animals in-
susceptible to malignant oedema are rendered susceptible
by injection of B. prodigiosus. Rabbits inoculated with
anthrax are saved by injection of B. prodigiosus.

MEMORANDA.

— 36 —

BACILLUS INDICUS. Koch.

Origin.— Isolated in India from the contents of the
stomach of a monkey.

Form. — Small, narrow, very short rod with rounded
ends.

Motility.— Actively motile.

Sporulation. — Not definitely observed.

Anilin Dyes. — Readily stain.

Growth.— Is rapid.

Gelatin Plates. — Deep colonies are yellowish, with wavy contour. Sur-
face colonies grayish yellow, finely granular, with fibrillated borders. Show
movement of contents, rapidly liquefy and may show a light pink color.

Stich Cultures.— Rapid liquefaction along line of inoculation. Dense
flocculent growth settles on the bottom, and is grayish or light pink in color.
A delicate scum forms on the surface and is colored from a light pink to
brick red.

Streak Cultures.— On agar, forms a low, moist, spreading growth, which
usually is faint pink in color. On potatoes, the growth is low, not slimy as M.
prodigiosus,and the color is more marked than on other media. On blood
serum, liquefaction results with or without pigment production.

Oxygen requirements. — Grows best in the pres-
ence of air, but is a facultative anaerobe. Pigment pro-
duction depends upon the presence of oxygen.

Temperature.— The optimum is about 35° C. Pig-
ment absent in cultures that develop in the incubator.

Behavior to Gelatin.— Liquefies very rapidly.

Pigment production.— Varies greatly. May be
grayish to bright brick red. Usually is light pink, so
that present cultures may be considered to be attenuated.

Pathogenesis. — Has marked toxic action, and when
injected in large amounts into the abdominal cavity, or
into the veins of rabbits and guinea-pigs, proves fatal.
Rabbits develop marked diarrhoea and die in from 3 to 20
hours. On post-mortem the intestines show a severe
inflammatory condition of the mucous membrane and at
times ulcerations.

MEMORANDA.

— 38 —

BACILLUS RUBER OF KIEL.

J. BREUNIG. — BACTERIOLOGISCHE UNTERSUCHUXG DES TRIXKVVAS-
SERS DER STADT KIEL (iNAUG. -DISSERTATION) KIEL, 1888.

EM. LAURENT.— ANNALES DE L'INSTITUT PASTEUR IV, 464, 1890.

Origin. — Drinking waler of Kiel.

Form. — Rods about three to five or seven times as
long as wide.

Motility. — Somewhat motile, and the motion de-
pends on presence of oxygen.

Sporulation.--Not observed.

Anilin Dyes.— Stain readily.

Growth. — Rapid and abundant.

Gelatin Plates.— Deep colonies are oval, pale yellow, with wavy or even
border. The surface colonies are blood red in color, spread rapidly and have a
sinuous border; are surrounded by a clear zone and liquefy gelatin.

Stich Cultures. — Develop along the line of inoculation and liquefaction
takes place. The fluid becomes strongly colored and gas may form in the
deeper layers.

Streak Cultures. — On agar, at 30-35°, the growth is at first a pale rose, and
later becomes a brick red. On potatoes, at 30-35°, develop rapidly, forming a
purple red growth. At lower temperatures the color is less intense, and at
first is orange, later carmine red.

Milk.— At 35°, coagulation takes place in 24 honrs, without a trace of
coloration, due to rapid growth and production of acidity. At ordinary tem-
perature the coagulation takes place slowly and the fluid gradually colors.

Oxygen requirements. — Is a facultative anaerobe,
but requires oxygen to form the pigment

Temperature.— Grows from 10 to 42°C. The opti-
mum is 30-35°, and above this the growth ceases to be
colored. Direct insolation kills it in 5 hours. By exposure
of 3 hours is not killed but no longer produces the pig-
ment, i. e , becomes attenuated.

Behavior to Gelatin. — Liquefies gelatin quite
rapidly.

Aerogenesis.— Some gas bubbles may form in gela-
tin tubes.

Pathogenesis. — No action observed.

MEMORANDA,

— 40 —

BACILLUS RUBIDUS.

RED BACILLUS OF WATER.

Origin.— Water.

Form. — Long-, narrow rod; forms threads.
Motility.— Ac-lively motile.
Sporulation.— No spores observed.
Anilin Dyes.— Stain readily.
Growth. — Fairly rapid.

Gelatin Plates.— Small, yellow, finely granular colonies, with irregular
border. Liquefies gelatin.

Stick Cultures.— Liquefies gelatin slowly along line of inoculation. The
mass of bacteria settles to the bottom, colored yellowish brown, and a thin
folded scum forms on the surface.

Streak Cultures.— On ogar, thin, irregular bordered, slightly folded and
colored growth. On potatoes, the most characteristic growth is developed,
which spreads and lias a bright brick red color. On blood serum, liquefaction
takes place and red pigment forms.

Oxygen requirements.— Is aerobic.

Temperature. — Does not grow at the temperature
of body.

Behavior to Gelatin.— Liquefies.
Pathogenesis. — No effect observed.

MEMORANDA.

42 —

BACILLUS VIOLACEUS.

VIOLET BACILLUS OF AVATEIJ.

Origin. — Water of the river Spree at Berlin, and of
the Thames at London ; also in well water.

Form. — Long, narrow rods, about three times as long
as wide ; forms threads.

Motility. — Actively motile.

Sporulation. — Forms median spores.
Anilin Dyes.— React readily.
Growth. — Is moderately rapid.

Gelatin Plates.— Irregular colonies, with loose fibrillaled borders. The
center shows quite early a violet color. Liquefies.

Stich Cultures.— Funnel-shaped liquefaction along entire line of inocu-
lation. A violet sediment collects on the bottom, while the liquefied gekxtin
above is perfectly clear.

Streak Cultures. — On agar, forms a thin, moist, bright violet covering.
On potatoes, the growth is somewhat slow but very characteristic, forming a
bright violet, eventually dark covering On blood serum, the violet color is
produced and liquefaction takes place.

Oxygen requirements. — Is a facultative anaerobe.
Oxygen is necessary to pigment formation.

Temperature. — Does not grow at higher tem-
peratures.

Behavior to Gelatin. — Liquefies.
Pathogenesis.— Has no effect.

MEMORANDA.

— 44 —

BACILLUS FLUORESCENS PUTIDTJS. Fliigge.

FLUORESCING BACILLUS OF WATER.

Origin.— Putrid media, water.

Form.— Short, small rods, with rounded ends.

Motility. — Very actively motile.

Speculation.— No spores observed.

Anilin Dyes.— Stain readily.

Growth.— Rapid .

Gelatin Plates.— Deep colonies are small, round, finely granular. Surface
colonies spread rapidly and form at first a very thin plaque, with irregular,
wavy border, which shows markings. Later a bluish green color diffuses
through the surrounding gelatin. Odor of trimethylamine. No liquefaction.

Stich Cultures.— No growth in lower part of tube. Surface of gelatin,
covered with grayish white growth, while the fluorescing pigment gradually
diffuses downward into the gelatin.

Streak Cultures.— On agar, a moist, spreading growth. The agar becomes
colored, but later the color fades. On potatoes, a thin grayish or brownish,
moist growth lorms.

Oxygen requirements.— Aerobic.
Temperature. — Ordinary room temperature is best.
Behavior to Gelatin.— Does not liquefy.
Pathogenesis.— Without action.

MEMORANDA,

— 46 —

BACTERIUM PHOSPHORESCENS. Fischer.

THIS IS BUT ONE OF A NUMBER OF BACTERIA FOUND IN SEA-WATER

WHICH POSSESSES THE PROPERTY OF PHOSPHORESCING IN THE DARK.
PHOTOBACTEBIUM.

Origin.— In water of the harbor of Kiel, also on sea
fish.

Form. — Short, thick bacillus, with rounded ends;
sometimes almost a coccus. Usually in pairs, may form
threads. Involution forms soon develop.

Motility. — No motion.

Sporulation.— Not observed.

Anilin Dyes.— Slain readily.

Growth. — Moderately rapid, and the cultures show
a greenish phosphorescence in the dark.

Gelatin Plates.— Show small, white, glistening colonies, which do not
liquefy gelatin. The border is sharp, irregular, and contents are granular,
and show several concentric rings.

Stich Cultures.- -Granular growth along the line of inoculation, but is
most abundant on the surface, forming a thin grayish white covering. Even-
tually the gelatin is colored a yellowish brown.

Streak Cultures. — On agar, potatoes, etc., growth is limited to the line of
inoculation. Grows also well on fish, beef, bread, fats, etc.

Oxygen requirements.— Is a facultative anaerobe.
The production of light depends upon the presence of
oxygen, and is therefore most marked on the surface
growths. The intensity of the iight may diminish and
eventually become lost — attenuation. May be restored
by growth on suitable media, as salt fish, etc.

Temperature. — Does not grow in incubator.
grow at 0° C.

Behavior to Gelatin. — Does not liquefy.
Pathogenesis. — No effect on animals.

MEMORANDA.

— 48 —

SARCINA AURANTIACA.

ORANGE SAKCIXE.

Origin. — From air, weiss-beer.

Form. — Small, spherical cocoi, grouped in 2 and 4,
and also forming package-shaped masses.

Motility. — None.

Sporulation. — None.

Anilin Dyes. — Slain very easily and are likely to
over stain.

Growth.— Rather rapid.

Gelatin Plates.— Show round, sharp-edged colonies, which are granular
and of an orange-yellow color. Liquefy.

Rtich Cultures.— Liquefies gelatin along entire line of inoculation. Even-
tually an orange-colored deposit of bacteria forms on the bottom and the
liquid above becomes clear.

Streak Culture^ — ')n (if/or, forms a thick, orange-colored growth. On
potatoes, the pigment i.s excellently developed.

Oxygen requirements.— Is aerobic.
Temperature. — Higher temperatures unfavorable.
Behavior to Gelatin.— Liquefies rapidly.
Aerogenesis. — Not observed.
Pathogenesis.— Has no effect.

MEMORANDA.

— 50 —

SARCINA LUTEA. Schroter.

YELLOW SARCIXE.

Origin. — Air.

Form. — Larger cocci than the orange sarcine and
forms more perfect package-shaped masses.

Motility.— None.
Sporulation.— None.

Anilin Dyes. —React readily and are likely to over-
stain.

Growth. — Very slow.

Gelatin Plates.— Colonies develop very slowly as minute yellowish spots,
which show an irregular outline and are markedly granular. The colonies do
not liquefy gelatin.

SticJt Cultures. — Gi'owth is especially developed on the surface and ex-
tends but slightly down the line of inoculation. Lower half of tube is usually
free from growth. The color is bright yellow and in very old tubes liquefaction
slowly shows itself, so that eventually a bright yellow deposit forms on the
bottom while the liquefied gelatin above is perfectly cjear.

Streak Cultures. — On a<t«r, forms a very thick, moist, bright yellow cov-
ering. On potatoes, the growth is slow, with production of same color.

Oxygen requirements. — Aerobe.
Temperature. — May grow in the incubator.

Behavior to Gelatin.— Very slow liquefaction, ap-
pearing after lapse of a week or two.

Pathogenesis. — None.

MEMORANDA.

BACILLUS SUBTILIS. Ehrenberg.

HAY BACILLUS.

Origin. — In air, water, soil, feces, putrid fluids, and
in infusions of hay.

Form. — Lame, rather narrow rods, about 3 times as
long as wide, and with rounded ends. Forms threads.

Motility. — Actively motile. Has a flagellum at
each end.

Sporulation. — Forms large, oval spores at or near
the middle, without enlargement. Are highly resistant
and can be readily double stained.

Anilin Dyes. — Stain readily.

Growth. — Very rapid. At 21° 0. the division of a
cell has been observed to take place in 1£ hours, and at
35° in 20 minutes.

Gelatin Plates.— The surface colonies liquefy gelatin rapidly and exten-
sively and present a characteristic appearance. The central portion appears
as a grayish yellow, irregular mass, which enclose examination can be seen
to be made up of moving cells. The border of the colony is quite character-
istic. It consists of a dense zone of bacilli and threads, radially arranged, so
that the ends project outward, thus presenting a peculiar appearance— the so-
called "ray crown." .

Stick Cultures.— Very rapid liquefaction takes place along the entire line
of inoculation. White flocculent masses accumulate at the bottom while the
liquid above, at first turbid, becomes clear. On the surface a dense white
scum or zoogloea usually forms.

Streak Cultures. — On ayur, forms a grayish white, thick, folded scum.
On potatoes, develops excellently, and forms a moist, thick, yellowish-white
covering, which at first is velvety in appearance but later becomes dry and
granular, and contains spores as well as involution forms. On blood serum,
forms also a folded scum and liquefies.

Oxygen requirements. — Is aerobic.

Temperature. — Grows from 10 to 45°. Optimum
about 30°C.

Behavior to Gelatin. — Liquefies rapidly and exten-
sively.

Pathogenesis. — Has no pathogenic power. Large
numbers of spores injected into the blood soon disappear
and are taken up by the liver and spleen. They may be
stored up in these organs for 60 to 70 days and yet pre-
serve their vitality (Wyssokowitsch).

MEMORANDA,

— 54 —

BACILLUS MESENTEBJCUS VULGATUS.

Flugge.

POTATO BACILLI'*. A GKOl'P OF ' 'POTATO BACILLl" ARE KNOWN WHICH
ll.\\'E MANY CIIAIIACTKRISTIC.S IN COMMON.

Origin. — Widely distributed in the soil, on surface
of potatoes in feces, putrid fluids, water, milk.

Form. — Small, thick rods, with rounded ends, usually
in pairs, inny form threads.

Motility. — Actively motile.

Sporulation. — Readily forms median, round spores.
The spores of one variety of " potato bacillus" described
by Globig. shoved enormous powers of existence, with-
standing the action of steam-heat for 5 to 6 hours.

Anilin Dyes.— React easily.

Growth.— Rapid.

(,'i'Ut/in 7'Iott'x. — Show yellowish white, slightly granular colonies, with
irregular borders. Liquefy rapidly and extensively.

,S7/'>/< Cultures.— Growth occurs along the entire line of inoculation, but
liquefaction is more energetic in the upper part. The liquefied gelatin
remains turbi'd for some time and a thin, grayish, folded scum forms on the
top.

.S7/v«/r CtiUii'rt'N.—On ac/(ir, forms a dull white or grayish, folded growth.
On potato!*, the most characteristic growth develops. The surface is rapidly
covered with a thick, white, strongly folded, coherent growth. Later the
color become s ;i dirty brown or red.

Milk. — 1« coagulated.

Oxygen requirements. — A e robe.

Temperature. — ({rows at ordinary as well as higher
temperatures.

Behavior to Gelatin.— Liquefies rapidly.
Pathogenesis. — No effect observed.

MEMORANDA.

— 56 —

BACILLUS MEGATERITJM. De Bary.

Origin. — From boiled cabbage leaves.

Form. — Cylindrical rods, with granular contents, 3
to 6 times as long as broad, with rounded ends. Are
usually slightly bent and may form threads. Involution
forms common.

Motility. — Slow, amseboid motion. Lateral flagella.
Sporulation. — Forms median spores.
Anilin Dyes. — Stain readily, though irregularities
due to granular protoplasm may be seen.
Growth. — Rapid.

Gelatin Plates.— Colonies are at first irregular, small, yellowish masses,
but subsequently show marked radiating or branching forms, which soon
Mqnef y the gelatin .

Stick Cu Itures.— Rapid growth and liquefaction along the line of inocu-
iution. May show threads of bacteria penetrating outward into the solid gel-
atin. Eventually the gelatin is wholly liquefied and a flocculent mass accu-
mulates on the bottom; the supernatant liquid clears up without formation
of scum on top.

Streak Cultures.— On agar, forms a dull white or grayish covering. On
potatoes, grows rapidly as a thick, slimy, grayish white mass, which is rich in
spores and involution forms.

Oxygen requirements. — Is aerobic.
Temperature.— Optimum about 20°C. May grow
in incubator.

Behavior to Gelatin.— Liquefies.
Pathogenesis.— No effect observed.

MEMORANDA.

— 58 —

BACILLUS RAMOSUS.

ROOT OR WURZEL BACILLUS.

Origin. — Very common in earth ; occurs also in river
and spring water.

Form. — Rather large rod?, thicker than the Hay
bacillus; with slightly rounded ends. Threads common.

Motility.— Slowly motile.
Sporulation. — Large median spores occur.
Anilin Dyes.— Stains well.
Growth. —Rapid.

Gelatin Plates.— The colonies present a characteristic appearance, resem-
bling somewhat fine branching rootlets, hence the name. At first the colo-
nies are round, dark and with bristly borders. Subsequently the colonies
branch and ramify throughout the gelatin which is liquefied.

Stick Cultures.— Are also characteristic. Growth develops along the line
of inoculation and from this threads penetrate or radiate into the surround-
ing gelatin. The growth is more rapid at the top than in the lower parts of
the tube so that the appearance of an "inverted pine tree" results. Later
the gelatin is liquefied completely. The bacterial growth accumulates on the
bottom while the Ijquid above becomes clear and has a thin scum on the
surface.

Streak Cultures.— On agar, forms a grayish growth, spreading outward
from the streak so that the appearance often is not unlike thatof a centipede.
On potatoes, a slimy, whitish growth which develop spores.

Oxygen requirements.— Is aerobic.

Temperature. — Grows at ordinary temperature and
also in incubator.

Behavior to Gelatin.— Liquefies.

Pathogenesis. — Without effect, even in very large
doses.

MEMORANDA.

— 60 —

PROTEUS VULGARIS. Hauser.

INCLUDED IN THE BACTERIUM TERMO OF OLDER WRITERS.

Origin. — Very widely distributed. Is commonly
present in the putrefaction of animal proteids; has also
been met with in water, in meconium, in purulent ab-
scesses, and in blood and tissues of two cases of fatal
putrid infection of intestines.

Form. — Rods, of varying length, from short oval
forms to those which are 2 to 6 times as long as wide. It
is usually bent and grows in pairs; may also form twisted,
interwoven threads. Roundish involution forms are
common.

Motility. — Actively motile. Flagella very numerous
and lateral.

Sporulation. — Not observed, though cultures are re-
sistant 1o desiccation and retain vitality for many months.

Anilin Dyes. — Stain readily.

Growth. — Very rapid.

Gelatin Plates.— Rapid and extensive liquefaction of the gelatin. The
colonies are yellowish brown, with bristly borders, and in soft gelatin tend to
spread over the surface and assume peculiar figures. Detached portions of
colonies can be seen to move about— "swarming islets." Disagreeable odor
and alkaline reaction.

Stich Cultures. — Rapid liquefaction along entire line of inoculation, so
that in a few days the entire contents are liquefied. The fluid is at first dif-
fusely cloudy, but later clears up and a flocculent sediment settles on the bot-
tom, while on ihe top a grayish white layer is formed.

Streak Cultures.— On agar, forms a grayish, slimy, rapidly spreading
growth. On potatoes, it forms a dirty colored, sticky covering.

Oxygen requirements.— Facultative anaerobe.

Temperature. — Optimum lies between 20 and 24°.
Grows excellently in the incubator.

Behavior to Gelatin. — Rapidly liquefied.

Aerogenesis. — Forms hydrogen sulphide.

Pathogenesis. — Small doses have no effect. Injec-
tion of large quantities of cultures, or filtrates from these,
produces in rabbits and guinea-pigs toxic effects, and even
death may result. It is therefore toxicogenic, but not
pathogenic.

NOTE.— When surface colonies as those above present special character-
istic they can be reprinted on cover-glasses. To make such an impression or
"Klatsch" preparation, select a suitable spreading colony, wilh the aid of No
3 objective, then raise the lube of the microscope and carefully drop a clean-
cover-glass on top of the colony. Apply gentle pressure with a pair of forceps,
then grasp the edge of the cover-glass and carefully remove: allow to dry in
the air; fix and stain in the usual manner.

In making the reprint only the growth should adhere to the cover-glass.
Considerable gelatin, solid or liquid, on the cover-glass, is undesirable and
interferes.

MEMORANDA.

— 62 —

BACTERIUM ZOPFII. Kurth.

Origin. — From the intestines of chicken.

Form. — Rods, 2 to 5 times as long as wide. Forms
threads, which in gelatin are often peculiarly bent or
twisted.

Motility. — Actively motile.

Sporulation. — Spore-like bodies are formed, which
resist desiccation, but are readily destroyed by heat, and
are readily stained by anilin dyes.

Anilin Dyes. — Stain easily.

Growth.— Rapid.

Gelatin Plates.— The colonies form delicate cloudy patches of radiating
threads, and under the microscope show, in addition to the network of
threads, numerous rounded little masses or bunches of cells.

Stick Cultures.— Marked growth in the upper part of the tube and almost
absent in the lower part. Shows fine radiating lines which, at or near the
surface, penetrate deepest into the surrounding gelatin.

Streak Cultures.— On agar, forms a very thin, dry, grayish growth.

Oxygen requirements. — Is aerobic.

Temperature. — Grows best at ordinary temperature.
Can grow at 37-40°, but tends to develop involution forms
and to die out.

Behavior to Gelatin. — Is not liquefied.

Pathogenesis. — No effect on animals.

NOTE.— Make "Klatsch" or impression preparations of the colonies.

MEMORANDA.

— 64 —

SPIRILLUM RTJBRTJM. Von Esmarch.

Origin. — Isolated from the putrefied cadaver of a
mouse.

Form. — Clear, transparent, thick cells, which com-
monly are single, appearing as large bent rods or comma
bacilli (vibrio). May form spirals of 3 or 4 or even 40
windings. Involution forms are common in old cultures.

Motility. —Actively motile. Each end of a spiral
has one wavy flagellum.

Sporulation. — True spores not observed.
Anilin Dyes.— Stain slowly but well.
Growth.— Extremely s?o\v.

Gelatin Plate 8 — Owing to the very slow development of colonies ordinary
plates cannot be used. In roll tubes, colonies develop in from 7 to 10 days, and
at first are minute and grayish; later the center becomes tinged with pink
and eventually becomes red. The edge is smooth and contents finely
granular.

Stick Cu//?nvx.— Are the most characteristic. Growth takes place along
the entire line of inocukvtion, forming a row of colonies. The growth spreads
slightly on the surface and is colored a light pink. The pigment formation is
most marked along the stich— where oxygen is absent. It passes through a
light pink to a beautiful dark wine-red color. Ordinary bacterial pigments
are formed only in the presence of air and are secondary products, whereas
this pigment is formed in the absence of air and is primary.

Streak Cultures.— On agar, forms moist, thick, non-spreading patches,
which, when old, possess a light pink or red color, especially near the center.
On potatoes, develops slowly, forming minute deep red colonies. On blood
serum, the growth is much the same as on agar.

Milk. — In fluid.media, milk, bouillon, etc., forms long spirals.

Oxygen requirements.— Is a facultative anaerobe.

Temperature.— Grows between 16° and 40°. Opti-
mum about 37°0.

Behavior to Gelatin. — Not liquefied.
Pathogenesis.— Has no effect.

NOTE.— Make Esmarch Roll-tubes of the Spirillum rubrum.

MEMORANDA,

— 66—

BACILLUS ACIDI LACTICI. Hueppe.

BACILLUS OF LACTIC ACID FERMENTATION. IS ONLY ONE OF A LARGE
NUMBER OF BACTERIA GIVING RISE TO LACTIC ACID.

Origin.— Sour milk.

Form. — Short, thick rods, about one-half as long as
long as wide; usually in pairs, rarely in chains.

Motility. — Has no motion. Brownian movement,
however, is marked.

Sporulation. — Hound, terminal spores observed.

Anilin Dyes. — Stain readily.

Growth.— Abundant and fairly rapid.

Gelatin Plates.— The deep colonies are round or oval, yellow, sharp bor-
dered, finely granular. The surface colonies spread, forming thin plaques,
with irregular, wavy borders. The outer zone of the colony is at first almost
transparent and shows markings resembling the venation of leaves.

Stich Cultures. — Slight growth along the stich, but on the surface it is
considerable and spreads rapMly as in thin, dry, pearly-white covering. In
old cultures bundles of crystals form along the stich at or near the surface.

Streak Cultures.— On agar, forms a grayish white, moist, spreading
growth, which offers no. special characteristics. On potatoes, it forms a
brownish yellow, slimy covering.

31Wc. — In sterilized milk converts the lactose or milk-sugar into lactic
acid and carbonic acid. The acid reaction thus produced causes a precipita-
tion of the casein or curd. This change occurs only in presence of air.

Oxygen requirements. — Is a facultative anaerobe.
Temperature.— Grows between 10° and 45°. Opti-
mum about 35°0.

Behavior to Gelatin.— Not liquefied.

Aerogenesis. — Gas is produced in milk.

Pathogenesis.— No effect. 0.75 per cent, lactic acid
stops the growth. Production of lactic acid in the mouth
and dental caries ; abnormal fermentations in the stomach,
in the intestines. Lactic acid bacteria favor the growth
of anaerobic bacteria.

MEMORANDA.

— 68—

BACILLUS BUTYRICUS. Hueppe.

BACILLUS OF BUTYRIC ACID FERMENTATION. IS ONLY ONE OF A LARGE
NUMBER OF AEROBIC AND ANAEROBIC BACTERIA WHICH GIVE RISE
TO BUTYRIC ACID. THE VIBRION BUTYRIQUE OF PASTEUR
WAS THE FIRST ANAEROBE DISCOVERED (1861).

Origin.— Milk.

Form. — Lon •;, narrow rods, with rounded ends , fre-
quently in pairs, may form threads.

Motility. — Actively motile.

Sporulation.— At about 30° forms bright, oval, me-
dian spores.

Anilin Dyes.— React well.

Growth. — Rapid.

Gelatin Plates.— The deep colonies form yellowish masses, whereas the
surface ones liquefy rapidly and then form grayish-brown, granular patches
with fibri Hated borders.

Mich Cultures.— Rapid liquefaction along entire line of inoculation. The
gelatin becomes colored yellowish and on the surface a thin, folded, grayish
white scum forms. The liquid remains cloudy for some time but later the
growth settles to the bottom.

Streak Cultures.— On agar, forms a light, yellow, sticky covering. On
potatoes, forms a light brown, transparent growth which sometimes becomes
folded.

Milk.— Without change in the amphoteric reaction the casein gradually
coagulates, as with rennet. Subsequently after about 8 days the casein is
redissolved or peptonized with formation of pepton, leucin,tyrosin, ammonia
and bitter products. From hydrated milk sugar and lactates it forms butyric
acid.

Oxygen requirements. — Is aerobic.
Temperature. — Can grow at ordinary temperature,
but its optimum is 35 to 40° C.

Behavior to Gelatin.— Liquefies.
Aerogenesis. — Butyric acid formed.
Fathogenesis. — No effect.

MEMOEANDA,

— 70 —

BACILLUS CYANOGENUS. Fuchs, (1841).

BACILLUS OF BLUE MILK.

Origin.— In blue milk.

Form. — Small, rather narrow rod.5, with slightly
rounded ends, 2 to 3 times as long as wide. Frequently
grows in pairs, very rarely in threads.

Motility. — Very actively rnolile.

Sporulation. — Small terminal spores observed in
gelatin, milk, etc., at ordinary temperature.

Anilin Dyes.— Stain easily.

Growth. — Rapid.

Gelatin Plates, — The deep colonies are round with sharp, smooth border,
and yellowish granular contents. The surface colonies are moist, elevated,
convex masses, which are round, finely granular and dark colored.

Stich Cultures — Little or no growth in the lower part of the stich.
Spreads over the surface as a thick, moist, dark gray covering. A dark steel-
blue color diffuses downward into the gelatin. The shade of color varies with
the reaction of the medium. In neutral or acid media it is quite blue, whereas
in very alkaline media it is dark or even black. The cultures when old
become dark colored.

Streak Cultures.— On agar, forms a dirty gray, thick, moist covering,
and the medium becomes diffusely colored. On potatoes, it likewise forms a
thick, raised, slimy growth, which rapidly spreads and becomes colored. On
blood scrum, no color is formed.

Milk. — In sterilized milk it produces no acid or coagulation, but the
liquid becomes colored a slate gray which with acids turns blue, In unsteril-
ized milk, that is in presence of lactic acid bacteria, the color is sky-blue.
The color is developed from casein, not from lactose.

Oxygen requirements.— Aerobic.

Temperature. — Can grow at ordinary temperature,
or in incubator. The pigment is best developed at low
temperatures, 15-18°C.

Behavior to Gelatin. — Not liquefied.

Pathogenesis.— No effect on animals.

NOTE.— Make " Kiatsch " or impression preparations of the colonies.

MEMORANDA.

— 72 —

OIDIUM LACTIS.

DOES NOT BELONG TO THE BACTERIA, BUT IS A SIMPLE MOULD.

Origin. — Almost invariably present in milk and in
butler.

Form. — A delicate white mycelium of wavy threads.
No special fruit organ. Large oblong spores.

Anilin Dyes. — Eeact readily.
Growth. — Rapid.

Gelatin Plates. — Delicate white stars form, which rapidly enlarge, and on
the surface spread as flat, whitish, dry masses. Under the microscope the
colonies show radiating branched hyphse.

Stich Cultures.— Growth takes place along the entire line of inoculation,
but most abundantly at or near the surface. A branching network of threads
extends outward into the solid gelatin. On the surface a grayish white, dry,
low growth forms. In old cultures only the upper layer of gelatin shows the
radiating lines.

Streak Cultures.— On agar, it forms a grayish white, thin growth.

Milk.— Growth occurs without any change in its composition.

Temperature. — Grows best at ordinary temperature.
Can grow in inc.ubator.

Behavior to Gelatin. — Does not liquefy.
Pathogenesis. — No effect on animals.

MEMORANDA.

MEMORANDA.

— 73 —

BACTERIOLOGICAL, EXAMINATION OF
WATER.

The water to be examined must be received in a
sterilized bottle or flask, thoroughly protected against
subsequent contamination. Furthermore, in view of the
rapid multiplication of bacteria, a given sample of water
should be examined as soon as possible after collection.
The method commonly employed consists in the deter-
mination of the number of bacteria present in a given
volume, 1 c. c., and the recognition of the several species or
kinds of microorganisms present. This process, as carried
out, is as follows :

Place several 1 c. c. pipettes, graduated in 1-10 c. c.,
in a pipette box and sterilize in the dry heat oven in the
usual way. Liquefy 3 gelatin tubes and with a sterilized
cooled pipette transfer into tube No. 1 one c.c. of the water ;
into tube No. 2 place one-half c.c., and into tube No. 3 one
drop of the water. Gently agitate the contents of the
tubes, to secure complete mixture, then pour the gelatin
onto sterilized glass plates, observing the usual precau-
tions in making plate cultures. Set aside the gelatin
plates thus obtained for two or three days and then count
the colonies when sufficiently developed.

When only a small number of colonies are present
the counting can be done with the unaided eye, but when,
as it frequently happens, the number is very large, it is
desirable to make use of a counting apparatus — that of
Wolffhiigel is usually employed. The gelatin plate on
which the colonies are to be counted is placed on the
black glass base and covered with a glass plate ruled into
squares. The number of colonies under six or more
squares is thus easily determined, and in this way the

— 74 —

average number of colonies per square readily ascertained.
By determining the number of squares which the gelatin
on the plate covers, and multiplying this figure by the
average number of colonies per square, the total number of
colonies on the plate is found. Since each colony is derived
from a single cell this number then represents the number
of bacteria present in 1 c. c. or ^ c. c. or 1 drop of the
water. The number of bacteria found should always be
expressed as so many per c. c.

To ascertain the kind of bacteria present, the colonies
are examined under the microscope in the usual way. A«
seen from the preceding work the form of the colony
and its behavior to gelatin may sometimes assist in its
identification. Hanging-drop examinations, stained prepa-
rations and stich cultures will still further assist the
recognition.

The chief object of the bacteriological examination of
water is to determine the presence or absence of patho-
genic or toxicogenic bacteria. In the above method this is
done by recognizing the colony of the specific organism
sought for. When the pathogenic bacteria, as the cholera
or typhoid fever bacillus for example, are present in large
numbers, and this is very rarely the case, the identification
can perhaps be easily d*one. On the other hand a few
pathogenic bacteria in the presence of a large number of
saprophytic organisms can be easily overlooked, and in
such cases their recognition becomes well-nigh impossible.
In view of these facts the following method has been
devised and used in this laboratory since 1888. It is based
upon the fact that the majority of bacteria present in
water are common saprophytes which grow at the ordi-
nary temperature, cannot grow at the temperature of the
body, and cannot, therefore, produce toxic or pathogenic
effects. Further, that those bacteria which can develop
at the temperature of the body may or may not be patho-
genic, and this is ascertained by animal experiment. The
process as used is as follows :

MEMORANDA.

MEMORANDA.

— /o — -

To sterilized beef tea or bouillon tubes add 1 c. c., ^ c.
c., and one drop of the water by means of a sterilized
pipette. Set aside in the incubator at 37 to 39° C. for 24
hours. If no growth occurs at this temperature it is at
once sufficient evidence that the water is free from disease-
producing organisms. On the other hand, if growth
develops, injections of 1 c. c. of the culture are made intra-
peritoneally into white rats by- means of a sterilized Koch
syringe. The recovery of the animal indicates the absence
of pathogenic bacteria. If death occurs the toxic or
pathogenic form can be found arid isolated from the organs
and tissues of the animal (see anthrax).

When it is desired to examine snow or ice this should
be melted in a sterilized flask and the water thus obtained
is examined as above.

The number of bacteria present in water from various
sources is subject to the greatest variation. Thus spring
water may be sometimes wholly free of microorganisms,
but as a rule the number is less than 50 per c. c., and may,
in exceptional case«, contain 3,000 per c. c. In well
waters considerable variation has been observed, but
usually the number is less than 500 per c. c. The water
of deep wells may be said to be free of microorganisms.
The same may be said to be true of the water of lakes.
The number of bacteria present in river water varies from
a few hundred to as many thousand, but in the neighbor-
hood of large cities it may reach hundreds of thousands
per c. c. In Paris the river water in the wool-washing
stations has been shown to contain from 12 to 40 millions
per c. c.

LABORATORY WORK. — Make plate cultures of two
samples of water — tap-water and well-water. Also Petri
dishes of milk. The gelatin tubes are inoculated with
milk in the same manner as with water.

— 76 —

BACTERIOLOGICAL EXAMINATION OF SOIL.

The collection of samples of earth from various depths
can be readily accomplished by means of Fraenkel's earth -
borer. For each culture experiment a definite quantity
of the soil should be weighed out, or a measured volume
taken. The latter is the simpler procedure, and can be
done with a Loffler platinum spoon (1-50 c. c.) which
serves the purpose of a standard volume.

With a sterilized Loffler spoon transfer one spoonful
of the earth to a tube of liquid gelatin. Mix thoroughly
with a sterilized platinum wire and then make an Esmarch
roll-tube. The soil and the organisms present are thus
brought into perfect contact with gelatin, and after a lapse
of a few days colonies develop. These can be readily
counted, and, if necessary, with the aid of an Esmarch
roll-tube counter. The kind of organisms — bacteria,
mould?, etc. — can be determined by the study of the
colonies, and by further culture and examination.

In this wav it is easy to determine approximately
the number and kind of organisms present. Unfortunately
this method is not adapted for the detection of anaerobic
bacteria which are apparently widely distributed in the
earth, and are represented by the well-known bacilli of
tetanus, malignant oedema and symptomatic anthrax.
These have thus far been obtained only by indirect
methods from the soil. Thus animals are inoculated with
earth, and from the tissues and organs after death the
bacteria are isolated.

The surface layers of soil, to a depth of about two feet,
are exceedingly rich in bacteria. The number has been
found to vary from 100,000 to 350,000, and may even reach
several million, per c. c. The number rapidly decreases with
the depth, and at 9 to 12 feet the soil is practically sterile.

LABORATORY WORK. — Examine three samples of soil by
the above method.

MEMORANDA.

MEMORANDA.

— 77 —

BACTERIOLOGICAL EXAMINATION OF AIR.

To determine the number and kind of bacteria present
in the air is a problem of considerable importance, and can
be accomplished quite satisfactorily with Hesse's appara-
tus. The large, wide tube is sterilized, nutrient gelatin
introduced, and a large Esmarch roll-tube then made. The
tube thus prepared is connected with an aspirating bottle
of known volume. In this way a definite volume of air
can be drawn through the apparatus. The bacteria pres-
ent in the air are deposited on the moist gelatin walls of
the tube, and subsequently develop, forming colonies-
These are counted and the number of colonies per liter of
air is thus ascertained. The kind of bacteria present can
be determined in the usual way.

The method of Petri, though somewhat more compli-
cated, requires less time and gives excellent results. The
air is filtered by means of an aspirator or air pump through
a tube filled with sterilized sand. The sand, which then
contains the bacteria originally in the air, is transferred to
a Petri dish containing gelatin, thoroughly mixed, and set
aside to develop.

The number of bacteria present in the open air is very
small and rarely exceeds 3-4 per liter. Usually the num-
ber is much less than this. Spores of moulds are more
abundant in the air than are bacteria. Air of mid- ocean
and of high altitudes is practically free of microorganisms.

— 78 —

PREPARATION OF BREAD FLASKS.

Moist bread, like potatoes, owing to its slightly acid
acid reaction, is an excellent medium for the growth of
some organisms, especially moulds.

Prepare some dry powdered bread, which can be read-
ily done by over-toasting it in the dry-heat oven, and then
crushing or pulverizing the dry mass. Keep in a stoppered
bottle.

Clean, plug, and sterilize in the dry-heat oven six
small Erlenmeyer flasks. When cool cover the bottom of
the flasks to a depth of about ^ inch with the dry powdered
bread, then add water till the mass becomes thoroughly
moist and soft. Sterilize in steam sterilizer for three con-
secutive days, \ hour each day.

Inoculate the bread flasks with the following moulds :
Penicillium glaucum.
.Mucor corymbifer.

" rhizopodiformis.
Aspergillus niger.

" flavescens.

" fumigatus.

All these flasks, except the first, should be placed in
the incubator at about 37° C., for 24 to 36 hours. They
should then be examined for the characteristic fruit organs
and spores. Transfer a portion of the growth to a watch-
glass containing about 50 per cent, alcohol, to which a
drop or two of ammonium hydrate has been added. When
the growth becomes moist, transfer a portion to a drop of
glycerine on a slide. Tease out the specimen thoroughly
and carefully with needles or pins. Cover with a cover-
glass and examine with No. 7 objective the fruit organs
and the structure. If the specimen is satisfactory it may

MEMORANDA.

MEMORANDA.

— 79 —

be made permanent by placing a ring of asphalt, with the
aid of a turn-table, around the edge of the cover-glass.

Make Petri dishes of white yeast; Esmarch roll tubes
of red yeast and of black yeast.

Examine baker's or brewer's yeast (Saccharomyces
cerevisise) in hanging drop and in stained preparations.
Observe the form and structure of the yeast cell and the
method of multiplication — by budding.

MEMORANDA.

MEMORANDA.

— 82 —

PENICILLITJM GLAUCUM.

ONE OF THE MOST COMMON GREEN MOULDS.

Origin. — Widely distributed in the air, water, soil.
Color. — Green.

Mycelium. — Consists of horizontally arranged,
straight or slightly wavy, jointed mycelial threads from
which the fruit hyphge rise vertically.

Fruit-organs. --The ends of the fruit hyphae are
forked, and on the ends are the intermediate spore bear-
ers, or "sterigmae, also sometimes called basidia. Each of
these in turn bears a row of spores or conidia, so that the
appearance of the whole is that of a brush.

Gelatin plates. — The colonies form whitish floccules which rapidly
increase in size, and at the same time the center colors green. The gelatin is
liquified quite early. A low objective will show the above chai'acteristics of
growth.

Bread flasks.— Show a low, finely flocculent covering, which at first is
white but soon changes to a distinct green.

Temperature.— Optimum temperature is from 22
to 26° C. Does not grow at the temperature of the body.
Behavior to Gelatin.— Liquefies.
Pathogenesis. — Has no effect on animals.

Mi ]V:CIMM?A.

— 84 —

MTJCOR, CORYMBIFER. Lichtheim.

THE MOST COMMON AND WIDELY DISTRIBUTED MUCOR IS MUCOR
MUCEDO, OCCURRING ON EXCRETA, ETC.

Origin. — Is of rare occurrence, and was found as a
contamination on bread-gelatin plates. Is present in white
bread, and has been found in the ear-passages of man.

Color. — Forms a snowy, cotton-like growth.

Mycelium. — Loose, wavy, branching, slender mycel-
ial threads.

Fruit-organs. — The fruit hyphae branch forming
clusters or corymbs which terminated with spherical or
pear-shaped sporangia. Within these are the oval or
elongated spores.

Growth. — Rapid and extensive.

Bread flasks. — In the incubator forms a white, elevated, cotton-like
growth which soon fills the flask.

Temperature.— Grows slow at ordinary tempera-
ture; best at 37° C.

Pathogenesis. — Intravenous injection of the spores
into rabbits produces death in 3 to 4 days. The kidneys,
mesenteric glands, Peyer's patches contain mycelial
masses. The Peyer's patches are swollen and ulcerated.
Intraperitoneal injections produce the same results.
Dogs are immune.

MEMORANDA.

— 86 —

MUCOR RHIZOPODIFORMIS. Lichtheim.

Origin.— White bread kept at 37° 0.

Color.— At first white, but later becomes grayish.

Mycelium. — The mycelial threads are colorless and
thicker than in the preceding mucor, and are not jointed
or divided.

Fruit-organs. — The fruit hyphae occur in groups or
bunches, which adhere to the nutrient medium by means
of special root tufts. The large sporangia on the ends of
the hyphae contain rounded spores which are larger than
those of the preceding organism.

Growth. — Rapid.

Gelatin plates— Development is best when the gelatin is made with bread
infusion. It forms a coarse grayish-black mass which liquefies the gelatin.

Bread flasks. — The growth is lower than that of M. corymbifer, and is
grayish, owing to the dark colored sporangia. An ethereal or aromatic odor
is present.

Temperature. — Slow growth at 12 to 15°, but
develops best at 37° 0.

Behavior to Gelatin.— Liquefies.

Pathogenesis. — Has a similar effect as M. corymbi-
fer, but is more pathogenic.

MEMORANDA.

ASPERGILLUS NIGER. Van Tieghem.

Origin. — In putrid organic substances ; in lungs of
birds.

Color. — Black or dark brown.

Mycelium. — The arrangement is much the same as
in penicillium.

Fruit-organs. — The fruit hyphse are swollen or
flask or club-shaped at the end, and this enlargement is
covered willi radially arranged minute bottle-shaped
bodies — the intermediate spore bearers or sterigmse from
which rows of spores extend. Sterigmee divided.

Growth.— Slow.

Bread flasks —Forms a slow growth which becomes very black.

Temperature.— Its optimum is about 35° C.

Pathogenesis. — Intravenous injection of spores in
rabbits is not followed by as malignant results as with the
next two forms.

ASPERGILLUS FLAVESCENS. Wreden.

Origin.— White bread.

Color. — At first whitish, eventually pale yellow.

Mycelium. — The mycelial threads and spores are
smaller than those of A. niger.

Fruit-organs.— The club shaped ends of the fruit
hyphge are covered with sterigmae, from which extend
rows of spore?, as in A. niger.

Growth.— Rapid.

Bread flasks. — Grows best on bread. Forms a yellowish, low growth.

Temperature.— Optimum about 28° C. Grows well
in incubator.

Pathogenesis. — Is more pathogenic than A. niger,
and less than A. fumigatus.

MEMORANDA,

— 90 —

ASPERGIKLUS FUMIGATUS. Lichtheim.

Origin. — White bread. In the air passages of a bird.

Color.— Greenish or bluish green growth, resembling
very much that of penicillium.

Mycelium. — About same as preceding.

Fruit-organs. — About same as preceding, but spores
only about one-half as large.

Growth. — Is best on bread and is rapid.

Bread flasks.— The growth is low and at first is bluish green, but when
old is grayish green.

Temperature.— The optimum is 39-40° C. Can
grow at the ordinary temperature.

Pathogenesis. — Intravenous injections of spores in
rabbits and dogs produced death in a few days. Mycelia
are found in the kidneys, heart muscle and other muscles,
and occasionally in the liver.

MEMORANDA.

— 92 —

RED YEAST.

SEVERAL RED YEASTS ARE KNOWN. THE RED, WHITE AND BLACK
YEASTS ARE NOT TRUE YEAST-PLANTS.

Origin. — Very common in air.
Color.— Bed or pink.

Form. — Round [or oval cells with granular proto-
plasm which stains irregularly. Multiplies by budding-
distinction from bacteria.

Motility. — None.

Sporulation. — None.

Anilin Dyes. —Stain readily.

Growth. — Abundant, though somewhat slow.

Gelatin Plates. — Colonies are small, round, elevated, moist and pink-
colored.

Stich Cultures. — Growth absent from the lower part of the tube. Spreads
slowly over the surface, forming a thick, moist, bright red covering.

Streak Cultures. — On agar, develops in a few days as a thick, slimy,
spreadftig, pink-colored growth. On potatoes, forms the same pigment.

Temperature. — Grows best at ordinary temperature.
Behavior to Gelatin.— Does not liquefy.
Aerogenesis.— Does not produce alcohol.
Pathogenesis.— No effect on animals.

MEMORANDA.

— 94 —

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MEMORANDA.

MEMORANDA.

— 95 —

PREPARATION OF NUTRIENT BOUILLON
AND OF NUTRIENT AGAR.

Place 500 g. of chopped lean beef into a clean 1^ or
2-litre flask ; add 1000 c. c. of tap-water and insert a cotton
plug into the neck of the flask. Shake the flask repeatedly
during the next 15 or 30 minutes, then immerse in a water-
bath containing boiling water, and heat for 15 or 30 min-
utes. Filter through muslin, and to the filtrate or meat
extract thus obtained add

10 g. of dry peptone,
5 g. of common salt.

Warm in the water-bath for some minutes, then render
slightly alkaline by cautious addition of saturated sodium
carbonate solution. Continue heating in a water-bath,
with occasional shaking, for f to 1 hour, then filter through
a plaited filter— bouillon. The bouillon thus prepared
should be (1) perfectly clear; (2) should be slightly
alkaline in reaction, and (3) should not coagulate or cloud
on heating.

Take 100 c. c. of the bouillon and fill into sterilized
plugged test-tubes, using a small funnel, to a depth of
1 — 1^ \i\c\\e'&= ordinary bouillon.

To 100 c. c. of the bouillon add two per cent, of
glucose, warm till dissolved, then fill likewise into test-
lubes— glucose bouillon.

To the remainder of the bouillon (800 c. c.) add H to 2
per cent, of agar, previously cut up into very small pieces.
Place on a wire gauze and heat at just below the boiling
point (to prevent frothing) for2or3hours, till the agar has
completely dissolved. Then turn the flame low and con-
tinue heating for 1 or 2 hours, when the suspended matter
largely subsides to the bottom. Then filter by decaritation
9

— 96 —

through a layer of cotton placed in the neck of the funnel,
and it' the filtrate is not fairly clear, heat it to the boil-
ing-point and filter again through the same cotton filter.
The nutrient agar thus obtained should be (1) transparent
or semi-transparent ; (2) slightly alkaline in reaction, and
(3) should not coagulate or cloud on heating.

To 100 c. c. of the filtered agar add 6 to 7 c. c. of pure
glycerine, mix thoroughly; lest the reaction again to see if
alkaline, and then fill into sterilized test-tubes=^///cer^e
agar.

To 100 c. c. of the filtered agar add 2 per cent, of glu-
cose; warm till dissolved, then fill into sterilized test-
tubes to a height of about 1| to 2 \\\U\\QS= glucose ayar.

Transfer the remainder of the agar to sterilized test-
tubes^ ordinary agar.

Sterilize the bouillon and agar tubes l>y heating in
steam sterilizer, 4- hour each day, for three consecutive
days. At the end of the third heat place the agar tubes,
while still liquid, in a slightly inclined position, so that
the agar reaches to within 1 to H inches of the plug, and
allow it to solidify.

Instead of preparing an extract of fresh meat it is
sometimes more convenient to employ commercial meat
extract, such as Liebig's. In that case 2.5 g. of Liebig's
extract with the usual amount of peptone and common
salt is added to 100U c. c. of water. To this solution or
bouillon the ordinary proportion of agar or gelatin is
added, and the nutrient media are otherwise prepared in
exactly the same manner as already given.

When a perfectly transparent agar is desired it is, as a
rule, necessary to filter though paper. Thiscan be accom-
plished most rapidly by placing a filter-stand with funnel
and plaited filter, slightly moistened, in a steam sterilizer.
When the funnel is thoroughly heated the boiling agar
solution is transferred to the filter.

MEMORANDA.

MEMORANDA.

— 97 —

PATHOGENIC BACTERIA.

By the application of the gelatin plate method it is
possible to readily separate a given organism from other
forms which may be present and thus obtain a. pure cul-
ture. The isolated colony as it develops on a plate fur-
nishes the first pure cultivation since it is derived from a
single micro-organism. Transplantations made from a
colony, if made with proper piecautions, in turn yield
pure cultures or growths containing but a single species.
Tube cultures can thus be made in gelatin, bouillon, agar,
blood serum, potato, etc., and where it is desired, as in the
study of chemical products of bacteria, flask cultures can
be made.

It is evident that in order to demonstrate that a given
bacterium is the cause of a certain fermentation, or of the
production of some pigment or of phosphorescence, etc., it
is necessary that it should, first, be isolated and obtained
in pure cultures, and that, second, pure cultures of the
organism grown under the same or similar conditions,
should give rise to the original phenomena — the produc-
tion of the same fermentation, pigment, phosphorescence,
etc. Having thus demonstrated that a given organism is
the cause of certain changes it does not follow that this
organism has the exclusive power to do so. Thus, in alco-
holic fermentation the yeast plant is commonly said to be
the cause, but a large number of different species of yeasts
are known which have this power, and not only the
yeasts but many bacteria possess similar properties.
Again a considerable number of bacteria have been shown
to be capable of inducing acetic, lactic, butyric acid fermen-
tations, the ammoniacal and hydrogen sulphide fermen-
tations of urine, the phosphorescence of sea-water, etc.

The most that can be said of a given organism which

— 98 —

induces a certain change, therefore, is that it is the cause
in that particular instance. The possibility of other
organisms giving rise to the same changes, or effect, or
chemical products, must be conceded, and the demonstra-
tion of the relations of an organism to such a change rests
with the proof that it is a cause.

Just as there are organisms which induce changes
in dead animal or vegetable matter, there are others which
are capable of inducing similar changes in living animals
and plants, thus living at the expense and frequently to
the detriment of the host. The infectious diseases in man,
animals and plants, possess as an essential characteristic
the property of transmissibility. They are the result, first,
of infection that is the entrance of a specific micro organ-
ism, and second, of intoxication due to the poisonous pro-
ducts elaborated by the microorganism. Poisonous chem-
ical compounds may produce the symptoms and the
changes observed in an infectious disease. They are
the cause of those symptoms and changes, but they
are not the cause of disease, since the symptoms and
changes thus obtained are not transmissible from one
individual to another. Chemical substances have no
power of multiplication and the effect observed is, there-
fore, directly proportional to the amount of the chemical
compound introduced. Microorganisms, however, have the
power of multiplication, and the introduction of a minute
amount, even a single cell, may bring about entirely dis-
proportionate results. The invading organism is therefore
the cause of the disease since it imparts the characteristic
property of transmissibility, and, through the action of its
chemical products, produces the symptoms and effects of
that disease.

In order to positively demonstrate the causal relation
of a microorganism to a given disease, it is necessary to
meet the following requirements, commonly known as the
four rules of Koch :

(1.) The organism must be present in all cases of
that disease.

MEMORANDA.

MEMORANDA.

— 99 —

(2.) The organism must be isolated and obtained as
an absolutely pure culture.

(3.) The pure culture of the organism when intro-
duced into susceptible animals must produce the disease.

(4.) In the disease thus produced the organism must
be found distributed the same as in the natural disease.

To these four requirements, a fifth may be added,
namely: That the chemical products of the organism must
produce the characteristic symptoms and effects of that
disease.

The demonstration of the constant presence of an
organism in a disease is accomplished by hanging-drop
examination, stained cover-glass preparation, or by stain-
ing sections of tissues and organs. Frequently the direct
detection of the organism is difficult owing either to its
scarcity or to the absence of definite characteristics. In
such cases artificial, culture or animal experiment will
prove the presence of the organism.

The mere fact that an organism is constantly present
in a given disease does not prove that it is the cause of
that disease. It certainly is strong presumptive evidence
that the organism does bear a causal relation to that dis-
ease, but at the same time the possibility must be admitted
that it may be an accompaniment, or even a consequent
of ihat disease. To complete the chain of evidence it is
necessary, therefore, to obtain the organism in a pure
culture, and, inoculation of animals with such cultures
must reproduce the disease.

The isolation of the organism and the preparation of
pure cultures is accomplished by the gelatin plate method
or its modifications. The isolated colony which develops
on a plate is derived from a single cell, and is, therefore, a
pure culture. Transplantations from the colony, when
properly made, into tubes of gelatin, agar, or bouillon, in
turn are pure cultures. Subsequent transplantations from
tube to tube can be made as often as may be desired, or as
may be necesssary. Each growth thus obtained is called

— 100 —

a generation. In many cases, as in tuberculosis, anthrax,
and in hog cholera, the organisms have thus. been carried
through several hundred consecutive generations without
impairment of pathogenic properties. In other instances,
as in glanders, the organism does not find in our artificial
media the conditions favorable for its growth and as a
result it undergoes a physiological alteration so that the
cultures become less and less active till finally they cease
to have any effect on animals. This change in the physi-
ological properties of an organism — known as attenuation
—is frequently accompanied by a corresponding decrease
in the vitality of the growth so that, when the virulence is
wholly lost, the culture soon dies out. Sometimes, how-
ever, the organism adapts itself to the artificial media and
continues to grow although with diminished pathogenic
properties.

The above four rules have been fully complied with
in a large number of infectious diseases. In others the
first two rules ;ire s;itij-fied bill the third is nor, owing to
the difficulty of obtaining a susceptible animal. Ay:ain, the
first rule maybe ihoonly one complied with, as in leprosy,
where the isolaiio'i of the organism has not, thus far,
been unquestionably successful. And again a large
number of infectious diseases remain, in which even the
presence of a specific organism has not been definitely
shown.

Although many of the infectious diseases have been
shown to be due to bacteria, it must not be forgotten that
other low forms of plant and animal life possess sim-
ilar properties. Thus there are infectious diseases due to
fungi and also such as are due to animal parasites — sporo-
zoa, etc.

MEMORANDA.

MEMORANDA.

— 101 —

METHODS OF INFECTION.

1. — Cutaneous application.
2. — Subcutaneous application.

In mice and rats this can best be done on the back,

over the root of the tail.
3. — Subcutaneous injection.

The Koch syringe is commonly used. Pravaz

syringe.
4. — Intravenous injection.

The large veins in the ears of rabbits are frequently

used ; also the jugular and femoral veins.
5. — Intraperitoneal injection.
6. — Intrapleural injection.

7. — Injection into the anterior chamber of the eye.
8.— Infection along respiratory tract.

(a) Inhalation, (b) Injection into the trachea.
9. — Infection of alimentary canal.

(a) With food or drink.

(b) Through a stomach-tube — the contents of the

stomach are previously rendered alkaline.

(c) Intraduodenal injection.

The inoculation of animals with pure cultures of
microorganisms must be made with rigid precautions to
prevent the introduction of foreign organisms. At the
site of inoculation the hair must be carefully cut away ;
the exposed skin is then well washed with alcohol, and
finally is thoroughly moistened with mercuric chloride
(1-1000). The instruments employed in making the inoc
illations, as knives, scissors, forceps, lance, wire, etc., must
be sterilized in a flarne shortly before use. The Koch
syringe is sterilized in the dry oven. After having used
the instruments they are at once sterilized.

— 102 —

In working with the pathogenic microorganisms the
student must specially observe the utmost precaution
against personal infection. The rule to sterilize every
instrument shortly before, and immediately after use,
before it has left the hands, must be strictly attended to.
Direct contact of the hands with infectious matter must
be carefully avoided, and when such contact has taken
place prompt disinfection must be resorted to. On no
account must lead pencils or glass rods be held in the
mouth, or labels moistened on the tongue. Gelatin or agar
plates must be set aside for some hours in mercuric chlo-
ride (1-1000). Old tube cultures are best sterilized by
heating in the steam sterilizer for about one-half hour. If
by accident infectious matter is dropped on the table or
floor it must at once be covered with mercuric chloride.
At the close of the day's work the table must be well
washed with the mercury solution, and the hands
thoroughly disinfected.

MEMORANDA.

MEMORANDA.

— 103 —

POST-MORTEM EXAMINATION.

Demonstration of post-mortem on guinea-pig that
died aftor subcutaneous inoculation with the anthrax
bacillus.

The animal is placed on a board ; the feet are extended
and tacked or nailed down. The hair over the abdomen
and thorax is moistened thoroughly with a cloth soaked
in mercuric chloride. With a pair of sterilized forceps the
skin over the lower part of the abdomen is raised and a
slight transverse nick is made with sterilized scissors.
Into the opening thus made the lower blade of the scis-
sors is introduced and an incision is made along the median
line to the neck. While making the incision the skin is
kept raised by means of the forceps to. avoid cutting
through the abdominal or thoracic walls. At each end of
this incision lateral cuts are made in the direction of the
extremities, and the two flaps of skin, thus prepared, are
carefully reflected, thus exposing the entire abdominal
and thoracic walls. The condition of the subcutaneous
tissue, of the abdominal walls, of the blood-vessels and
the presence or absence of oedema, gas, etc., should be
noted.

The scissors and forceps are sterilized, and when cool
a similar incision is made into the abdominal wall and
extended through the cartilages of the ribs to the neck.
Special care must be taken to prevent cutting into the
intestines or internal organs. Lateral cuts are made as
before, and after nicking the. ribs on the inside of the thorax
close to the vertebral column, the entire abdominal and
thoracic walls can be reflected, thus exposing to view all
the internal organs. The condition of the abdominal and
thoracic cavities should be observed ; also the appearance
of the peritoneum, liver, spleen, kidneys, heart, lungs, etc.

10

— 104 —

With re-sterilized forceps and scissors (lie spleen,
kidneys, liver, etc., should be removed to sterilized Petri
or Esmarch dishes and can be used for subsequent exam-
ination.

In making post-mortem examinations the utmost care
must be taken to prevent the introduction of foreign
microorganisms, and at the same time to prevent- scatter-
ing any infectious matter, from the animal. For that
reason the hair on the skin is thoroughly moistened to
prevent it from flying about or entering the opening in the
body. The forceps, knives and scissors must be sterilized
in a flame for each separate incision. When blood or
pieces of tissue adhere to the instruments, they should not
be placed at once into the flame, otherwise the sudden
heating will cause the material to spurt and scatter about.
To avoid this the material should first be dried by holding
I he instruments close to the flame. This precaution should
also be observed when sterilizing wires which are covered
with gelatin.

LABORATORY WORK, WITH ASTHKAX TISSUE.

Isolation of the bacillus in pure culture. — The bacil-
lus of anthrax which is present in the blood, tissues and
organs of the guinea pig, must be isolated and obtained in
pure culture. This can be readily accomplished by the
gelatin plate method. For this purpose a small piece of
liver, about half the size of a grain of wheat, is cut off with
a sterilized pair of scissors. The piece of tissue is placed
on the loop of a sterilized platinum wire and transferred
to a tube of liquefied gelatin. By rubbing the piece
against the walls of the tube with the wire the blood can
be squezed out and the oigani-m piesent is thus spread
throughout the gelatin. From this tube, which is No. 1,
transfers are made in the usual manner to tube No. 2, and
from this to tube No. 3. Gelatin plates are then made in
the usual manner, and set aside for two or three days to
develop.

MEMORANDA.

MEMORANDA.

— 105 —

When the colonies develop their form should be care-
fully studied as it is very characteristic, and, if possible,
impression preparations should b6 made from the surface
colonies and stained with methylene blue.

As the colony is a pure culture of the anthrax bacillus,
transplantations to tubes in turn yield pure cultures. Make
a stich culture in gelatin and a streak culture on inclined
agar. This latter is made by simply drawing the end of
the platinum wire along the middle on the surface of the
agar. The agar tube is placed in the incubator at 37 to
39° G. for one or two days, then removed and examined.

Another agar tube is liquefied and -J to 1 drop of cal-
cium hydrate is added, thoroughly mixed, and the tube is
then set aside in an inclined position till the agar solidifies.
Then make a streak culture on this Ca (OH)2-agar, and
set it aside to develop in the incubator.

With the pure cultures of the anthrax bacillus thus
obtained the student can inoculate a number of white
mice, white rats and rabbits, and in these, after death, the
organism can in turn be detected and isolated. In this
way each one has an opportunity to demonstrate all four
rules of Koch with reference to anthrax, thus proving that
the anthrax bacillus is the cause of the disease.

MICROSCOPICAL EXAMINATION.

Hanging-drop. — Take a clean f -inch cover-glass and
pass it once through the flame. Transfer a small drop of
sterile bouillon to the cover-glass and then add to it, with a
sterilized wire, a minute amount of the heart-blood.
Apply the concave slide, ringed with vaseline, and
examine the hanging-drop, thus prepared, with the No. 7
objective. Study the characteristics of the anthrax
bacillus as it exists in the blood, and compare its size with
that of the blood-cell. Then label the slide and set aside
in the incubator for 24 hours. Examine the slide
on the following day and observe the formation of
threads, of sporogenic granules and possibly of spores.

— 106 —

Finally make permanent stained mounts of these threads
by transferring a small portion of this drop culture to a
minute drop of water on a clean cover-glass ; spread, dry,
fix and stain the preparation in the usual manner.

Stained preparations. — Place about two dozen clean
cover-glasses on the lid of a slide box. Pick up a piece of
the spleen, kidney or liver in a pair of forceps, and while
holding the cover-glass down with another pair of forceps,
lightly streak the cut surface of the organ over the cover-
glass. A very thin and even film is desirable. In this
way streak all the cover-glasses, then allow them to dry
in the air and fix cautiously by passing once or twice
through the flame. These cover- glasses are commonly
known as streak preparations.

Stain some of the fixed cover-glasses will) simple ani-
lin dyes, as gentian violet or i'uchsine ; examine and
study the specimens carefully and make permanent prep-
arations. The remainder of the cover-glasses will serve
for double-staining by Gram's method.

Gramas method. — This excellent method for demon-
strating the presence of certain bacterin, as anthrax, in the
fluids and tissues of the body is based upon the fact that
the protoplasm of the bacterial cell when stained with
anilin water-gentian violet, and then treated with iodine
forms a difficultly soluble compound. By proper exposure
to a solvent the dye can now be removed from the entire
cover-glass, but not from the bacterial cell. The deeply
stained violet rods lie on a colorless back-ground, which
on treatment with a contrast color, as eosine or picro car-
mine, becomes stained a light pink. The method is as
follows :

A solution of anilin water-gentian violet is first pre-
pared. Anilin oil is placed in a test-tube to a depth of
about half an inch. The tube is then filled with water,
closed with the thumb and thoroughly shaken in order to
obtain a saturated aqueous solution of anilin. The liquid
is then passed through a small filter and collected in

MEMORANDA.

MEMORANDA.

— 107 —

another test'- tube. The filtrate should be perfectly clear,
not cloudy. To the anilin water thus obtained a satu-
rated alcoholic solution of gentian violet is added till the
iluid is deeply colored.

Some of the anilin water-gentian violet thus pre-
pared is poured out into a watch-glass. A streak cover -
glass preparation of anthrax is now carefully fixed in tlie
flame. Care must be taken not t.o over-heat the specimen,
as the anthrax bacillus when over-heated does not stain
satisfactorily. The fixed cover-glass is then placed
between the thumb and forefinger, with the specimen side
down, and carefully dropped upon the surface of the stain
in the watch-glass. It is then allowed to float on the dye
for 10 to 15 minutes. Sometimes it is necessary to warm
the dye on the radiator or on an iron plate in order to
obtain a rapid and intense stain. The cover-glass is then
picked up with the forceps, thoroughly washed with
water, and immersed in a solution of iodine in potassium
iodide. This is made by dissolving 2 g. of potassium
iodide and 1 g. of iodine in 300 c. c. of distilled water.
The specimen is allowed to remain in the iodine for ^ to
1 minute, or even several minutes. Care must be taken
not to expose too long to the action of iodine, as it tends
to contract the protoplasm into granules. The cover-glass
is then removed from the iodine, washed with water, and
moved about in a watch glass of strong alcohol, to which,
if necessary, a drop of acetic acid may be added, to assist
the decoloration. From time to time the cover-glass
should be washed with water and examined with No. 7
objective to ascertain the progress in decoloration. When
finally a colorless back-ground is obtained for the deeply
stained violet bacilli the washing in alcohol is discontin-
ued. The cover-glass is then washed with water and
stained with dilute eosine for ^ to ^ minute. The eosine
is an acid anilin dye, and therefore stains the protoplasm
of cells, nuclei, etc., but not bacteria. Care must be taken
not to overstain the preparation with eosine, as it would

— 108 —

tend to diminish the sharp contrast that is desired. The
specimens after staining with the eosine is thoroughly
washed with water and examined under the microscope.
It should show the deeply stained violet bacilli on a light
pink back-ground.

Weigert's picro-carmine solution, or Bismarck brown,
can be also used for contrast colors. The Gram's method
is applicable to many pathogenic bacilli and to most
micrococci. A notable exception among the latter is the
gonococcus. The other important organisms that do not
stain with this method are the bacillus of typhoid fever,
of Asiatic cholera, of glanders, of chicken cholera, of
rabbit septicaemia; also Friedlaender's pneumo-bacillus,
and the spirillum of recurrent fever.

The following synopsis of the staining methods for
streak preparations will be of service:

Cover glass preparation.

Air-dried.

3 x through tlame.

Simple slain : Gram?s stain :

Dilute anilin dye Anilin water gentian violet

(i to | min.). (10 10 15 min.; if hot, 2 to

Water (and examine). 5 inin.).
Air-dried. Water.

Canada balsam. Iodine in potassium iodide

(| to 1 to 3 min.).
Water.
Alcohol.

Water (and examine).
Contrast color (eosine or

picrocarmine, few sec.).
Water (and examine).
Air dried.
Canada balsam.

The hanging-drop examination and the streak prepa-
rations stained by the simple and double method as

MEMORANDA,

MEMORANDA.

— 109 —

described, serve the purpose of demonstrating1 the pres-
ence of the anthrax bacillus in the different organs and
tissues of the body. The form, size, etc., of the bacillus
found under these conditions should be compared with the
growth of the organism in pure cultures in different
media. For this purpose make hanging-drop examina-
tions and permanent simple stains of the bacillus grown
in the stich culture in gelatin, on ordinary agar, and on
calcium hydrate agar. The preparation of impression
cover-glasses of the anthrax colonies and simple stains of
bouillon hanging-drop culture have been mentioned.

Double stain for spores. — The growth of the anthrax
bacillus on calcium hydrate agar when examined, as
mentioned above, in hanging-drop will show the presence
of an abundance of bright, highly refracting oval bodies,
or spores, which may be observed free and also within the
parent cell. Simple stains of this growth with fuchsine,
etc., will show the bacilli deeply stained, whereas the
spores remain colorless. This is undoubtedly due to the
dense impenetrable wall which surrounds the spores and
prevents the dye from passing into the spore, as well as to
a special composition of the spore contents. By proper
treatment with strong anilin dyes it is possible to force
the stain into the spore. Once within the spore it is as
difficult to remove the dye as it was to cause it to enter.
By suitable decoloration it is, therefore, possible to remove
the stain from everything on the cover-glass, except from
the spores. Then, on the application of a contrast color the
specimens will show a bright red spore within a blue
bacillus. The method of double staining of spores is as
follows :

The cover-glass preparation from the calcium hydrate
agar is dried in the air and fixed in the usual manner.
The cover-glass is held in the forceps, in the left hand,
with the specimen side up and covered with a solution of
carbolic fuchsine. This is held over a Bunsen flame, so
that vapors are given off from the liquid. Active ebullition

— 110 —

should be avoided. From time to time the liquid which
is lost by evaporation is replaced by a fresh addition of the
carbolic-fuehsine, and under no condition should the dye
be allowed to dry down on the cover-glass. Best results
in heating are obtained with the flame turned low, so that
it is not over two inches high. After heating the speci-
men in this manner for two or three minutes the stain is
thoroughly washed off with water and the cover-glass
examined wiih the No. 7 objective. Colorless spores
should no longer be visible, but everything should be
stained a deep red. If the spores are not colored the heat-
ing with carbolic-fuchsine is repeated until they become
stained. The cover-glass may be floated on hot carbolic-
fuchsine in an Esmarch dish for ^ to 1 hour.

The cover glass having deeply stained spores is then
moved about in dilute alcohol, and, from time to time,
washed with water and examined with the No. 7 objective.
As soon as the bacilli are decolored the washing in alco-
hol is discontinued. The specimen then shows bright red
spores within cells that are almost or wholly colorless.
The cover-glass is then stained for a short time with
methylene blue, washed with water and examined. The
spores should be stained deep red while the bacillus itself
should be light* blue.

Spores may be readily simple stained by passing the
cover-glass, after it has been fixed, 8 to 10 times through
the flame. Then the specimen is heated for 1 to 2 min-
utes with carbolic-fuchsine.

The carbolic-fuchsine solution known also as ZiehTs
solution, is prepared by adding 1 g. of fuchsine and 13 c. c.
of absolute alcohol to 100 c. c. of 5% carbolic acid. The
solution is heated on the water-bath until everything
dissolves and the solution has a clear bright red color.

MEMORANDA.

MEMORANDA.

— Ill —

SPORE STAINS.

Cover-glass preparations.
Air dried.

Simple:

12 x through flame.
Carbolic-fuchsine (hot

inin.).

Water (and examine).
Air dried.
Canada balsam.

Double:

3 x through flame.
Carbolic-fuchsine (hot 2 to

5 min ).

Water (and examine).
Dilute alcohol.
Water (and examine).
Contrast color (metbylene

blue, ]- to •£• min.j.
Water (and examine).
Air- dried.
Canada balsam.

2; to Metchnikoff's cellular
theory of immunity, the white blood cell is endowed with
the power of taking into itself, and ultimately destroying,
the invading organism. Phagocytic action can be readily
demonstrated in frog-* inoculated with anthrax. For this
purpose a pure culture of the amiirax baciilus is intro-.
duced into the dorsal lymph sac of a frog, and at the end
of 12 or 18 hours it is killed with chloroform.

Make cover glass preparations with the. fluid in the
dorsal lymph sac and stain some with simple anilin dyes
and others after Gram's method.

Pliagocytes. — Accordin;

i i

— 112 —

Summary of laboratory work with anthrax:
From guinea-pig :
Gelatine plates,

Colonies — Impression preparations.

Stich cultures — Hanging-drop and permanent

mounts.

Agar streak cultures — Hanging-drop and perma-
nent mounts.
Ca (OH)2-agar streak cultures — Hanging-drop

and permanent mounts.

Bouillon hanging-drop of blood — threads — perma-
nent mounts.
Streak preparations.
Simple stain.
Gram's stain.

From frog — phagocytes, simple and Gram's stain.
Spores — simple and double stain.

MEMORANDA.

— 114 —

BACILLUS ANTHRACIS.

Davaine. Pollender. (1849).

SYNONYMS OF ANTHRAX. — SPLENIC FEVER (IN CATTLE) : WOOL-SORTER* S

DISEASE, MALIGNANT PUSTULE (IN MAN) ; MILZBRAND (Germ.} ;

CHARBON., SANG DE KATE (/*>.).

Origin. — In the blood and tissues in anthrax.

Form. — Large, clear, homogeneous rods, with slightly rounded
ends ; si/e varies witli different media, but the length is less
than the diameter of a blood cell. Occurs in blood in short threads
of 2-4-0 cells, which may show slightly swollen ends. In bouillon
and on agar forms long threads. Involution forms.

Motility. — lias no motion.

Sporulation — Forms median, oval spores, without enlarge-
ment of cell. Alter long cultivation it may lose the property of
forming spores — asporogenic variety. I; such cases the addition of
fo-1 drop of Cu(OH)2 to an agar tube favors spore formation.
Optimum temperature, 30° C. Not formed below 18° C. Spores
possess variable resistance. Spores not formed within the body.

Anilin Dyes. — Stu.n readily, also by Gram's method.

Growth. — Is rapid.

<;<'lii/iti !'!«(cs. — Deep colonies form round, granular, yellowish-brown
masses, with irregular borders. Surface colonies are very characteristic, and
according to the consistency of the gelatin the border is fibril I tiled, or shows
very wavy strands of threads— Medusa head. Liquefy.

Mich Cultures.— .Short threads radiate from the line of inoculation into
the surrounding" gelatin, imparting a brush-like appearance. Cup-shaped
liquefaction forms on top and gradually extends till the contents are wholly
liquefied. The mass of bacteria settles to the bottom and leaves a perfectly
clear solution above, without scum.

Streak Cultures. — On agar, forms a dry, grayish-white growth On
potatoes, the growth is abundant, white, cream-like and rather dry; spores.

Oxygen requirements. — Is aerobic, but can grow in the body
as a facultative amierobe.

Temperature. — Grows between 12 and 45° C. Optimum :>7 .

Behavior to Gelatin. — Liquefies.

Attenuation — By heating for ten minutes at 35° C. ; ^-1
minute at 100°. By growing at 42.5° for four weeks. By action of
chemicals, mercuric chloride, carbolic acid, etc. By insolation. By
growth under pressure. In the body of immune animals, as frogs.

Immunity. — Obtained with attenuated cultures, first and
second vaccine of Pasteur; with sterilized cultures; with extract of
thymus gland and of testes.

Pathogenesis — White mice, guinea-pigs, rabbits, sheep, cat-
tle, horses and man are susceptible. Dogs, old white rats, birds
and frogs are insusceptible. Subcutanec us application kills in 24-
48 hours. Post-mortem shows subcutaneous oedema and enlarged
spleen. Bacilli everywhere.

Infection. — (1) Through the food, presence of spores, — Intes-
tinal anthrax in sheep and '.attle. (2) Through wounds, — Inocu-
lation anthrax in man (malignant pustule), (3) Through the air, —
Lung anthrax in man, the wool-sorter's disease and possibly rag-
picker's disease.

MEMORANDA.

— 116 —

BACILLUS OF SYMPTOMATIC ANTHRAX.

Feser and Bellinger (1878).

SYNONYMS OF SYMPTOMATIC ANTHRAX. — BLACK LEG, QUARTER EVIL;
CHARBON SYMPTOMATIQUE (Fr.) ', RAUSCHBRAND (Germ.}.

Origin. — In the subcutaneous tissue, muscles, serous exudate,
etc., of symptomatic anthrax.

Form. — Rather large, narrow rods, with distinctly rounded
ends ; almost invariably single, may form in twos. About three
times as long as wide. Involution forms appear in old cultures —
swollen in the middle or at the ends.

Motility.— Actively motile. Spore bearing rods eventually
lose their motion. Shows lateral flagella, also giant whips.

Sporulation. — Spores develop readily in all media as bright
oval bodies, situated near one end which is somewhat enlarged.

Anilin Dyes.— Stain readily. Not by Gram's method. Spores
readily double stained.

Growth. — Rapid, and gives off a strong butyric acid odor.
Acid or alkaline. glucose media are best. Requires anaerobic con-
tions.

Plates. — On gelatin, forms irregular masses surrounded by a dense whorl
of threads. Liquefies. On ayar, the form of colonies varies. Usually appears
as a dense mass of threads.

Stick Cultures.— In glucose gelatin development takes place in the lower
part of the tube; the contents are liquefied and gas is produced. Energetic
growth and gas production in glucose agar. The contents of the tube are torn
into several parts. Giant whips common. (NovY.)

Streak Cultures. — On glucose cigar, in hydrogen forms a whitish spread-
ing film. On blood serum good growths; giant whips (Loftier).

Bouillon.— Becomes cloudy; gas bubbles accumulate on the surface;
-after several days the growth settles to the bottom, forming a compact,
adherent sediment. Liquid above remains cloudy for several days.

Glucose gelatin, colored with litmus, develops growth in incubator
under ordinary conditions. The color of the litmus changes to a wine-red,
•showing formation of acids. Heavy flocculent sediment on the bottom.

Milk.— The casein is coagulated. Starch is not inverted.

Oxygen requirements. — Is an obligative anaerobe. Grows in
vacuum, hydrogen, carbonic acid, etc.

Temperature. — Grows slowly at ordinary temperature. Best
at 37-38° C.

Behavior to Gelatin.— Liquefies.

Aerogenesis. — Energetic production of gas, having a disagree-
able odor; is inflammable and consists of marsh gas, etc.

Attenuation. — Bouillon cultures soon lose virulence but main-
tain their vitality. Attenuation takes place at 42-43°. Spore bear-
ing material heated to 80° and 100° becomes attenuated. Virulence
•restored by inoculating animals, and at same time injecting some
•lactic acid. Virulence maintained in solid media.

Immunity. — Can be obtained (1) by inoculating small
amounts of virulent organism ; (2) by intravenous injections; (3)
by injecting heated cultures, 100° and 80° C. ; (4) with inactive old
•cultures; (5) with filtered cultures.

Pathogenesis. — Young cattle, sheep, goats, guinea-pigs are
highly susceptible. Horse, ass, white rat are less so; while hogs,
dogs, cats, ordinary rats, rabbits, doves, ducks, chickens are wholly
immune. Subcutaneous injection in guinea-pigs produces death in
24-48 hours. An extensive subcutaneous oedema is present. The
muscles are dark and infiltrated.

Infection. — Takes place naturally by inoculation through
wounds ; not through the food or air. Poisoned arrows used in
fishing in Norway.

MEMORANDA.

— 118 —

BACILLUS CEDEMATIS MALIGNI.

Pasteur. (1877).

VIBRION SEPTIQUE OF PASTEUR. SYNONYMS OF MALIGNANT (EDEMA. —

SEPTICEMIE (Fr.); MALIGNES ocDEM (Germ.).

Origin.— From animals inoculated with garden soil; from
horse and from man (septicemie gangretieuse).

Form. — Rods about three times as long as wide, with rounded
ends; usually single, but may form threads, especially in the body.
In size, etc., resembles the bacillus of S. anthrax ; is narrower than
anthrax bacillus.

Motility. — Actively motile. Show lateral flagella; also giant
whips (NovY).

Sporulation. — In bouillon and agar, spores appear in 24 hrs.
The best temperature is about 37° C. The spores are median or
nearly so, with corresponding enlargement of the parent cell.

Anilin Dyes. — React readily. Is stained by Gram's method.
Spores stain double.

Growth — Is very rapid, especially on glucose media. Requires
anaerobic conditions.

Plates. — On gelatin, colonies develop in 2-3 days, and under the micro-
scope resemble those of the Hay bacillus. As they become larger gas bubbles
form. On agar plates at 37° the colonies appear as an irregular, dense net-
work of threads.

&lich Cultures. — In gelatin, growth occurs in the lower part of the tube;
the gelatin is liquefied, gas given off and the growth settles on the bottom.
Agar cultures are torn into several parts by the gas which is formed. In the
liquid on the bottom of the tube, giant whips can be found by staining.

Streak Cultures.— On agar, offer no special characteristics. Grows on
potatoes without forming a scum.

Bouillon.— Becomes cloudy, and in 1-2 days the growth settles on the
bottom as a low, adherent sediment, and in a few days the liquid becomes clear.

Glucose gelatin, colored with litmus.— In air at 37° C. is liquefied and
litmus first reduced, then in presence of oxygen Becomes red — acid production.

Milk.— Develops a good growth; a part of the casein is precipitated.
Starch is not changed to sugar.

Oxygen requirements.— Is an obligative anaerobe. Grows in
vacuum, hydrogen, carbonic acid, etc.

Temperature. — Growth is best at the temperature of the body.
Can grow at ordinary temperature.

Behavior to Gelatin — Liquefies.

Aerogenesis. — On glucose media, especially when distinctly
alkaline, it gives rise to the production of gas.

Attenuation. — Bouillon cultures retain virulence for months.

Immunity. — One attack of malignant (edema does not protect
against a second. 100 c. c. of heated or filtered cultures injected
into guinea-pigs in three portions confers immunity ; 6-8 c. c. of the
serous exudate accomplish the same result.

Pathogenesis, — Rabbit susceptible — distinction from sympto-
matic anthrax. The horse, hog, dog, cat, chicken, dove, guinea-
pig and mice are susceptible. Cattle are immune. Subcutaneous
inoculation in guinea-pigs of % c- c- or more of bouillon culture
produces death in about 24 hours. Marked subcutaneous, spread-
ing, reddish oedema. Bacilli present, single or in threads, in subcu-
taneous tissue, serous surfaces as peritoneum, etc. ; scarce in the
blood. 25-30 c. c. of the filtered bouillon culture, injected subcu-
taneously, kills guinea-pigs.

Infection. — Takes place exclusively by inoculation through
wounds. Poisoned arrows of the New Hebrides. Rag-picker's
disease.

MEMORANDA,

_120 —

BACILLUS CEDEMATIS MALIGNI, NO. II.

Novy. (1893).

Origin. — From guinea-pigs inoculated with milk nuclein
obtained from casein by digestion with artificial gastric juice.

Form.— In the animal body it occurs usually in single rods, 4-5
times as long as wide ; may also' occur in short threads. On arti-
ficial media it develops as straight or bent rods, sometimes forming
peculiarly twisted threads. The contents are often granular, and
show a bright body at one end.

Motility. — Possesses a slight swaying motion, which is often
absent. Has lateral flagella, and in pure culture, as well as in the
animal, it gives rise to giant whips which may attain a length of
40-50-72 microns.

Speculation.— Spore formation not observed.

Aniliii Dyes. — Stain readily. Gram's method applicable.

Growth. — Depends upon the vitality of the organism. When
taken from an animal it grows rapidly.

Plates:— On glucose agar good colonies develop in 2-3 days at 37° C.
Show a very irregular, fibril ated border, and often give rise tongas bubbles.
May contain giant whips.

Stick cultures.— Develop only in the lower part of the tube. In glucose
agar having proper alkalinity, it develops rapidly, forming a plainly visible
growth along the line of inoculation; the agar is soon torn into several parts
by the gas that is produced. Cultures soon die out.

Streak cultures.— Develop on glucose agar only when oxygen is com-
pletely excluded-. It forms a white film which spreads over the surface. On
acid agar involution forms develop.

Bouillon.— An excellent growth develops which in 24 hours settles to
the bottom as a loose, flocculent sediment; the liquid above becomes clear.

Glucose f/elatin, colored with litmus. — Is liquified and acid is produced —
the litmus is turned red.

Oxygen requirements. — Is an obligative anaerobe. Grows in
vacuum, hydrogen, nitrogen, carbonic acid, illuminating gas.

Temperature. — Does not grow below 25° C. Optimum temper-
ature about 39° C. Can withstand freezing for 24 hours.

Behavior to Gelatin. — Liquefies.

Aerogenesis. — In alkaline media gives rise to gases. Volatile
acids, as butyric acids, etc., are formed in artificial culture and also
in the body (of rabbits).

Attenuation. — Cultures left in hydrogen, or exposed to light,
lose their virulence. Is not attenuated when left in the dark or
when frequently passed through animals. Lost virulence can be
reconstituted by inoculation with a "mixed" culture containing
Proteus vulgaris.

Immunity. — Not conferred by a non- fatal inoculation, or by
old, weakened cultures, or by the serous exudate of the pleural
cavity.

Pathogenesis. — Subcutaneous injection of % c. c. of hydrogen
bouillon cultures kills guinea-pigs, rabbits, white rats, white mice,
doves, in 12-24 hours. Marked subcutaneous cedema present;
serous exudates in thoracic and abdominal cavities. Cover-glass
preparations made from the subcutaneous tissue, or serous surfaces,
as peritoneum, shows usually enormous numbers of bacilli, and
frequently giant wrhips are also present.

MEMORANDA.

— 122 —
BACILLUS TETANI. Nicolaier (188-4J.

SYNONYMS OF TETANUS. — LOCK JAW ; \\TNDSTARRKRAMPF (Germ.}.
TETANOS — (Fr.).

Origin. — Found in animals that diedof tetanus after inoculation
with earth ; from traumatic tetanus of man and animals ; from
head-tetanus.

Form. — Large, narrow rods with rounded ends ; frequently
forms threads.

Motility. — Is motile. Simple stains with gentian violet of old
agar culture may show long spirals.

Sporulaticn. — Occurs rapidly, in 24-48hours at 37° C. Forms
terminal spores, with enlargement— drum-sticks.

Anilin Dyes. — Stain rapidly. Gram's method is applicable.
Spores can be double-stained.

Growth — Pure cultures obtained by heating the spore-bearing
material to 80° C., to destroy the ordinary bacteria. Growth slow.

Plates.— At ordinary temperature colonies develop in gelatin in 4-7 days,
and resemble those of the Hay bacillus or Proteus. The gelatin is slowly
liquefied and gas produced. On agar plates the colonies appear as fain't
clouds which, under the microscope, are seen to be made up of a whorl of
threads which are finer than those of other anaerobes.

Stich cultures.— Development restricted to the lower part of the tube.
Cultures of glucose gelatin lubes show along the line of inoculation a cloudy
growth, radiating outward into the surrounding gelatin; resembles that of
the Root, bacillus. Eventually the gelatin is liquefied. Gas bubbles present.
In glucose agar at 37° C. the growth is sometimes indistinct and shows radi-
ations.

Streak cultures.- -On glucose (tf/nr develop rapidly.

Houillnn. At :>7° becomes diffusely cloudy and remains so for several
days; eventually the growth settles to the bottom, forming a scarcely visible
sediment— distinction from preceding anaerobes.

Glucose geldfin colored with litmus.— At "7° C. becomes liquefied; a
very small sediment forms, and the culture remains blue, showing absence of
acid formation— distinction from preceding.

Milk — Grows well in milk without inducing any change. Does not
invert starch.

Oxygen requirements. — Is an obligative anaerobe Grows in
vacuum, hydrogen, nitrogen, and carbonic acid.

Temperature. — Does not grow below 16° C. The optimum is
about 38° C.

Behavior to Gelatin. — Liquefies.

Aerogenesis. — Gives rise to gaseous products, also disagree-
able penetrating odor. Hydrogen sulphide.

Attenuation. — Partial loss of virulence by culture. Thymus
bouillon attenuates.

Immunity. — Iodine trichloride; thymus bouillon cultures;
blood serum of artificially immunized rabbits, horse, sheep, dog ;
milk of immunized goat.

Pathogenesis. — Man, horse, sheep, guinea-pigs, young cattle,
goats, white mice and white rats, are susceptible. Rabbits and
dogs are less susceptible. Ducks and chickens are immune. The
bacillus is present at the point of inoculation, although in small
numbers. Intensely poisonous products. The filtered bouillon
culture in a dose of 0.0002 c. c. kills mice, and 0.002 c. c. kills
guinea-pigs.

Infection. — Occurs through wounds, Poisoned arrows of the
New Hebrides.

MEMORANDA.

MEMORANDA.

— 123 —

CULTURES OF ANAEROBIC BACTERIA.

Obligative anaerobic bacteria, those which grow only
in the absence of oxygen, require special conditions for cul-
tivation. Their growth is favored by the addition of 1 to 2
per cent, of glucose to the nutrient, medium, whether gel-
atin, bouillon or agar. Freshly prepared media are, as a
rule, best adapted for culture purposes.

The numerous methods which have been proposed for
obtaining growths of anaerobic bacteria can be classified
under the following heads:

(1.) Exclusion of oxygen.

(2.) Exhaustion of air.

(3.) Absorption of oxygen.

(4.) Displacement of air.

(5.) Cultures apparently in the presence of air.

The well-known method of Liborius, of culture in
deep layers of gelatin or agar, depends upon the exclusion
of air. The method is .simple and very convenient. The
culture-tubes contains glucose agar or gelatin, l|-2 inches
high. Stich cultures are made in the usual manner.
Growth develops in the lower two-thirds of the medium,
while the upper layer of J to £ inch serves to exclude the
air. In order to insure complete exclusion of oxygen, the
contents of an ordinary agar orgelatin tube can be lique-
fied and then, with proper precautions against contamina-
tion, poured on top of the inoculated medium and quickly
cooled. This extra layer is, as a rule, unnecessary.

Colonies of anaerobic bacteria can be obtained by
making ordinary gelatin or agar plates, and then placing* a
sterilized glass plate on top to exclude oxygen.

Vacuum cultures are frequently resorted to. Gruber's

— 124 —

tubes with constricted necks are commonly employed for
this purpose. The air is pumped out, after the medium is
inoculated, and the tube is then sealed in a llame.

The absorption of oxygen can be accomplished by
means of an alkaline solution of pyrogallic acid. In
Buclmer's method the inoculated tube is placed within a
larger tube, which is closed with a rubber stopper, and
which contains on the bottom the pyrogallate solution.

The displacement of air by some inert gas, as hydro-
gen, is frequently made use of in cultivating anaerobic
bacleria. Special tubes, as those of Li bonus, have been
introduced for this purpose. A current of hydrogen is
passed through the inoculated tube until all the air has
been displaced, after which it is sealed in a ilame. Plate
cultures in hydrogen can be readily obtained with Botkin's
apparatus — a bell jar inverted over liquid paraffin, or
mercury.

Cultures of anaerobic bacteria can be readily obtained
by inoculating glucose gelatin tubes, colored with litmus,
and placing them in the incubator. Although the con-
tents of the tubes are liquid, and apparently the air has
free access, yet energetic growth takes place. These cul-
tures preserve their vitality for a considerable period of
time and have the additional advantage of being readily
accessible.

The most convenient method for obtaining cultures in
a vacuum, or in an atmosphere of any desirable gas, is to
use some form of bottle in which the ordinary culture tubes
can be placed, and the exhaustion or displacement of air
carried out. Fig. 1 shows such a bottle, which is provided
with a special stopper through which a current of gas, as
hydrogen, carbonic acid, etc., can be passed. The bottle is
sealed air-tight by merely turning the stopper through
ninety degrees. Fig. 2 shows a simple and eilicient form
of bottle in which the same result is obtained by means of
two glass stop-cocks.

Ordinary test-tubes containing glucose gelatin, bouil-

Fig. 1.

12

Fig.

MEMORANDA.

— 125 —

Ion, agar, etc., are inoculated in the usual manner. The
projecting part of the cotton plug is cut off close to the
mouth of the tube, and the plug slightly raised, with
sterilized forceps, to facilitate diffusion of the gas. The
tube is then placed in the bottle by means of a pair of
long forceps and the apparatus connected with a Kipp's
hydrogen generator. The current of hydrogen should be
passed first through an alkaline solution of lead acetate,
and then through a six per cent, solution of potassium
permanganate. After passing through the apparatus the
gas passes through a small wash-bottle containing water,
which serves as a valve. If carbonic acid is used it should
be passed through a saturated solution of sodium carbonate.
A rapid current of gas is passed through the bottle for 1 to
2 hours, it is then sealed by turning the stopper, and set
aside in the incubator to develop.

The apparatus can also be used for vacuum cultures,
in which case it is connected with a Chapman aspirator
and the air pumped out. The alkaline pyrogallate method
can be employed with excellent results. — (NovY, Central-
Uatt fur Bakteriologie, 14, 581, 1893).

By far the easiest and simplest method for obtaining
plate cultures of anaerobic bacteria is that devised also in
this laboratary. The apparatus, which has the form of a
desiccator, is provided with the special stopper seen in
the bottle, Fig. 1. Petri plates are placed in the appara-
tus, hydrogen is then passed through for 1 to 2 hours,
and finally it is sealed by turning the stopper.

LABORATORY WORK. — Liquefy four glucose agar tubes
by heating in the water bath ; then allow to solidify in an
upright position. When cool make deep stich cultures of

Bacillus of symptomatic anthrax.
Bacillus of malignant oedema.
Bacillus of malignant oadema, No. II.
Bacillus of tetanus.

— 126 —

If the agar in the tube is less than one inch high, it
will be necessary to pour on top, after inoculation, the con-
tents of another agar tube, taking care to sterilize the
mouths of both tubes. Set aside the inoculated tubes in
the incubator for 24 to 48 hours. The cultures are then
examined in hanging-drop. Simple stains are made, also
double stains of spores. The drop or two of liquid which
sometimes accumulates on the surface of the agar, and
invariably on the bottom of the tubes can be stained for
ordinary nagella and for giant-whips.

Make the following cultures at the same time as the
preceding :

(1) Streak culture on inclined glycerine agar of the
tubercle bacillus, using either a pure culture, or a tubercle
from a guinea-pig inoculated with tuberculosis. Spread
the material thoroughly over the surface of the medium.

(2) Streak culture on ordinary inclined agar of the
Achorion Schonleinii — the fungus of favus.

(3) Streak culture on ordinary inclined agar of Actin-
omyces — the fungus of lumpy-jaw.

After these three inoculations have been made the
cotton plug of each tube is cut off close to the mouth of
the tube, and this is then sealed either with a rubber cap,
or with sealing wax, or with paraffin of a high melting
point, 56° C. The sealed tubes are then placed in the
incubator for several weeks.

STAINING OF FLAGELLA.

In order to obtain good stains of nagella special care
must be given to the preparation of the cover-glasses. These
must contain as little organic matter as possible in order
to prevent the formation of a dirty precipitate on the
cover-glass. Excellent cover-glasses can be made by
dilution. A small loopful of the turbid fluid from the
bottom of the agar tube culture of (Edema bacillus No. II,

MEMORANDA.

MEMORANDA.

— 127 —

or from that of the Bacillus of malignant oedema, is trans-
ferred to a large drop of distilled water in the center of a
wide cover-glass. By means of a straight platinum wire,
three transfers are made from this drop to another drop of
distilled water on a second cover-glass. This second
cover glass will now contain only a small number of
bacteria and very little foreign matter. By means of a
platinum wire, with a very small loop, not much larger
than a pin-head, transfers can now be made to t> or 8 clean
wide cover glasses. Each small loopful is spread at once
over as much of the surface of the cover-glass as possible.
The thin film of liquid evaporates almost immediately,
and the cover-glass can then be fixed by passing it once
through the flame. Overheating the cover-glass is very
likely to destroy the slender flagella.

The cover-glass, with the specimen side up, is held in
a pair of forceps and covered, by the aid of a pipette, with
Loffler's mordant solution. The cover-glass is then held
over the flame, which should be turned low, for about a
minute. The liquid should be warmed so as to give off
vapors, but should not be actually boiled. As fast as
evaporation takes place fresh mordant solution should be
added, and at no time should it be allowed to dry down
on the cover-glass.

The mordant must then be thoroughly and completely
washed off the cover-glass by a jet of water. If the edge
has dried down, it should be loosened with a pin or knife
and then washed off. To still further clean the cover-
glass, it should be dipped for a few seconds in absolute
alcohol and again washed with water.

The mordanted cover-glass is then covered with a satu-
rated solution of anilin water fuchsine, or with carbolic
fuchsine, and heated over the flame for 1 to 2 minutes,
observing the same precaution as before. The specimen
is then thoroughly washed with water and examined with
the -i1/ inch oil-immersion objective.

— 128 —

Summary for staining flagella :

Dilution cover-glass preparation.
Air-dried.
1 x through flame.
Mordant, hot (1 to 2 min.).
Water.

Alcohol (few seconds).
Anilin-water fuchsine, hot (1 to 2 min.).
Water (and examine).
Air-dried.
Canada balsam.

The mordant employed is prepared by dissolving 20 g.
of tannic acid in 80 c. c. of distilled water. To 10 c. c. of
this tannic acid solution, add 5 c. c. of ferrous sulphate
solution (1-2), and 1 c. c. of saturated alcoholic solution of
fuchsine.

The stain employed is made by adding 4 to 5 g. of
fuchsine to 100 c. c. of anilin water (p. 106). Both mor-
dant and stain should be kept warm while in use.

MEMORANDA.

MEMORANDA.

MEMORANDA.

— 130 —

EXAMINATION OF SPUTUM FOR THE TUBERCLE BACILLUS.

Ziehl-Neelsen Method. — A ]oopful of the sputum is
transferred to a wide cover-glass and thoroughly spread
over the surface. It is then allowed to dry in the air, or
by moving it to and fro over the flame, and then fixed in
the usual way. The cover-glass is held in the forceps,
specimen side up, and covered with carbolic fuchsine solu-
tion. It is warmed over the flame for 1 to 2 minutes,
avoiding actual ebullition, and then washed with water.
The specimen is now dipped in dilute nitric acid (a watch-
glass is filled with water and 3 or 4 drops of nitric acid
added), for a few seconds. Then transferred to dilute
alcohol (60 to 70X), where it is moved about till it is
almost decolored. After this it is washed with water and
stained for a few seconds with methylene blue. The lat-
ter is washed off with water and the specimen examined
under the microscope. It should show the tubercle bacil-
lus stained bright red, on a light blue back-ground.

Heavily stained preparations can be obtained by
floating the prepared cover-glass on the carbolic-fuchsine
solution for 15 or 30 minutes, then decoloring, as before.

Cover-glass preparation.

Air-dried.

3 x through flame.

Carbolic-fuchsine, hot, (1 to 2 min.).

Water.

Dilute nitric acid (few seconds).

Dilute alcohol.

Water.

Methylene blue (i to % min.).

Water (and examine).

Air-dried.

Canada balsam.

A 2 per cent, aqueous solution of anilin hydrochloride
can be used to excellent advantage instead of the dilute
nitric acid.

MEMORANDA.

— 132 —
BACILLUS TUBERCULOSIS. Koch. (1882).

TUBERCLE BACILLUS.

Origin. — In tuberculosis of mammals. Lupus vulgaris. The
bacillus, present in chicken tuberculosis is distinct from that in
mammals.

Form. — Very narrow, rather long rods which are smaller than
the diameter of a red blood cell. The ends are distinctly rounded
and the bacillus itself may be straight or more frequently is slightly
bent or nicked. Occurs usually single but may form short threads
of 3-6 cells. In the sputum, tissues, etc., is" frequently found in
small bunches.

Motility. — Has no motion.

Sporulation. — Frequently shows a number of bright bodies
within the cell, but these cannot be considered as true spores.
.The bacillus itself possesses a relatively high power of resistance to
heat, desiccation, acids, putref action, etc.

Anilm Dyes — Stains very slowly and difficultly with simple
anilin dyes; readily with hot carbolic-fuchsine, or anilin-water
fuchsiue or gentian violet. When once stained it is difficult to
decolor, whereas ordinary bacteria do so readily. Specimens from
sputum and tissues can therefore be readily double stained — dis-
tinction from all known bacteria, except the leprosy bacillus. Can
be stained by Gram's method.

Growth. — Takes place very slowly, requiring usually several
weeks to become clearly visible. Furthermore, a special tempera-
ture, at or near that of the body, and special media as blood-serum
or glycerine-agar, etc., are necessary.

Plntes — .No growth has been obtained on plates. Colonies can be readily
obtained by making successive streaks on glycerine-agar or blood-serum.
Colonies obtained direct from the sputum are round, white, opaque, and raised,
resembling colonies of white yeast. On subsequent culture the colonies are
dry, grayish scales. Under the microscope they appear as interwoven,
twisted strands of threads.

Stick Cultures.— Can be obtained on glycerine-agav. Growth restricted
to the upper part of the tube. It spreads over the surface as a thick, raised
plaque which at first is white, but later becomes yellowish.

Streak Cultures.-— On glycerine agar or blood-serum eventually develops
an abundant dry, granular, raised growth, which at first is grayish, but later
takes on a light yellow tinge. Similar growths develop on potatoes.

Jiouill on.— Grows well, especia'ly on the surface in bouillon which con-
tains the usual amount of glycerine, 5-6 per cent. Such bouillon cultures,
filtered and concentrated, constitute the so-called tuberculin.

Oxygen requirements. — Free access of oxygen necessary for
growth. Is a facultative anaerobe (FHAENKEL).

Temperature. — The optimum is about 37-39°C. Slight varia-
tions above or below this stop the growth. It cannot, therefore,
grow at ordinary temperatures.

Behavior to Gelatin. — No growth.

Attenuation. — Slight attenuation probably does result with
age, but otherwise it has not been positively demonstrated.

Pathogeneais. — Man, monkeys, cattle', guinea-pigs, field mice,
rabbits, and cats are susceptible. White mice, rats, and dogs are
somewhat insusceptible. Chickens are immune. Inoculation of
pure cultures produces in susceptible animals tuberculosis. The
formation of tubercles and of giant cells. The bacilli may be very
abundant, at other times are scarce and difficult to find.

Infection — Takes place most frequently along the respiratory
tract — Inhalation tuberculosis. May occur tlirough wounds — Inocu-
lation tuberculosis, and also through food — Intestinal tuberculosis.
Placental infection.

MEMORANDA.

— 134 —

BACILLUS LEPRJE. Hansen. (1879).

LEPROSY BACILLUS.

Origin.— Found in the leprous nodules of the skin
and mucous membrane, lymphatic glands, liver, spleen,
marrow, etc. Not in the blood.

Form. — Rather large, narrow rods, which resemble
the tubercle bacillus.

Motility .— Non- motile.

Sporulation. — Bright bodies frequently observed
within the cell, as is the case of the tubercle bacillus.
Doubtful if these are spores.

Anilin Dyes.— Stain readily. Can be stained by
Gram's method, also by the method for the tubercle
bacillus. Sections kept in alcohol lose the property of
double staining.

Growth. — Has not been obtained under artificial
conditions with certainty. The cultures of Bordoni-
UfFreduzzi on glycerine blood-serum inoculated with the
marrow of long bones. Apparently is an obligative para-
sitic organism.

Pathogenesis.— While the constant presence of the
leprosy bacillus in leprous tissue leads to the prevailing
view that it is the cause of that disease, it should never-
theless be remembered that as yet unquestioned pure
cultures have not been obtained and hence successful in-
oculations are impossible. Direct infection with leprosy
tissues has given but few positive results.

Infection. — The mode in which this occurs in man
is entirely unknown.

MEMORANDA.

136 —

AGAR PLATE CULTURES.

The ordinary gelatin plates are applicable for the
isolation of colonies of only those organisms which can
grow at ordinary room temperature. Above 25° C. the
nutrient gelatin melts and cannot therefore be employed
as a solid medium for the growth of those organisms which
develop only at a higher temperature. In such cases plates
can be made with ordinary, or glycerine or glucose agar.
The method of making agar plate cultures is briefly as
follows:

Three agar tubes are immersed in boiling water in a
water-bath until the contents are liquefied. The burner is
then removed from under the water-bath and the water
with the immersed tubes is allowed to cool slowly until a
temperature of 45° C. is reached. Tube 1., is inoculated
with the material to be plated and the usual dilutions to
tubes 2 and 3 are made as rapidly as possible. The cotton
plugs are then cut off short, pushed in slightly, and the
lips of the tubes sterilized in the flame. The inoculated
contents are then poured into sterilized Petri dishes, or on
ordinary sterilized plates. Inasmuch as the agar solidifies
at about 40° it will require rapid work to inoculate the
tubes and pour the contents before solidification takes
place. Ice-water must not be used to congeal the agar.
The Petri dishes or plates are then placed in the incubator.

Esmarch roll-tube cultures can also be made with
agar in the same manner as described for gelatin cultures.
The tubes should be rotated in ordinary tap water.

LABORATORY WORK. — Make glycerine agnr Petri
dishes from the spleen of a guinea-pig inoculated with
glanders. When the colonies develop, make streak cul-
tures on inclined glycerine ngar. Examine the spleen and
also the pure cultures in the usual manner by making
hanging-drops and cover-glass preparations.

MEMORANDA.

— 138 —
BACILLUS MALLEI. Loftier and Schtitz. (1882).

BACILLUS OF GLANDERS. MORVE (Fr.) | ROTZ (Germ.} } MALLEUS (.Ld£.).

Origin. — Found in the nodules, ulcers, discharges,
etc., of glanders or farcy.

Form. — Rods with rounded ends, straight or slightly
curved, shorter and thicker than the tubercle bacillus.
May grow in pairs or in short threads.

Motility. — Has no motion.

Sporulatipn. — Bright bodies are frequently found
in the cells, as in the tubercle bacillus; are considered by
Loffler as the first indication of degeneration. Keal spores
are said to have been double stained. The bacillus itself
is highly .resistant to desiccation.

Anilin Dyes. — Is readily stained and also decolors
rapidly. Carbolic-fuchsine, or alkaline anilin gentian
violet, or anilin fuchsine stain well, especially when
warmed. Not stained by Gram's method.

Growth. — Occurs only at relatively high tempera-
tures. Growth is rapid. Glycerine agaris the best medium.

Plates.— Cannot be obtained with gelatin. On glycerine agar at 37Q C.
forms excellent colonies in a day or two. These are round, grayish, and glis-
tening in appearance, with granular contents and smooth sharp borders.

Stich Cultures.— Can be made in glycerine agar, not in gelatin.

Streak Cultures. --O\\ glycerine agar forms a thick, moist, slimy, semi-
transparent growth. On potatoes the growth is very characteristic. At first
it forms a thin, transparent, honey or amber-colored growth which later be-
comes reddish-brown. On blood-serum forms yellowish, transparent spots
which eventually fuse together and yield a slimy, whitish growth.

Bouillon.— Grows readily and abundantly.

Oxygen requirements. — Is a facultative anaerobe.

Temperature. — Does not grow below 25° or above
42° C. The optimum is about 37° C.

Behavior to Gelatin. — Scarcely any growth.

Attenuation. — Takes place rapidly when grown on
artificial media; must therefore be frequently passed
through an animal, otherwise the virulence is lost and the
organism dies out. Mallein — the filtered cultures of the
glanders bacillus — analogous to tuberculin.

Immunity.— Sm all amounts of bouillon cultures in-
jected intravenously into dogs confer immunity.

Pathogenesis. — Man, horse, ass, guinea-pigs, field
mice, cats, and goats are highly susceptible. Ordinary
and white mice, cattle, and hogs are immune, while dogs,
rabbits, and sheep are slightly susceptible. White mice
become susceptible when fed with phloridzin. Susceptible
animals on inoculation develop typical glanders. In
guinea-pigs death results in 4-6-8 weeks. Field mice die
in a few days. Enlarged lymphatics, nodules in liver,
spleen, etc. Bacilli present.

Infection.— Through wounds — inoculation glanders.
One instance in man with pure culture. Along the re-
spiratory tract — probably the usual source of infection in
horses.

MEMORANDA.

— 140 —
BACILLUS DIPHTHEBIJE. Klebs, Loffler (1883).

BACILLUS OF DIPHTHERIA.

Origin.— Found in diphtheritic pseudo-membranes, and in
very small numbers in the spleen, liver, etc., of diphtheria.

Form. — Rather large thick rods which are straight or slightly
bent and have rounded ends. The form is subject to considerable
variation, and rods with swollen, club-shaped ends are frequently
met with — involution forms.

Motility.— Has no motion.

Sporulation. — Spores have not been observed. Tne bacillus
is very susceptible to desiccation, or to heat of 50° and above.

Anilin Dyes. — Dimple anilin dyes react poorly. Can be best
stained with carbolic-fuchsine, or with Loffler's alkaline methylene
blue (30 c. c. of cone, alcoholic solution of methylene blue + 100 c.c.
of a 0.01 per cent, solution of potassium hydrate). Is also stained
by Gram's method.

Growth. — Is very rapid at higher temperatures and on special
media as glycerine agar and blood serum.

Plates.— On gelatin plates left at about 24° C. forms very small, round,
white colonies wh'ich have granular contents and irregular borders; do not
liquefy gelatin. Cn glycerine agar plates, kept in the incubator, excellent
colonies form in 24-48 'hours The deep colonies are round, or oval, coarsely
granular. The surface colonies are flat, grayish white, glistening, with irregu-
lar borders and coarsely granular contents.

Rl.ich Cultures.— In gelatin a very limited, scarcely preceptible growth
of small, round, white dots— marked involution forms present.

Streak Cultures.— On glycerine agar show a thin, grayish, spreading,
adherent film, which is quite characteristic. On potato the growth is invisible
or forms a dry, thin glaze — irregular forms of the bacillus are numerous. On
blood-serum it forms a thick white, opaque growth.

Bouillon.— Becomes diffusely clouded and the growth eventually sub-
sides on the sides of the tube and on the bottom. A pellicle may form on the
surface.

Oxygen requirements. — Is a facultative anaerobe, but grows
best in presence of oxygen.

Temperature.— Very slight growth at 20-25° C. The maxi-
mum is about 42° and the optimum 35-37° C.

Behavior to Gelatin. — Does not liquefy.

Attenuation. — Cultures directly isolated from membranes
show frequently marked variation in virulence. By artificial cul-
ture the virulence is still further diminished. Cultures can be at-
tenuated by growth at 40° in a current of air.

Immunity. — Is produced by filtered bouillon cultures heated
to 60-70° C. Also by injections of thymus bouillon cultures prev-
iously heated to 65-70°. Partial results with iodine trichloride.

Pathogeiiesis. — Mice and rats are wholly immune. Finches,
sparrows, doves, chickens, rabbits, guinea-pigs and cats are suscep-
tible. Subcutaneous inoculation in guinea-pigs produces death in
24-48 hours. Pseudo-membranous masses form at point of inocula-
tion ; an extensive hemorrhagic oedema forms under the skin and
exudates occur in the pleural cavity. Inoculation in the trachea of
cats, chickens, doves, rabbits, etc., is followed by pseudo-membrane
formation, and by death. In some animals as rabbits typical diph-
theritic paralysis of the extremities can be observed. The highly
poisonous toxalbumin.

Infection. — Exact mode of infection is not known, but un-
doubtedly occurs through the air.

NOTE.— Make glycerine agar Petri dishes of the diphtheria bacillus.

MEMORANDA.

— 142 —

MICROCOCCUS PNEUMONIA CROUPOS.2E.
Sternberg (1880). Frankel (1883).

SYNONYMS: — MICROBE OF SPUTUM SEPTIC^MIA, DIPLOCOCCUS PNEU-
MONIA, FKANKEL'S DIPLOCOCCUS.

Origin. — Occasionally in saliva of healthy persons; especially
in " rusty " sputum of pneumonia. The same organism or scarcely
distinguishable varieties, are present in cerebro-spinal meningitis,
pleuritis, peritonitis, pericarditis, etc.

Form. — Oval or lance-shaped diplococci, may form chains of
4-6 cells and resemble a streptococcus. Owing to its oval form it is
sometimes regarded as a bacillus. In the animal body it is sur-
rounded by large capsules.

Motility. — Has no motion.

Sporulation. — Unknown.

Anilin Dyes. — Stains readily, also by Grain's method. The
•capsules remain colorless.

Growth. — Takes place somewhat slowly and only at higher
temperatures, and on alkaline media.

Plates. — On gelatin plates kept at 24° C. small, round, sharply denned,
tly granular, whitish colonies develop slowly. On agar plates in the in-
-cubator, in 48 hours, delicate, glistening, transparent drops form which under

slightly granular, whitish colonies develop slowly. On agar plates in the in-
-cubator, in 48 hours, delicate, glistening, transparent drops form
the microscope are round, sharply bordered and finely granular.

Stich Cultures.— In. gelatin a row of small, white granules develop along
the line of inoculation. Does not liquefy.

Streak Cultures.— On agar, in the incubator, the growth develops as a
thin layer of delicate, glistening, almost transparent drops. Dies out rapidly.
On blood-serum forms a transparent film-like dew drops. No growth on
potato.

Bouillon. — Excellent growth occurs; vitality preserved for some time.

Milk. — Is a favorable culture medium, becomes coagulated.

Oxygen requirements.— Is a facultative anaerobe.

Temperature. — Growth occurs only between 24 and 42°. Its
optimum is about 37° C.

Behavior to Gelatin, — Does not liquefy.

Attenuation. — Cultures from different sources show marked
difference in virulence. When grown on artificial media it rap-
idly attenuates and soon dies out, unless it is passed through a sus-
ceptible animal, as a rabbit, every few weeks. Rapidly attenuates
*it42°O.

Immunity. — Intravenous injection of very small amount of
virulent culture ; injections of filtered cultures, especially when
heated to 00° C. ; blood serum of immune animals. Blood-serum
from pneumonic patients immunizes rabbits against the pure cul-
ture.

Pathogenesis. — Subcutaneous injection of 0.1 — 0.2 c. c. of
bouillon cultures in rabbits produces death in 24-48 hours. The
•diplococcus is found in the blood and internal organs and is sur-
rounded by a capsule. Tracheal injections in rabbits produce true
pneumonia. Mice and rabbits are highly susceptible ; guinea-pigs,
sheep, dogs are less susceptible. Is the" recognized cause of croup-
ous pneumonia.

NOTE.— Make agar Petri dishes from the peritoneum exudate in a rabbit.
Make cover-glass preparations from the peritoneum, surface of intestines and
tieart-blood, and stain by simple and by Gram's method.

MEMORANDA.

— 144 —

PNEUMOBACILLUS OF FEIEDLAENDER.

(1883).

ALSO KNOWN AS FRIEDLAENDER's PNEUMOCOCCUS.

Origin. — Is frequently found in normal saliva ; also
in lungs and " rusty " sputum of pneumonia.

Form. — May appear as an oval coccus, but in reality
is a short, thick rod, which may grow in pairs and even in

short threads. In the animal body it is enveloped by a
capsule.

Motility. — Has no motion.

Sporulation. — No spores observed. Cultures retain
vitality for many months.

Anilin Dyes. — The cell is stained readily but the
capsule remains colorless. Is not stained by Gram's
method — distinction from Rhinoscleroma bacillus and
Frankel's fiiplococcus.

Growth.— Is rapid and abundant.

Platen. — On gelatin plales it develops rapidly. The deep colonies are
round or oval, sharply bordered, finely granular and yellowish. The surface
colonies are quite characteristic and appear as thick, moist, glistening, white
masses which do not lend to spread but rather to become convex and raised.
No liquefaction.

Stich Cultures.- (Irmvth takes place along 1he entire line of inoculation
and is especially developed on the surface forming a " nail-shaped " culture.
As the culture becomes old the gelatin near the surface becomes brownish in
color and small gas bubbles may form.

Streak Cultures.— On ac/ar forms a thick, white, moist, shiny growth
On blood-serum develops as a grayish, shinv mass. On potatoes forms a thick,
yellowish, sticky growth, showing gas bubbles.

Oxygen requirements.— Is a facultative anaerobe.

Temperature. — Grows rapidly at low temperatures,
16-20; also in the incubator.

Behavior to Gelatin.— Does not liquefy.

Aerogenesis. — Abundant production of gas in 4 per
cent, gelatin ; potato cultures grown in the incubator
also give rise to gas.

Pathogenesis. — Is pathogenic for mice and young
rats; guinea-pigs and dogs are less susceptible, while rab-
bits are immune. While not the cause of pneumonia, its
frequent presence in that disease may serve to bring about
a " mixed infection."

NOTE —Make gelatin plates and cover-glass preparations from the
lungs and blood of a young rat which has received an intrapleural injection.

MEMORANDA.

— 146 —

BACILLUS OF RHINOSCLEROMA.

Frisch (1882).

Origin. — In the tumors of rhinoscleroma, a rather
rare disease occurring in Austria and Italy.

Form. — Short, thick rods with rounded ends resem-
bling the Friedlaender's pneumobacillus, may form short
threads. Are likewise surrounded by a colorless capsule.
Cells of Mickulicz.

Motility.— Has no motion.
Sporulation. — Not observed.

Anilin Dyes. — Stain readily, and show colorless
capsule; also stained by Gram's method.

Growth. — Growth resembles in almost every respect
that of the Friedlaender bacillus, The colonies, stich and
streak cultures, agree so closely as to be scarcely distin-
guishable.

Oxygen requirements. — Is a facultative anaerobe.
Temperature. —Grows rapidly at ordinary tempera-
ture. The optimum is about 36-38° <J.

Behavior to Gelatin.— Not liquefied.
Aerogenesis. — Gas produced by potato cultures.

Pathogenesis. — The relation of this bacillus to rhin-
oscleroma has not been positively established. It has less
virulence than the Friedlaender bacillus. Is pathogenic
for mice and guinea-pigs, Rabbits are less susceptible.

MEMORANDA.

— 148 —
VIBRIO OF ASIATIC CHOLERA. Koch (1884).

BACILLUS, COMMA BACILLUS, SPIRILLUM OF ASIATIC CHOLERA.

Origin.— In the excreta of cholera patients, also in the intesti-
nal contents after death. Found several times in the water supply.

Form. — Usually appears as a short, rather thick rod with
rounded, narrowed ends, and with a more or less decided bend or
twist. May therefore vary from apparently a straight rod to one
bent in the form of a half circle. Usually the bend is such as to
resemble a comma, hence the name, comma bacillus. When two
cells remain attached the elongated " 8 " form results. Grown in
liquid media under unfavorable conditions may form long spirals.
As the usual form, the bent rod, is a segment of a spirillum it is des-
ignated as a \ ibrio. Peculiar involution forms develop in old cul-
tures.

Motility. — Is actively motile ; has at one end a single flageilum.

Speculation. — Has no highly resistant form. Has been said
to form arthrospores. •

Anilin Dyes. — Stains slowly with simple anilin dyes. Carbolic
fuchsine is excellent. Is not stained by Gram's method.

Growth — Is fairly rapid at ordinary temperature.

Plates.— Un gelatin plates kept at 22° C, characteristic colonies develop
in 15-20 hours. The colonies appear as small, white points, which gradually
reach the surface and produce a rather slow liquefaction so that funnel-shaped
depressions form. After several days the plate becomes wholly liquefied.
Under the microscope the colonies show an irregular, rough border; have a
white or pale-yellow color, and the contents are coarsely granular, as if made
up of broken glass. A faint rosy hue surrounds the border. On agar plates,
at 37° the large colonies have a peculiar bright grayish-brown transparent ap-
pearance, quite distinct from common bacteria of water and feces.

Stich Cu Mures.— Growth in gelatin along the entire line of inoculation.
At the surface a funnel-shaped liquelaction forms with an air space above,
while the lower part contains the subsided growth. The lower part of the
sticli gradually widens by liquefaction, the growth settles to the bottom and
eventually the entire contents of the tube are liquefied.

Streak Cultures.— On agar it forms a bright, glistening, whitish growth.
Blood-serum is slowly liquefied. On potatoes, kept in the incubator it forms
a grayish or yellowish brown, thin uml rather transparent lnyer, which re-
sembles somewhat that of glanders bacillus on the same medium.

Bouillon.— Growth takes place rapidly, especially in the incubator, and
a folded scum forms on the surface. Cultures, 12-^4 hours old, on addition of
sulphuric acid, show a reddish violet color— the indol reaction— due to forma-
tion of indol and nitrous acid.

Milk.— Grows abundantly in sterilized milk, without much change; and
also in sterilized water.

Oxygen requirements. — In artificial cultures requires oxygen-

Temperature. — Grows oetween 35° and 42° C. The optimum
is at or about 37° C. Above 53° it is killed.

Behavior to Gelatin. — Liquefies.

Pathogenesis. — Intravenous injection in rabbits kills rapidly.
In guinea-pigs intraduodenal injections or introduction of cultures
into the previously alkalinized stomach produces death with choleraic
effects. Intraperitoneal injections of the pure bacillus from agar
cultures are extremely fatal to guinea-pigs, producing rapid fall of
temperature. Bacterial cellular proteids, soluble poisonous pro-
ducts. Infection of man with pure cultures produces typical cholera.
It is therefore recognized and accepted as the cause of Asiatic
cholera.

Infection. — -Takes place along the alimentary canal, through
the water, food, contact with soiled matter, etc.

NOTE.— Make impression preparations of the colonies. Also place in
two sterilized plugged tubes, tap-water solution of 1 per cent, peptone and
1 per cent. Na Cl. Sterilize the peptone tubes in steam sterilizer. Then inocu-
late with cholera vibrio, place in incubator over night and then apply the
indol test.

MEMORANDA.

— 150 —

VIBRIO OF FINKLEE, AND PRIOR. (1884).

VIBRIO PROTEUS, SPIRILLUM OF FINKLER AND PRIOR.

Origin — In the dejections of cholera nostras which
had been kept fourteen days. Is not the cause of cholera
nostras.

Form. — Resembles in form the cholera vibrio but
is larger and thicker; occasionally forms short spirals.
Involution forms.

Motility. — Is actively motile and has a single flagel-
lum at one end.

Sporulation.— Has not been observed.

Anilin Dyes.— Stains readily with the anilin dyes.

Growth. — Is much more rapid than that of the
cholera vibrio.

Plates. — The colonies develop rapidly on gelatin plates and produce
extensive circular liquefactions which are diffusely clouded; under the micro-
scope they appear as yellowish brown, finely granular masses, the contents of
which can be seen to possess marked motion. The edge is beset with short
delicate fibrils.

Stick Culture*.— In gelatin tubes rapid growth and liquefaction along the
entire line of inoculation— the so-called stocking shaped liquefaction. In a
few days the entire contents are liquefied and a thin film usually forms 011
the surface.

Streak Cultures. — On agar forms a thick, moist, slimy, spreading growth.
On potatoes growth occurs rapidly even at ordinary temperature forming a
grayish yellow, slimy, glistening, spreading mass. On blood serum, rapid de-
velopment with liquefaction.

Milk. — Can grow in milk, but in water it soon dies out. Abundant-
growth in bouillon.

Oxygen requirements.— Is a facultative anaerobe.

Temperature. — Grows well at ordinary temperature,
also in the incubator.

Behavior to Gelatin.— Liquefies rapidly and exten-
sively.

Aerogenesis.— Not observed.

Pathogenesis. — As a rule it is fatal to guinea-pigs
when bouillon cultures are introduced into the previously
alkali nized stomach. The intestines are pale and contain
watery contents.

MEMORANDA.

— 152 —

VIBRIO OF DENEKE. (1885).

SPIRILLUM TYKOGENUM. SPIRILLUM OF DENEKE. CHEESE SPIRILLUM.

Origin.— From old cheese.

Form— Sliirhtly bent rods, which forms spirals, and
resemb'e greatly the cholera vibrio.

Motility.— Very motile.

Speculation.— Not known.

Anilin Dyes.— Stain readily.

Growth.— Is quite rapid, but less than (hat of the
Finkler-Prior vibrio. On some gelatin media it liquefies
very slowly or not at all.

Plates. — The colonies which develop on c/clatin plates are yellowish,
liquefy and the plate as a whole may resemble somewhat that of the cholera
vibrio, but the liquefaction is more rapid. Under the microscope they are
seen to be irregular coarsely granular, and the center is yellowish-green.

8ticJi Cultures.— Growth and liquefaction takes place in gelatin tubes
along the entire line of inoculation. The mass of bacteria settle to the bottom
while on the surface a yellowish scum or layer forms.

Streak Cultures.— On agar a thin yellowish growth develops along the
line of inoculation. On potatoes, in the incubator, it forms a delicate, yel-
lowish covering which frequently contains well-formed spirals. On blood
serum, cultures soon produce liquefaction.

Oxygen requirements.— Is a facultative anaerobe.

Temperature. — Grows at ordinary temperature, also
at 37° 0.

Behavior to Gelatin. — Liquefies more rapidly than
the cholera vibrio.

Aerogenesis.— Not observed.

Pathogenesis — Is less pathogenic to guinea pigs
lhan the Finkler Prior vibrio.

MEMORANDA.

' R y
THE

V

M

OF

— 154 —

VIBRO METCHNIKOVI. Gamaleia (188S.)

SPIRILLUM OP METCHNIKOFF.

Origin.— From the intestinal contents, blood and
organs of chickens afflicted with a disease resembling
chicken cholera. The disease exists in Russia during the
summer months and is due to this organism.

Form.— Occurs as a bent rod which bears a marked
resemblance to the vibrio of Asiatic cholera, although it
is somewhat shorter and thicker and more decidedly bent.
Has a marked tendency to form spirals. In the animal
body it is very short.

Motility.— Actively motile. Possesses a long, slen-
der wnip at one end.

Sporulation.— Has not been positively shown to
have spores. Is readily destroyed like the cholera vibrio
by heat, desiccation, acids, etc.

Anilin Dyes.— Stains fairly well— bi-polar stain;
not by Gram's method.

Growth.— In the hanging-drop and in stained prepa-
rations this organism can scarcely be distinguished from
the cholera vibrio. The cultural properties show some
diiferences, and especially is this seen in the pathogenic
action on animals. The rapidity of growth is greater
than that of the cholera vibrio and less than that of the
Finkler- Prior vibrio.

Plates.— The colonies on gelatin plates may resemble those of the cholera
vibrio and also those of the Finkler-Prior. As a rule it grows and liquefies
more rapidly than the cholera vibrio.

Stich Cultures.— In gelatin tubes the growth resembles exactly that of
the cholera vibrio, which is about twice as old.

Streak Cultures. — On agar the growth resembles that of the cholera
vibrio. On potatoes in the incubator it develops moderately as a yellowish
brown covering.

Bouillon.— Abundant growth in the incubator. Gives the indol reaction
almost as well as the comma bacillus.

Oxygen requirements. — Same as cholera vibrio.

Temperature. — Same as cholera vibrio.

Behavior to Gelatin.— Grows and liquefies more
rapidly.

Immunity. — Is conferred on pigeons and guinea-pigs
by injection of sterilized cultures.

Pathogenesis. — Is very infectious for guinea-pigs,
pigeons, and chickens; rabbits are also susceptible. Pigeons
die after subcutaneous injection of minute amounts with-
in 2-i hours. The vibrios are abundant in the blood and
internal organs. Toxicity of old sterilized cultures. Rapid
fall in temperature.

MEMORANDA.

— 156

BACILLUS NEAPOLITANUS. Emmerich.

(1884).
EMMERICH'S BACILLUS.

Origin — Found first in the blood, organs and intestinal
contents of cholera cadavers in Naples. Has since been
shown to be normally present in feces ; it occurs in air and
in putrid fluids. Is closely related to the B. coli comraunis.

Form. — Small, short rods with rounded ends ; usually
single, rarely in long threads.

Motility. — Has no motion. Brownian movement
marked.

Sporulation. — Not observed. When desiccated re-
tains it vitality for some time.

Anilin Dyes.— Stains readily, but not by Gram's
method.

Growth. — Is rather rapid, even at ordinary temper-
ature.

Plates.— On gelatin plates the deep colonies are small, round or whet-
stone shaped, yellowish-brown, finely granular and may show concentric
rings. The surface colonies spread freely as a thin plaque with irregular or
wavy border. A delicate marking or venation can be seen in young colonies.
No liquefaction.

Stick Cultures.— Are characterized by a pronounced surface growth on
the gelatin. It spreads rapidly over the surface as dry, grayish white, irreg-
ularly bordered mass. Abundant growth along the stich. In old cultures the
gelatin frequently becomes cloudy — due to acid production — and bundles of
crystals appear.

Streak Cultures.— On agar forms a moist, white, spreading growth. On
potatoes it develops as a yellowish- brown sticky mass.

Oxygen requirements. — Is a facultative anaerobe.

Temperature. — Grows readily at ordinary tempera-
ture and at 37° C.

Behavior to Gelatin. — Does not liquefy.

Aerogenesis. — Not observed.

Pathogenesis. — Fatal results in guinea-pigs, rabbits,
etc., may follow the injection of large quantities of the
pure culture. It is a toxicogenic organism.

MEMORANDA.

— 158 —

BACILLUS COLI COMMUNIS. Escherich (1885).

BACTERIUM COLI COMMUNE ', THE COLON BACILLUS OF ESCHERICH.

Origin. — Is very common and constant in the intes-
tinal contents of man and animals, especially in the colon;
•occurs in the discharges of healthy infants, also in summer
diarrhoea. Is frequently present, accompanying the com-
ma bacillus, in the discharges of Asiatic cholera, and in
later stages may be the only organism present. In many
respects it resembles Emmerich's bacillus, and also the
typhoid fever bacillus.

Form. — Short, narrow rods ; may vary in length from
oval or coccus-like forms to rods 4-6 times as long as wide.
Usually grows in pairs, arranged in groups.

Motility. — Very slowly motile.

Sporulation.— Not observed.

AnilinDyes. — Stains readily; not by Gram's method.

Growth. — Is fairly rapid and the cultural properties
lesemble those of the preceding organism.

Plates.— On gelatin plates the surface colonies are flat, spreading, an-
isodiametric and have a dull-white color. The border is irregular and mark-
ings are present in the outer zone. No liquefaction.

Stich Cultures.— Rather energetic growth along the line of inoculation,
while on the surface it spreads as a delicate white film.

Streak Cultures.— On agar, are moist, white, spreading, as with the
Emmerich bacillus. On potatoes, it forms an abundant, yellowish, moist,
slowly spreading growth.

Milk.—Ls coagulated in 7- 10 days.

Oxygen requirements. — Is a facultative anaerobe.

Temperature. — Grows well at ordinary temperature.
Its optimum is about 37° 0.

Behavior to Gelatin. — Does not liquefy.

Aerogenesis. — Under anaerobic conditions produces
•carbonic acid and hydrogen.

Pathogenesis. — Guinea-pigs are very susceptible;
rabbits less so; mice insusceptible. Small quantities in-
jected subcutaneously or intravenously produce diarrhoea,
collapse and death in 1-3 days. The small intestine is
hyperaemic, more or less intensely inflamed ; serous exu-
viates may be present. The bacilli are abundant in the
blood and organs.

MEMORANDA.

— 160 —

BACILLUS TYPHI ABDOMINALIS.

Eberth(lS80).

BACILLUS OF TYPHOID FEVER J KOCII-EBERTIl's BACILLUF.

Origin. — First obtained from the spleen and lymphatic glands
of typhoid fever cadavers; present in the blood, in 'small numbers,
and in the feces of typhoid patients.

Form. — Well formed rods, 3-5 times as long as wide, with
rounded ends. The length varies greatly with the nature of the
medium on which it grows. Thus on agar it forms very short rods,
while on potatoes it may grow into long threads. Involution forms.

Motility. — Is very actively motile. Has numerous lateral
whips.

Sporulation. — Terminal, round or oval bodies are found in
potato and agar cultures which are grown in the incubator for sev-
eral days. They do not double stain and the bacilli containing
these are very susceptible to heat. They are not therefore true
spores. The bacilli are very resistant to desiccation and may retain
vitality for months.

Anilin Dyes. — Does not stain as well with ordinary anilin
dyes as most bacteria; carbolic-fuchsine stains excellently. Does
not stain by Gram's method.

Growth. — Is rather rapid, In its cultural properties it greatly
resembles the two preceding organisms.

Ptdfcx. — The deep co'onies on gelatin plates are small, round, sharply
bordered, finely granular and yellowish. Th- surface colonies spread freely
as an almost transparent film, which has an irregular, wavy horder, and is
delicately marked with branching lines. No liquefaction.

Stich< ullun'x —Abundant growth along tn<> entire line of inoculation,
and especially so on i he surface wh^re it spreads as a thin, grayish white
covering. Gelatin eventually becomes cloudy, due to the production of acids.

Streak Cnttui'm. — Jn ut/nr and on hi •>')<! serutn, forms moist, white
growth, without any special characteristics. On potatoes, as a rule, the growth
is very characteristic. It covers the surface as a moist, invisible layer— -dis-
tinction from preceding organisms. On alkaline potatoes the growth is yel-
lowish and no longer characteristic.

Oxygen requirements. — Is a facultative anaerobe.

Temperature — Grows well at ordinary temperature. The
optimum is about 37° C. Is quicklv killed by even short exposures
to heat of 60°.

Behavior to Gelatin. — Does not liquefy.

Pathogenesis. — Intravenous injections usually kill rabbits.
Is usually fatal to guinea-pigs, when introduced into the previously
alkalinized stomach, or when injected into the duodenum. Intoxi-
cation. This bacillus is generally accepted as the cause of typhoid
fever.

Infection. — Commonly takes place through the mouth by
means of water, food, contact with soiled articles, etc. In later
stages other organisms as streptococci frequently appear — "mixed
infection."

NOTE.— Make Esmarch potato cultures of the Eberth, coli communis,
and Emmerich bacilli; place in the incubator for 2-8 days. Carefully compare
these as well as the cultures on other media, etc. Make impression prepara-
tions of colonies.

MEMORANDA.

— 162 —

STREPTOCOCCUS ERYSIPELATIS.

Fehleisen (1883).

Origin. — Occurs in erysipelas, in the lymphatic
vessels of the diseased skin; very rarely present in the
blood and internal organs.

Form. — Small, spherical cells, which (end to grow in
chains of 6-8 ; not infrequently, as when grown in bouillon,
the chains may consist of a hundred or more cells.

Motility. — Has no motion.

Sporulation. — None. Arthrospore formation has
been suggested.

Anilin Dyes. —Stain readily; Gram's method is
applicable, and this is true of most micrococci.

Growth. — Is readily obtained on various media, even
at ordinary temperature, but the growth is slow and
limited.

Plates. - On gelatin plates, the colonies develop rather slowly, forming
minute, round, yellowish-brown, finely granular colonies, which are sharply
bordered and usually show concentric rings. No liquefaction. On affar
plates, developed in the incubator, it forms delicate, grayish, translucent,
drop-like colonies.

8lich Vultures. — In gelatin the growth is quite characteristic. Along the
line of inoculation a row of minute colonies forms, which usually remain sep-
arate, but may fuse together, giving rise to a continuous stich. Scarcely any
growth forms on the surface.

Streak Cultures.— On agar or blood-serum, it develops as minute, scarcely
visible, round colonies, which do not tend to spread. Growth oil potato is
doubtful.

Bouillon.— At 37° C. soon becomes diffusely clouded and a slight, whitish
sediment forms.

Oxygen requirements.— Is a facultative anaerobe.

Temperature. — Grows slowly at ordinary room tem-
perature ; best at 30-37° 0.

Behavior to Gelatin. — Does not liquefy.

Attenuation. — The virulence of the organism is sub-
ject to considerable variation, even when taken directly
from a case of the disease. Artificial cultures soon become
attenuated.

Pathogenesis.— Man, rabbits are susceptible. Mice
are wholly immune. Typical erysipelas results from in-
oculation with pure cultures. Inoculations in man in
capes of inoperable carcinoma, etc. Infection in young
rabbits frequently gives rise to suppuration, severe general
symptoms, elevation of temperature, and death.

Infection. — Occurs undoubtedly through wounds or
injuries of the skin.

MEMORANDA.

— 164 —

STREPTOCOCCUS PYOGENES.

Rosenbach (1884).

Origin. — In abscesses, pyaemia, etc. Similar, if not
identical streptococci, are to be met with under most
varied conditions. Tims I hey are found in the mouth and
sputum, on the mucous membranes of the nose, urethra,
vagina, etc. They are also frequently present as a result
of •' mixed in e*-!ion '* in diphtheria, typhoid fever, pneu-
monia, tuberculous-, scarlet fever, etc.

Form. — Spherical cells or cocci which may grow in
pairs, but usually forms rosary-like chains of 20 to SOcells.
Almost identical with the streptococcus of erysipelas.

Motility.— None.
Sporulation. — None.

Anilin Dyes.— Is stained readily; also by Gram's
method.

Growth. — The characteristics of growth on artificial
media are essentially the same as those of the erysipelas
sireptococcus. So much so that the two organisms are
frequently considered as one and the same species.

Oxygen requirements. — Is a facultative am,e;obe.

Temperature.— Grows slowly at room temperature;
best at 35-37° 0.

Behavior to Gelatin.— Does not liquefy.

Pathogenesis. — Mice and rabbits are susceptible —
distinction Irom the sireptococcus of erysipelas. Like the
Fiankel diplococcus, it is a widely distributed engenderer
of inflammatory processes, either in connection with other
diseases as diphtheria, scarlet fever, etc., or by itself pro-
ducing effects depending largely upoh the locus of inocu-
lation. Thus it is apparently the sole cause of puerperal
fever; infection of the lymphatics of ihe skin induces
erysipelas, while subcutaneously purulent erysipelatoid
changes results. Is also considered the cause of endo-
carditis although this at times may be due to other organ-
isms which have the similar property of inducing inflam-
matory changes, as the Fiankel diplococcus and theStaphy-
lococcus pyogenes aureus.

MEMORANDA.

— 166 —

STAPHYLOCOCCUS PYOGENES AUREUS.
Rosenbach (1884).

GOLDEN PUS PRODUCING COCCUS.

Origin. — One of the most common organisms in pus
—in about 80 per cent. Has been found on the surface of
the skin, in saliva, air, water, dust and soil.

Form. — Smail cocci, arranged in irregular groups;
may also grow single or lorm diplococoi. Size varies with
the medium.

Motility. — Has no motion.

Sporulation. — No spores observed. Possesses a high
degree of resistance to desiccation, heat, chemicals, etc.

Anilin Dyes. — Siains readily, also by Gram's
method.

Growth.— Is rapid.

Plates.— On (jelatin plates the colonies are round, with sharp smooth
borders, strongly granular and of a dark-brown or yellow color. The gelatin
is liquefied somewhat rapidly. On cigar the surface colonies are bright yellow
in color.

Slich Cultures.— In gelatin development takes places along the entire
line ol inoculation, forming a finger-shaped liquefaction. The growth settles
to the bottom as a yellowish deposit while the liquid above remains clouded
for some time. Peculiar acid odor.

Streak Cultures.— On ayar it forms a moist, glistening orange-yellow
covering. On potatoes the growth is excellent forming a thick, moist yellow
mass. The peculiar odor is also present.

Bouillon.— A slight cl'HUi permeates the liquid and eventually a yellow
sediment forms.

Milk.— Coagulation results and the casein is then slowly peptonized.

Oxygen requirements.— Is a facultative anaerobe.
Pigment formation depends on presence of oxygen.

Temperature.— Grows at ordinary temperature; best
at 39-37° 0.

Behavior to Gelatin.— Liquefies rapidly.

Attenuation. — The virulence is rapidly decreased on
artificial media.

Pathogenesis. — Pure cultures applied to man pro-
duced suppuration and carbuncles. Subcutaneous appli-
cation in mice, rabbits, and guinea-pigs induces local ab-
scesses. Intraperitoneal and intravenous injections pro-
duce fatal results with formation of minute abscesses in
the different organs and tissues — pyaemia. Intravenous in-
joction of potato cultures induces ulcerative endocarditis.
Osteomyelitis results when the bones of the leg are first
fractured.

Infection. — Usually through scratches and wounds.
May penetrate the uninjured skin.

NOTE —In suppuration other staphylococci may be found, as the S.
pyogenes albus and the 8. pyogenescitreus. These perhaps are less frequent
and less virulent. The cultural properties are nearly the same with the ex-
ception of the difference in pigment production.

MEMORANDA.

— 168 —
BACILLUS PYOCYANEUS. Gessard (1882).

BACILLUS OF GREEN OK BLUE PUS.

Origin. — In green pus. The color forms on exposure
to air. Several varieties have been described.

Form. — Small narrow rod resembling that of blue
milk. At times it has almost a coccus form. The ends
are rounded ; mny form short threads of 4-6 cells.

Motility. — Actively motile.

Sporulation. — Has not, been observ-ed.

AnilinDyes. — Stains easily also by Gram's method.

Growth. — Is rapid and abundant. Oxygen is neces-
sary to the formation of the pigment.

Plates.— On gelatin plates a green fluorescing pigment develops quite
early. The surface colonies at first tend to spread then produce funnel-shaped
liquefactions. The deep colonies appear as round^granular masses with ser-
rated borders.

Mich Cultures.— In gelatin tubes funnel-shaped liquefaction results. The
upper layer is at first green but later the entire contents are colored. In very
old cultures the color changes to a brownish black. A scum forms on the sur-
face.

Streak Cultures. — On agar a moist, slimy, yellowish growth develops
and the medium itself becomes bright green. When very old the agar be-
comes dark colored and the growth has a peculiar scaly, metallic appearance.
On potatoes a yellowish green or brownish slimy growth forms.

Milk. — Grayish yellow spots form on the surface; the casein is precipi-
tated and subsequently peptonized with production of ammonia.

Oxygen requirements. — Is a facultative anaerobe.
No growth under mica plates, but can grow in the body.

Temperature.— Grows at ordinary temperature, also
in the incubator.

Behavior to Gelatin.— Liquefies rapidly.

Attenuation. — Artificial cultures diminish in viru
lence.

Immunity.— After recovery from the effects of in-
jection of small amounts of the culture the animal is
immune. Sterilized cultures also induce immunity.

Pathogenesis. — Subcutaneous injection, in guinea-
pigs and rabbits, of about 1 c.c. of a fresh bouillon culture
produces a rapidly spreading oedema, purulent inflnmma-
tion and death. Bacilii present in the tissues, blood,
organs, etc. Intra peritoneal injections produce purulent
peritonitis and death. Sin* 11 amounts produce less marked
results and recovery. Cure of animals infected with an-
thrax by inoculation with B. pyocyaneus.

MEMORANDA.

— 170 —

MICROCOCCTJS GONORRHOEA. Neisser (1879).

GONOCOCCUS, DIPLOCOCCUS OF GONORRIICEA.

Origin. — Constant in gonorrhoea! discharges.

Form. — " Biscuit-shaped" micrococci which are usu-
ally in pairs, with the flattened surfaces facing each other.
The diplococcus is usually grouped in masses of 20-40
or more cells. The pus cells are frequently invaded by
the gonococcus which sometimes fills the cells.

Motility. —Has no real motion.
Sporulation. — Not known.

Anilin Dyes. — Stain readily ; Gram's method is not
applicable. Methylene blue is best adapted for staining
cover-glasses of gonorrhoea! pus.

Growth. — Behaves as a strict parasite. Growth has
been successfully obtained only on human blood-serum,
on which it forms a very thin, scarcely visible layer which,
however, soon dies out. Best results have been obtained
with a mixture of 1 part of human blood-serum and 2-3
parts of ordinary nutrient agar. With this mixture plate
cultures can be made and an excellent growth obtained in
24 hours.

Oxygen requirements.--Apparently it is an aero-
bic organism.

Temperature. — Does not grow below 25°, or above
38° C.

Pathogenesis. — Pure cultures of the gonococcus,
obtained by the plate method, produce typical gonorrhoea
when introduced into the healthy urethra.

NOTE.— To examine gonorrhoaal pus, covei'-glasses should be prepared
from it while fresh and before it has dried down. These should be simple
stained with methylene blue.

MEMORANDA,

— 172 —

MICROCOCCUS TETRAGENUS.
Koch, Gaffky (1881).

Origin. — First obtained from the contents of a tuber-
cular lung cavity; present in normal saliva (26-times out
of 111 cases, MILLER), rather common in sputum of tuber-
cular persons. Has been found in a few instances, as the
only organism present in acute abscesses.

Form. — Large cocci, which in pure cultures on artifi-
cial media are either single or in pairs, or irregular groups.
In the animal body it forms perfect tetrads, which are
surrounded by a wide colorless capsule.

Motility.— None.
Sporulation.— None.

Anilin Dyes. — Stain readily. Gram's method is
applicable.

Growth. — Is rather slow.

Plates.— The colonies which develop on the gelatin plate are round or
oval, slightly granular, yellowish and sharp bordered. No liquefaction. The
surface colonies are white, elevated and thick,

Stich Cultures. — Along the line of inoculation, in the gelatin tube, the
growth develops either as a row of white dots or as a continuous white line.
On the surface a characteristic moist, white, thick mass forms.

Streak Cultures.— On agar usually develops as sharply defined, round,
white colonies. On potatoes it forms a thick, slimy covering, which can be
drawn out into long threads.

Oxygen requirements.— Is aerobic, and also fac-
ultative anaerobic.

Temperature. — Grows well at ordinary temperature ;
better in the incubator.

Behavior to Gelatin. — Does not liquefy.

Attenuation. — Cultures grown for years on artificial
media eventually become attenuated.

Pathogenesis. — White mice and guinea-pigs are
susceptible. House and field mice are usually insuscepti-
ble, while rabbits are immune. By subcutaneous applica-
tion or intraperitoneal injection, white mice and guinea-
pigs die in from 3-10 days. The blood-vessels of the kid-
ney, spleen, liver, etc., are full of the tetrads which are
invested by capsules.

MEMORANDA.

— 174 —

SPIRILLUM OBERMEIERI. Obermeier (1873).

SPIRILLUM OP RELAPSING OR RECURRENT FEVER |
SPIROCHAETE OBERMEIERI.

Origin. — Always and exclusively present in the blood
of relapsing fever patients, especially during the febrile
paroxysms, when they may be present in large numbers.

Form. — Delicate flexible, long, wavy spirals.

Motility. — Actively motile. Flagella have been
demonstrated. Preserves its motility at ordinary tempera-
ture for many days.

Sporulation. — Unknown.

Anilin Dyes. — Rapidly and intensely stained by
ordinary dyes.

Growth.— Is an obligative parasite. Has not been
successfully cultivated outside of the living body.

Pathogenesis. — Inoculation of healthy individuals
with blood which contains these spirals produces typical
relapsing fever, which is accompanied by the presence of
the characteristic spirals. Can also be transmitted to
monkeys, but the animal usually recovers. In monkeys
from which the spleen has been removed the spirilla
develop in enormous numbers in the blood, and death
results. Although it has not been isolated and grown in
pure culture, and this, in turn, tested on animals yet the
constant presence of the organism in this disease leads to
the accepted belief that it is the cause. This is also true
of the leprosy bacillus, theplasmodium of malaria and the
amaeba coli of dysentery.

MEMORANDA.

— 176 —

BACILLUS OF CHICKEN CHOLERA.

Perroncito, Pasteur (1880).

SYNONYMS OF CHICKEN OK FOWL CHOLERA. — CHOLERA DES POULES (Fr.) ;
HUHNER-, GEFLUGEL-CI10LERA {Germ.}.

Origin. — In the blood, organs and excreta of chicken which
have thejdisease. A somewhat similar disease of chickens, occur-
ing in Russia, has been shown to be due to the Vibrio Metchnikovi
which resembles very closely the vibrio of Asiatic cholera.

Form. — Small short rods which have rounded ends and are
frequently in pairs, rarely in long threads. At times the form is
almost that of a coccus.

Motility. — Has no motion.

Sporulation. — Spores have not been observed. Nevertheless,
it possesses considerable power of resistance and can withstand the
acidity of the gastric juice.

Anilin Dyes. — Usually stain the ends first while the center
remains uncolored — bi-polar stain. The appearance then is that of
a diplococcus. On more intense staining the entire rod becomes
colored. Gram's method is not applicable.

Growth. — Is rather slow.

Plates Colonies appear in ;» few days on gelatin plates as minute white
dots, which, under the microscope, are seen to be roundish plates with sharp,
smooth borders. The contents ure finely granular, show concentric rings and
are yellowish in color. No liquefaction.

Ktich Cultures. Forms in gelatin, a delicate white line or row of dots
along the line ot inoculation. On the surface it forms a delicate whitish
growth which sprctids veiy slowly.

Streak Culture* on aaar it develops as a thick, glistening, grayish-
white mass. No growth <>n potatoes at ordinary temperatures, but in the in-
cubator in u few tla\ s it gives rise to a yi llowi^h-gray transparent covering.

Oxygen requirements.— Is a facultative anaerobe.

Temperature. — Grows at ordinary temperature and also in the
incubator.

Behavior to Gelatin.— Does not liquefy.

Attenuation. — Artificial cultures soon lose their virulence. It
was in connection with this organism that attenuation was first ob-
served by Pasteur (1880). Influence of oxygen, of heat.

Immunity. — Is produced in chickens and pigeons by inocula-
tion with first and second vaccines.

Pathogenesis. — Chickens, geese, pigeons, sparrows, mice and
rabbits are susceptible. Guinea-pigs, sheep, horses are less suscep-
tible and only local abscesses form. After death the bacilli are found
distributed throughout the body — a true septicaemia.

Infection. — Usually results in chicken through the food
and along the alimentary canal. May possibly also occur through
scratches and wounds.

MEMORANDA.

BACILLUS OF HOG CHOLERA.

Detmers (1880).
BILLING'S SWINE PLAGUE BACILLUS. BACTERIUM OF HOG CHOLERA

(SALMON AND SMITH).

Origin. — In the blood, organs and intestinal contents
of swine that died of hog cholera.

Form. — Short, small rods, resembling those of chicken
cholera. On some media, as gelatin, it may form long
rods. Occurs single or in pairs.

Motility. — Is actively motile. Has long, wavy flag-
ella. Shows no motion in serum or in blood.
Sporulation. — Not observed.

Anilin Dyes. — At first impart a bi-polar stain, but
on sufficient exposure the entire rod is colored. Is not
stained by Gram's method.
Growth. — Is fairly rapid.

Plates.— In a couple of days colonies develop on gelatin plates. The
deep colonies are very small, yellowish-brown and spherical. The surface
colonies spread slightly. No liquefaction.

Stich Culture*.— &\\o\v along the line of inoculation a white line or row
of colonies, while on the surface of the gelatin a thin, very slowly spreading
growth forms.

Streak Cultures— Qn agar forms a moist grayish-white growth without
any special characteristics. On potatoes a straw yellow growth develops, re-
sembling somewhat that of glanders.

Oxygen requirements. — Is a facultative anaerobe.

Temperature. — Grows well at ordinary temperature.
Best at about 37° 0.

Behavior to Gelatin. — Does not liquefy.

Attenuation.— Artificial cultures retain their viru-
lence apparently indefinitely, same as the anthrax bacillus.

Immunity. — Can be produced experimentally by
inoculation with filtered cultures ; with repeated small
doses of blood, previously heated to 54-58° C , from infec-
ted rabbits.

Pathogenesis. — Hog«, mice, rabbits and guinea-pigs
are highly susceptible ; pigeons are less susceptible, while
chickens, sheep and calves are immune. -\ c.c. of bouillon
culture injected subcutaneously into rabbits kills in about
four days. Bacilli distributed everywhere.

Infection.— May result through the food, also by in-
oculation through wounds.

MEMORANDA.

— ISO —

BACILLUS OF HOG ERYSIPELAS.

Pasteur (1883).

SYNONYMS. — SCIIWEINEKOTHLAUF (Germ.}', ROUGET (Fr.).

Origin. — In the blood, internal organs, etc., of swine infected
with the disease.

Form. — Very small, narrow rods resembling needle-shaped
crystals. Are usually single, but may occur in pairs and even in
threads.

Motility. — Has motion.

Sporulation. — Spore formation is not known.

Anilin Dyes.— Stain readily. Gram's method gives excellent
results.

Growth — Is rather slow.

Growth.— On gelatin plates the colonies are very characteristic and ap-
pear as diffuse cloudy patches which are sometimes difficult to see. Little
or no surf are growth. No liquefaction

Stick Cultures.— In gelatin are likewise very characteristic. The growth
develops along the line of inoculation as a delicate, cloud-like radiating col-
umn. As the culture becomes old a depression forms at the top, due to slow
liquefaction and corresponding evaporation. .Sometimes liquefaction can
be observed.

Streak Cultures. — On agar and on blood- serum it forms a scarcely visible
thin film or group of colonies. No growth on potatoes.

Bouillon.— A very delicate diffuse cloudiness forms which can best be
seen on slight agitation. Resembles the bouillon culture of the Tetanus
bacillus.

Oxygen requirements. — Is a facultative aerobe. Best growth
under anaerobic conditions.

Temperature. — Grows slowly at ordinary temperature. Best
at 36° C.

Behavior to Gelatin. — Does not perceptibly liquefy gelatin.

Aerogenesis — Produces hydrogen sulphide in pure cultures,
and in the body. This gas is also produced by the anaerobic bac-
teria and to a less extent by nearly all pathogenic bacteria.

Attenuation — Old cultures become attenuated and this re-
sult can also be obtained by growing the virulent germ at high tem-
peratures, about 42° C.,for*some time (Pasteur).

Immunity. — By inoculation with attenuated cultures — first
and second vaccine of Pasteur — perfect immunity can be produced.
One attack of the disease confers immunity.

Pathogenesis. — Swine, rabbits, pigeons, white mice, house mice
'are susceptible, while guinea-pigs and chickens are insusceptible.
Bacilli distributed throughout the organism ; are single or in pairs,
and very often can be seen to be enclosed in cells.

Infection. — Probably occurs naturally in swine through the
food.

MEMORANDA.

— 182 ~

BACILLUS OF MOUSE SEPTIC^MIA.
Koch (18T8J.

SYNONYMS. — BACILLUS MURISEPTICUS. MAUSESEPTIKAMIE (Germ.).

Origin. — From mice after inoculation with putrid blood.

Form. — The rods are narrower and thinner than those of the
rouget bacillus, but otherwise resemble the latter very much.

Motility. — Appears to possess motion. Said to be non-motile
by some.

Sporulaticn. — Round, glistening bodies, or spores form within
the cells.

Anilin Dyes. — Stain rapidly. Gram's method is applicable.

Growth. — Is rather slow and resembles very closely that of
the rouget bacillus.

Plates.— The colonies on the gelatin plate resemble those of the rouget
bacillus, except that they spread somewhat more rapidly and are especially
delicate and transparent in appearance.

Stich Cultures.— Show this distinction in growth quite sharply. While
the cloudy growth of the rouget bacillus is dense and somewhat limited to the
line of inoculation, that of the mouse septicaemia bacillus spreads readily
throughout the entire gelatin. This difference is clearly seen in young
cultures.

Streak Cultures. — On agar the growth is scarcely to be distinguished
from that of the rouget bacillus.

Bouillon — The bacillus develops a growth similar to that of the bacillus
of rouget.

Oxygen requirements. — Is a facultative aerobe. Grows better
when air is excluded.

Temperature. — Grows well at ordinary temperature, also in
the incubator.

Behavior to Gelatin. — Ordinarily no liquefaction can be ob-
served. Sometimes, however, it is present.

Aerogenesis. — Produces less hydrogen sulphide than the rou-
get bacillus.

Attenuation — Old cultures possess diminished virulence.

Immunity. — Rabbits that recover after one inoculation with
the pure culture are rendered immune against subsequent inocula-
tion.

Fathogenesis. — White mice, house mice, pigeons, sparrows
and rabbits are susceptible. Chickens, guinea-pigs and field mice are
wholly immune. After death the bacilli are distributed throughout
the body, single or in pairs, and frequently inclosed in cells.

MEMORANDA.

16

— 184

ACTINOMYCES. Bellinger (1877).

SYNONYMS. — RAY-FUNGUS. STRAIILENPILZ (Germ.}.

Origin. — From actinomycosis or lumpy-jaw in cattle,
hogs, and in man.

Form. — The exact position of this organism is uncer-
tain, but it is closely related to the fungi or moulds. It
forms nodules which consist of a whorl of mycelial-like
multiple branched threads. These radiate outward from
a central point and become club-shaped. In pure cultures
only slender, wavy threads are formed, and the club-shaped
or swollen ends, so commonly present in tissues are lacking.

Anilin Dyes.— Stain readily with carbolic fuchsine;
also by Gram's method.

Growth. — Develops somewhat slowly, requiring sev-
eral days in the incubator.

Streak Cultures. — On agar, the growth begins as minute, isolated colo-
nies, which slowly enlarge, forming thick, convex, glistening, yellowish
masses. These colonies are exceedingly hard and for examination should be
crushed between two glass slides previously sterilized by passing several times
through the flame. Cover-glass preparations are then made and stained in
the usual manner.

Oxygen requirements.— Said to grow best in the
absence of air, but grows very well on the surface of agar.

Temperature. — Grows only at or near the body
temperature.

Pathogenesis. — In rabbits, intraperitoneal injection
of the pure culture produces typical actinomycotic nodules
on the peritoneum, mesentery, intestinal walls, etc.

MEMORANDA.

— 186 —

ACHORION SCHONLEINII. Schonlein (1839).

THE FUNGUS OP FAVUS.

Origin. — Found in the scaly accumulations on the
skin of persons afflicted with favus.

Form. — Apparently belongs to the moulds. It shows
on microscopical examination peculiarly twisted threads,
which show divisions and give off branches at right angles.

Fruit-organs.— No true fruit organs observed, but
on special media as on blood-serum at 30° 0. conidia or
spores form.

Anilin Dyes.— Stains well, also by Gram's method.

Growth. — Is rather slow.

Plates.— On gelatin plates, the colonies grow slowly and form whitish,
stellate masses, which rapidly liquefy the gelatin. No conidia present.

Slich Cultures.— Growth is very poor in the lower part of the gelatin
tube. On the surface it forms a white covering, the lower side of which is
light yellow. Liquefies.

Streak Cultures.— On agar it forms a closely adherent, whitish, dry mass.

Temperature. — Dies out at the ordinary tempera-
ture. The optimum is about 30° C.

Behavior to Gelatin.— Liquefies.

Pathogenesis.— Inoculation with pure culture pro-
duces typical favus in man.

The favus fungus is closely related to that of Herpes
tonsurans — the Tricophyton tonsurans (1845); to that of
Pityriasis versicolor— the Microsporon furfur (1846); and
also to the Oidium lactis.

MEMORANDA.

— 188 —

MONILIA CANDIDA. Robin (1847).

SYNONYMS. — THRUSH FUNGUS; OIDIUM ALBICANS, SACCHAROMYCES

ALBICAXS. SOORPILZ (Germ.}.

Origin. — Found in the mouths of infants ; in thrush.

Form. — Occupies an intermediate position between
the moulds and yeasts. On gelatin plates and on sugar
media it forms yeast-like cells, whereas in the deeper
part of the stich culture it forms mycelial threads.

Anilin Dyes.— Stain readily.

Growth. — Is rapid and abundant.

Plates.— Snow-white colonies form on gelatin plates and no liquefaction
takes place.

Stich Cultures.— In gelatin show growth along the line of inoculation,
while on the surface a milk-white, thick mass forms.

Streak Cultures. — On agar, forms a glistening, moist, thick, white
growth. On potatoes, it grows rapidly as a thick, white, yeast-like mass.

Temperature. — Grows at ordinary temperature, also
in incubator.

Behavior to Gelatin. — Does not liquefy.

Pathogenesis. — Intravenous injection in rabbits
produces death in 1-2 days. The internal organs are per-
meated with a growth of long mycelial threads.

MEMORANDA.

MEMORANDA.

MEMORANDA.

MEMORANDA.

— 189 —

SPECIAL WORK.

Direct microscopical examination of streak prepara-
tions made from the organs and tissues of infected ani-
mals, as well as cultural experiments will reveal the pres-
ence of microorganisms. In order to ascertain the presence
and especially the distribution of organisms within tissues
and organs it is necessary to harden these, then to cut
sections and finally to stain the sections by suitable meth-
ods.

Hardening.— For this purpose alcohol is usually
employed and gives excellent, results. The tissue is cut
into small pieces which are either transferred direct to a
wide-mouthed bottle containing 92-96 per cent, alcohol, or
are first placed on pieces of filter paper and then in the
alcohol. The pieces of tissue should remain in this alcohol
for at least 3 or 4 days, or until it is desired to make sec-
tion?, when they are transferred to absolute alcohol for
one or two days. The tissue is then hardened and ready
for cutting sections. To do tljis a piece of the tissue is at-
tached to a small cork by means ot a glycerine gelatin
mixture made by warming 1 part of gelatin, 2 parts of
water and 4 parts of glycerine. The cork is then securely
clamped to the microtome and sections made. The tissue
and knife must be kept moist with alcohol and the sec-
tions are at once transferred to alcohol by means of a
camel hair brush.

Very satisfactory and rapid hardening can be obtained
with a solution of mercuric chloride made by saturating
an aqueous five per cent, glacial acetic acid solution with
mercuric chloride. The tissue can be fixed in this solution
in 4 to 12 hours. It is then passed through a series of

— 190 —

alcohols of different strength, — 60, 80, 96X and absolute,
in each of which the tissue remains for 24 hours.

Cutting sections. — As already stated the tissue
which has been hardened in alcohol may be cut directly
and sections can thus be obtained which are fairly good.
Another method for obtaining sections is to employ the
freezing microtome, in which case the alcohol is first re-
moved from the tissue by placing the pieces in water.
This is accomplished in cold water in 4-8 hours, depend-
ing: on the size of the pieces. Warm water about 38° C.
will remove the alcohol more rapidly, in 1 to 2 hours.
The tissues can then be frozen and sections cut. The
knife should be kept moistened with water and the sec-
tions are transferred at once to water.

Undoubtedly the most satisfactory method of prepar-
ing sections is to first imbed the hardened tissue either in
celloidin, or in paraffin. Either method gives excellent
results. The method for imbedding in paraffin which is
usually employed in the laboratory is briefly as follows :

The hardened tissue is placed in absolute alcohol for
24 hours; then for 4 to 5 hours in chloroform, then in a
chloroform-paraffin solution over night. The pieces are
then placed in paraffin which melts at about 42° C. and kept
in a water air-bath at a temperature of about 50° for 24
hours. From this the tissue is transferred to hard paraffin
which melts at about 48° C. This may be obtained by
taking equal parts of 42° and 56° paraffin. After 24
hours the piece of tissue is "blocked.-' . Two glass L's are
fitted together so as to make a trough of suitable size, and
this then filled with melted paraffin (48° C.) The piece of
tissue is transferred by means of a pair of forceps, slightly
warmed, to the center of the block and the whole allowed
to cool. The solid block, if necessary, is then trimmed,
fastened to the microtome and sections cut with a dry
knife.

From absolute alcohol the pieces of tissue can be
placed first in toluene for 24 hour,s; then in a mixture of

MEMORANDA.

MEMORANDA.

— 191 —

equal parts of toluene and paraffin for 24 hours and then
in paraffin for 24- hours.

The paraffin can be dissolved from the sections by
means of xylol or turpentine. The sections are then placed
in absolute alcohol and finally transferred to 10% alcohol,
in which they may be kept for any length of time and are
now ready for staining,

Paraffin sections sometimes tend to curl or become
folded. This difficulty can be readiiy overcome by plac-
ing the sections in a Petri dish containing tepid water.
This must not be so warm as to melt the paraffin. The
dish may be kept on an iron plate which is heated gently
at one end. The sections spread out on the surface of the
warm water. They can be received on strips of paper and
transferred to a glass-slide or cover-glass which is covered
with a film of albumin. The section is then dried with a
piece of paper and caused to adhere by slightly warming
the glass slide. It can then be stained in the usual man-
ner. The method is very convenient in working with very
thin sections or with very delicate tissues. (BORREL).

Staining of Sections. — The presence of organisms
in sections of tissues is sometimes very difficult to demon-
strate although they may be easily shown to be present
in ordinary streak cover-glass preparations. This is fre-
quently due to the absence of any sharp means of differ-
entiating the organism from the surrounding tissue. In
many cases, however, a sharp differentiation can be ob-
tained by double staining either by Gram's method, or, as
in the case of leprosy and tuberculosis, by the Triplication
of the usual process for staining these bacilli.

Simple stain. — The student should begin with cec-
lions of the spleen, kidney and liver of a guinea-pig which
died of anthrax. The sections are transferred by means
of a needle to the dilute anilin .dye, as fuchsine or gentian
violet and are allowed to remain there for 10 to 30
minutes. They are then transferred to water slightly acid-
ulated with acetic acid, or to very dilute alcohol. This is

— 192 —

done to remove the excess of dye and to differentiate the
bacteria in the tissue. From the decolorizing solution the
section is transferred to water then, by means of a spa-
tula, to a glass slide and examined with a No. 7 objective.
If the section is still too intensely stained it should be re-
turned to the decolorizing agent and after a while again
examined. When satisfactorily stained the sections should
be placed in absolute alcohol, for a few seconds, till
thoroughly dehydrated, they are then cleared up in oil of
cloves, cedar or anise; placed in xylol and examined on
a slide. If satisfactory the cover-glass is carefully lifted
off and the xylol removed from the section by means of a
piece of filter paper. A drop of Canada balsam is then
applied to the section and the whole covered with a clean
cover-glass. The exposure to absolute alcohol and to oil
of cloves should be carefully watched as both tend to re-
move the stain. The oil of cloves can indeed be relied
upon to remove any excess of dye that may be present.

Instead of the ordinary dilute anilin stain, Lo (Tier's
methylene blue (page 140) or ZiehFs carbolic fuchsine
(page 110) can be employed in special cases to excellent
advantage. A dilute ZiehTs solution gives particularly
good results. The sections remain in this for about half an.
hour and are then transferred to absolute alcohol which is
very slightly acidulated with acetic acid. As soon as the
color changes to a peculiar reddish violet tint the section
is removed, cleared up in xylol, examined and mounted in
balsam. (Pfeiffer's method.)

Double stain — Gramas method. — Those microorgan-
isms which can be stained by this method can be readily
detected in sections, as the preparations when properly
made show the heavily stained violet bacilli on a light pink
background. The student should begin with sections of
the kidney of the anthrax guinea-pig. A strong solution
of anilin water gentian violet is prepared according to the
directions given on page 106. It should be warmed slightly
on the radiator, or on an iron plate. The sections are placed

MEMORANDA.

MEMORANDA.

— 193 —

in this slain for 15 to 30 minutes. They are then washed
in anilin water to remove excess of the dye, and thus to
prevent the formation of unsightly deposits on subsequent
contact with iodine. The sections are then placed in the
solution of iodine in potassium iodide (p. 107) for 2 or 3
minutes. From this they are transferred to absolute alco-
hol and gently moved about till most of the stain is re-
moved. The sections should be still slightly stained, not
completely decolored. They are then placed in Weigert's
picrocarmine solution or in eosine, for 1-2-3 minutes, de-
hydrated in absolute alcohol for a few seconds and then
transferred to oil of cloves in which the sections are al-
lowed to remain till all the gentian violet lias been re-
moved. Oil i/f cloves, especially when dark colored, has
strong decolorizing properties and will remove all traces
of gentian violet from the tissues without affecting the
bacilli to any extent. The sections are then placed jn
xylol and examined and if satisfactory mounted in Can-
ada balsam.

ANTHRAX SECTIONS.

Simple Stain: Gra'tns Method:

Dilute anilin stain Anilin water-gentian violet

(10 to 30 min.). (warirr 15 to 30 min.).

Acetic water. Iodine in potassium iodide

Water (and exam- (2-3 min.).

ine). Absolute alcohol.

Absolute alcohol Picrocarmine (1-2-3 min.).

(few seconds). Absolute alcohol (few

Oil of cloves. seconds).

Xylol (and exam- Oil of cloves (till violet

ine). ceases to be given off).

Canada Balsam. Xylol (and examine).

Canada balsam.

Malignant oedema.— Prepare sections from the ab-
dominal wall, kidney and liver of a guinea-pig which died
after inoculation with the bacillus of malignant oedema.

— 194 —

The tissues and organs should be removed 48 hours after
the death. Stain with dilute carbolic fuchsine according
to Pfeiffer's method as given on page 192.

Symptomatic anthrax.— Prepare sections from the
same tissues as above from a guinea-pig which was not ex-
amined till 48 hours after the death. Stain by the same
method and compare the two organisms.

Bacillus cedematis maligni, No. II.— Section the
thickened abdominal wall and stain after Gram's method.

Tubercle bacillus. — Prepare sections of tubercular
human lung, also of the spleen, liver, and mesenteric tu-
bercles of a guinea-pig inoculated with tubercular spu-
tum. Stain the sections according to the following method
which is a modification of the Ziehl-Neelsen method.

The sections are placed in Ziehl's carbolic fuchsine,
slightly warmed, for 15-30 minutes. They are then trans-
ferred to Ebner's solution where they are moved about
till the color ceases to be given off. The sections should still
possess a slight pink color. They are then placed in dilute
methylene blue for ^-1 minute. From this they are trans-
ferred by means of a spatula to absolute alcohol for -J-l
minute. The sections must not remain in the alcohol till
all the blue disappears. They are then placed in oil of
anise, transferred to xylol and examined. If satisfactory
the section is mounfed in Canada balsam.

Ebner's decalcifying solution is prepared according to
the formula: — Sodium chloride 0.5, hydrochloric acid 0.5,
alcohol 100, distilled water 30.

Instead of using Ebner's solution for decoloring the tis-
sues a 2 per cent, aqueous solution of anilin hydrochloride
can be employed with excellent results as it has little or
no tendency to decolor the tubercle bacilli. (KiiHNE,
BORREL). The sections are stained in Ziehl's solution as
above, then placed for a few seconds in the 2 per cent,
aqueous solution of anilin hydrochloride, then washed in
alcohol and counter-stained as above.

Leprosy bacillus.— Sections of the skin of a leper

MEMORANDA.

MEMORANDA.

— 195 —

can be double stained according to the method described
for the tubercle bacillus. It can be summarized as fol-
lows :

Sections.

Carbolic fuchsine (warm 15-30 min.).

Ebner's solution (till it turns a light pink).

Dilute methylene blue (-J— 1 min.),

Absolute alcohol (-J-1 min.).

Oil of anise.

Xylol (and examine).

Canada balsam.

Leprosy sections left in dilute alcohol soon lose their
capacity for double staining. They can be simple stained
with methylene blue, or with carbolic fuchsine by Pfeif-
fer's method.

Glanders bacillus.— The detection of this bacillus
in tissue i? rather difficult owing to its marked peculiarity
of readily becoming decolorized. Sactions from the
spleen, of a guinea pig should be simple stained with
Lo filer's alkaline meihylene blue (p. 140) or with carbolic
fuchsine.

Typhoid fever bacillus. —The E berth bacillus al-
though it is siained readily and intensely is very likely
to become decolorized in the ordinary method of staining.
Sections of human spleen are stained in Loffler's alkaline
methylene blue for 24 hours. Then washed and decolored
in water, dehydrated in anilin oil, allowed to dry on a slide
and finally cleared up with xylol. Simple stains can be
made with carbolic fuchsine, decolorizing carefully in acid-
water and alcohol.

Frankel's diplococcus.— Sections from the lung,
spleen, liver etc., of a rabbit can be stained by Gram's
method,

Loffler's diphtheria bacillus. — Sections of diph
thentic membranes, or of muscles from the neighborhood
of the point of inoculation should be stained with Loffler's
alkaline methylene blue, or by Gram's method.

— 196 —

Staphylococcus pyogenes aureus.- This organism

also the Streptococcus pyogenes can be detected in
sections of the kidney, suprarenal body etc. in pyaemia
of man, or in the organs of rabbits inoculated with pure
Cultures. The sections should be stained by Gram's
method, or with carbolic fuchsine.

Chicken cholera bacillus.— This can best be de-
monstrated in sections of the liver, spleen and pectoral
muscles of a pigeon. Simple staining with carbolic fuch-
sine or anilin water gentian violet will give fair results.

Micrococcus tetragenus. — The kidneys, lungs etc.
•of white mice and guinea-pigs give excellent preparations
when stained by Gram's method.

MEMORANDA.

OF THE

( UNIVERSITY )

OF

MEMORANDA.

— 197

TESTING OF DISINFECTANTS.

In studying the action of physical and chemical agents
on bacteria it is necessary to rigidly adhere to certain re-
quirements without which the results would be of little
value, if not wholly contradictory. The conditions which
underly.the testing of disinfectants may be summed up as
follows.

(1 ). Variable resistance of spores and of the vegetat-
ing forms of one and the same organism. It has been
shown in recent years that considerable variation may exist
in the resistance which an organism possesses to destruc-
tion. Thus, while there are some spores of anthrax which
are readily destroyed by steam-heat, 100° C., others have
been known to withstand this temperature for 10-12 min-
utes. Again it was formerly stated that anthrax spores
were destroyed by 5 per cent, carbolic acid in two days
but the researches of Fraenkel have shown that spores of
anthrax may be had which are not destroyed by an ex-
posure of 30 to 40 days. In view of these facts several
standards have been proposed. Thus Fraenkel designates
anthrax spores which are destroyed by 5 per cent, carbolic
in less then 10 days as feebly resistant; in 10 to 20 days
as of average resistance; in 20 to 30 days as very resistant;
in 30 to 40 days as extremely resistant. Geppert's stand-
ard an fchiMX sp)t35rir e those which are infectious after
boiling for one minute 1 c. c. of a spore suspension which
is added to 30 c. c. of boiling water. Esmarch has sug-
gested as a standard anthrax spores which when fixed on
silk threads resist steam-heat of 100° G. for 10 minutes.

(2). The influence of the medium in which the organ-
ism is tested. Thus it has been shown that to destroy an-
thrax spores in bouillon it requires'20 tin)3s as much mer-

— 198 —

curie chloride (1-1000) than when they are suspended in
water, and 250 times as much when they are distributed
in blood serum.

(3). The temperature at which the disinfection is
made. The higher the temperature at which the experi-
ments are made the more rapid and energetic will be the
action of the disinfectant. Cholera bacteria are not de-
stroyed bymercuric chloride (1-1000) in one hour at —3°,
whereas at 36° C. they are killed in a few minutes.

(4). Immediate and thorough contact of all the or-
ganisms present with the disinfectant. This can be done
perfectly only with bacterial suspensions in which each or-
ganism is entirely free and separate from others. To ob-
tain such a suspension it is necessary first to filter through
glass wool and then to agitate the liquid thoroughly at a
temperature of about 37° until microscopical examination
shows no aggregations of bacteria. Silk threads which have
been soaked in bacterial suspensions and then dried are
open to the objection that on exposure to the disinfectant
organisms are unequally exposed and some even protected
by their position and hence when transplanted soon de-
velop. The same objection, to a less degree, applies to
cover-glasses on which a thin film of the suspension has
been deposited.

(5). The number of bacteria in a given experiment.
It can readily be shown that the greater the number of
bacteria present the more slowly does the disinfection
take place. In order therefore that results may be com-
parable, approximately the same number of organisms
should be present in each experiment. This is readily as-
certained by diluting a small portion of the bacterial sus-
pension witli 1-2000 parts of sterilized water and then
making a gelatin plate with one drop of this dilution.

(6). The amount of the disinfectant which is carried
over in each trial inoculation. Thus, when the disinfect-
ant is applied to the bacterial suspension and at the end
of stated intervals transfers of 1-3 loopfuls of the mixture

MEMORANDA.

MEMORANDA.

— 199 —

are made to sterilized nutrient media, a sufficient amount
of the disinfectant may be carried over to prevent the
growth of the organism which mny still possess vitality.
This has been a most serious source of error in the past.
The error is more marked, the greater the antiseptic
power of the disinfectant. It is of course less marked
where the substance has weak antiseptic properties
and where the transplantation occurs into relatively
large amounts of the nutrient medium (10 to 15 c. c.).
It must be remembered that probably in all cases the
first action of a disinfectant is to attenuate the organism
and that when the latter is in this condition a much
smaller amount of the disinfectant will act as an antiseptic
and prevent growth. This has been especially shown to
be the case with reference to the action of mercuric chlo-
ride on anthrax spores. Formerly it was disposed that
these were killed by this substance in a strength of 1 to
1000 in one minute but if the mercury which is held fast
by the silk thread, and which cannot be removed by mere
washing, is removed by the action of hydrogen sulphide it
can be shown that the organism is alive and infectious
even alter an exposure of four hours. It may even possess
vitality alter an exposure of 24 hours. The first action of
the disinfectant in this instance is to attenuate the organ-
ism the growth of which is then prevented by mere traces
of the mercury. One part in two million according to
Geppert suffices to produce this result.

(7). Observation of the trial inoculation tubes over a
considerable length of time. The failure of tubes to grow
within 24 hours is not a positive indication that the organ-
ism has been destroyed by the disinfectant. In the at-
tenuated condition the organism will grow much more
slowly then it would if normal and in possession of full vi-
tality. Moreover, as stated already, traces of the disin-
fectant which are carried over in the experiment will still
further tend to retard the growth. For these reasons the

— 200 —

tubes should be kept under observation for 1 — 2 — 3 weeks
before definite conclusions can be drawn.

(8). Temperature at which the trial inoculation
tubes are kept. The organism which has been exposed to
the action of the disinfectant should be placed under con-
ditions which are most favorable to its growth. That is,
the best nutrient medium and the most suitable tempera-
ture should be furnished. Transplantations made into gel-
atin and kept at ordinary room temperature frequently
fail to grow while parallel bouillon and agar cultures, kept in
the incubator,develop. It is therefore desirable to make the
transplantation onto the surface of inclined agar tubes or
into bouillon and to keep the tubes under observation at a
temperature of about 37.5° C. for two or three weeks.

(9). Negative experiments with animals inoculated
with organisms exposed to heat, or to the action of chemi-
cals prove nothing. The organism may be dead or it may
have become attenuated and is therefore without action,
although it may still grow on artificial media. Thus, an-
thrax spores exposed to the boiling temperature for 2 min-
utes no longer kill guinea-pigs, but nevertheless can grow
in tubes, even after 5 minutes exposure. Again, positive
experiments may be obtained by inoculating white mice or
guinea-pigs with the mixture of bacteria and disinfectant at
a time where transplantation of a corresponding amount on
a nutrient medium fails to grow owing to the antiseptic
power of the disinfectant carried over.

METHODS FOR TESTING DISINFECTANTS.

(1). . Silk threads. This method was introduced by
Koch and has been extensively used. Threads of silk, linen,
or cotton are cut up into lengths of about 1 cm. They are
placed in a sterilized plugged test-tube and sterilized in
the dry-heat oven. A cloudy suspension of the spores or
bacteria to be tested is made in sterilized water. The
pieces of sterilized threads are immersed in this suspen-
sion for some minutes, then transferred with sterilized for-

MEMORANDA.

18

MEMORANDA.

— 201 —

ceps to a sterilized Petri dish and allowed to dry. They
can then be placed in a test-tube and kept for future use.

To ascertain the disinfecting action of a solution a
thread impregnated with the bacteria to be tested is im-
mersed in it fora given length of time, as for instance 2
minutes. It is then removed with sterilized forceps and
gently washed in sterilized water or alcohol. Finally it is
transferred to a tube of nutrient bouillon (10-15 c. c.) and
then set aside in the incubator for a week or more. Simi-
lar tests with exposures of 2, 5, 10, 3.0, and 60 minutes
should be made.

The objections to this method are twofold and have
already been incidentally mentioned. In the first place
the bacteria on the thread may not be evenly exposed to
the action of the disinfectant and secondly the disinfec-
tant itself may be transferred to the nutrient medium.
The attempt is made to obviate the latter objection by
washing the threads and while this may be successful
in some cases, in others it fails. Thus mercuric chloride
is apparently held fast by the fibre and can only be re-
moved by the action of hydrogen sulphide (GEPPERT).

(2). Cover glasses. This method was introduced by
Geppert and has been used bySpirig and others. Ordinary
microscopic cover-glasses are cut in two, cleaned and
rendered free from far, and finally sterilized. They are
then immersed in the bacterial suspension, or in bouillon
cultures, transferred to a sterilized wire gauze, under a
bell jar, and allowed to dry. To test a disinfectant a dry
cover-glasses is immersed in it for a given length of time
as in the case of the silk threads. It is then removed with
sterilized forceps and washed in about 400 c. c. of sterilized
water for about -|-| hour. Then placed in sterilized bouil-
lon and set aside in the incubator.

The advantages of this method are (1) that a thin film
of evenly spread bacteria is employed, and (2) that the
cover-glass does not unite with the disinfectant, as is the
case with the silk threads. It is open to the objection,

— 202 —

which holds true also for the silk threads, that the process
of desiccation tends to lower the vitality of the organism.
Furthermore it may be urged that the disinfectant has not
free access to all sides of the bacteria.

(3.) Bacterial suspensions. This method in some of
its modifications is the one which is commonly employed
and, if used with proper precautions, yields perfectly reli-
able results. The first essential is to secure a suitable sus-
pension of the organism to be tested. For this purpose
the fresh growth on the surface of 3 or 4 agar tubes is care-
fully removed and thoroughly rubbed up in about 10 c. c. of
sterilized distilled water. In order to remove the coarse
floccules the suspension is filtered through glass wool, and
the filtrate immersed in a water-bath at 37.5° C. and fre-
quently agitated till a microscopic examination shows no
longer the presence of groups or masses of bacteria. In
this suspension now the number of bacteria present can
determined as already stated.

By means of a sterilized pipette, graduated in 1-10 c. c.,
an exact volume, 3 c. c., is transferred into each of several
sterilized test-tubes. To the suspension in one of these
tubes an equal volume of the disinfectant, of double the
strength to be tested, is added. At intervals of 2, 5, 10. 20,
30, 60 minutes etc. transfers are made to sterilized bouillon
or agar tubes and these are then set aside in the incubator
for at least one week. The inoculations should be made in
duplicate and 2 or 3 loopfuls used for each tube.

The method as given is open to the objection that an
appreciable amount of the disinfectant is transferred each
time to the culture tubes and that it may prevent growth.
This is specially true with substances which possess
marked antiseptic properties, as mercuric chloride. Where
possible, the disinfectant should be rendered inert. Thus,
traces of mercuric chloride can be removed by precipita-
tion with hydrogen sulphide. With other substances the
error is not so marked and is partly counterbalanced by

MEMORANDA.

MEMORANDA.

— 203 —
growing the tubes in the incubator for many days.

(SCHAFFER.)

LABORATORY WORK. — The student should test, by the
methods given, the disinfecting action of mercuric chloride
(1-1000), carbolic acid (5 per cent), hydrochloric acid
(0.4 per cent.). Anthrax bacillus, anthrax spores, staphy-
lococcus pyogenes aureus, cholera, typhoid fever and
dipththeria bacilli may be used, suspended in distilled
water, bouillon and blood-serum.

The blood-serum required in this work may be readily
prepared as follows: — The flowing blood from an ox or
calf is received into a large sterilized Erlenmeyer flask
and when firmly clotted is carried to the laboratory and
placed in the ice-chest. After 24 — 48 hours the clear yel-
low serum separates out. A portion of this may be placed
in a beaker, diluted with 5—10 parts of distilled water,
then filled into tubes and sterilized as in the case of or-
dinary bouillon. The dilution with water prevents coagu-
lation of the blood-serum. Another portion of the blood-
serum may be filled direct in tubes which are then placed
in an inclined position in an air-bath and the temperature
slowly raised to about 80° C. which is maintained for
about one hour. The serum coagulates in the inclined
position. On the following day the tubes should be steri-
lized in the steam sterilizer for ^— 1 hour.

To obtain undiluted fluid blood-serum the blood is re-
ceived directly from the artery or vein into sterilized jars
or flasks which are protected against contamination from
the air. As soon as the serum separates it is transferred
by means of a sterilized pipette to the sterilized tubes.
When this is properly done no organisms are introduced
into the serum and hence it requires no subsequent steri-
lization.

>i,

OF THE

UNIVERSITY
of

MEMORANDA.

MEMORANDA.

MEMORANDA.

— 205 —

List of Apparatus and Aecessorie:

1
1
1

6
1
1
2

12
12
6

H

1

100
100

3
12
12

8

200
50
100

3
100

4

1

Flask, 2 litre.
I "

" y* "

" 50 c.c. Erlenmeyer.
Funnel, 15 cm. diameter.

6 "

Moist Chain hers.
Esma'ch Dishes.
Petri Dishes.

Staining Di>hes, with covers.
Watch Glasses, 5 cm. diarn.
Test Glass. 18cm. high.
Test Tubes, 150x14 mm.

125x12 "
Tumblers.
Glass Plates.
Glass Benches.
Glass Rods, 18 cm.
Cover Glasses, No. 1, % in. diarn.

Glass Slides.

Concave Slides.

Labels for Slides.

Slide Boxes.

Slide Disinfecting Jar, with top,

Six 10 cm.
Disinfecting Jar, with top, 15x20

cm.
Stain bottles, 1 oz. with pipettes,

in stand.

Glass Pipettes, 1 c.c. with iron box.
Woltfhii^el Colony Counter.
Novy Bottle for Anaerobic Tube

Culture.

Novy Anaerobic Plate Apparatus.
Cylinders, graduated, 25, 100, 1000 c.c.
Bottles, 2 oz.
Waste Dish.
Wire Gauze.

Wire Basket, large 18x18x24 cm.

" " small 10x12x18 cm.

Iron Sterilizing Box,5xl4Uxl7V£

cm

Bunsen Burner, with tubing.
Test tube Stand, for 48 tubes.
Support Board, large, 25x25 cm.
" small, 8x20 cm.
Platinum Wires, No. 23, 5 cm,
Pair Pincers, narrow pointed, 10

cm.

Pair Scissors, 14 cm.
Scalpel.
Potato Knives.
Colored Wax Pencil.
Potato brush.
Iron Water-bath, with tripod, 18

cm. diam.

Wash-bottle, siphon or bulb.
Ice apparatus for plates.
Battery Jars, 11x11 cm.
Rat Jars, with leaded top.

1 Crucible Forceps.

1 Chapman Aspirator.

1 Kipp's hydrogen generator.

1 Koch steam Sterilizer, with

crown ourner.
1 Dry Heat Sterilizer, with crown

burner.

1 Incubator, with safety lamp.

2 Thermoregulatorss.

1 Thermometer, 200° C.
1 " 00° C.

1 Microtome.

1 Microscope, with 3 objectives, %,
1-0, and 1-12; 2 eyepieces; Abbe
condenser and iris diaphragm.
1 Roll of Cotton.
12 Sheets of Filter Paper.

Rubber caps.

Fnchsine.

Gentian Violet.

Methylene Blue.

Methyl Violet.

Bismarck Brown.

Kpsine.

Picrocarrnine, Weigert's.

Anilin Oil.

Anilin Hydrochloride.

Iodine.

Potassium Iodide

Mercuric Chloride.

Carbolic Acid.

Sulphuric Acid.

Nitric Acid.

Hydrochloric Acid.

Acetic Acid.

Pyrogallic Acid.

Tannic Acid.

Ferrous Sulphate.

Sodium Carbonate.

Sodium Hydrate.

Ammonium Hydrate.

Oil of Cloves.

Oil of Cedar,

Oil of Anise.

Xylol

Alcohol.

Ether

Chloroform.

Paraffin, 40°, 46°, 52°, 56° C.

Collodium.

Celloidin

Sealing Wax

Tube of Canada Balsam,

Gelatin, silver.

Agar-Agar.

Peptone^ sice. Witte.

Glucose.

Glycerine.

Litmus.

Vaseline.

Extract of Meat.

ERRATA.

Page 15. — Above the fifth line from the bottom insert:
Classification according to oxygen requirements— aerobic and
anaerobic.

Gradations in requirements— facultative and obligative.

Page 122.— On the 23rd. line read "Cultures in"

Page 123. — First line, read "Culture" instead of "Cultures."

MEMORANDA.

INDEX.

Abbe condenser. 12.
Achorion. 126, 186.
Aetinomyces, 126. 184.
Aerobic bacteria, 204.
Aerogenic bacteria, 17.
Agar, nutrient, 95.

plates, 136.
" roll-tubes. 136.
" streak cultures. 126.
Air, 77.

Alkaline methylene blue, 140.
Amoeba coli, 174.

Anaerobic apparatus for tubes, 124.
" *' " plates, 125.

Anaerobic bacteria, 116-122, 204.

•* culture of, 123.
Anilin water, 106.

" fuchPine, 128.
" gentian violet, 106.
" hydrochloride, 130, 194.
Animal inoculations, 101, 200.
Animal parasites, 100.
Anthrax bacillus, 114.
" sections, 191.
" work with, 104.
Arthrospore, 10.
Asiatic cholera, 148, 158.
Aspergillus flavescens, 88
" furnigatus, 90.

" niger, 88.

Asporogenic bacteria, 10.
Attenuation, 100, 176, 199, 200.
Bacillus, 5

" acidi lactici, 66.

" anthracis, 114.

" butyrieus, 68.

" of chicken cholera, 176.

•' coli communis, 158.

" cyanogenus, 70.

" diphtheria?, 140.

" fluorescens putidus, 44.

of Friedlaehder, 144.
•' of hog cholera, 178.
" of hog erysipelas, 180.

Indicus, 36.
" leprae, 134.
mallei, 138.
" mega teri urn, 56.
" mesentericus vulgatus, 54.
" murisepticus, 182.
" Neapolitanus, 156.
" oedernatis rnaligni, 118.

Bacterium, 5.

coli commune, 158.
" of hog cholera, 178.

phosphorescens, 46.
" terrno, 60.

" Zopfli, 62.

Black-leg, 116.
Blue milk, 70.
Blue pus, 168.
Blood-serum, 203.
Botkin apparatus, 124.
Bouillon, 95.
Bread flasks, 78.
Buchner's method, 124.
Butyric acid, 17, 68, 120.
Calcium hydrate agar, 103.
Capsule, 7, 142, 144, 172.
Carbolic fuchslne, 110.
Caries, dental, 18, 66.
Cedar oil, 12.
Cell wall, 7.
Charbon, 114.
Cheese spirillum, 152.
Chemistry of bacteria, 17.
Chicken cholera, 154, 176. 196.

" tuberculosis, 132.
Chlorophyll, 7, 15.
Cholera, Asiatic, 148, 158.

" of chicken, 154, 176.

" nostras, 150.
Chromogenic bacteria, 17.
Classification, 5, 15, 17, 18, 94, 204.

" of plants, 94.

Clostridium, 10.
Colony, 9, 21,97.

" examination of 25.
Comma bacillus, 148.
Concave slide, 13.
Condenser, Abbe, 12.
Cover-glasses, 12.

" " preparation, 19, 106.

" " for disinfection, 201.
Croupous pneumonia, 142.
Cutting sections, 190.
Deep layer cultures. 123, 125.
Deneke's bacillus, 152.
Diaphragm, Iris, 12.
Diphtheria, 140.

sections, 195.
Diplococcus, 11.

of pneumonia, 142.

Disinfection, methods of, 197, 200.
No. II, 120.Drum-stick forms, 10.

prodigiosus, 34. Eberth's bacillus, 160.

pyocyaneus, 168. Ebner's solution, 194.

ramosus, 58. Emmerich's bacillus, 156.

of rhinoscleroma, 146. Endocarditis, 164, 166.

rnber of Kiel, 38. Endospore, 10.

rubidus, 40. Enzyme, 17.

subtilis, 52. Erysipelas, 162. 164.

of symptomatic anthrax, 116. Escherlch's bacillus, 158.

tetani, 122. Esmarch potato culture, 30.

" tuberculosis, 132. Esmarch roll culture, 30.

" typhi abdominalis, 160. Facultative, 15, 204.

" violaceus, 42. Farcy, 138.

Bacteria, 5, 94. Favus, 126, 186.

— 208

Fermentation, 17.
Kinkier-Prior's bacillus, 150.
Fhigellu, 7.

'• staining of. 126.
Flnoresfriuw bacillus. 44.
Frankel'sdiplococrus. 142, l'.»5.
FnetJleenUers baeiliu.-, 144.
Fungi, 5, <M, 100.
Gelatin, niurient, 0.

plates. 2!, 2).
" roll cultures, 3'.).

stich cultures, 27.
Generation, 10).
Giant whins, 7. 116-120.
Glanders, 130, 138.

" sections, 19").
Glucose agar.96.

bouillon, 95.
gelatin. 124.
Glycerine ayar, 9 i.
Golden pus producing coccus, ICO.
Gonococcus, 171).
Gonorrhoea, 170.
Gram's method, cover-glasses, 108.

" " sections, 192.

Granulose, 7.
Green pus, 108.
Growth, (Conditions of, 15.
Gruber's tnl)es, 123.
Hanging-drop culture, 105.

examination, 12.
Hardening tissue, 189.
Hav baciliu.s, 52.
Herpes, i?-6.
liog cholera, 173.
Hog erysipelas, 180.
Hydrogen cultures, 124, 125.
Hydrogen sulphide, 18, 122, 180.
Hydrothionuria, is.
Impression preparations, GO.
Indol reaction, 148.
Infection, 98.

methods of, 101.
Infectious diseases, 98
Insolation, 10, 38.
Intoxication, 98.
Involution forms 5.
Iodine solution, 107.
Iris diaphragm, 12
Isolation of bacteria, 8. 21, 9!», 104.
'• Klatsch " preparation's, 00.
Lactic acid, 17, 00.
Leprosy, 134

sections, L94.
Liborius tubes, 124.
Liebig's meat' extract, 96.
Liquefaction. 18.
Litmus media, 121.
Lock-jaw, 122.
Ldffler's methyiene blue, 140.

mordant, 128.
Lumpy-jaw, 120, 184.
Lupus, 1 32
Malignant oedema, 1 18. i

sections, 193.
Malignant oedema, No. II, 12U

•*.•-. " " " sect ions, 194

Malignant, pustule, 111.
Mai lei n, 138.
Meningitis, 142.
Meningococcus. 142.
Mercuric chloride, 8, 189, 199.
Microcorcus, 5.

of gonorrhoea, 170.
pneumonias, 142.
prodigiosus, 34.
tetrasienus, 172.
" " sections, 196.

Microscope, 12.

Micros poron, 180.

Mi Ik, 75.

Mixed infection, 120, 144, 164.

Moist chamber. 8, '24

Monilia Candida, 188.

Mordant, 128.

Morve, 138.

Motion, 7

Moulds, 78, 94.

'• culture of. 7S

" examinalion of, 78.

Mouse septicaemia, 182.

Mucor corymbifer. 84.

rhizopodiformis. 8fi.

Multiplication of bacteria, 10, 11.

Tsitrification. 18.

Non ])athogenic bacteria, 1^.

Non-toxicogenic bac;cria, IS.

Nucleus, 7.

Qiiligative, 15,204

< >bjectives, 12.

(Edema, malignant. 118, 120.

Oidium albicans, 88.
lactis, 72.

Orange sarcine. 48.

Osteomyelitis, HJ ,.

Paraffin sections, 190

Parasitic bacteria, 15.

Pathogenic bacteria, 18. 97.

Penicillium glaucum, 82.

Pericarditis, 142.

Peritonitis, 142.

Petri dish cultures, 29.

Pfeiffer's method, 192.

Phagocytes, li.l.

l>hosphore^cence, IS, 46.

Photobacterium, 46

Phoiogenic bacteria, 17.

Pigment, 18,04.

Pityriasis, 180.

Plasmodium, 174.

Plants. 94.

Plates, sterilization of, 22, 29.

Plates, culture on, 21, 29, 130.

Pleuritis, 142.

Pneumococcus, 144.

Pneumonia, 142, 144, 195.

Poisoned arrows, 110, 1 18, 122.

Post-mortem examination, 103.

Potato bacillus, 54.

cultures. 7, 30.
" Esmarch cultures, 30.
" tube culture, 31.

Precautions. !», 102, 101.

Proteids, 17.

Proteus vulgaris, 00.

Ptomaines, 17.

Puerperal fever, 161.

Pure culture, 9, 21,26, 97.

Putrefaction, 18.

Pya>miu, 104

sections. 196.

Pyrogallate met hod, 124, 125.

Quarter-evil, 1 10.

Kag-picker'-s disease. 114, 118.

Kay-fungus, 184.

Recurrent lever, 171

Red bacillus of Kiel, 38.
". \vater, 40.

Ked yeast, 92.

Relapsing lever, 174.

Reproduction, of bacteria, 10.

Khinoscleroma, 146.

Roll culture, agar, 136.
gelatin, 30.

Root bacillus, 53.

Rouget, J80.

— 209 —

Rules of Koch, 98.
Saccharomyces, 79, 188.
Sjiliva. 21, 30, 142, 144, 172.
Saprogenic bacteria, 17.
Saprophytic bacteria, 15.
Sarcine, 11.

" orange, 48.
" yellow, 50.
Sections, "89.

" Gram's stain, 192.
" simple stain, 191.
" tubercle, 194.
Septicemie, 118.
Silk threads, 198,200.
Soil, 7(i.
Spirillum, 5.

" Oberrneieri, 174.

rubrurn, 64.
" tyrogenum, 152.

Spirocheete, 174.
Splenic fever, 114.
Spontaneous generation, 15.
Spores, 10, 109, 197.
Spores, double stain, 109.
Sporogenic granules, 10, 105.
Sporozoa, 100.
Sputum, 130, 142, 144,172.
Sputum septica3mia, 142.
Siaining coverglasses, simple, 19, 106.

Gram's, 106.
" tubercle, 130.

Staining sections, 191.
Stains, 19.
Staphylococcus. 11.

" pyog. albus, 166.

" aureus, 166, 196.
" citreus. 166.
Sterilization of media, 6, 8, 78, 96, 203.

" plates, 22, 29.
" " tubes, 6.

Stich cultures, 27.
Streak cultures, 32, 126.
Streak preparations, 106.
Streptococcus, 11.

erysipelatis, 162.
pyogenes, 164, 196.

Summer diarrhoea, 18.

Suppuration, 162-172.

Suspensions for disinfection, 202.

Swine plague, 178.

Symptomatic anthrax, 116, 194.

Temperature. 15, 198.

Testing disinfectants, 200.

Tetanus, 122.

Tetrads. H.

Threads, 11.

Threads for disinfection, 198.

Thrush, 1 88

Toxicogenic bacteria, 18.

Tricophyton, 186.

Tubercle bacillus, 126, 130,132.

sections, 194. ;
sputum, 130.
Tuberculin, 1&2.
Tuberculosis of chicken, 132.
Typhoid fever, 160, 195.
TTrine, fermentation of, 18.
Vficuum cultures, 123, 125.
Vibrio, 5.

of Asiatic cholera, 148.
of Deneke, 152.
of Finkler-Prior, 150.
Metchnikovi, 154, 176.
proteus, 150.
Vibrion butyrique, 68.
Vibrion septique, 118.
Violet bacillus of water, 42.
Water, 73.
Whips, 7.

Wool-sorter's disease, 114.
Wurzel bacillus, 58.
Yeast, 5, 94.

" baker's, 79.

" black, 79.

" red, 79, 92.

" white, 79.
Yellow sarcine, 50.
Ziehl-Neelsen method, 130.
Ziehl's solution, 110.
Zoogloea, 7.
Zymogenic bacteria, 17.

MEMORANDA.

BOOK T ,„. ^

132699

JUBRARY
G

i

THE I

r " * fI70IJ

TBRARY