HARVARD UNIVERSITY 


L_IihkWANR Y 


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> ait a Po = ey i 


MARVELS OF POND-LIFE: 


OR, 


A YEAR’S MICROSCOPIC RECREATIONS 


AMONG THE 


POLYPS, INFUSORIA, ROTIFERS, WATER-BEARS, 
AND POQLYZOA. 


BY 


HENRY J. SLACK, F.GS., 


SECRETARY TO THE ROYAL MICROSCOPICAL SOCIETY ; 


AUTHOR OF 
“SHE PHILOSOPHY OF PROGRESS IN HUMAN AFFAIRS,’ ETC. ETC: 


os 


SECOND EDITION. 


—____——— 


ILLUSTRATED WITH COLOURED PLATES AND NUMEROUS 
WOOD ENGRAVINGS. 


LONDON: 
GROOMBRIDGE AND SONS, 
5, PATERNOSTER ROW. 
MDCCCLXXI. 


¥, 


eeniiae Tahar ie) 


te PRINTED BY J. E. ADLARD, 
-BARTHOLOMEW CLOSE. 


INTRODUCTION. 


As this little book is intended to be no more than an 
introduction to an agreeable branch of microscopical study, 
it is to be hoped it will not require a formal preface; but 
a few words may be convenient te indicate its scope and 
purpose. 

The common experience of all micrescopists confirms the 
assertion made by Dr. Goring, that the most fascinating 
objects are living creatures of sufficient dimensions to be 
easily understood with moderate magnification; and in no 
way can objects of this description be so readily obtained, 
as by devoting an occasional hour to the examination of the 
little ponds which are accessible from almost any situation. 
A complete volume of pond lore would not only be a bulky 
book—much bigger than the aldermanic tomes which it is 
the fashion to call “ Manuals,” although the great stone 
fists in the British Museum would be required to grasp 
them comfortably,—but its composition would overtask all 
the philosophers of our day. In good truth, a tea-spoonful 
of water from a prolific locality often contains a variety of 
living forms, every one of which demands a profound 
and patient study, if we would know but a few things 
concerning it. 

To man, then, is a vast and a minute. Our minds ache 
at the contemplation of astronomical immensities, and we 
are apt to see the boundless only in prodigious masses, 


1V Introduction. 


countless numbers, and immeasurable spaces. The Creative 
Mind knows no such limitations; and the microscope 
shows us that, whether the field of nature’s operation be 
what to our apprehension is great or small, there is no 
limit to the exhibition of marvellous skill. If the “un- 
devout astronomer” be “mad,” the undevout microscopist 
must be still more so, for if the matter be judged by human 
sense, the skill is greateras the operation is more minute; 
and not the sun itself, nor the central orb round which he 
revolves, with all his attendant worlds, can furnish sublimer 
objects of contemplation, than the miraculous assemblage of 
forces which make up the life of the smallest creature that 
the microscope reveals. 

There is an irresistible charm in the effort to trace 
beginnings in nature. We know that we can never 
succeed ; that each discovery, which conducts back towards 
some elementary law or principle, only indicates how much 
still lies behind it: but the geologist nevertheless loves to 
search out the first or oldest traces of life upon our globe ; 
and so the microscopist delights to view the simplest 
exhibitions of structures and faculties, which reach their 
completion in the frame and mind of man. That one great 
plan runs through the whole universe is now an universally 
accepted truth, and when applied to physiology and natural 
history, it leads to most important results. 

The researches of recent philosophers have shown us 
that nature cannot be understood by studying the parts of 
animals with reference merely to their utility in the 
economy of the creature to which they belong. We do, 
indeed, find an admirable correspondence between struc- 
tures and the services they perform; but every object in 
creation, and every part of it, is in harmonious relation to 
Some grand design, and exhibits a conformity to some 
general mode of operation, or some general disposition and 
direction of forces, which secures the existence of the 


Introduction. v 


individual or the species, and at the same time works out 
the most majestic schemes. Microscopic researches, such 
as are within the reach of millions, offer many of the most 
beautiful illustrations of these truths; and although the 
following pages are confined to such objects as are easily 
obtainable from ponds, and relate almost exclusively to the 
Infusoria, the Rotifers, the Polyps, and the Polyzoa, it is 
hoped that they will assist in associating a few of the highly 
suggestive reaSonings of science, with one of the most 
pleasurable recreations that human ingenuity has devised. 
After a preliminary chapter, which is intended to assist 
the young microscopist in some technical matters, that 
could not be conveniently introduced into the text, the 
observations are distributed in chapters, corresponding with 
the twelve calendar months. This arrangement was sug- 
gested by the author’s diary of operations for the year 
1860, and although it by no means follows that the months 
in which particular creatures were then discovered, will be 
those in which they will be most readily found in other 
years, it was thought advantageous to give a real account 
of an actual period of microscopic work, and also that the 
plan would facilitate a departure from the dry manner of a 
technical treatise. The index will enable any one to use 
the book for the purpose of reference, and it will be 
observed that the first chapter in which any member of a 
group of creatures is introduced, is that in which a general 
description of the class is given. The illustrations are 
taken from drawings made by the wife of the author from 
the actual objects, with the exception of a few instances, in 
which the authority is acknowledged. The sketches were 
made especially for beginners, and the rule followed, was 
not to introduce any details that could not be seen at 
one focus, and with the simplest means: more elaborate 
representations, though of the highest value to advanced 


students, are bewildering at the commencement. 
b 


vi Introduction. 


The ponds referred to are all either close to, or within a 
moderate distance of, London ;* but similar objects will in 
all probability be obtained from any ponds similarly 
situated, and the descriptions and directions given for the 
capture of the minute prey will be found generally applic- 
able. Care has been taken throughout to explain the most 
- convenient methods of examining the objects, and although 
verbal descriptions are poor substitutes for the teachings of 
experience, it is hoped that those here given will remove 
some difficulties from a pursuit that no intelligent person 
can enter upon without pleasure, or consent to abandon 
when its elementary difficulties have been mastered, and 
the boundless fields of discovery are opened to view. Let 
not the novice be startled at the word “discovery.” It is 
true that few are likely to arrive at new principles or facts 
which will inscribe their names upon the roll of fame; but 
no one of ordinary powers can look at living objects with 
any considerable perseverance, without seeing much that 
has never been recorded, and which is nevertheless worthy 
of note; and when the mind, by its own exertions, first 
arrives at a knowledge of new truth, an emotion is felt 
akin to that which more than recompenses the profoundest 
philosopher for all his toil. 


* Many are now (1871) destroyed by the progress of building. 


CONTENTS. 


CHAPTER I. 


MICROSCOPES AND THEIR MANAGEMENT. 
PAGE 


Powers that are most serviceable—Estimated by Focal 
length—Length of Body of Microscope and its Effects— 
Popular Errors about Great Magnification—Modes of 
Stating Magnifying Power—use of an ““Hrector”— Power 
of various Objectives with different Eye-pieces—Exami- 
nation of Surface Markings—Methods of Illumination 
—Direct and Oblique Light—Stage Aperture—Dark- 
ground Illumination—Mode of Softening Light—Micro- 
scope Lamps—Care of the Eyes ; : ‘ 


‘ 


CHAPTER II. 
JANUARY. 


Visit to the Ponds—Confervee—Spirogyra quinina— Vorti- 
cella—Common Rotifer—Three Divisions of Infusoria— 
Phytozoa—Protozoa—Rotifera—Tardigrada—Meaning 
of these Terms—Euglene—Distinction between Animals 
and Vegetables—Description of Vorticella—Dark- 
ground Ilumination—Modes of producing it—The 


Vill Contents. 


PAGE 
Nucleus of the Vorticella—Methods of Reproduction— 
Ciliated Protozoa—Wheel-bearers or Rotifers—Their 
Structure—The Common Rotifer—The young Rotifer 
seen inside the old one—an Internal Nursery—“ Differ- 
entiation ” and “ Specialization ”—Bisexuality of Roti- 
fers—Their Zoological Position—Diversities in their 
Appearance—Structure of their Gizzard—Description of 
Rotifers . Pere ‘ ses mB ee 


CHAPTER ITI. 
FEBRUARY. 


Visit to Hampstead—Small ponds— Water- Fleas— Water- 
Beetle—Snails—Polyps—Hydra viridis—The Dipping- 
tube—A Glass Cell—The Hydra and its Prey—Chy- 
dorus Sphezricus and Canthocamptus, or Friends and — 
their Escapes—Cothurnia—Polyp Buds—Catching 
Polyps—Mode of Viewing Them—Structure of Polpys— 
Sarcode—Polyps Stimulated by Light—Are they Con- 
scious P—Tentacles and Poison Threads—Paramecium 
—Tracheliuns—Motions of Animalcules, whether Autom- 
atic or directed by a Will—Their Restless Character . 30 


CHAPTER IV. 
MARCH. 


Paramecia—Effects of Sunlight—Pterodina patina—Curi- . 
ous Tail—Use of a Compressorium—Internal Structure 
of Pterodina—Metopidia—Trichodina pediculus—Co- 
thurnia—Salpina—Its Three-sided Box—Protrusion of 
its Gizzard Mouth . pikes ; : ; » Se Ra 


Contents. 1x 


CHAPTER V. 


APRIL. 


PAGE 
The Beautiful Floscule—Mode of Seeking for Tubicolar 


Rotifers—Mode of Illuminating the Floscule—Difficulty 
of seeing the Transparent Tube—Protrusion of Long 
Hairs—Lobes—Gizzard—Hairy Lobes of Floscule not 
Rotatory Organs—Glass Troughs—Their Construction 
and Use—Movement of Globules in Lobes of Floscule— 
Chetonotus larus—Its mode of Swimming—Coleps 
hirtus—Devourer of Dead Entomostraca—Dead Rotifer 
and Vibriones—Theories of Fermentation and Putrefac- 
tion—Huplotes and Stylonichia—Fecundity of Styloni- 
chia : d : avons : ee ; . o4 


CHAPTER VI. 
MAY. 


Floscularia cornuta—Euchlanis triquetra—Melicerta rin- 
gens—lIts Powers as Brick-maker, Architect, and Mason 
—Mode of Viewing the Melicerta—Use of Glass Cell— 
Habits of Melicerta—Curious Attitudes—Leave their 
Tubes at Death—Carchesium—Epistylis—Their Ele- 
gant Tree Forms—A Parasytic Epistylis like the “ Old 
Man of the Sea”—Halteria and its Leaps—Aspidisca 
lynceus  . ; , : : : : Bares 369 


CHAPTER VII. 
JUNE AND JULY. 


Lindia torulosa—Ccistes crystallinus—A Professor of 
Deportment on Stilts—Philodina—Changes of Form 


x Contents. 


PAGE 
and Habits—Structure of Gizzard in Philodina Family 
—Mr. Gosse’s Description—Motions of Rotifers—Indi- 
cations of a Will—Remarks on the Motions of Lower 
Creatures— Various Theories—Possibility of Reason— 
Reflex Actions—Brain of Insects—Consensual Actions 
—Applications of Physiological Reasoning to the Move- 
ments of Rotifers and Animalcules ; ; , ia 


CHAPTER VIII. 


AUGUST. 


s 


Mud Coloured by Worms—Their Retreat at Alarm—A 
Country Duck-Pond—Contents of its Scum—Crypto- 
monads—Their Means of Locomotion—A Triarthra 
(Three-limbed Rotifer)—The Brachion or Pitcher Roti- 
fer—Its Striking Form—EHnormous Gizzard—Cilary 
Motion inside this Creature—Large Eye and Brain— 
Powerful Tail—Its Functions—Eggs . : é . &6 


CHAPTER IX. 
SEPTEMBER. 


Microscopic Value of Little Pools—Curious Facts in Ap- 
pearance and Disappearance of Animalcules and Roti- 
fers—Mode of Preserving them ina Glass Jar—Frag- 
ments of Melicerta Tube—Peculiar Shape of Pellets— 
Amphileptus—Scaridium longicaudum—A_ Long-tailed 
Rotifer—Stephanoceros Hichornii—A Splendid Rotifer 
—Its Gelatinous Bottle—Its Crown of Tentacles— 
Retreats on Alarm—TIllumination Requisite to see its 
Beauties—Its Greediness—Richly-coloured Food—Ner- | 
Pane Anemia oo iy eo! ape cl, ; ee Me" 


Contents. Xl 


CHAPTER X. 


OCTOBER. 
PAGE 


Stentors and Stephanoceri—Description of Stentors— 
Mode of viewing them—Their Abundance—Social 
Habits—Solitary Stentors living in Gelatinous Caves— 
Propagation by Divers Modes—Cephalosiphon limnias— 

A Group of Vaginicole—Changes of Shape—A Bubble- 
blowing Vorticella . b : ‘ é ; 3 LICE 


CHAPTER XI. 
NOVEMBER. 


Charactéristics of the Polyzoa—Details of Structure ac- 
cording to Allman—Plumatella repens—Its Great 
Beauty under proper Illumination—Its Tentacles and 
their Ciia—The Mouth and its Guard or Epistome— 
Intestinal Tube—How it swallowed a Rotifer, and what 
happened—Curiosities of Digestion—Are the Tentacles 
capable of Stinging P—Resting Eggs, or “ Statoblasts ” 
—Tube of Plumatella—Its Muscular Fibres—Physiolo- 
gical Importance of their Structure. : : . 118 


\ 


CHAPTER XII. 
DECEMBER. 


Microscopic Hunting in Winter—Water-Bears, or Tardi- 
grada—Their Comical Behaviour—Mode of viewing 
them—Singular Gizzard—Wenham’s Compressorium— 
Achromatic Condenser—Mouth of the Water-Bear— 
Water-Bears’ Exposure to Heat—Soluble Albumen— 
Physiological and Chemical Reasons why they are not 


} 


xl Contents. 


PAGE 
killed by Heating or Drying—The Trachelius ovuam— 
Mode of Swimming—Method of Viewmg—By Dark- 
ground Illumination—Curious Digestive Tube with 
Branches—Multiplication by Division—Change of Form 
immediately following this pao a a Ap- 
pearances ; : 3 : ; : : . 128 


CHAPTER XIII. 


ConcLusion.—Remarks on Classification, &. . i . 140 


MARVELS OF POND-LIFE. 


CHAPTER I. 


PLAIN HINTS ON MICROSCOPES AND THEIR 
MANAGEMENT. 


Powers that are most serviceable—Estimated by focal length—Length 
of body of microscope and its effects—Popular errors about great 
magnification—Modes of stating magnified power—Use of an 
“ Erector ”—Power of various objectives with different eye-pieces 
—Examination of surface markings—Methods of illumination— 
Direct and oblique light—Stage aperture—Dark ground illumina- 
tion—Mode of softening light—Microscope lamps—Care of the eyes. 


panion of every intelligent family that can 
afford its purchase, and, thanks to the skill of 
our opticians, instruments which can be made to answer 
the majority of purposes may be purchased for three 
or four guineas, while even those whose price is counted 
in shillings are by no means to be despised. The most 
eminent English makers, Wales, and Toller, in America, 
and Hartnack, in Paris, occupy the first rank, while the 
average productions of respectable houses exhibit so 
high a degree of excellence as to make comparisons . 
] 


2 Marvels of Pond-Life. 


invidious. We shall not, therefore, indulge in the praises 
of particular firms, but simply recommend any reader 
entering upon microscopic study to procure an achro- 
matic instrument, if it can be afforded, and having at 
least two powers, one with a focus of an inch or two 
thirds of an inch, and the other of half or a quarter. 
Cheap microscopes have usually only one eye-piece, 
those of a better class have two, and the best are fur- 
nished with three, or even more. 

The magnifying power of a compound microscope 
depends upon the focal length of the object-glass (or 
glass nearest the object), upon the length of the tube, 
and the power of the eye-piece. With regard to object- 
glasses, those of shortest focal length have the highest. ~ 
powers, and the longest eye-pieces have the lowest 
powers. The body of a microscope, or principal tube 
of which it is composed, is, in the best instruments, 
about nine inches long, and a draw tube, capable of 
being extended six inches more, is frequently useful. 
From simple optical principles, the longer the tube the 
higher the power obtained with the same object-glass ; 
but only object-glasses of very perfect construction will 
bear the enlargement of their own imperfections, which 
results from the use of long tubes; and consequently for 
cheap instruments the opticians often limit the length of 
the tube, to suit the capacity of the object-glasses they 
can afford to give for the money. Such microscopes 
may be good enough for the generality of purposes, but 
they do not, with glasses of given focal length, afford 
the same magnifying power as is done by instruments 
of better construction. The best and most expensive 


Marvels of Pond-Life. 3 


glasses will not only bear long tubes, but also eye-pieces 
of high power, without any practical diminution of the 
accuracy of their operation, and this is a great con- 
venience in natural history investigations. To obtain 
it, however, requires such perfection of workmanship 
as to be incompatible with cheapness. An experienced 
operator will not be satisfied without having an object- 
glass at least as high as a quarter, that will bear a deep 
eye-piece, but beginners are seldom successful with a 
higher power than one of half-inch focus, or there- 
abouts, and before trying this, they should familiarise 
themselves with the use of one with an inch focus. 

It is a popular error to suppose that enormous mag- 
nification is always an advantage, and that a microscope 
is valuable because it makes a flea look as big as a cat 
oracamel. The writer has often smiled at the excla- 
mations of casual visitors, who have been pleased with 
his microscopic efforts to entertain them. ‘“ Dear me, 
what a wonderful instrument; it must be immensely 
powerful ;’ and soforth. These ejaculations have often 
followed the use of a low power, and their authors have 
been astonished at receiving the explanation that the 
best microscope is that which will show the most with 
the least magnification, and that accuracy of defi- 
nition, not mere increase of bulk, is the great thing 
needful. 

Scientific men always compute the apparent enlarge- 
ment of the object by one dimension only. ‘Thus, 
supposing an object one hundredth of an inch square 
were magnified so as to appear one inch square, it 
would, in scientific parlance, be magnified to “ one hun. 


a Marvels of Pond-Life. 


dred diameters,” or one hundred linear ; and the figures 

100 would be appended to any drawing which might be 
made from it. It is, however, obvious that the length 
is magnified as well as the breadth; and hence the 
magnification of the whole surface, in the instance 
specified, would be one hundred times one hundred, or 
ten thousand: and this*is the way in which magnifi- _ 
cation is popularly stated. A few moments’ considera- 
tion will show that the scientific method is that which 
most readily affords information. Any one can in- 
stantly comprehend the fact of an object being made 
to look ten times its real length; but if told that it is 
magnified a hundred times, he does not know what this 
really means, until he has gone through the process of 
finding the square root of a hundred, and learnt that a 
hundredfold magnification means a tenfold magnification 
of each superficial dimension. If told, for example, 
that a hair is magnified six hundred diameters, the 
knowledge is at once conveyed that it looks six hundred 
times as broad as it is; but a statement that the 
same hair is magnified three hundred and sixty 
thousand times, only excites a gasping sensation 
of wonder, until it is ascertained by calculation that 
the big figures only mean what the little figures express. 
In these pages the scientific plan will always be fol- 
lowed. 

If expense is not an object, a binocular instrument 
should be purchased, and it is well to be provided with 
an object-glass as low as three or even four inches focus, 
which will allow the whole of objects having the diameter 
of half an inch or more to be seen at once. Such a low 


Marvels of Pond-Life. 8 


power is exceedingly well adapted for the examination 
of living insects, or of the exquisite preparations of 
entire insects, which can now be had of all opticians. 
Microscopes which have a draw tube can be furnished 
with an erector, an instrument so called because it 
erects the images, which the microscope has turned 
upside down, through the crossing of the rays. This is 
very convenient for making dissections under the in- 
strument; and it also gives us the means of reducing 
the magnifying power of an object-glass, and thus 
obtaining a larger field. The erector is affixed to the 
end of the draw tube, and by pulling it out, or thrusting 
it in, the rays from the object-glass are intercepted at 
different distances, and various degrees of power ob- 
tained. 

A binocular microscope is most useful with low 
powers from two thirds upwards. A new form, devised 
by Mr. Stephenson, acts as an erector, and is very 
valuable for dissections. It works with high powers. 

Beginners will be glad to know how to obtain the 
magnifying power which different objects require, and 
it may be stated that, with a full-sized microscope, a 
two-inch object-glass magnifies about twenty-five dia- 
meters with the lowest eye-piece; a one-inch object- 
glass, or two thirds, from fifty to sixty diameters; a 
half-inch about one hundred ; a quarter-inch about two 
hundred. The use of deeper eye-pieces adds very con- 
siderably to the power, but in proportions which differ 
with different makers. One instrument used by the 
writer has three eye-pieces, giving with a two thirds 
object-glass powers of sixty one hundred and five, and 


6 Marvels of Pond-Life. 


one hundred and eighty respectively; and with 
a fifth two hundred and forty, four hundred and, 
thirty, and seven hundred and twenty, which can be 
augmented by the use of a draw tube. 

It has been well observed that the illumination of 
objects is quite as important as the glasses that are 
employed, and the most experienced microscopists have 
never done learning in this matter. Most microscopes 
are furnished with two mirrors beneath the stage, one 
plane and one concave. ‘The first will throw a few 
parallel rays through any transparent object properly 
placed, and the latter causes a number of rays to 
converge, producing a more powerful effect. The first 
is usually used in daylight, when the instrument is 
near a window (one with a north aspect, out of direct 
sunlight, being the best); and the second is often 
useful when the source of illumination is a candle or a 
lamp. By varying the angle of the mirror the light is 
thrown through the object more or less obliquely, and 
its quantity should never be sufficient to pain the eye. 
Few objects are seen to the best advantage with a 
large pencil of perfectly direct light, and the beginner 
should practise till the amount of inclination is obtained 
which produces the best effect. 

It is advisable that the hole in the stage of the 
microscope should be large—at least an inch and a half 
each way—so that the entrance of oblique rays is not 
obstructed, and it is desirable that the mirror, in 
addition to sliding up and down, should have an arm 
by which it can be thrown completely out of the 
perpendicular plane of the body of the instrument. 


Marvels of Pond-Life. . a 


_ This enables such oblique rays to be employed as to 
give a dark field, all the light which reaches the eye 
being refracted by the object through which it is sent. 
The opticians sell special pieces of apparatus for this 
purpose, but though they are very useful, they do not 
render it less desirable to have the mirror mounted as 
described. 

Most microscopes are furnished with a revolving 
diaphragm, with three holes, of different sizes, to 
diminish the quantity of light that is admitted to the 
object. This instrument is of some use, and offers a 
ready means of obtaining a very soft agreeable light for 
transparent objects, viewed with low powers. For this 
purpose cut a circular disk of India or tissue paper, 
rather larger than the biggest aperture; scrape a few 
little pieces of spermaceti, and place them upon it, then 
put the whole on a piece of writing-paper, and hold it 
a few inches above the flame of a candle, moving it 
gently. Ifthis is dexterously done, the spermaceti will 
be melted without singeing the paper, and when it is 
cold the disk will be found transparent. Place it over 
the hole in the diaphragm, send the light through it, 
and the result will be a very soft agreeable effect, well 
suited for many purposes, such as viewing sections of 
_ wood, insects mounted whole, after being rendered 
transparent, many small water creatures, etc. Another 
mode of accomplishing this purpose is to place a 
similarly prepared disk of paper on the flat side of a 
bull’s-eye lens, and transmit the light of a lamp through 
it. This plan may be used with higher powers, and 
the white opaque light it gives may be directed 


& Marvels of Pond-Life. 


at any angle by means of the mirror beneath the 
Stage. : . 

An ordinary lamp may be made to answer for micro- 
scopic use, but one of the small paraffine lamps now 
sold everywhere for eighteen-pence is singularly conve- 
nient. It is high enough for many purposes, and can 
easily be raised by one or more blocks. A paraffine 
lamp on a sliding stand is still more handy, and all the 
better for a hole with a glass stopper, through which 
the fluid can be poured. 

Many people fancy that the eyes are injured by 
continual use of the microscope, but this is far from 
. being the case if reasonable precautions are taken. 
The instrument should be inclined at a proper angle, 
all excess of light avoided, and the object brought into 
focus before it is steadily looked at. Most people 
solemnly shut one eye before commencing a micro- 
scopic examination ; this is a practical and physiological 
mistake. Nature meant both eyes to be open, and 
usually resents a prolonged violation of her intentions 
in this matter. It requires but a little practice to keep 
both eyes open, and only pay attention to what is seen 
by that devoted to the microscope. The acquisition of 
this habit is facilitated, and other advantages gained, 
by a screen to keep out extraneous light. For this 
purpose take a piece of thin cardboard about nine 
inches square, and cut a round hole in it, just big 
enough to admit the tube of the microscope, about two 
inches from the bottom, and equidistant from the two 
sides. Next cut off the two upper corners of the card- 
board, and give them a pleasant-looking curve. Then 


Marvels of Pond-Life. 9 


cover the cardboard with black velvet, the commonest, 
which is not glossy, answers best, and your screen is 
made. Put the hole over the tube of the microscope, 
and let the screen rest on the little ledge or rim which 
forms an ornamental finish to most instruments. A 
piece of cork may be gummed at the back of the screen, 
so as to tilt it a little, and diminish its chance of 
coming into contact with that important organ the 
nose. ‘This little contrivance adds to the clearness and 
brilliancy of objects, and is a great accommodation to 
the eyes. 

One more oculistic memorandum, and we have done 
with this chapter. Do not stare at portions of objects 
that are out of focus, and consequently indistinct, as 
this injures the eyes more than anything. Remember 
the proverb, “ None so deaf as those that won’t hear,” 
which naturally suggests for a companion, “ None so 
blind as those that won’t see.” It is often impossible 
to get every object in the field in focus at one time ;— 
look only at that which is in focus, and be blind to all 
the rest. This is a habit easily acquired, and is one 
for which our natural microscopes are exceedingly 
grateful; and every judicious observer desires to keep 
on the best terms with his eyes. 


10 Marvels of Pond-Life. 


CHAPTER II. 


JANUARY. 


Visit to the ponds—Conferve—Spirogyra quinina—Vorticella—Com- 
mon Rotifer—Three divisions of Infusoria—Phytozoa—Protozoa 
—Rotifera—Tardigrada—Meaning of these terms—Euglene— 
Distinction between animals and vegetables—Description of 
Vorticelle—Dark ground illumination— Modes of producing it— 
The Nucleus of the Vorticelle—Methods of reproduction—Ciliated 
Protozoa— Wheel bearers or Rotifers—Their structure—The com- 
mon Rotifer—The young Rotifer seen inside the old one—An 
internal nursery — “ Differentiation” and ‘ Specialisation ” — 
Bisexuality of Rotifers—Their zoological position—Diversities in 
their appearance — Structure of their Gizzard — Description of 
Rotifers. 


favorable to the collection of microscopic 
objects from ponds and streams than the 
warmer portions of the year; but the difference is 
rather in abundance than in variety, and with a very 
moderate amount of trouble, representatives of the 
principal classes can always be obtained. 

On a clear January morning, when the air was keen, 
but no ice had yet skinned over the surface of the 
water, a visit to some small ponds in an open field not 
far from Kentish Town provided entertainment for 
several days. The ponds were selected from their open 


Marvels of Pond-Life. 1] 


airy situation, the general clearness of their water, and 
the abundance of vegetation with which they were 
adorned. Near the margin conferve abounded, their 
tangled masses of hair-like filaments often matted 
together, almost with the closeness of a felted texture. 
At intervals, minute bubbles of air, with occasionally a 
few of greater size, indicated that the complex processes 
of vegetable life were actively going on, that the tiny 
plants were decomposing carbonic acid, dexterously 
combining the carbon—which we are most familiar 
with in the black opaque form of charcoal—to form 
the substance of their delicate translucent tissues, and 
sending forth the oxygen as their contribution to the 
purification of the adjacent water, and the renovation 
of our atmospheric air. This was a good sign, for 
healthy vegetation is favorable to many of the most 
interesting forms of infusorial life. Accordingly the 
end of a walking-stick was inserted among the green 
threads, and a skein of them drawn up, dank, dripping, 
and clinging together in a pasty-looking mass. To 
hold up a morsel of this mass, and tell some one not in 
the secrets of pond-lore that its dripping threads were 
objects of beauty, surpassing human productions, in 
brilliant colour and elegant form, would provoke 
laughter, and suggest the notion that you were poking 
fun at them, when you poked out your stick with the 
slimy treasure at its end. But let us put the green 
stuff ito a bottle, with some water from its native 
haunt, cork it up tight, and carry it away for quiet 
examination under the microscope at home. 

Here we are with the apparatus ready. We have 


12 Marvels of Pond-Life. 


transferred a few threads of the conferva from the 
bottle to the live box, spreading out the fine fibres with — 
a needle, and adding a drop of water. The cover is 
then gently pressed down, and the whole placed on the 
stage of the microscope, to be examined with a power 
of about sixty. A light is thrown somewhat obliquely 
by the mirror through the object, the focus. adjusted, 
and a beautiful sight rewards the pains. Our mass of 
conferva turns out to contain one of the most elegant 
species. Fine hair-like tubes of an organic material, 
as transparent as glass, are divided by partitions of the 
same substance into cylindrical cells, through which a 
slender ribbon of emerald green, spangled at intervals 
with small round expansions, is spirally wound. We 
shall call it the Spiral Conferva, its scientific name 
being Spirogyra quinina. Some other species, though 
less elegantly adorned, make a pleasing variety in the 
microscopic scene; and appended to some of the 
threads is a group of small crystal bells, which jerk up 
and down upon spirally twisted stalks. These are the 
“Bell Flower Animalcules”’ of old observers, the 
Vorticelle, or Little Vortex-makers of the present day. 
Other small creatures flit about with lively motions, 
and among them we observe a number of green spindles 
that continually change their shape, while an odd- 
looking thing crawls about, after the manner of certain 
caterpillars, by bringing his head and tail together, 
shoving himself on a step, and then repeating the 
process, and making another move. He has a kind of 
snout, behind which are two little red eyes, and some- 
thing like a pig-tail sticks out behind. This is the 


Marvels of Pond-Life. 13 


Common Wheel-bearer, Rotifer vulgaris, a favourite 
object with microscopists, old and young, and capable, 
as we shall see, of doing something more interesting 
than taking the crawl we have described. 

A higher power, say one or two hundred, may be 
conveniently applied to bring out the details of the 
inhabitants of our live box more completely ; but if the 
glasses are good, a linear magnification of sixty will 
show a great deal, with the advantage of a large field, 
and less trouble in following the moving objects of our 
search. . 

Having commenced our microscopic proceedings by 
obtaining some Euglenez, Vorticelle, and a Rotifer, we 
are in a position to consider the chief characteristics of 
three great divisions of infusoria, which will often 
engage our attention. 

It is well known that animalcules and other small 
forms of being may be found in infusions of hay or 
other vegetable matter, and hence all such and similar 
objects were called Infusoria by early observers. Many 
groups have been separated from the general mass 
comprehended under this term, and it is now used in 
various senses. ‘The authors of the ‘ Micrographic 
Dictionary’ employ it to designate ‘‘a class of micro- 
scopic animals not furnished with either vessels or 
nerves, but exhibiting internal spherical cavities, mo- 
tion effected by means of cilia, or variable processes 
formed of the substance of the body, true legs being 
absent.” The objection to this definition is, that it 
to some extent represents theories which may not be 
true. That nerves are absent all through the class is an 


14 Marvels of Pond-Life. 


assumption founded merely upon the negative evidence 
of their not having been discovered, and the complete 
absence of “ vessels” cannot be affirmed. 

In the last edition of ‘ Pritchard’s Infusoria,’ to which 
some of our ablest naturalists have contributed, after 
separating two groups, the Desmids, and the Diatoms, 
as belonging to the vegetable world, the remainder of 
the original family of infusoria are classified as Phytozoa, 
Protozoa, Rotifera, and Tardigrada. We shall explain 
these hard names immediately, first remarking that the 
Desmids and the Diatoms, concerning whom we do not 
intend to speak in these pages, are the names of two 
groups, one distinctly vegetable, while the other, 
although now generally considered so, were formerly 
held by many authorities to be in reality animal. The 
Desmids occur very commonly in fresh water. We have 
some among our Conferve. They are most brilliant 
green, and often take forms of a more angular and 
crystalline character than are exhibited by higher 
plants. The Diatoms are still more common, and we 
see before us in our water-drop some of their simplest 
representatives in the form of minute boats made of 
silica (flint) and moved by means still in dispute. » 

Leaving out the Desmids and Diatoms, we have said 
that in Pritchard’s arrangement the views of those 
writers are adopted who divide the rest of the infusoria 
into four groups, distinguished with foreign long-tailed 
names, which we will translate and expound. First 
come the Phytozoa, under which we recognise our old 
acquaintance zoophyte turned upside down. Zoophytes 
mean animal-plants, Phytozoa mean plant-animals. We 


Marvels of Pond-Life. 15 


shall have by-and-bye to speak cof some of the members 
of this artificial and unsatisfactory group, and postpone 
to that time a learned disquisition on the difference 
between animals and plants, a difference observable 
enough if we compare a hippopotamus with a cabbage, 
but which “grows small by degrees, and beautifully 
less,”” as we contemplate lower forms. 

After the Phytozoa come the Protozoa, or first forms 
in which animality is distinctly recognised. Under this 
term are assembled creatures of very various organiza- 
tion, from the extreme simplicity of the Proteus or 
Ameba, a little lump of jelly, that moves by thrusting 
out portions of its body, so as to make a sort of ex- 
tempore legs, and in which no organs can be discerned,* 
up to others that are highly developed, like our Vorti- 
celle. This group is evidently provisional, and jumbles 
together objects that may be widely separated when 
their true structure and real affinities are discerned. 

Following the Protozoa, come the Rotifera, or Wheel- 
bearers, of which we have obtained an example from 
our pond, and whose characteristics we shall endeavour 
to delineate when our specimen is under view; and last 
in the list we have the Tardigrada, “ Slow-steppers,” or 
Water Bears, queer little creatures, something like new- 
born puppies, with a double allowance of imperfect feet. 
These, though somewhat connected with the rotifers, 
are considered to belong to a low division of the arach- 
nida (spiders, &c.). 

Feeling that we must be merciful with the long-tailed 


* In some kinds and in some stages of growth this is not strictly 
true. 


16 Marvels of Pond-Life. 


words and explanations of classification, we reserve 
further matter of this kind for the opportunities that 
must arise, and direct our attention to living forms by 
watching the Euglene which our water-drop contains. 
We have before us a number of elegant spindle-shaped 
bodies, somewhat thicker in front than behind, and in 
what may be called the head there glitters a brilliant 
red speck, commonly called an eye-spot, although, like 
the eyes of potatoes, it cannot see. Round this eye- 
spot the tissues are clear, like glass; but the body of 
the creature is of a rich vegetable green, which shines 
and glistens as it catches the light. Some swim rapidly 
with a rollicking motion, while others twist themselves 
into all manner of shapes. Now the once delicate 
spindle is oddly contorted, now it swells out in the 
middle, like a top, and now it rolls itself into a ball. 


—da, motile; and 8, resting condition of Euglene. 


The drawings will afford some idea of these protean 
changes, but they must be seen before their harlequin 
character can be thoroughly appreciated. Some of the 
specimens exhibit delicate lines running lengthwise, and 
taking a spiral twist as the creature moves about; but 
in none can any mouth be discerned, and their antics, 


“3 


Marvels of Pond-Life. ly 


although energetic and comical, afford no certain indi- 
cations of either purpose or will. What are they? 
animals. or vegetables? or something betwixt and 
between ? 

The first impression of any casual observer would be 
_ to declare in favour of their animality; but before this 
can be settled, comes the question, what is an animal, 
and how does it differ from a vegetable ? and upon this 
the learned do by no means agree. One writer con- 
siders the presence of starch in any object a proof that 
it belongs to the dominions of Flora, while another 
would decide the issue by ascertaining whether it evolves 
oxygen and absorbs carbon, as most plants do, or whether 
it evolves carbon and absorbs oxygen, as decided animals 
do. Dr. Carpenter asserts that the distinction between 
Protophyta and Protozoa (first or simplest plants and 
animals), “lies in the nature of their food, and the 
method of its introduction, for whilst the Protophyte 
obtains the materials of its nutrition from the air and 
moisture that surround it, and possesses the power of 
detaching oxygen, hydrogen, carbon, and nitrogen from 
their previous binary combinations, and of uniting them 
into ternary and quaternary organic compounds (chlo- 
rophyll, starch, albumen, &c.), the simplest Protozoa, 
in common with the highest members of the animal 
kingdom, seems utterly destitute of any such power, 
makes, so to speak, a stomach for itself in the substance 
of its body, into which it injects the solid particles that » 
constitute its food, and within which it subjects them 
to a regular process of digestion.” 

Unfortunately it is very difficult to apply this simple 

2 


18 Marvels of Pond-Life. 


theory to the dubious objects which lie on the border- 
land of the animal world, and no other theory that has 
been propounded appears to meet all cases. Some 
naturalists do not expect to find a broad line of de- 
markation between the two great divisions of living 
things, but others characterise such an idea as “ un- 
philosophical,” in spite of which, however, we incline 
towards it. | 

Mr. Gosse, whose opinion is entitled to great respect, 
calls the EHuglene “animals” in his ‘ Evenings with 
the Microscope;’ but from the aggregate of recorded 
observations it seems that they evolve oxygen, are 
coloured with the colouring matter of plants, reproduce 
their species in a manner analogous to plants, and have 
in some cases been clearly traced to the vegetable 
world. It is, however, possible that some Huglene 
forms may be animal and others vegetable, and while 
their place at nature’s table is being decided, they must 
be content to be called Phytozoa, which, as we have 
before explained, is merely Zoophyte turned upside 
down. 

Some authorities have thought their animality proved 
by the high degree of contractility which their tissues 
evince. This, however, cannot go for much, as all 
physiologists admit contractility to belong to the vege- 
table tissues of the sensitive plant, “ Venus’ Fly-trap,” 
&c., and a little more or less cannot mark the boundary 
between two orders of being. 

We shall have occasion again to notice the Proto- 
phytes, and now pass tothe Protozoa, of which we have 
a good illustration in the Vorticella already spoken of. 


Marvels of Pond-Life. 19 


In the group before us a number of elegant bells or 
vases stand at the end of long stalks, as shown at the 
- top of the frontispiece, while round the tops of the bells, 
the vibrations of a wreath or cilia produce little vortices 
or whirlpools, and hence comes the family name. This 
current brings particles of all sorts to the mouth near 
the rim of the bells, and the creature seems not entirely 
destitute of power to choose or reject the morsels ac- 
cording to its taste. Every now and then the stalk of 
some specimen is suddenly twisted into a spiral, and 
contracted, so as to bring the bell almost to the ground. 
Then the stem gracefully elongates again, and the cilia 
repeat their lively game. 

The general effect can be seen very well by a power 
of about sixty linear, but one of them from one to two 
hundred is necessary to bring out the details, and a 
practised observer will use still more magnification with 
good effect. They should be examined by a moderately 
oblique light, or most of the cilia are apt to be rendered 
invisible, and also by dark ground illumination. This 
may be accomplished in a well-made microscope by 
turning the mirror quite out of the plane of the axis of 
_ the instrument, that is to say, on one side of the space 
the body would occupy if it were prolonged. By this 
means, and by placing the lamp at an angle with the 
mirror, that must be learnt by experiment, all the light 
that reaches the eye has first passed through the object, 
and is refracted by it out of the line it was taking, 
which would have carried it entirely away. Or the 
object may be illuminated by an apparatus called a 
spotted lens, which is a small bull’s eye placed under 


20 Marvels of Pond-Life. 


the stage, and having all the centre of its face covered 
with a plaster of black silk. In this method the cen- 
tral or direct rays from the mirror are obstructed, but 
those which strike the edge of the bull’s-eye are bent 
towards the object, which they penetrate and illuminate 


! 


Vorticella, with posterior Vorticella in process of self-division. 
circlet of cilia in process of A new frontal wreath in formation in 
separation,300 linear. Sfeiz. each of the semi-lunar spaces. 


if it is sufficiently transparent and refractive. Another 
mode of dark ground illumination is by employing an 


Marvels of Pond-Life. 21 


elegant instrument called a parabolic illuminator, which 
need not be described. 

Different specimens and species of Vorticelle vary in 
the length of their bells from one three or four 
thousandth to one hundred and twentieth of an inch, 
and when they are tolerably large, the dark ground 
illumination produces a beautiful effect. The bells 
shine with a pearly iridescent lustre, and their cilia 
flash with brilliant prismatic colours. 

The Vorticellina belong to the upper division of the 
Protozoa—the ciliata, or ciliated animalcules, and they 


Vorticella microstoma, showing Vorticella microstoma, the en- 
alimentary tube, ciliated mouth, cysted animal protruding through 
and formation of a gemma atthe a supposed rupture of the tunic. 
base, 300 linear.— Stein. 


have a mouth, an cesophagus, and an orifice for the 
exit of their food. 


Many observers usea to ascribe to those creatures a. 


22 Marvels of Pond-Life. 


complete intestinal canal, but such an apparatus is now 
believed not to exist in any of the Infusoria. Food 
particles, after leaving the cesophagus, are thrust for- 
ward into the sarcode, or soft flesh, and any cavity thus 
formed acts as a stomach. 

The bells or cups are not, as might be fancied from 
a casual inspection, open like wineglasses at the top, 
but furnished with a retractile disk or cover, on which 
the cilia are arranged. Their stalks are not simple 
stems, but are hollow tubes, which in the genus Vorti- 
cella are furnished with a muscular band, by whose 
agency the movements are principally made. 

Some of the Vorticellids will be observed to leave 
their stalks, having developed cilia round their base, 
and may be seen to swim about in the enjoyment of 
individual life. They are also capable of becoming 
encysted, that is, of secreting a gelatinous cover. 


iq i i Thins . 
‘ i te \ 
‘ a 


Encysted Vorticella, eae the obliteration of special organs by 
the advancement of the process.—Pritchard. 


These changes are exhibited in the annexed cuts, 
which are copied from known authorities. By careful 
observation of the bodies of Vorticellids, a contractile 
vesicle may be observed, which appears to cause a 
movement of fluids, that is probably connected either 
with respiration or secretion. 


Marvels of Pond-Life. 23 


Another piece of apparatus in this family, but not 
confined to it, is the so-called nucleus, which in this 
case is of a horseshoe shape and granular texture, 
and greater solidity than the surrounding parts. The 
functions of this organ formed the subject of various 
conjectures, but it is now generally held to be an 
ovary. 

In common with many of the lower animals, the 
Vorticellids have three ways of multiplying their race. 
One by fission, or division of their bodies: another by 


Vorticella microstoma, in process of encystment, 300 linear; in the 
last the inclosing tunic is plainly developed.—Stezn. 


buds, somewhat analogous tothose of plants; and another 
by reproductive germs. These processes will come 
again under our notice, and we shall leave the Vorti- 
cellids for the present by observing that if they are 
fed with a very small quantity of indigo or carmine, 
the vacuoles or spaces, into which their nutriment 
passes, will be clearly observed. Ehrenberg thought 
in these and similar creatures that every vacuole 
was a distinct stomach, and that all the stomachs 
were connected by an intestinal canal ; hence his name 


24 Marvels of Pond-Life. 
Polygastrica, or many stomached. In these views he 
has not been followed by later observers, and it is pro- 
bable he was misled, partly by pushing the process of 
reasoning from the analogies of higher animals much 
too far, and partly by the imperfection of the lasses he 
employed. | 

Having thus briefly considered the Vorticellids we 


Rotifer vulgaris—A, mouth, or gizzard; B, contractile 
vesicle.—Wicrographie Dictionary. 

N.B.—When the cilia and tail part are retracted, and the 
body shortened, the creature assumes an obtuse oval form. 


must turn to the wheel-bearer, who belongs “to a 
higher race than even the ciliated Protozoa. We left 
her crawling about with her snout or proboscis pro- 
truded, but now she has moored herself by her tail-foot, 
pulled in her nose, and put out two groups of cilia, 


Marvels of Pond-Life. 25 


which look like revolving wheels, and a little below 
them is seen a gizzard in a state of active work. After 
a little while she swims away with her wheels going, 
and her tail, forked at the end, is found to be telescopic, 
or capable of being pulled in and out. As the cilia 
play, the neighbouring water is agitated, and the mul- 
titudes of small objects are brought by the whirlpools 
within her ravenous maw. But the strangest thing of 
_all is that inside her body is seen a young one; in this 
case a large and fine infant, which, like “ a chip of the 
old block,” imitates the parental motions, thrusts forth 
its cilia and works its gizaard.* In other genera the 
eggs are hatched externally, but this one is ovoviparous, 
and carries its nursery inside. 

A very slight investigation is sufficient to show that 
in the wheelbearer we have made a great advance 
towards a higher organization than we discovered in 
the preceding creatures. We witness what the learned 
call a ‘‘ differentiation” of parts and tissues, and a 
** specialization ”’ of organs. The head is plainly dis- 
tinguishable from the body, the skin or integument is 
distinctly different from the internal tissues, behind the 
eyes we can detect a nervous ganglion or miniature 
brain, the gizzard is a complicated piece of vital 
mechanism, such as we have not met with before, and 
in various parts of the transparent imside we see organs 
to which particular functions are assigned. 

It was at one time thought that Rotifers were her- 

* This was met with in the summer, but is described here to avoid 


repetition. I do not know whether the eggs are hatched in very cold 
weather. 


26 Marvels of Pond-Life. 


maphrodite—uniting both sexes in one body—but that 
idea is now generally abandoned, for in many species 
the males have been discovered, and the fair sex may 
be gratified to hear that they are without doubt the 
‘inferior animals.” Their function is simply to assist 
the female in producing young, and as this can be 
quickly accomplished, their lives are short, and they 
are not supplied with the gizzard and digestive appa- 
ratus, which their lady-loves possess. Much discussion 
has taken place as to the rank which the Rotifers hold 
in the animal kingdom, some naturalists thinking them 
relations of the crabs, and others believing them to 
belong to the family of the worms. Professor Huxley, 
who adopts the latter view, which has the most friends, 
groups the lower Annulosa together under the name of 
Annulotda, in which he includes Annelides, or worms 
of various kinds, the Echinodermata (or “spine skins,” 
among which are the star-fish and sea hedgehogs), and 
some other families. He considers the Rotifers to be 
“the permanent forms of Echinoderm larve.” This 
does not mean that they were ever produced by 
Echinoderms, and had their development checked, but 
that they resemble them in organization, and illustrate 
a general law, observable in animated beings, namely, 
that the lower creatures are like the imperfect stages of 
‘higher animals, and that all things are formed accord- 
ing to general principles, and exhibit a uniformity of 
plan. 

Mr. Gosse adopts a different view, and while admit- 
ting a connection between the Rotifers and the worms, 


Marvels of Pond-Life. 27 


adduces important reasons for associating them with 
the insects. 

Leaving zoologists to settle their position, we may 
remark that the Rotifers form a very numerous family, 
presenting very great diversities of structure, some of 
the most interesting of which we shall meet with in the 
course of our rambles; but-they all possess a gizzard, 
which, though differing in complexity, is throughout 
formed upon the same principle, and that we must now 
explain. 

We have called the masticatory apparatus of the 
Rotifers a gizzard; but Mr. Gosse, who has done most 
to elucidate its structure, contends that it is a mouth; 
and in some species it is frequently protruded, and used 
like the mouth of higher animals. Taking one of the 
most typical forms of this organ, and drawing our illus- _ 
trations from Mr. Gosse’s admirable paper in the 
“Transactions of the Royal Society,’’ we may describe 
it, when completely developed, as consisting of three 
lobes, having a more or less rounded form. The 
eminent naturalist we have named calls the whole organ 
the mastaz, and states that it is composed of dense mus- 
cular fibre. The tube which leads down to it he 
designates the “ buccal (mouth) funnel,” and the tube 
that issues from it, and conveys the food to the digestive 
sac or stomach, he calls the wsophagus, in conformity 
with the nomenclature applied to creatures whose 
mouths are in the usual place. Inside the mouth- 
gizzard are placed two organs, which work like ham- 
mers, and which Mr. Gosse therefore names mallet. 
The hammers work against a sort of anvil, which is 


28 Marvels of Pond-Life. 


called incus, the Latin for that implement. Tach 
hammer consists of two portions articulated by a hinge 
joint. The lower portion, the manubrium, or handle, — 
gives motion to the upper portion, which from its 
shape is named the wncus, or hook. The wunci are 
furnished with finger-like processes of teeth, which 
vary in number. There are five or six in the best 
developed specimens. These hooks or teeth work 
against each other, and against the incus, or anvil, 
which consists of distinct articulated portions, of which 


Gizzard of Notomata. 


the principal are two rami, or branches, jointed so that 
they can open and close like a pair of shears. These 
two rest upon the third portion, which is called the — 
fulcrum. Some faint idea of the working of the 
toothed hammers may be obtained by rubbing the 
knuckles of both hands together, but the motion is 
more complicated, and the rami play their part in the 
trituration of the, food. Mr. Gosse states that when 
an objectionable morsel has got as far as this mouth- 


Marvels of Pond-Life. 29 


gizzard, “it is thrown back by a peculiar scoop-like 
action of the wnci, very curious to witness.” The 
foregoing diagram will help the reader to comprehend 
this description, but no opportunity should be lost for 
viewing this remarkable organ busy at work in the 
living animals. 

The respiration of the Rotifers is supposed to be 
effected by the passage of water through vessels run- 
ning round them, and called the “water vascular 
system,” and in addition to their eyes, which often 
disappear in adult specimens, the organ we described 
as standing out like a pig-tail, as our acquaintance 
crawled along, is thought to act as an antenna, or 
feeler, and brings its possessor in further relation to 
the external world. It is also called the calcar, or 
spur, and is furnished with cilia or bristles at its 
extremity. : 

Sometimes the particles swallowed by the Common 
Rotifer are large enough for their course to be traced, 
but there is frequently a great commotion and grinding 
of the gizzard, without any appreciable cause, although 
doubtless something is taken in, and when the creature 
is tired, or has had enough, we see both head and tail 
retracted, and the body assumes a globular form. In 
_ another chapter, when viewing a Philodine, we shall see 
how in the family to which the Common Rotifer 
belongs, the gizzard departs from the periect type. 


30 Marvels of Pond-Life. 


CHAPTER III. 
FEBRUARY. 


Visit to Hampstead—Small ponds—Water-fleas— Water-beetle—Snails 
—Polyps—Hydra viridis—The dipping-tube—A glass cell—The 
Hydra and its prey—Chydorus sphericus and Canthocamptus, or 
friends and their ,escapes—Cothurnia— Polyp buds— Catching 
Polyps—Mode of viewing them—Structure of Polyps—Sarcode— 
Polyps stimulated by light—Are they conscious P—Tentacles and 
poison threads—Paramecium—Trachelius— Motions of Animalcules, 
whether automatic or directed by a will—Their restless character. 


page) has been a bitterly cold night, and as the sun 
}| shines on a clear keen morning, and glistens 
in the hoar-frost which covers the trees, it 
might seem an unpropitious time for visiting the ponds, 
in search of microscopic prey. We will, however, 
try our luck, and take a brisk trot to the top of 
Hampstead Heath, where the air is still keener, and 
the ice more thick. Arriving at the highest point, 
London appears on one side enveloped in its usual 
great coat of smoke, through which St. Paul’s big 
dome, with a score or two of towers and steeples, can 
be dimly made out ; while looking towards Harrow-on- 
the Hill, or Barnet, we see the advantage of country 
air in the sharpness with which distant objects cut the 
blue sky. We leave the large ponds for another time, 


Marvels of Pond-Life. 31 


and hunt out the little hollows among the furze and 
fern. One looks promising from the bright green 
vegetation to be discovered under the sheet of ice, 
which is almost firm enough to bear human weight. 

Breaking a convenient hole we hook up some of the 
water-plants, and place them in a wide-mouthed vial, 
which we fill with water, and cursorily examine with a 
pocket-lens. Some water-fleas briskly skipping about, 
and a beautiful little beetle, with an elegant dotted 
pattern on his brown back, and a glistening film of air 
covering his belly, show that we have not been unsuc- 
cessful, although we must wait till we get home to 
know the extent of our findings, among which, however, 
we can only discern the graceful spiral shell of a small 
water-snail, the Planorbis. 

Arriving at home the bottle was left undisturbed for 
some hours in a warm light place, and then on being 
examined several specimens of that beautiful polyp, the 
Hydra viridis, were seen attached to the glass, and 
spreading their delicate tentacles in search of prey. 
One of the polyps is carefully removed by the dipping- 
tube, a small glass tube, open at both ends. The fore- 
finger is placed upon the top, and when the other end 
is brought over the object the finger is raised for an 
instant, and as the water rushes in the little hydra 
comes too, and is placed in a glass cell, about half an 
inch wide, and one tenth of an inch deep. These cells 
are obtained from the opticians,.and cemented with 
varnish or marine glue to an ordinary glass slide. 
After an object has been placed in one of them, a little 
water is taken up in the dipping-tube, and the cell 


32 Marvels of Pond-Life. 4 


filled until the fluid stands in a convex heap above its 
brim. We then select a round glass cover, and press 


Hydra viridis with developed young one, and bud beginning 
to sprout. 


Marvels of Pond-Life. — 33 


it gently on the walls of our cell. A few drops of 
superfluous water escape, and we have the cell quite 
full, and the cover held tight by force of the capillary 
attraction between the water and the glass. 

_ The polyp deposited in one of these water cages is 
then transferred to the stage of the microscope, and its 
proceedings watched. At first it looks like a shapeless 
mass of apple-green jelly. Soon, however, the tail end 
of the creature is fixed to the glass, the body elongates, 
and the tentacles (in this case eight) expand some- 
thing after the manner of the leaves of a graceful 
palm. 

By accident two small Water Fleas were imprisoned 
with the polyp, and one (a shrimp-like looking crea- 
ture, carrying behind her a great bag of eggs) came 
into contact with the tentacles, and seemed paralysed 
for atime. The hydra made no attempt to convey the 
captive to its mouth, but held it tight until another 
Water Flea, a round merry little fellow (Chydorus 
sphericus), came to the rescue, and assisted Cantho- 
camptus to escape by tugging at her tail. This friendly 
action may not have been prompted by the intelligence 
which seemed to suggest it, but those who have kept 
tame soldier-crabs and prawns in an aquarium, will 
not be indisposed to attribute to the crustaceans more 
brains than they have usually credit for. It must, 
however, be confessed that the subsequent conduct of 
Mrs. Canthocamptus did not indicate the possession of 
much prudence, for she learnt no lesson from experi- 
ence, but repeatedly swam against her enemy’s tenta- 
cles, suffered many captures, and only escaped being — 

3 


34 Marvels of Pond-Life. 


devoured through the indifference, or want of appetite, 
which the polyp evinced. 


A, Canthocamptus minutus; B, Chydorus sphericus ; C and 
D, Capsules and poison-thread of polyp; E, Zvicodina pedi- 
culus, side view and under view; F, Kerona polyporum.— 
Microg. Dict. 


On the body of the Canthocamptus were some 
small transparent vases or bottles, containing living 
objects, which sprang up and down. ‘These were 


Marvels of Pond-Life. 35 


members of the Vorticella family, called Cothurnia, and 
will be hereafter described. 

Watching the hydra it was curiovs to note the 
changes of form which these creatures are able to 
assume. Now the tentacles were short and thick, and 
the body squat - now the body was elongated, like the 


Hydra viridis, in various shapes. 


stem of a palm tree, and the tentacles hung gracefully 
from the top. From some of the polyps little round 
buds were growing, while other buds were already 
developed into miniature copies of the parent, and only 
attached by a slender stalk. In a few days many of 
these left the maternal side, fixed their own little tails 
to the glass, and commenced housekeeping on their 
own account. 

Polyps may be obtained at all times of the year by 
bringing home duckweed, conferva, and other water- 
plants from the ponds. Some hauls may be unsuc- 
cessful, but if one pond is not propitious others should 
be tried. The plants should be put in a capacious 


36 Marvels of Pond-Life. 


vessel of water, and placed in the light, where, if polyps - 
be present, they will show themselves within twenty- 
four hours, either attached to the sides of the glass, or 
hanging from the plants, or suspended head downwards 
from the upper film of the water. They are elegant 
objects, and may be kept without difficulty for some 
weeks. After being confined in a small quantity of 
water for purposes of examination, they should be care- 
fully replaced in the larger vessel, and may thus be 
used again and again without suffering any injury. A 
low power—a three or two-inch glass—or a one-: 
inch, reduced by employing the erector—is the most 
convenient for examining the whole creature, but 
higher powers are necessary to make out its minute 
structure. They should be viewed with direct and 
oblique light, as transparent and also as opaque 
objects. In the latter case the “ Lieberkuhn,” or 
polished silver speculum, is convenient, and if the 
microscope is not furnished with Lister’s dark wells, 
a small piece of black paper may be stuck behind the 
object, by simply wetting it with the tongue.* 
Although the polyps are remarkable for the sim- 
plicity of their organization, they do not the less 
exhibit the wonderful nature of animal life. Their 
bodies are composed of the substance, called sarcode, 
in which is imbedded a colouring matter resembling that 
in the leaves of plants; every part possesses irritability - 
and contractility, and they are very sensitive to the 
stimulus of light. The outer layer of their bodies is 


* The side silver reflector is useful for illuminating such objects. 


Marvels of Pond-Life. 37 


harder than the inner layer. These layers are severally 
called ectoderm and endoderm. They may be cut and 
grafted like trees, and if turned inside out, the new 
inside digests and assimilates as well as the old. 
Whether any form of consciousness can belong to 
creatures which have no distinct nervous system 1s 
open to doubt, but it would seem probable from their 
movements that food and light afford them something 
like a pleasurable sensation in a very humble degree. 
If we were sufficiently acquainted with the secrets of 
molecular combination we might discover that the 
various functions of these simple organisms were dis- 
charged by different particles, although it is only in 
higher creatures that muscular particles are ageregated 
into muscles, or nerve particles into nerves. 

Having examined the general appearance and pro- 
ceedings of the hydra, let us cut off a tentacle, or take 
a small specimen and gently crush it by pressing down 
the cover of the live box, and place the object so pre- 
pared under a power of about three hundred linear. If 
we then illuminate it with a moderate quantity of oblique 
light, we shall discover round the edge of the tentacle 
a number of small cells or capsules, from some of 
which a very slender wire or thread will be emitted.* 
These are the stinging organs of the polyp, and 
resemble those which Mr. Gosse has so ably elucidated 
in the sea anemones. Some writers have endeavoured 
to show that they are not stinging organs at all, but so 
large an amount of evidence to the contrary is accu- 
mulated in Mr. Gosse’s ‘ Actinologia Britannica,’ 

* See page 34, C and D. 


88 Marvels of Pond-Life. 


that no reasonable doubt remains. The stinging 
capsules of the polyp are shown in the annexed sketch, 


Anguillula pierced by stinging organs of the Hydra viridis. 


and also the way in which they are employed, for it 


Marvels of Pond-Life. | 39 


fortunately happened that on exposing one of the 
hydras to pressure in the live box, a small worm 
(Anguillula) escaped, which had been pierced with the 
minute weapons which are supposed to convey a poison 
into the wound. The authors of the ‘ Micrographic 
Dictionary’ think that the prongs of the forks, 
which will be seen to poimt upwards in the sketch,* 
are springs, and occupy a reversed. position in the 
capsule cells, and that their function is to throw out 
the threads. However this may be, the polyps, and 
similarly endowed creatures, have the power of darting 
out their poison threads with considerable force, and 
Mr. Gosse found that the anemone was able to pierce 
a thick piece of human skin. 

The same excellent observer attributes the emission 
of the anemone poison threads, which he considers 
hollow, to the injection of a fluid. In their quiescent 
state, he thinks they are drawn in, like the finger of a 
glove, and are forced out as the liquid enters their 
slender tubes. Possibly the polyp stinging organs may 
have the same structure. 

Notwithstanding their dangerous weapons, polyps 
are often infested with a parasite, the Trichodina pedi- 
culus, as shown in Fig. £, page 49, and it must happen 
that either this visitation is not disagreeable, or that 
the Trichodina is not influenced by the poison. 

As the plants in the bottles decayed, some of the 
animalcules died off and others appeared. In one 
bottle, containing: ecaying chara, Paramecia abounded. 
The Paramecia, of which there are various species, 


* See page 38. 


40 i Marvels of Pond-Life. 


have always been favourite objects with microscopists. 
The Germans call-them “ slipper animalcules,”. and 
they vary in size from 1—96”* tol—1150”. They are 
flat rounded-oblong creatures, with a distinct integu- 
ment or skin, “ through which numerous vibratile cilia 
pass in regular rows.’+ They are furnished with a 
distinct mouth, and adult specimens exhibit star-shaped 
contractile vesicles in great perfection. 

The swarm of specimens before us belong to one 
species, Paramecium aurelia, the Chrysalis animalcule, 
and they crowd every portion of the little water-drop 
we have taken up, and examined with a power of about 
one hundred linear. When they are sufficiently quiet 
a power of about four hundred may be used with 
advantage, and Pritchard recommends adding a little 
indigo and carmine to the water, in order to see the 
cilia more clearly, or rather to render their action more 
plain. The cilia are disposed lengthwise, and Ehrenberg 
counted in some rows sixty or seventy of them, making 
an aggregate of three thousand six hundred and forty 
organs of motion in one small animated speck. This 
number seems large, but although we have never per- 
formed the feat of counting them, we should have 
expected it to prove much greater. Unlike most 
animalcules they are susceptible of being preserved by 
drying upon glass, and we subjoin a figure from 
Pritchard, of one thus treated, in which the star-shaped 
vesicles are clearly seen. ‘These curious organs com- 

* The usual mode of giving dimensions is by fractions thus 


expressed: 1—96” means one ninety-sixth of an‘inch. 
¥* ‘Micrographic Dictionary.’ 


Marvels of Pond-Life. | 4] 


municate with other vessels, and, as we have previously 
stated, are probably connected with respiration and 
excretion. 


Paramecium aurelia. 
A dried specimen showing the vesicles.—Pritchard. 


The genus Paramecium is now confined to those 
-ereatures which exhibit rows of longitudinal cilia of 
uniform length, which are destitute of hooks, styles, or 
other organs of motion than the cilia, which have a 
lateral mouth, and no eye-spots. One mode of increase 
is by division, which may be easily observed; another 
is through the formation of true eggs as traced by 
Balbiani. 

Another of the treasures from the pond was a species 
of Trachelius, or long-necked ciliated animalcule, which 
kept darting in and out of a slimy den, attached to the 
leaf of a water-plant. The body was stout and fish- 
shaped, the tail blunt, and the neck furnished with long 
conspicuous cilia, which enabled the advancing and 
retreating movements to be made with great rapidity. 
The motions of this creature exhibit more appearance 
of purpose and design than is common with animal- 


42 Marvels of Pond-Life. 


cules, but in proportion as these observations are pro- 
longed, the student will be impressed with the difficulty 
of assuming that anything like a reasoning faculty and 
volition, is proved by movements that bear some 
resemblance to those of higher animals, whose cerebral 
capacities are beyond a doubt. It is, however, almost 
impossible to witness motions which are neither con- 
stant nor periodic, without fancying them to be dictated 
by some sort of intelligence. We must, nevertheless, 
be cautious, lest we allow ourselves to be deceived by 
reasoning so seductive, as the vital operations of the 
lowest organisms may be merely illustrations of blind 
obedience to stimuli, in which category we must reckon 
food, and until we arrive at forms of being which 
clearly possess a ganglionic system, we have no. cer- 
tainty that a real will exists, even of the simplest kind ; 
and perhaps we must go still higher before we ought to 
believe in its presence. 

Ehrenberg was much struck with the restless cha- 
racter of many infusoria—whether he looked at them 
by day or by night, they were never still. In fact 
their motions are like the involuntary actions which 
take place in the human frame; and if attached to 
their bodies we observe cilia that never sleep, the 
living membrane of some of our own organs, the nose, 
for example, is similarly ciliated, and keeps up a per- 
petual though unconscious work. 


Marvels of Pond-Life. 43 


CHAPTER IV. 


MARCH. 


Paramecia—Effects of Sunlight—Pterodina patina—Curious tail— 
Use of a Compressorium—Internal structure of Pterodina—Meto- 
pidia—Trichodina pediculus—Cothurnia—Salpina—Its three-sided 
box—Protrusion of its gizzard mouth. 


have increased and multiplied their kind 
without any fear lest the due adjustment 
between population and food should fail to be preserved. 
A small drop of the scum from the surface of the water 
in their bottle is an astounding sight. They move 
hither and thither in countless numbers, seldom 
jostling, although thick as herrings in a tub, and in 
many portions of the field the process of self-fissure, or 
multiplication by division, is going on without any 
symptoms of discomfort on the part of the parent crea- 
ture. This is an interesting sight, but we will not 
linger over it, for the sun is shining, and there is enough 
warmth in the air to make it probable that the ponds 
will be more prolific than in the cold winter months. 
Sunshine is a great thing for the microscopic hunter ; 
it brings swarm of creatures to the surface, and the 
Rotifers are especially fond of its genial beams. Even 


A Marvels of Pond-Life. 


if we imitate it by a bright lamp, we shall attract 
crowds of live dancing specks to the illuminated side of 
a bottle, and may thus easily effect their capture by 
the dipping-tube. : 
This year the March sunshine was not lost, for on 
the third of that month I obtained a bottleful of 
conferva from a pond about a mile from my house, and 
lying at the foot of the Highgate hills. Water-fleas 
were immediately discovered in abundance, together 
with some minute worms, and a ferocious-looking larva 


Pterodina patina. 


covered with scales ; but what attracted most attention 
was a Rotifer, like a transparent animated soup-plate, 
from near the middle of which depended a tail, which 
swayed from side to side, as the creature swam along. 
The head exhibited two little red eyes; two tufts of 
cilia rowed the living disk through the water, and the 
gizzard worked with a rapid snapping motion, that left 
no doubt the ciliary whirlpools had brought home no 
slender stores of invisible food. Sometimes the end of 
the tail acted as a sucker, and fixed the animal tightly 


Marvels of Pond-Life. 45 


to the glass, when the wheels were protruded, and the 
body swayed to and fro. Then the sucker action 
ceased, and as the creature swam away, a tuft of cilia 
was thrust out from the extremity of the tail. A power 
of one hundred linear was sufficient to enable the 
general nature of this beautiful object to be observed, 
but to bring out the details, much greater amplification 


Pterodina patina—gizzard. 


was required, and this would be useless if the little 
fidget could not be kept still. 

The size of the creature, whose name we may as well 
mention was Pterodina patina, rendered this practicable, 
but required some care. The longest diameter of the 
body, which was not quite round, was about 1—120”, 
so that it was visible to the naked eye, and as a good 
many were swimming together, one could be captured 
without much difficulty, and transferred with a very 
small drop of water to the live-box. Then the cover 


46 Marvels of Pond-Life. 


had to be put on so as to squeeze the animal just 
enough to keep it still without doing it any damage, or 
completely stopping its motions. This was a trouble- 
some task, and often a little overpressure prevented its 
success. 

Some observers always use in these cases an instru- 
ment called a compressorium, by which the amount of 
pressure is regulated by a lever or a fine screw; but 
whether the student possess one or not, he should learn’ 
to accomplish the same result by dexterously manipu- 
lating a well-made live-box. We will suppose the 
Pterodina successfully caged, and a power of about one 
hundred and fifty linear brought to bear upon her, for 
our specimen is of the “‘ female persuasion.”” This will 
suffice to demonstrate the disposition and relation of 
the several parts, after which one of from four hundred 
to five hundred linear may be used with great advan- 
tage, though in this case the illumination must be 
carefully adjusted, and its intensity and obliquity fre- 
quently changed, until the best effect is obtained. 

We find, on thus viewing the Pterodina, that it is 
a complex, highly-organized creature, having its body 
protected by a carapace, like the shell of a tortoise, but 
as flexible as a sheet of white gelatine paper, which it 
resembles in appearance. Round the margin of this 
carapace are a number of little bosses or dots, which 
vary in different individuals. The cilia are not disposed, 
as at first appeared, in two separate and distinct disks, 
but are continuous, as in the annexed sketch. Down 
each side are two long muscular bands, distinctly 
striated, and when they contract, the ciliary apparatus 


Marvels of Pond-Life. 4.7 


is drawn in. As this contraction takes place, two 
apparently elastic bands, to which the ciliary lobes are 
attached, are bent downwards, till they look like the C 
springs behind a gentleman’s carriage ; and they regain 
their former position of slight curvature, when the cilia 
are again thrust out. 


<a 


Kung 


wai 
NIN 


Ki 


i 


Pterodina patina—tail-foot. 


The gizzard is three-lobed, and curiously grasped by 
forked expansions of the handles of the hammers. The 
tail, or tail-foot, can be withdrawn or thrust out at the 
will of the creature ; and when in a good position for 
observation, a slight additional pressure will keep it so 
for examination. Delicate muscular longitudinal bands, 
forked towards the end of their course, supply the means 
of performing some of its motions, and one, or perhaps 
two, spiral threads extend through the upper half of its 
length, and either act as muscles, or as elastic springs for 
its extension. The intestines and other viscera are 
clearly exhibited, and a strong ciliary action conducts 
the food to the gizzard-mouth. 

To return to the tail. One spiral fibre is easily dis- 


48 Marvels of Pond-Life. 


>» 


covered; butI have often, and at an interval of months, 
seen the appearance of two, and am in some doubt 
whether this was a deception, arising from the com- 
pression employed, or was a genuine indication, 

Where this Rotifer occurs I have usually found it 
plentiful, but unfortunately could obtain no constant 
supplies after I had determined to make a special study 


A. Metopidia acuminata, as drawn by Mr. Gosse. B. Specimen 
as seen and described in text. ce. Mouth or gizzard. 


of the remarkable tail, which is much more complicated 
than I have described. The Pterodina lived for some 
time in captivity, and for a week or two I could obtain 
them from my glass tank. They were likewise to be 
found for some weeks in the same part of the pond, but 
not all over it, until one day not a single specimen 
could bediscovered, notwithstanding a persevering search 


Marvels of Pond-Life. 49 


nor was I afterwards able to get any from that pond’ 
during the remainder of the year. 

Several other Rotifers, with and without carapaces, 
were among the same mass of conferve, among them 
a Metopidia, with a firm shell, a forked jointed tail, and 
a projection in front which worked like a pickaxe among 
the decaying weed. There were likewise specimens of 
the long-necked animalcules (Trachelii), groups of 
Vorticeila, some specimens of Volvox, and a small 
Trichodina pediculus, which, when magnified two hun- 
dred and sixty linear, was about the size of a sixpence 


260 


Trichodina pediculus. 


and equally round. The edge was beautifully fringed 
with a circle of cilia; in an inner circle was a row of 
locomotive organs, and the centre exhibited vacuoles 
constantly opening and shutting. This creature, as 
before explained, is often found asa parasite upon the 
polyps. On one occasion a glimpse was caught of a 
Rotifer similar in shape to the common wheel animal- 
cule, but with a yellow inside. Possibly it was the 
object so beautifully delineated by Mr. Gosse, in his 
“Tenby,” and described as the “Yellow Philodine,” 
but this must remain in doubt, as it managed to escape 
before it could be secured. 


a 


‘ 


Marvels of Pond-Life. 


50 


2 Sy I 


| UOTJVOYTUSBU waU2] O44 OAS SoINSY oY], . 
*3x0} UI poqtosop suouttoods oy, “O Pur A (:yo1q “‘YdvaSosoryy ,)—SIqtoquar wrung “VW 


— 2 


Marvels of Pond-Life. o1 


By the 18th of the month the Vorticellids were much 
more plentiful, and their changes easily watched; many 
left their stalks while under the microscope, after which 
some rushed about like animated and demented hats, 
others twirled round like tee-to-tums, while others took 
a rest before commencing their wild career. But the 
common Vorticellz were not the only or the most in- 
teresting representations of their charming order, for 
upon some threads of conferva were descried several 
elegant crystal vases standing upon short foot-stalks, 
and containing little creatures that jumped up and down 
like “ Jack in the box.” These were so minute, that a 
power of four hundred and thirty linear was advan- 
tageously brought to bear upon them. When elongated 
their bodies were somewhat pear-shaped, but more 
slender, and variegated with vacuoles and particles of 
food. The mouths resembled those of Vorticelle, and 
put forth circles of vibrating cilia. They were easily 
alarmed, when the cilia were retracted, and down they 
sank to the bottom of their vases, quickly to rise again. 
In one bottle there were two living in friendly juxta- 
position. This was not a case of matrimonial felicity, 
nor of Siamese twins, but of fission, or reproduction by 
division. The original inhabitant of the tube finding 
himself too fat, or impelled by causes we do not under- 
stand, quietly divided himself in two, and as the house 
was big enough, no enlargement was required. How 
many stout puffy gentlemen must envy this process ; 
how convenient to have two thin lively specimens of 
humanity made out of one too obese for locomotion. 
Man is, however, sometimes the victim of his superior 


_ 52. Marvels of Pond-Life. 


organization, and no process of “ fission” can make the 
lusty lean.* 

The bottles in which these creatures live, in happy 
ignorance that they are called by so crackjaw a name 
as Cothurnia imberbis, were described as Carapaces by 
Ehrenberg, but they bear no resemblance to the shell 
of aturtle or crab. They are thrown off by the animals 
who preserve no other connection with them than the 
attachment at the bottom. 

The Micrographic Dictionary describes the family 
Ophrydinaas corresponding to Vorticellina with a cara- 
pace. Stein places them with Vorticellids, &c., amongst 
his Peritricha, which are characterised by a spiral 
wreath of cilia round the mouth. 

Towards the end of the month a great number of 
black pear-shaped bodies (Stentor niger), visible to 
the naked eye, were conspicuous in some water from 
the Kentish Town ponds. Upon examination they 
were found to be filled with granules that were red by 
reflected, and purple by transmitted light. Hach one 
had a spiral wreath of cilia, with a mouth situated like 
those of the stentors, hereafter to be described, but none 
of them became stationary, and in a few days they all 
disappeared. Stein divides Ehrenberg’s Stentor igneus 
from S. niger; the creature described seems to have 
agreed with Stein’s igneus, which he describes as having 
blood-red lilac, cinnabar, or brown-red pigment particles, 
and as much smaller than his 8. niger. In the same 


* Balbiani in his ‘Recherches sur les Phénoménes Sexuels des Infu- 
soires,’ speaks of the Vorticellids as the only Infusoria dividing longi- 
tudinally. In other species such appearances arise from conjunction. 


- 


Marvels of Pond-Life. 53 


water were specimens of that singular Rotifer, the 
Salpina, about 1—150” long, and furnished with a 
lorica, or carapace, resembling a three-sided glass 
box, closed below, and slightly open along the 
back. At the top of this box were four, and at the 
bottom three, points or horns, and the creature had 
one eye and a forked tail. Keeping him company 
was another little Rotifer, named after its appearance, 
Monocerca rattus, the ‘One-tailed Rat.’ This little 
animal had:green matter in its stomach, which was in 
constant commotion. I ought to have observed that 
the Salpina repeatedly thrust out its gizzard, and used 
it as an external mouth. In the annexed sketch the 
Salpina is seen in a position that displays the dorsal 
opening of the carapace. Its three-cornered shape is 
only shown by a side view. 

Here we close a brief account of what March winds 
brought in their train. The next chapter will show the 
good fortune that attended April showers. 


Salpina redunca. 


54 Marvels of Pond-Life. 


CHAPTER V. 


APRIL. 


The beautiful Floscule—Mode of seeking for Tubicolor Rotifers—Mode 
of illuminating the Floscule—Difficulty of seeing the transparent 
tube—Protrusion of long hairs—Lobes—Gizzard—Hairy lobes of 
Floscule not rotatory organs—Glass troughs—Their construction 
and use—Movement of globules in lobes of Floseule—Chzetonotus 
larus—Its mode of swimming—Coleps hirtus—Devourer of dead 
Entomostraca—Dead Rotifer and Vibriones—Theories of ferment- 
ation and putrefaction—Euplotes and Stylonichia—Fecundity of 
Stylonichia. 


ann EW living creatures deserve so well the appel- 
: yi lation of “ beautiful ” as the Floscularia ornata, 
=) or Beautiful Floscule, although to contemplate 
a motionless and uncoloured portrait, one would 
imagine that it exhibited no graces of either colour or 
form. Mr. Gosse has, however, done it justice, and 
the drawing in his “ Tenby” is executed with that 
rare combination of scientific accuracy and artistic 
skill, for which the productions of his pencil are 
renowned. 

Probably the sketches in several works of authority | 
representing the long cilia as short bristles, are merely 


copies from old drawings, from objects imperfectly 


‘aSSOD ‘IJ AQ PoINsY sv ‘opnosoj;] jo smer—*q “pflO sanoy wsequeAes sTNOsoT¥—'q ‘“SunoK jo 
gourmmaddy—"9  ‘sdse 001g} YIM *pepnujoid Ajoory—"gq ‘pepnajoad Al[eITegG--*y ‘aTMOsoT,] TaIMMReg ouL 


~ 


Marvels of Pond-Life. 55 


seen under indifferent microscopes, and before the 
refinements of illumination were understood. Be this 
as it may, any reader will be fortunate if on an April, 
or any other morning, he or she effects the capture of 
one of these exquisite objects, although the first im- 
pression may not equal previous expectations, as the 
delicacy of the organism is not disclosed by a mode of 
using the light which answers well enough for the 
common infusoria. 

When the Floscules, or other tubicolar Rotifers are 
specially sought for, the best way is to proceed to a 
pond where slender-leaved water-plants grow, and to 
examine a few branches at a time in a phial of water 
with a pocket-lens. They are all large enough to be 
discerned, if present, in this manner, and as soon as 
one is found, others may be expected, either in the 
same or in adjacent parts of the pond, for they are 
gregarious in their habits. With many, however, the 
first finding of a Floscule will be an accident, as was 
the case last April, when a small piece of myriophyllum 
was placed in the live-box, and looked over to see 
what it might contain. The first glimpse revealed an 
egg-shaped object, of a brownish tint, stretching itself 
upon a stalk, and showing some symptoms of hairs or 
cilia at its head. This was enough to indicate the 
nature of the creature, and to show the necessity for a 
careful management of the hight, which being adjusted 
obliquely, gave quite a new character to the scene. 
The dirty brown hue disappeared, and was replaced by 
brilliant colours ; while the hairs, instead of appearing 
few and short, were found to be extremely numerous, 


56 Marvels of Pond-Life. 


very long, and glistening like delicate threads of spun 
glass. : 

Knowing that the Floscules live in transparent 
gelatinous tubes, such an object was carefully looked 
for, but in this instance, as is not uncommon, it was 
perfectly free from extraneous matter, and possessed 
nearly the same refractive power as the water, so that 
displaying it to advantage required some little trouble 
in the way of careful focusing, and many experiments 
as to the best angle at which the mirror should be 
turned to direct the light. When all was accomplished, — 
it was seen that the Floscule had her abode in a clear 
transparent cylinder, like a thin confectioner’s jar, 
which she did not touch except at the bottom, to which 
her foot was attached. Lying aside her in the bottle 
were three large eggs, and the slightest shock given to 
the table, induced her to draw back in evident alarm. 
Immediately afterwards she slowly protruded a dense 
bunch of the fine long hairs, which quivered in the 
light, and shone with a delicate bluish-green lustre, 
here and there varied by opaline tints. 

The hairs were thrust out in a mass, somewhat after 
the mode in which the old-fashioned telescope hearth- 
brooms were made to put forth their bristles. As soon 
as they were completely everted, together with the 
upper portion of the Floscule, six lobes gradually 
separated, causing the hairs to fall on all sides in a 
graceful shower, and when the process was complete, 
they remained perfectly motionless, in six hollow fan- 
shaped tufts, one being attached to each lobe. Some 
internal ciliary action, quite distinct from the hairs, 


Marvels of Pond-Life. 57 


and which has never been precisely understood, caused 
gentle currents to flow towards the mouth in the 
middle of the lobes, and from the motion of the gizzard, 
imperfectly seen through the integument, and from the 
rapid filling of the stomach with particles of all hues, 
it was plain that captivity had not destroyed the 
Floscule’s appetite, and that the drop of water in the 
live-box contained a good supply of food, 

Sometimes the particles swallowed were too small to 
be discerned, although their aggregate effect was 
visible ; but often a monad or larger object was in- 
gulfed, but without any ciliary action being visible to 
account for the journey they were evidently compelled 
to perform. The long hairs took no part whatever in 
the foraging process, and as they do not either provide 
victuals or minister to locomotion, they are elearly not, 
as was supposed by early observers, representatives of 
the ‘ wheels,’ which the ordinary Rotifers present. 
Neither can the cylindrical jar or bottle be justly 
deemed to occupy the position of the lorica, or carapace 
which we have before described. The general structure 
of the creature and the nature of its gizzard distinctly 
marked it out as a member of the family we call 
“ Rotifers,” but the absence of anything like “ wheels” 
proves that those organs are not essential characteristics 
of this class. | 

Noticeable currents are not always produced when 
the mouth of this Floscule is fully expanded. On one 
occasion, one having five lobes was discovered standing 
at such an angle in a glass trough that the aperture 
could be looked down into. The position rendered it 


58 Marvels of Pond-Life. 


impossible to use a higher power than about two 
hundred linear, but with this, and the employment of 
carmine, nothing like a vortex was seen during a whole 
evening, although a less power was sufficient to show 
the ciliary whirlpools made by small specimens of 
Epistylis and Vaginicola, which were in the small 
vessel. The density of the integument was unfavorable 
to viewing the action of the gizzard, but it could be 
indistinctly perceived. The contractions and subsequent 
expansions of the cup, formed by the upper part of the 
creature, may be one way in which its food is drawn 
in, but there is no doubt it can produce currents when 
it thinks proper. Sometimes animalcules in the 
vicinity of Floscules whirl about as if under the influ- 
ence of such currents. Some may be seen to enter the — 
space between the lobes, swim about inside, and then 
get out again, while every now and then one will be 
sucked in too far for retreat. 

Above the gizzard in the Horned Floscule,* I have | 
seen an appearance as if a membrane or curtain was 
waving to and fro, while another was kept in a fixed 

* The Horned Floscules (#. cornuta) which I have found, and which 
ored in a glass jar, were not so large as those described by Mr. Dobie, 
as quoted in ‘Pritchard’s Infusoria.” Mr. Dobie’s specimens were 
1—40” when extended ; mine about half that size, five-lobed, and with 
a long slender proboscis, standing in a wavy line outside one lobe. 
Mr. Dobie also describes an F. campanulata, with five flattened lobes. 
The ‘ Micrographic Dictionary’ pronounces these two species “ doubt- 
fully distinct.” I have three or four times met with a variety of 
F. ornata, in which one lobe was much enlarged and flattened, but 
they had no proboscis. In what I take for /. cornuta, the horn or 


proboscis has sometimes been a conspicuous object, and at others so fine 
and transparent as to be only visible in certain lights. 


Marvels of Pond-Life. 59 


perpendicular position. Mr. Gosse, speaking of this 
genus, observes “that the whole of the upper part of 
the body is lined with a sensitive, contractile, partially 
_ opaque membrane, which a little below the disk recedes 
from the walls of the body, and forms a diaphragm, 
- with a highly contractile and versatile central orifice. 
At some distance lower down another diaphragm 
occurs, and the ample chamber thus enclosed forms a 
kind of crop, or receptacle for the captured prey.” 

“From the ventral side of the ample crop that 
‘precedes the stomach, there springs in F. ornata a 
perpendicular membrane or veil, partly extending 
across the cavity. This is free, except at the vertical 
edge, by which it is attached to the side of the 
chamber, and being ample and of great delicacy, it 
continually floats and waves from side to side. At the 
bottom of this vez, but on the dorsal side, are placed 
the jaws, consisting of a pair of curved, unjointed, but 
free mallei, with a membranous process beneath each.” 

The Beautiful Floscule could always be made to 
repeat the process of retreating into her den, and 
coming out again to spread her elegant plumes before 
our eyes, by giving the table a smart knock, and her 
colours and structure were well exhibited by the dark- 
ground illumination, which has been explained in a 
previous page. 

An object lke this should be watched at intervals 
for hours and even days, especially if the eggs are 
nearly ready to give up their infantile contents. This 
was the case with the specimen described, and after a 
few hours a young Floscule escaped, looking very much 


i 


60 Marvels of Pond-Life. 


like a clumsy little grub. After a few awkward 
wriggles the new-born baby became more quiet, and on 
looking at it again at the expiration of seventeen hours, 
it had developed into the shape of a miniature plum- 
pudding, with five or six tiny lobes expanding their 
tufts of slender hair. Unfortunately its further pro- 
ceedings were not seen, or it would have been 
interesting to note the growth of the foot, and the 
formation of the gelatinous tube, which is probably 
thrown off in rings. 

To view the details of the structure of a Floscule, it 
must be placed in a live-box or compressorium, and if 
specimens are scarce, they should not be allowed to 
remain in the limited quantity of water those contriv- 
ances hold, after the observations are concluded, but 
should be carefully removed, and placed in a little vial, 
such as homceopathists use for their medicime. By 
such means an individual may be kept alive for many 
days. It is also interesting to place a little branch 
of the plant occupied by Floscules or similar creatures, 
in a glass trough, where they may be made quite at 
home, and their proceedings agreeably watched by a 
one-inch or two-thirds power. These troughs,* which 
can be obtained of the optician, should be of plate 
glass, about three inches long, nearly the same height, 
and about half an inch wide. If narrower, or much 
taller, they will not stand, which is a great incon- 


* The shallow cells with thin sliding covers devised by Mr. Curteis 
(of Baker’s), are still more convenient when no pressure is required, 
and the objects are small. When not under the microscope they can 
be kept full of water by immersion in a tumbler. 


Marvels of Pond-Life. 61 


venience. The pieces of glass are stuck together with 
marine glue, and a very simple contrivance enables the 
plants or other objects to be pressed near the front, and 
thus brought into better view. A strip of glass, rather 
narrower than the width of the trough, is dropped into 
it, and allowed to fall to the bottom. Then a piece of 
glass rather shorter than the trough, and rather higher 
than its front side, is placed so as to slope from the 
front of the bottom towards the back at the top. The 
piece of glass first dropped in keeps it in the right 
position, and the trough is thus made into a V-shaped 
vessel, wide at the top and gradually narrowing. Any 
object then placed in it will fall till it fits some part of 
the V, where it will remain for observation. A small 
wedge of cork enables the moveable piece of glass to 
be thrown forwards, until it assumes any angle, or is 
brought parallel to the front of the trough. 

A power of five or six hundred diameters generally 
enables a movement of small globules to be seen at the 
extremity of the lobes of the Floscule, and the gizzard 
may be made plain by dissolving the rest of the creature 
in a drop of solution of caustic potash. It also becomes 
more visible as the supply of food falls short. Mr. 
Gosse describes the body as “lined with a yellowish 
vascular membrane,” and young specimens exhibit two 
red eyes, which may or may not be found in adults. 
When these eyes of Rotifers are not readily conspicuous, 
they must be sought for by opaque illumination, or by 
the dark-ground method which, especially with the 
parabola, is successful in bringing them out. 

Naturalists, and possibly the specimens also, do not 


62 Marvels of Pond-Life. 


always agree in the number of lobes assigned to the 
‘‘ Beautiful Floscule,” and although it is easy enough 
to count them in some positions, the observer may have 
to exercise a good deal of patience before he is certain 
whether they are five or six. Jor a long evening only 
five could be discerned in the specimen now described, 
but the next night six were apparent without difficulty 
or doubt. The hairs also will not appear anything like 
their true length or number, unless the object glass is 
good, and great care is taken not to obscure them by a 
blaze of ill-directed light. 


so INS 


Cheetonotus larus (swimming). 


After the Floscules had been sufficiently admired and 
put aside, for observations to be repeated on future 
occasions, a Rotifer attracted attention by his merry- 
andrew pranks, throwing himself in all directions by 
means of two long and extremely mobile toes attached 
to his tail-foot. Then came a creature swimming like 
an otter, thrusting his head about on all sides, and 
looking much more intelligent than most of his compeers 
of the pond. Looked at vertically, he was somewhat 


Marvels of Pond-Life. 63 


slipper-shaped, the rounded heel forming his head, then 
narrowing to a waist, and expanding towards the other 
end, which projected in a fork. All round him were 
long cilia, which were conspicuous near the head, and a 
fine line indicated the passage from his mouth to the 
stomach, which seemed full of granular matter.  Pre- 
sently he took to crawling, or rather running, over a 
thread of conferva, and then his back was elegantly 
arched, and his cilia stood erect like the quills of a 
porcupine. This was the Chetonotus larus. 


Cheetonotus larus (crawling). 


in Pritchard’s “ Infusoria,” the views of those writers 
are followed who rank this animal amongst the Rotifers, 
and place it in the family Icthidina. To help out this 
theory, the cilia upon the ventral surface are imagined _ 
to form a “ band-like rotary organ ;” but in truth they 
bear no resemblance whatever to the so-called wheels of 
the ordinary Rotifers, nor is there anything like the 
gizzard which true Rotifers present. Ehrenberg treated 
it as a Rotifer, and Dujardin placed it among the In- 
fusoria, in a particular class, comprehending sym- 
metrical organisms. The ‘Microscopic Dictionary’ 
remarks that its “ structure requires further investiga- 


64 Marvels of Pond-Life. 


tion,’’* and while the learned decide all the intricate 
questions of its zoological rank, the ordinary observer 
will be pleased to watch its singular aspect and lively 
motions. Its size, according to the ‘ Micrographic 
Dictionary,’ varies from 1-710” to 1-220”, and while 
its general proceeding may be watched with an inch or 
two-thirds object glass, and the second eye-piece, a 
power of five hundred linear (obtained by a quarter or 
a fifth) is required to make out the details of its struc- 
ture. If placed in a live-box with threads of conferva, 
and a little-decayed vegetation, it may be observed to 
group about among them, and shake them like a dog. 

We have said that water-fleas were among the in- 
habitants of a bottle filled at the pond, and as they go 
the way of all flesh, it 1s common to find some odd- 
looking animalcules ready to devour their mortal 
remains. These are creatures shaped like beer-barrels, 
upon short legs, and which swim with a tubby rolling 
gait. Looking at one of these little tubs lengthwise, a 
number of lines are seen, as though the edge of each 
stave projected a little above the general level, and 
transverse markings are also apparent, which may be 
compared to hoops. This is the Coleps hirtus, which 
differs from the usual type of Infusoria, by being sym- 
metrical, that is, divisible into two equal and similar 
halves. The dimensions of this species vary from — 
1-570 to 1-430, and its colour varies from white to 


* See a valuable paper by Mr. Gosse, “ History of the Hairy-backed 
Animalcules,” ‘Intellectual Observer,’ vol. v, p. 387, in which the 
known species are described and reasons given for following Vogt and © 
ranging them with the Turbellarian worms. 


Marvels of Pond-Life. 65 


brown. It has been observed to increase by transverse 
self-division, and has two orifices, one at each end, for 
receiving food and ejecting the remains. It often 
requires some little trouble to get a good view of the 
cilia, which are arranged in transverse and longitudinal 
rows. ‘ A power of one hundred and fifty linear is 

convenient for viewing it in motion, but when quiet 
under pressure, one of five or six hundred may be used 
with advantage. 


Coleps hirtus. 


Among the rubbish at the bottom of the bottle, in 
_ which the coleps was found, was a minute dead Rotifer, 
the flesh of which was fast disappearing, but upon being 
examined with a power of nine hundred and sixty 
diameters, it was observed to swarm with extremely 
minute vibriones, the largest only appearing under that 
immense magnification like chains of bluish-green 
globules, not bigger than the heads of minikin pins, 
while the smallest were known by a worm-like wrig- 
gling, although their structure could not be defined. 
5 


66 Marvels of Pond-Life. 


These vibriones are probably members of the vegetable 
world, and they always appear when animal matter 
undergoes putrefaction. . 

M. Pasteur has brought forward elaborate experiments 
to show that the development of the yeast plant is an 
act correlative to alcoholic fermentation, and in like 
manner the growth of vidriones may stand in correlation 
to putrefactive decomposition. 

Ehrenberg considered them animals, and fancied he 


{fs 


54 
WN 


Ley 1/4, 


5 


D1 


ne 
Se 


SAND 
Ss Wee WSS 
=> Ng mee SS 
es aN OS 
4 : 


A, Euplotes (patella) ; B, side view of ditto; ©, stylonichia. . 


detected in them a plurality of stomachs; but the 
vegetable theory is the more probable, at any rate of the 
species under our notice, which is often seen, though 
not always so minute. 

At this time two interesting animalcules were very 
plentiful—the Euplotes patella, and Stylonichia, both 
remarkable as exhibiting an advance in organization, 
which approximates them to the higher animals. In 
addition to cilia they possess styles, which take the 


Marvels of Pond-Life. 67 


place of the limbs of more elaborately-constructed 
creatures, and give a variety to their means of locomo- 
tion. The Huplotes is furnished with an oval carapace 
covering the upper surface, which in different indivi- 
duals, and probably at different ages, exhibits slightly 
varied markings round its margin, which in the specimen 
drawn above consisted of dots. They can run, climb, 
or swim, and exemplify a singular habit which several 
of the infusoria possess, that of moving for a little time 
in one direction, and then suddenly, and without any 
apparent cause, reversing it. If the reader is fond 
of learned appellations, he can call this diastrophy, 
but we do not know that he will be any the wiser 
for it. 

The Stylonichia are oval animalcules, surrounded by 
cilia, and having moreover a collection of styles, both 
straight and curved, the latter called uncini, or little 
hooks. They swim steadily on, and then dart back, but 
not so far as they have advanced, and may be seen to 
keep up this fidgety motion by the hour together. 
Pritchard tells us Ehrenberg found that a single ani- 
malcule lived nine days; during the first twenty-four 
hours it was developed by transverse self-division into 
three animals; these in twenty-four hours formed two 
each in the same manner, so that by self-division only 
(without ova), these animalcules increased three or four- 
fold in twenty-four hours, and may thus produce a million 
from a single animalcule in ten days. Such are the 
amazing powers of reproduction conferred upon these 
humble creatures, powers which are fully employed 
when the surrounding circumstances are favorable, 


68 Marvels of Pond-Life. 


and which, in the aggregate, change the condition of 
large masses of matter, and bring within the circle of 
life millions upon millions of particles every minute of 
the day. 


Marvels of Pond-Life. 69 


CHAPTER VI. 


MAY. 


Floscularia cornuta—Euchlanis triquetra— Melicerta ringens — its 
powers as brickmaker, architect, and mason—Mode of viewing the 
Melicerta—Use of glass-cell— Habits of Melicerta — Curious 
Attitudes—Leave their tubes at death—Carchesium—Epistylis— 
Their elegant tree forms—A Parasitic Epistylis like the ‘‘ Old Man 
of the Sea”—Halteria and its Leaps—Aspidisca Lynceus. 


See AY, the first of summer months, and of old 

41 famous for floral games, which found their 
latest patrons in the chimney-sweeps of 
London, is a good time for the microscopist among the 
ponds, for the increase of warmth and heat favours both 
animal and vegetable life, and so we found as we car- 
ried home some tops of myriophyllum, and soon dis- 
covered a colony of tubicolor rotifers among the tiny 
branches. They proved to be Floscules, generally 
resembling the F. ornata, described in a previous page, 
but having a long slender proboscis hanging like a 
loose ringlet down one side. The cilia or hairs were 
not so long as in the Beautiful Floscules we had before 
obtained, nor was their manner of opening so elegant ; 
but they were, nevertheless, objects of great interest, 
and were probably specimens of the Floscularia cornuta. 
A swimming rotifer in a carapace somewhat fiddle- 


70 Marvels of Pond-Life. 


shaped, with one eye in its forehead, and a two-pronged 
tail sticking out behind (the Euchlanis triquetra), also 
served to occupy attention ; but a further search among 
the myriophyllum revealed more treasures of the tube- 
dwelling kind. These were specimens of that highly — 
curious Rotifer, the Melicerta ringens, who, not con- 
tent with dwelling, lke the Floscules, in a gelatinous — 
bottle, is at once brickmaker, mason, and architect, 
and fabricates as pretty a tower as it is easy to con- 
ceive. The creature itself stands upon a retractile foot- 
stalk, and thrusts out above its battlements a large 
head, with four leaf-like expansions surrounded by 
cilia. Between the lower lobes, or leaves, the gizzard 
is seen grinding away, and above it is an organ, not 
always displayed, and of which Mr. Gosse was fortunate 
-enough to discover the use. This eminent naturalist — 
likens it to the circular ventilator sometimes inserted 
in windows, and he found it was the machine for 
making the yellow ornamental bricks of which the 
' tower is composed. Pellet by pellet, or brick by brick, 
does the Melicerta build her house, which widens 
gradually from the foundation to the summit, and every 
layer is placed with admirable regularity. | 

In order to obtain the materials for her brickmaking 
the Melicerta must have the power of modifying the 
direction of the ciliary currents, so as to throw a stream 
of small particles into the mould, which is a muscular 
- organ, and capable of secreting a waterproof cement, by 
which they are fastened together. The result is, not to © 
produce anything like the tubes made by the caddis- 
worms out of grains of sand, but entirely to change 


Marvels of Pond-Life. rg 


the appearance of the materials employed. All large 
particles are rejected, and only those retained which 
will form a homogeneous pulp with the viscid secretion ; 
and when the process is complete the head of the crea- 
ture is bent down, and the pellet deposited in its appro- 
priate place. Hach pellet appears originally to possess 
a more or less conical figure, but when they are 
squeezed together to make a compact wall they all tend 
to a hexagonal form, by which they are able to touch 
at all points, and any holes or interstices are avoided. 

According to Professor Williamson the young 
Melicerta commences her house by secreting “a thin 
hyaline cylinder,’ and .the first row of pellets are 
deposited, not at the base as would be expected, but in 
a ring about the middle of the tube. “ At first new 
additions are made to both extremities of the enlarging 
ring; but the jerking constrictions of the animal at 
length force the caudal end of the cylinder down upon 
the leaf, to which it becomes securely cemented by the 
same viscous secretion as causes the little spheres to 
cohere.” 

Round the margins of the lobes or expansions may 
be seen delicate threads towards which others radiate ; 
these are thought by Mr. Gosse to be portions of a 
nervous system, and two calcars or feelers serve as 
organs of relation. The young Melicertas are likewise 
furnished with a pair of eyes, which are probably 
rudimentary, and disappear as they grow up. 

The Melicerta tubes, being large enough to be visi- 
ble to the naked eye, are easily crushed in the live- 
box, and to avoid this, they are conveniently viewed in a 


\ 


72 Marvels of Pond-Life. 


shallow glass cell; covered up as before described. By 
occasionally changing the water one may be kept for 
‘days in the same cell, and will reward the pains by fre- 
quently exposing its flower-like head. Usually the 
horns or feelers come out first, and then a lump of flesh. 
After this, if all seems right, the wheels appear, and 
make a fine whirlpool, as may be readily seen by the 
use of a little indigo or carmine. 

The Melicerta is, however, an awkward object to 
undertake to show to our friends, for as they knock at 
the door she is apt to turn sulky, and when once in this 
mood it is impossible to say when her fair form will 
reappear. At times the head is wagged about in all 
directions with considerable vehemence, playing singu- 
lar antics, and distorting her lobes so as to exhibit a 
Punch and Judy- profile. When these creatures die 
they leave their tubes, which are often found empty in 
the ponds they frequent. The Melicertas are con- 
veniently viewed with a power of from sixty to one 
hundred linear, and a colony of them may be kept alive 
for some weeks in a glassjar or tank. 

Among the remainder of my tiny captives were two 
beautiful members of the Vorticella family, Hpistylis 
and Carchesium. The reader will remember that in 
the Vorticella previously described, the bells stood upon 
stalks that were very flexible, and retractile by means 
of a muscle running down their length. The Kpistylis 
is, as its name imports, the dweller on a pillar. The 
stem is stiff, or only slightly flexible, and has no appa- 
ratus by which it can be drawn down. The specimen 
mentioned stood. like a palm-tree, and the large oval 


esium Poly pinum 


are! 


Nike 6-5 ; au he 
f 


"is s d 
) ear hE oA 7 2 
7 . » ; 


Marvels of Pond-Life. 73 


bells drooped elegantly on all sides, as its portrait will 
show. At times they nodded with a rapid jerk. 

The Carchesium differs from the common Vorticella, 
by branching like a tree, but the stems are all retrac- 
tile, although the trunk seldom exercises the power. 
A group of these creatures presents a spectacle of extra- 


Epistylis. 


ordinary beauty—it looks like a tree from fairy-land, 
in which every leaf has a sentient life. In general 
structure the bells of the Fpistylis and the Carchesium 
resemble the common Vorticella, and like them may be 
seen with a power of about one hundred linear for 
general effect, and with a higher one for the examina- 


74 Marvels of Pond- Life. 


tion of special points. Pritchard notices three species 
of Carchesium, and eighteen of Epistylis ;* some of 
which it is to be hoped will turn out to be only varie- 
ties. | } 

Towards the end of this month rotifers abounded, and 
polyps were plentiful. Among the rotifers was one 
about a two-hundredth of an inch long, protected by a 
carapace, and having a tail terminating in a single style, 
hence called ‘‘ Monostyle.”’? There is perhaps no class 
of creatures that present so many curious and unex- 
pected forms as the rotifers; and although we have 
noticed a good many, there are far more that remain to 
be found and described. 

The water in which the preceding animals dwelt was 
enlivened by the jumps of the Halteria, a little globe 
surrounded by long fine cilia, with which its movements | 
were effected; and its companion was the Aspidisca 
lynceus, an oval animalcule, having a distinct cilia or 
Jorica, and furnished, in addition to cilia, with bristles, 
which enable it to walk and climb as well as swim. 

There were also some eggs of rotifers attached to the 
water plants, in which motion could be descried at inter- 
vals, and a little red eye observed. These eggs are 
always large in proportion to the creatures that 
lay them, and if they escape being devoured by 


* An interesting Hpistylis, called Digitalis, from its bells resembling 
fox-glove flowers in shape, occurs as a parasite upon the Cyclops quadri- 
corms, a very common entomostracan in fresh-water ponds. At this 
moment I have a beautiful specimen, branching like a. bushy tree, and 
attached to the tail of a Cyclops, who can scarcely move under his 
burden, which is like Sinbad’s “ Old Man of the Sea.” 


‘ 


~“ 


Marvels of Pond-Life. 75 


enemies, may be watched until their contents step 
forth. 

In this, as in other months, omission is made of 
creatures that have already come under notice, or our 
list would assume larger dimensions. 


76 Marvels of Pond-Life. 


CHAPTER VII. 


JUNE AND JULY. 


Lindia TorulosaCcistes Crystallinus—A professor of deportment on 
stilts—Philodina—Changes of form and habits—Structure of 
Gizzard in Philodina family—Mr. Gosse’s description—Motions of 
Rotifers—Indications of a will—Remarks on the motions of lower 
creatures— Various theories—Possibility of reason—Reflex actions 
Brain of insects— Consensual actions—Applications of physiological 
reasoning to the movements of Rotifers and Animalcules. 


PRESSURE of other occupations prevented 

full use being made of June and July, nor 
was the weather at all propitious. For this 
reason the microscopic doings of these two months are 
recorded in one chapter. 

As usual the Kentish Town ponds were productive 
of objects, and among them were several rotifers not 
found in the previous months.. The first of these was a 
very small worm-like thing, with one eye, a tuft of cilia 
about the mouth, and two toes at the tailend. Had it 
- not been for the jaws, which were working like fingers 
thrust against each other, and which were unmistakably 
of the rotifer pattern, the animal might have been 
supposed to belong to some other class. According to 
the ‘ Micrographic Dictionary,’ the Lindia torulosa is’ 
1-75” long, but this specimen was only about 1-200”. 


Marvels of Pond-Life. ; yd 


It was possibly very young, and did not thrust out its 
cilia in two distinct tufts, as Cohn describes, although 
it may have had the power of doing so. At times it 
sprang quickly backwards and forwards, bringing its 
head where its tail was before. This object required for 
~ its comfortable elucidation a power of about six hundred 
linear. 


CEcistes crystallinus. 


Among the common water-plants, which are worth 
examining as the probable abodes of rotifers or in- 
fusoria, is the pretty little thing called “ star-weed,” 
some of which was obtained from the last-mentioned 


78 Marvels of Pond-Life. 


ponds, and on examination yielded a specimen of a 
tube-dwelling rotifer, the icistes crystallinus, which, 
although less beautiful than the Floscules or the 
Melicerta, is, nevertheless, a pretty and interesting 
object. In this instance a little rough dirty tube, about 
1—70” long, was observed to contain an animal capable 
of rising up and expanding a round mouth garnished 
with a wreath of cilia; while a little below, the inde- 
fatigable and characteristic gizzard of the tribe was in 
full play. A power of two hundred and forty linear 
sufficed to afford a good view, and it was seen that a 
long, irregular, conical body was supported upon a short 
wrinkled stalk. The usual drawings represent this 
creature with a short bell-shaped body upon a very long 
slender pedicle. Possibly this one might have been able 
to show himself under this guise, but he did not attempt 
it; his appearance being always pretty much as de- 
scribed, which made the foot shorter and the body 
longer than the measurements which naturalists have 
given, and according to which the whole creature is 
1—86” long, although the body is only 1—140”. The 
tube of the Cicistes is called a “ lorica,” or carapace; 
but it has in truth no right whatever to the appel- 
lation. 

Another strange rotifer, of whose name I am un- 
certain, had an ovalish oblong body, and a pair of legs 
like compasses, twice as long as himself. His antics 
were those of a posture-master, or ‘ Professor of De- 
portment” on stilts. Sometimes he stood bolt upright, 
bringing his legs close together ; then they were jauntily 
crossed, and the body carried horizontally ; then the 


Marvels of Pond-Life. 79 


two legs would be slightly opened, and the body thrown 
exactly at right-angles to them. These antics were 
repeated all the while the observation lasted, and hada 
very funny effect in proving that drollery is practised. 
if not understood, in the rotatorial world. 

Another kind of rotifer was abundant—the Philodina, 
which belongs to the same family as the common wheel- 
bearer, namely, the Philodinea. The Philodina is a 
good deal like the common wheel-bearer, or Rotifer 


Philodina (swimming). 


vulgaris, but is usually of a stouter build, and carries 
his eyes in a different place. In the common rotifer 
these organs are situated on the proboscis, while those 
of the Philodina are lower, and said to be “ cervical.” 
The changes of form in this rotifer are still more 
remarkable than in the common wheel-bearer. When 
resting it resembles a pear-shaped purse, puckered in at 
the mouth. Then it thrusts out its tail-foot, swells its 
body to an oval globe, protrudes its feeler, and slightly 


80 Marvels of Pond-Life. 


exposes a'row of cilia. After this two distinct wheels 
are everted, and as their cilia whirl and spin, the animal 
is swiftly rowed along, until it thinks proper to moor 
itself fast by the tail-foot, and employ all its ciliary 
_ power in causing currents to converge towards its 
throat. When it pleases it can elongate the body, till 
it becomes vermiform, and it walks lke the common 
rotifer, by curving its back, and bringing its nose and 
its tail in contact with the ground. 


The gizzard of this family (Philodinea) presents a 
considerable deviation from the perfect form exhibited 
by the Brachions. According to Mr. Gosse, “'The 
mallet and the incus (terms already explained) are 
soldered together into two subquadrantic-globular 
masses, which appear to be muscular, but invested with 
a solid integument. The manubria (handles) may still 
be recognised in a vertical aspect as three loops, of 
which the central one is chiefly developed, and in a 
vertical aspect as a translucent reniform (kidney-shaped) 
globe.”” These descriptions are not easy to understand, 


Marvels of Pond-Life. 81 


not from any want of clearness or precision in the words 
employed, but from the complicated character of the 
organ, and its very different appearance under different 
aspects. ‘To make the matter more intelligible, Mr. 
Gosse adds, “ the structure and action of an apparatus 
of this type may be made more clear by a homely illus- 
tration. Suppose an apple to be divided longitudinally, 
leaving the stalk attached to one half. Let this now 
be split again longitudinally so far as the stalk, but not 
actually separating either portion from it. Draw the 
two portions slightly apart, and lay them down on their 
rounded surfaces. They now represent the quadrantic 
masses in repose, the stalk being the.fulcrum, and the 
upper surfaces being crossed by the teeth. By the 
contraction of the muscles, of which they are composed, 
the two segments are made to turn upon their long axis, 
until the points of the teeth are brought into contact, 
and the toothed surfaces rise and approach each other. 
The lower edges do not, however, separate as the upper 
edges approach, but the form of the mass alters, becom- 
ing more lenticular, so that when the toothed surfaces 
are brought into their closest approximation, the outline 
has a subcircular figure. It is on account of this change 
of form that I presume the masses themselves to be 
partially composed of muscle.” 

These remarks, although specially made of the Rotifer 
macrurus, are in the main applicable to all the Philo-— 
dinas, but the student must not expect to understand 
any of the complicated gizzards of the rotifers without 
repeated observations, and no small exercise of patience. 
lt is common to call the portions of the Philodine- 

6 


82 Marvels of Pond-Life. 


‘pattern gizzard ‘‘stirrup-shaped,” but Mr. Gosse has 
shown them to be quadrantic, that is, shaped like the 
quarter of a sphere. 

As we are not very well off with subjects for descrip- 
tion in these two months, we can afford a little time to 
consider a question that continually arises in the mind, — 
on viewing the movements of animalcules, and especially 
of any so highly developed as the rotifers, namely, to 
what extent motions which appear intelligent are really 
the result of anything like a conscious purpose or will. 
When any of the lower animals—a bee, for example— 
acts in precisely the same way as all bees have acted 
since their proceedings have been observed, we settle 
the question by the use of the term instinct. Those who 
take the lowest’ view of insect life, assume that the bee - 
flies because it has wings, but without wishing to use 
them, and that the nerves exciting them to action are 
in their turn excited, not by volition, but by some 
physical stimulus. 

The sight or the smell of flowers is thought by the 
same reasoners to be capable of attracting the insect, 
which is unconscious of the attraction, while proximity 
of food stimulates the tongue to make the movements 
needful for its acquisition, and so forth. The cells, 
they tell us, are built according to a pattern which the 
earliest bee was impelled to construct by forces that 
bear no analogy to human reason and human will, and 
so originate all the ordinary processes of bee life. Some-. 
times, however, it happens that man or accident inter- 
poses particular obstacles, and forthwith there appears 
a particular modification of the orthodox plan, calcu. 


Marvels of Pond-Life. 83 


lated to meet the special difficulty. Howisthis? Does 
any one of the difficulties which the bee or the ant is 
able to get over, produce precisely that kind of electrical 
disturbance, or polar arrangement of nerve particles 
that is necessary to stimulate the first step of the action 
by which the difficulty is surmounted; and does the 
new condition thus established stimulate the second 
step, and so forth, or can the bee, within certain limits, 
really think, design, and contrive? 

No questions are more difficult of solution; but 
while protesting against a tendency to undervalue all 
life below that of man, we must remember we have in 
our bodies processes going on which are not the result 
of volition, as when the blood circulates, and its 
particles arrange themselves in the pattern required to 
form our tissues and organs, and also that many of our 
actions belong to the class termed by physiologists, 
“reflex,”’ that is, the result of external impressions upon 
the nervous system, in which the sentient brain takes no 
part. Thus when a strong light stimulates the optic 
nerve, the portion of brain with which it is connected 
in its turn stimulates the iris to contract the pupil; 
and it is supposed that after a man has begun to walk, 
through the exercise of his will, he may continue to 
walk, by a reflex action; as his feet press the ground 
they transmit an impression to the spinal cord, and the 
legs receive a fresh impulse to locomotion, although the 
mind is completely occupied with other business, and pays 
no attention to their proceedings.* The ordinary move- 


* See Carpenter’s ‘ Manual of Physiology.’ 


/ 


84, Marvels of Pond-Life. 


ments of insects appear to be of this character, and 


to be excited by the ganglia belonging to the ~ 


segment to which the moving limbs are attached. 
Thus a centipede will run, after its head has been cut 
off, and a water-beetle (Dytiscus) swam energetically 
when thrown into water after its brain has been 
removed.* 

It must not, however, be assumed that the brain of 
insects has nothing to do with their movements. It is 
probably the means of co-ordinating or directing them 
to a common end, and gives rise to what are called 
consensual movements, that is, movements which are 
accompanied or stimulated by a sensation, although 
not controlled by a will. In man these actions are 
frequently exhibited, “‘as when laughter is provoked 
by some ludicrous sight or sound, or by the remem- 
brance of such at an unseasonable hour.”}+ Sneezing 
is another instance of a sensation leading to certain 
motions, without any intervention of the human will. 

Speaking of these consensual motions, Dr. Carpenter 
observes, “It is probable, from the strong manifesta- 
tions of emotion, exhibited by many of the lower 
animals, that some of the actions which we assemble 
under the general designation of instinctive are to be 
referred to this group.” 

The insect brain is composed of a supra-cesophagal 
ganglion and infra-cesophagal one. Von Siebold says, 
the first corresponds to the cerebrum of the vertebrata, 
and ‘‘the second is comparable, perhaps, to the cere- 


* Carpenter’s ‘ Manual of Physiology,’ p. 551. 
7 Ibidi, p. 543. 


Marvels of Pond-Life. 85 


bellum or spinal cord.”* The superior ganglion gives 
off nerves to the antennz and eyes, the lower one to the 
mandibles, &c. So far as is known the insects that 
exhibit the most intelligence have the largest and best 
developed brains. _ 

A special volume would be required for anything hike 
a complete examination of the little which is known on 
this subject, but these few remarks may assist the 
- microscopic beginner in examining the movements of 
his subjects, and guard against the error of referring to 
reason and volition those which are, probably, either the 
direct result of stimulants applied to the surface (as in 
nerveless creatures), or the indirect (reflex) result of 
such stimulants in beings like the rotifers, who have a 
nervous system; or the result of sensations, which 
excite actions without previously referring the matter 
to the decision of a will. It must not, however, be 
too readily assumed that the behaviour of creatures 
possessing distinct organs is entirely automatic; and 
we must not forget that even the best physiologists 
know very little concerning the range of functions 
which the nervous ganglia of the invertebrata are able 
to discharge. 


* * Anatomy of Invertebrates,’ Burnett’s trans. 


86 Marvels of Pond-Life. 


CHAPTER VIII. 
AUGUST. 


Mud coloured by worms—Their retreat at alarm—A country duck- 
pond—Contents of its scum—Cryptomonads—Their means of 
locomotion—A Triarthra (three-limbed Rotifer)—The Brachion or 
Pitcher Rotifer—Its striking form—Enormous gizzard-—Ciliary 
motion inside this creature—Large eye and brain—Powerful tail 
—Its functions—Eggs, 


[xeee|N the beginning of this month a pond in the 
4 | Finchley Road, a little beyond the Highgate 
sees. Archway, supplied some’ more specimens of 
the Pterodina patina, described in a previous chapter ; 
but towards the middle of the month a visit to 
Chipstead, in Surrey, enabled a new region to be 
explored. 

It is always a treat to a Londoner to get down to 
any of the picturesque parts of Surrey; the trees 
exhibit a richness of foliage and variety of colour not 
seen within the regions of metropolitan smoke; the 
distance glows with the rich purples so much admired 
in the pictures of Linnel, and the sunsets light up earth 
and sky with the golden tints he is so well able to 
reproduce. Probably the warmth-of the soil, and the 
purity of the air, may make Surrey ponds prolific in 


Marvels of Pond-Life. — 87 


microscopic life; but of this we do not know enough to 
make a fair comparison, although our own ape into 
them were tolerably lucky. 

Walking one day down a lane leading towards 
Reigate, where the trees arched overhead, ferns grew 
plentifully in the sandy banks, and the sunlight flitted 
through the branches, and chequered the path, we came 
to a shallow pond, or great puddle, which crossed the 
way, and near the edge of the water the eye was struck 
with patches of crimson -colour. On attempting to 
take up a portion of one of these patches the whole 
disappeared, although when the disturbance ceased 
the rich colour again clothed the dingy mud. The 
appearance was caused by thousands of little worms, 
belonging to the genus Tudifer, not uncommon in 
such situations, who thrust themselves out to enjoy the 
light and air, and retreat the moment an alarm is 
given. Probably both actions belong to the class 
described in the last chapter, as “reflex ;” but it would 
be interesting to know whether creatures so humble 
have any sense of fear. These worms will repay obser- 
vation, but in these pages we eschew all their tribe— 
unless the rotifers be assigned to them—and take our- 
selves once more to our especial subjects. 

Knowing that farm-ponds are usually well stocked 
with microscopic game, we made a dip into one more 
especially assigned to ducks, and obtained wondrous 
little for-our pains. We were not, however, discou- 
raged, but made an examination of the circumstances, 
which determined a particular course of action. Our 
piece of water was simply a dirty duck-pond, in which 


88 Marvels of Pond-Life. 


no large plants wer. growing, and which did not even 
exhibit the little disks of duckweed that are common 
to such situations. There was, however, on the surface, 
in parts, an exceedingly fine scum of pale yellow green, 
and this, armed with a teaspoon, we proceeded to 
attack. By careful skimming, a small bottle was half- 
filled with minute organic particles, which were likely 


200 
Cryptomonad—Euglena. 


to be interesting in themselves, and pretty sure to be 
the food for something else. A small drop was placed 
on a tablet of the live-box, flattened out by the applica- 
tion of the cover, and viewed with a power of two 
hundred linear, which. disclosed swarms of. brilliant 
green globes, amongst which were a good sprinkle of 
minute creatures, like the Huglene already described, 


Marvels of Pond-Life. > Se 


and whose little red eyes contrasted vividly with the 
prevailing emerald hue. 

One of the higher infusoria, whose species I could 
not identify, was devouring them like a_ porpoise 
among sprats. It did not, however, exhibit any sense 
in its hungry career ; it moved about in all directions, 
gulping down what came in its way, but often per- 
mitting the escape of the little green things that were 
almost in its mouth. The little globes rolled and 


Cryptomonad. 


whirled about without the faintest indication of a 
purpose, and without exhibiting any instrument with 
which their locomotion was effected. To find out how 
this was done, a higher power was used, and from their 
extreme minuteness an amplification of seven hundred 
and twenty linear was conveniently employed, although 
a lower one (three or four hundred) disclosed the secret 
by showing that a little whip was flourished about 
through the neck, which the lower power revealed. 
When highly magnified, each little globe was seen to 
consist of an outer case of a reddish orange colour, 


90 | Marvels of Pond-Life. 


which was noticeable on looking at the edges, although 
in the centre it was transparent enough to show the 
brilliant green contents, that resembled the chlorophyl, 


or green colouring matter of plants. From a short — 


neck proceeded the whip-like filament, which was 
lashed and twisted about in all directions. These little 
creatures belong to the monad family, but whether they 
are to be called Trachelomonads, or by some other hard 
name, the learned must decide. 

The ‘Micrographic Dictionary’ puts a note of 
interrogation to the assertion of some writers that 
Trachelomonads have no necks, and draws some with 
such an appendage. 

Pritchard’s last edition is against necks, and whether 
the necks or no necks are to win, is a mighty question 
equal at least to the famous controversy, which divided 
the world into “big and little endians in the matter 
of breaking eggs.” 

A discussion of more importance is, whether these 
Cryptomonads—that name will do whatever comes of 
the neck controversy—are animals or vegetables. 
Lachmann and Mr. Carter affirm that they have 


detected a contractile vesicle, which would assimulate — 


them to the animal series, but their general behaviour 
is vegetable; and the ‘ Micrographic Dictionary’ is in 
favour of referring them to the A/ge—that great family 
of simple plants, of which the sea-weeds are the most 
important representatives. 

When any of the monads swarm, there are sure to 
be plenty of other creatures to eat them-up, and in 


this instance the predaceous animalcule, already. 


Marvels of Pond-Life. 91 


described, was not the only enemy the little green 
globes had to suffer from, as two sorts of rotifer were 
frequently met with. One of these was a very hand- 
some and singular creature, which in some positions 
had the general contour of a cockatoo, only that the 
legs were wanting, and the head exhibited a monkey 
face. The “wheels” were represented by ciliary tufts, 


Triarthra. 


and two bright red eyes twinkled with a knowing look. 
From each shoulder proceeded a long curved spine, and 
about two thirds down the body, and lying between 
the two long spines, a shorter one was articulated, 
which followed the same curve. A gizzard was busy in 
the breast, and the body terminated in two short toes, 
which grasped a large round egg. Whenever the cilia 
were drawn in, the three spines were thrown up; but | 
they had an independent motion of their own, and 
every now and then were jerked suddenly and violently 


92 Marvels of Pond-Life. 


back, which occasioned a rapid change in the creature’s 
position. The gizzard appeared to consist of two 
rounded masses, having several ridges of teeth, which 
worked against each other something like the promi- 
nences of a coffee-mill. From the three spines, this 
animal was a TJriarthra, or Three-limbed Rotifer, but 
the position of the spines, and the toes, made it differ 
from any species described in the ‘ Micrographic 
Dictionary,’ or in Pritchard. 

Whether or not this species is to be regarded as 
having a lorica or not, must depend upon the precise 
meaning attached to that word. At any rate the 
integument was much firmer than in many of the 
rotifers, and gave an efficient support to the spines 
which a mere skin could not do. As Mr. Gosse 
remarks of an allied genus, the Polyarthra, or Many- 
limbed Rotifer, this creature could not be investigated 
without coming to the conclusion “‘ Here again we have 
true jointed limbs;” a fact of great importance in 
determining the zoological rank of the family, and in 
supporting Mr. Gosse’s view some at least bore a strong 
affinity with the group of Arthropoda, of which the 
insects are the principal representatives. 

Another rotifer of even greater interest, which was 
busy among the Cryptomonads, was the Brachion, or 
“Pitcher Rotifer” (Brachionus). The members of 
this genus will frequently reward the searcher into 
pond-life. Their main characteristic is a cup or pitcher- 
shaped lorica, which is cut or notched at the top into 
several horns or projections, the number of which 
indicates the species; while two or more similar 


Marvels of Pond-Life. 93 


projections ornament the bottom. This lorica is like 
the shell of a tortoise open at both ends; from the top 
an extremely beautiful wreath of cilia is protruded, and 


Brachionus urceolaris. 


‘This drawing has been accidentally reversed by the engraver, 
which alters the relative place of the internal organs. 


also some longer and stiff cilia, or slender spines, which 
do not exhibit the rotatory movement. The ciliary 


/ 


94, Marvels of Pond-Life. 


apparatus is in reality continuous, but it more often 
presents the appearance of several divisions, and the 
lateral cilia frequently hang over the sides. From the 
large size of each cilium they are very favorable 
creatures for exhibiting the real nature of the action, 
which gives rise to the rotatory appearance, and which © 
can be easier studied than described. By movements, 
partly from their base, and partly arising from the 
flexibility of their structure, the cilia come alternately 
in and out of view, and when set in a circular pattern, 
the effect is amazingly like the spinning round of a wheel, 
The internal arrangements of the Brachiones are finely 
displayed, and they have a most aldermanic allowance 
of gizzard, which extends more than half way across 
each side of the median line, and shows all the portions 
described by Mr. Gosse. As the joints of this machine 
move, and the teeth are brought together, one could 
fancy a sound of mill-work was heard, and the observer 
is fully impressed with a sense of mechanical power. 
When the creature is obliging enough to present a 
full front view, her domestic economy is excellently 
displayed. The prey that is caught in her whirlpool is 
carried down by a strong ciliary current to the gizzard, 
which may be often seen grappling with objects that 
appear much too big for its grasp; and Mr. Gosse was 
lucky in witnessing an attempt to chew up a morsel 
that did actually prove too large and too tough, and 
which, after many ineffectual efforts, was suddenly cast 
out. As soon as food has passed the gizzard, it is. 
assisted in its journey by more ciliary currents, which 
are noticeable in the capacious stomach, in the neigh-— 


. 


Marvels of Pond-Life. 95 


bourhood of which the secreting and other vessels are 
readily observed. Just over the gizzard blazes a great 
red eye, of a square or oblong form, and it reposes 
upon a large mass of soft grauular-looking brain, 
which well justifies Mr. Gosse’s epithet “ enormous,” 
Whether this brain is highly organized enough to be a 
thinking apparatus, we do not know, but it is evidently 
the cause of a very vigorous and consentaneous action 
of the various organs the Brachion possesses. 

A description of the Brachion would be very in- 
complete if it omitted that important organ the tail, 
which in this family reaches the highest point of 
development. It is a powerful muscular organ, of 
great size 1n proportion to.the animal, capable of com- 
plete retraction within the carapace, and of being 
everted wholly, or partially, at will. It terminates in 
two short conical toes, protruded from a tube-like 
sheath, and capable of adhering firmly even to a sub- 
stance so slippery as glass. This tail may be observed 
to indicate a variety of emotions, if we can ascribe 
such feelings to a rotifer, and it answers many purposes. 
Now we see it cautiously thrust forth, and turned this 
way and that, exploring like an elephant’s trunk, and 


~ almost as flexible. Now it seizes firm hold of some 


substance, and anchors its proprietor hard and fast. A 
few moments afterwards it lashes out right and left 
with fury, like the tail of a cat in a passion. Then 
again it will be retracted, and a casual observer might 
not imagine the Brachion to be furnished with such a 
terminal implement. 

The Brachiones may often be seen with one or more 


96 Marvels of Pond-Life. 


large eggs stuck about the upper part of the tail, and 
others may be discerned inside. One specimen before 
us has three eggs attached to her in this way. They 
are large oval ‘bodies, with a firm shell. These 
creatures differ very much in appearance, according to 
the direction in which they are seen, and a side view 
makes them look so different from a full front or back 
aspect, that it would be easy to’suppose another animal 
was under observation. The extent to which the 
ciliary apparatus is protruded, and the pattern it forms 
likewise differs continually; and hence no drawing, 
however correct, is sure to resemble the arrangement 
that may be presented to the observer’s eye. But 
however our little ‘‘ Pitcher ”? may be viewed, it is sure 
to prove a spectacle of interest and delight. 


—~<B Ee 


Marvels of Pond-Life. 97 


CHAPTER IX. 


SEPTEMBER. 


Microscopic value of little pools—Curious facts in appearance and 
disappearance of Animalcules and Rotifers—Mode of preserving 
them in a glass jar—Fragments of Melicerta tube—Peculiar shape 
of Pellets—Amphileptus—Scaridium Longicaudum—A long-tailed 
Rotifer—Stephonoceros Eichornii—A splendid Rotifer—Its gela- 
tinous bottle—Its crown of tentacles—Retreats on alarm—Illumi- 
nation requisite to see its beauties—Its greediness— Richly -coloured 
Food—Nervous ganglia. 


yCATTERED about Hampstead Heath are a 
number of little pools, not big enough to be 
dignified by the name of ponds. They are 
generally surrounded by furze bushes, and would escape 
attention if not actually looked for. Those which are 
mere puddles, and have only a brief existence in rainy 
weather, seldom reward the labour of investigation ; 
but others are permanent, except after prolonged 
drought, and afford convenient situations for the 
erowth of conferve, star-weed, and other plants. These 
will nearly always repay the microscopic collector 
during the winter, when he must break the ice to get 
at their contents; in spring, when long chains of frog- 
spawn afford ocular evidence of the prolific properties 
7 


98 Marvels of Pond-Life. | 


of the Batrachian reptiles ; and in summer, when they 
afford both shade and sunshine to their numerous 
inhabitants. Small beetles, water-spiders, larve of 
. gnats, and other insects, rotifers, including the tubi- 
colar sorts, and several varieties of infusoria may be 
expected and generally found. There is, however, a 
curious fact about ponds, big and little, which Prit- 
chard remarks upon in his ‘ Infusoria,’ and which 
corresponds with our own experience, that those which 
have proved to be well stocked with any particular 
creature during one year, will very likely contain none 
of it in the next. There are of course exceptions to 
this rule, but we have often been astonished and dis- 
appointed at finding the complete change, both in 
populousness and population, that a revolution of 
twelve months will make; and it would be extremely 
interesting to notice the changes that took place during 
a term of years. 

Such researches might unfold some unexpected laws 
in the succession of infusorial life. Those germs which 
are most widely diffused, will be the most likely to be 
developed in any mass of convenient water; but how 
and why the rarer forms come and go is very imper- 
fectly understood. Slight modifications in surrounding 
circumstances will materially affect the result. Thus, 
if we bring home a handful of conferva, and a few 
water-plants of higher organisation, such as duck-weed 
and anacharis, and place the whole in a glass jar full 
of pond-water, we shall at first have a good stock of 
objects ; but they will usually grow less and less, until 
scarcely anything is left. If, however, we introduce a 


Marvels of Pond-Life. 99 


few pieces of straw, or a tiny wisp of hay, we shall 
succeed much better, and not only preserve our popula- 
tion longer, but enjoy a succession of animated crops. 
Extensive decomposition of vegetable matter kills off 
all but certain families, such as Paramecia, who enjoy 
it; on the other hand, too little decomposition proves 
fatal to some creatures, by depriving them of their food, 
and when they have died off, those who depended upon 
them for a living, die too. Different vegetables in 
decomposition suit different creatures, and hay and 
straw in that state seem to please the largest number. 
An animalcule tank will succeed best when it contains 
two or three kinds of growing plants, which oxygenize 
the air, and a moderate variety of decomposing or- 
ganisms will supply food without making the water 
offensive. 

From these considerations it will be apparent that 
not only the nature of the vegetation of a pond, which 
is often changed by accidental circumstances, but also 
the quality of the odds and ends that the winds may 
blow into it, or which may fall through the air, will do 
much to determine the character and number of its 
inhabitants, while the quantity of shade or sunshine it 
enjoys, will also exercise an important influence. Hay 
and other infusions have from the beginning of micro- 
scopic investigations been employed to obtain the 
creatures which the Germans call “Infusions thier- 
chen” (infusion animalcules), and the English “ Infu- 
soria ;’ but very little has yet been done in the way of 
their scientific culture and management. 

To return from this digression to our little Hamp- 


100 Marvels of Pond-Life. 


stead ponds, we obtained from one, in September, that 
was full of star-weed, a number of sugar-loaf bodies, 
adhering to one another, and of a pale yellow brown 
colour. The specimens first examined looked complete 
in themselves, and were taken for eggs of some water 
creature. Further search, however, disclosed aggrega- 
tions of similar sugar-loaves that had evidently formed 
part of a tubular structure, and the idea at once 
occurred that they were fragments of a Melicerta tube, 
a conclusion that was verified by finding some tubes 
entire and a dead Melicerta in the rubbish at the 
bottom. All the specimens of Melicerta tubes we had 
hitherto examined were composed of rounded pellets, 
but these were made of pointed cones or sugar-loaves, 
with the points projecting outwards from the general 
surface. In Pritchard’s ‘Infusoria,’ these pellets are 
described “‘ as small lenticular bodies.” The ‘ Micro- 
graphic Dictionary’ states that the tubes of the 
Melicerta are composed of “numerous rounded or 
discoidal bodies;’? and Mr. Gosse, in his ‘ Tenby,’ 
which contains an admirable description, and an 
exquisite drawing of this interesting rotifer, calls the 
pellets “ round.” 

Not being able to obtain a living specimen of the 
Melicerta, who made her tube of long sugar-loaves, I 
could not tell whether she differed in: structure from 
the usual pattern of her race, but the general appear- 
ance of the dead body was the same. It is possible 
that these creatures possess some power of modifying 
the form of their singular bricks, or they may at 
different ages vary the patterns, which matters some 


Melicerta ringens. 


Marvels of Pond-Life. 101 


fortunate possessor of a colony of these animals oy be 
able to verify. 

In the sediment of the water containing the Meli- 
certa cases was found an animalcule about 1-120" long, 
- covered with cilia, and having a proboscis seldom more 
than a quarter of the length assumed by the body, 
which continually changed its form, sometimes elon- 
gating, sometimes shortening, and often contracting 
one side into a deep fissure. It was, probably, an 
Amphileptus, though not precisely agreeing with any 


Scaridium longicaudum. 


drawing or description I am acquainted with. Another 
inmate of the same water was a lively long-tailed rotifer, 
with a small oval body, a tuft of vibrating cilia and a 
curved bristle visible among them on one side. This 
creature had a jointed tail-foot, ending in two long 
style-shaped toes, and by means of this appendage 
executed rapid leaps or springs. It was the Scaridium 
longicaudum, and agreed in dimensions tolerably well 
with the size given in the books, namely, total length 
1-72”. With a power of five hundred diameters the 


102 Marvels of Pond-Life. 


muscles of the tail-foot presented a beautifully striated 
appearance. . 
Towards the end of the month I passed the Vale of 
Heath Pond, Hampstead, and although I had not gone 
out for the purpose of collecting, was fortunately 
provided with a two-dram bottle. Close by the path the 
Anacharis alsinastrum grew in profusion, quantities of 
water-snails crawled among its branches, and small fish . 
darted in and out, threading their mazes with lightning 
rapidity. Thrusting a walking-stick among the mass 
of vegetation, a few little tufts were drawn up and care- 
fully bottled, with the addition of a little water. 
Returning home, a few leaves were placed in the live- 
box, and on examination with the power of sixty dia- 
meters they disclosed a specimen of, perhaps, the most 
beautiful of all the rotifers, the Stephanoceros Kichornii. 
In this elegant creature an oval body, somewhat ex- 
panded at the top, is supported upon a tapering stalk, 
and stands in a gelatinous bottle, composed of irregular 
rings superimposed one upon the other, as if thrown off 
by successive efforts, the upper ones being inverted and 
attached to the body of the animal. But that which 
constitutes the glory of this little being is the crown of 
five tapering tentacles, each having two rows of long 
cilia arranged on opposing sides, but not in the same 
plane. The ordinary position of the tentacles is that 
of a graceful elliptical curve, first swelling outwards, 
then bending inwards, until their points closely approxi- 
mate, but each is capable of independent motion, and 
they are seldom quiet for many minutes at a time. 
The cilia can be arranged in parallel rows or in tufts 


4 


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Marvels of Pond-Life. 108 


at the will of the creature, and their motion appears 
under control, and susceptible of greater modification 
than is exhibited by the ordinary infusoria. 

The Stephanoceros is a member of the Floscule 
family, but in all the specimens I obtained and watched 
for several weeks, there was an important difference in 
the relation of the tube to the creature. In the Flos- 
cules I had never seen anything like an adhesion 
between the tube and the animal, but in the Stephano- 
ceros I noticed it continually, and always in the manner 
already described. Like the Floscule, the ‘Stephano- 
ceros is readily alarmed, and retreats into her house, 
carrying with her the invaginated portion. In the last 
edition of ‘ Pritchard’s Infusoria,’ this case is spoken of 
as apparently not tubular, but a solid gelatinous mass, 
enveloping the animal as high up as the base of the 
rotatory arms. It is very likely that specimens at 
different ages, and possibly in different seasons, may 
vary in the structure of their abodes; but I am not 
able to concur in the preceding account, as all the 
tubes I examined resembled sacks turned in at the 
mouths, and attached to the shoulders only of their 
inmates ; and on one occasion I was able to look down 
into a deserted tube, which had not collapsed, as it 
would have done if it had been merely a solid gelatinous 
mass. 

Like the Floscule, the Stephanoceros only reveals 
her beauties under careful illumination. A direct light 
renders them invisible, and only when the requisite 
obliquity has been obtained, does the exquisite char- 
acter of the structure become displayed. The dark- 


104: Marvels of Pond- Life. 


ground illumination is very useful, and makes the 
ciliary action very distinct. At times a view can be 
obtained, in which the cilia of perhaps a single tentacle 
are all ranged like the steel springs of a musical box. 
For a moment they are quiescent, and then they vibrate 
in succession, each moving thread sparkling in the 
light. With a clumsy mode of lighting them, the cilia 
look like stumpy bristles, and are often so drawn; but 
precisely the right quantity of light coming in the 
right direction, makes them appear more numerous, 
and much longer than would at first be supposed. 
When well exhibited the tentacles have a lustre between 
glass and pearl ; the body, in a favorable specimen, is 
like a crystal cup, and the food, usually composed of 
small red and green globes, glows like emeralds and 
rubies, as if in the height of luxury the little epicure 
had more than rivalled Cleopatra’s draught, and instead 
of dissolving, swallowed its jewelry whole. So lustrous 
and varied in colour is the whole appearance of the 
animal under these circumstances, that it is frequently 
alluded to by one of our first artists, to whom it was 
displayed. 

It is said by some authors that the tentacles are used 
to seize prey. This never occurred under my observa- 
tion, although their basal portions are often approxi- 
mated when an object is forced down to the grinding 
apparatus below. The Stephanoceros is a ravenous 
feeder, and swallows a variety of creatures. Green 
vegetable monads, rich red and brown globes of similar . 
characters, and any animalcule that comes in her way 
is acceptable; and even good-sized rotifers do not 


Marvels of Pond-Life. 105 


escape her all-consuming maw. On one occasion I 
noticed one of the loricated sort, more than half as 
long as one of her tentacles, rapidly swallowed, and 
passed downwards without attempting to escape. 
Objects much too big for the gizzard are often gulped 
down, and probably receive a preliminary softening and 
maceration in the crop. Very often, when food is 
plentiful, the creature is filled to the brim, but still 
endeavours to continue her abundant meal. From the 
presence of large quantities of food and the density of 
the integuments, the gizzard cannot always be seen; 
but in favorable specimens its teeth may be observed 
busily at work. 

At the base of the tentacles small masses of matter 
may be discovered, which are probably nervous ganglia. 
and other organs; and Ehrenberg discovered small 
vibrating bodies, supposed to be connected with the 
function of respiration. A single egg, as shown in the 
annexed drawing, is often found, and the ovarian is said 
to develop but few at a time. Two red eyes are found 
in young specimens, but in adults they either disappear 
or are not conspicuous. The Stephanoceri are sociable 
animals, and when one is found, others are probably 
near at hand. Several may often be discovered on the 
same branch of a small water-plaut, of various dimen- 
sions, and in different stages of growth. The full size 
is about 1-36” in height, and from its magnitude care 
is required not to crush it in the live-box. When 
specimens are plentiful, some should be placed in that 
convenient receptacle; and others with the plant on 
which they are growing, in a glass cell or trough, 


106 ' Marvels of Pond-Life. 


where they have more room to display their motions, 
and can with fresh supplies of water, be preserved for 
days and weeks. With occasional, renewals from one 
pond, I was able to keep up a stock for about three 
months, and never had objects which gave more plea- 
sure to myself or to my friends. 


Marvels of Pond-Life. 107 


CHAPTER X. 


OCTOBER. 


Stentors and Stephanoceri—Description of Stentors—Mode of viewing 
them—Their abundance—Social habits—Solitary Stentors living in 
Gelatinous caves—Propagation by divers modes—Cephalosiphon 
Limnias—A group of Vaginicole—Changes of shape—A bubble- 
blowing Vorticella. 


Mazen CTOBER, the finest of our autumn months, is 
f ert | noted for usually granting the inhabitants of 
our dripping climate about twenty pleasant 
sunshiny days, and it is probably on this account some- 
what of a favourite with the infusorial world, although 
the cold of.its nights and early mornings thins their 
numbers, which reach a maximum in the summer heat. 
Even in the dismal year 1860, October maintained its 
character, and afforded a great many opportunities of 
animalcule hunting, during which a constant supply of 
Stephanoceri were readily obtained, together with 
swarms of Stenfors, which are not exceeded in interest 
by any of the Ciliated Protozoa. The Stentors were 
abundant on the same weed (Anacharis), that formed 
the residence of the Stephanoceri, and might be seen 
in large numbers hanging from it like green trumpets, 
visible to the unassisted eye. In the ‘ Micrographic 


108 Marvels of Pond-Life. 


Dictionary ’ they are said to belong to the Vorticella 
family, which has already given us several beautiful 
objects, and possess a marvellous power of changing 
their shape. It is, however, better to follow Stein, who 
separates them from the Vorticellids and ranges them 
in his order Heterotricha, as they have two distinct 
sets of cilia, small ones covering the body and the 
larger ones round the mouth. Those before us are 
named after this property Stentor polymorphus,* or 
Many-shaped Stentors, and owe their exquisite tint to 
numberless green vesicles, or small cavities filled with 
colouring matter like that of plants. This, however, is 
not essential to. the species which may often be found 
of other hues. In size this Stentor varies from a 
hundred and twentieth to one twenty-fourth of an 
inch. It is entirely covered with fine cilia, disposed in 
longitudinal rows, and round the head is a spiral 
wreath of larger and very conspicuous cilia leading to 
the mouth. 

Having observed the abundance of these creatures, a 
few small branches to which they were appended, were 
placed in the glass trough, and viewed with powers of 
sixty and one hundred linear. Some had tumbled 
down as shapeless lumps, others presented broad 
funnel-shaped bodies ; while others stretched themselves 
to great length like the long, narrow post-horns which 
still wake the echoes of a few old-fashioned towns. 
The ciliary motion of the elegant wreath was active 
and rapid, causing quite a stir among all the little 
particles, alive and dead; and when the right sort of 


* See Frontispiece. 


Marvels of Pond-Life. 109 


food came near the corkscrew entrance to the mouth, 
down it went, and if conspicuous for colour, was 
subsequently seen apparently embedded in little 
cavities, which Ehrenberg supposed were separate 
stomachs, although that theory is now rejected. One 
advantage of viewing these objects in a sufficient 


A, B, C, D, Stentor polymorphus in different degrees of ex- 
pansion. A large specimen is one twenty-fourth of an inch 
long. 


quantity of water, to leave them in freedom, is that 
they frequently turn themselves, so that you can see 
right down into them; and the drawing given in the 
frontispiece represents such a view, which is the most 
favorable for the exhibition of the mouth. To make 


110 Marvels of Pond-Life. 


‘out the details of their structure, to see the nucleus 
and other organs, the flattening in the live-box is 
useful, and it enables much higher powers to be em- 
ployed. 7 

After leaving the Anacharis in a glass jar for a few 
days, the Stentors multiplied exceedingly ; some clung 
to the sides of the vessel in sociable communities, 
others hung from the surface of the water, and crowds 
settled upon the stems, visibly changing their tint, as 
the Stentor green was much bluer than that of the 
plant. Scores swam about in all sorts of forms. Now 
they looked like cylindrical vessels with expanding 
brims, now globular, now oddly distorted, until all 
semblance of the original shape was lost. Many were 
found in shiny tubes, but these were never so lively or 
green as the free swimmers, but mostly of a dingy 
dirty hue. 

These housekeepers were more timid and cautious — 
than the roving tribe. They came slowly out of their 
dens, drew back at the slightest alarm, never took their 
tails from home, and only extended their full length 
when certain not to be disturbed. Some authors have 
thought they only take to private lodgings when they 
feel a little bit poorly, but others dispute this opinion, 
and I do not think it is correct. I have found these 
Stentors at all seasons, from January to the autumn, 
but they are never so numerous, nor aggregated in 
numbers like the roving sort. Whether they are old 
folks, who are tired of the world and its gaieties, and 
devote the remainder of their lives to contemplation, or 
whether they are bachelors disappointed in love, I am 


Marvels of Pond-Life. 111 


unable to say; but they are very inferior in beauty to 
the “ gay and glittering crowd.”’* 

For some weeks my Stentors abounded, and then 
most of them suddenly disappeared. They could not 
have “‘ moved,” but probably “went to smash” by a 
process peculiar to infusoria, and which Dujardin 
politely describes as ‘“ diffluence.’ This mode of 
making an exit from the stage of life is more tragical 
than the ripping up so fashionable in Japan. The 
integument bursts, and its contents disperse in minute 
' particles, that in their turn disappear, and scarcely 
leave a “ wrack behind.” 

The Stentors obey the injunction to “increase and 
multiply ” by self-division, which Stein says is always 
oblique, and the nucleus, which plays such an impor- 
tant part in infusoria, is band-like, moniliform (bead- 
shape), or round. When an animalcule increases by 
self-division, a portion of the nucleus goes with each 
part, and it is probably the organ which stimulates the 
change. It is also concerned in other modes of propa- 
gation. “The anus is situated on the back close 
beneath the ciliary circle ;” and the “ contractile vesicle 
on a level with the ciliary wreath.” Stein records that 
in November, 1858, he met green Stentors (Poly- 
morphus) encysted, and he figures one in a gelatinous 
flask having a stopper in its narrow néck. 

Before closing our account of the Stentor, let us 
revert a moment to the ciliary wreath, as it may be 
made the subject of a curious experiment. If, for 


* Stein says the colourless variety of S. Polymorphus is sometimes 
found with a tube, and the 8. Réssellii very frequently so provided. 


112 Marvels of Pond-Life. 


example, the cilia are viewed at right-angles to their 
length, they will seem to form a delicate frill, in which 
a quivering motion is perceived. But if the table is 
shaken by a sharp blow, the frill is thrown into waves, 
or takes the form which washerwomen give to certain 
female articles by the use of the Italian iron, and the 
ciliary motion is thus made to take place in different 
planes, and rendered strikingly apparent. 

One day turning over the Anacharis in search of 
subjects, a small brown tube was noticed, from which 
a glassy rod protruded like the feeler of a rotifer. 
Keeping the table quiet, and watching the result, was 
soon rewarded by a further protrusion of the feeler, 
accompanied by a portion of the body of the inmate of 
the tube. The feeler was thrust on this side and on 
that, as if collecting information for its proprietor, who, 
I suppose, was satisfied with the intelligence, and 
gradually extended herself, until she stood out two 
thirds in length beyond the tube, and set two lobes of 
one nearly continuous ciliary organ in rapid motion. 
Sometimes the creature, Cephalosiphon limnias, bent 
its neck, if I may so speak, to the right, and sometimes 
to the left, and sometimes stood upright, when the 
true form of the ciliary apparatus could be seen. The 
tube of this creature was opaque, from the adhesion of 
foreign matter, and presented an untidy appearance, 
strangely contrasting with the clear, neat bottles of the 
Floscules. These Cephalosiphons are very whimsical 
in their ways, and many that were sent to different 
observers never exhibited their ciliary wreaths, but 
performed sundry antics, disguising their true shape. 


Marvels of Pond-Life. 113 


Somewhat like the Cephalosiphon, though much 
commoner and without the siphon, is Limuias cerato- 
phylli, which every collector is sure to meet. The 


Cephalosiphon limnias. 


length of the Limnias varies, according to Pritchard, 
from 1-20” to 1-40”, Our Cephalosiphon, when fully 
extended and magnified one hundred and eighty linear, 


8 


114 Marvels of Pond-Life. 


looked about three inches and a half long, and was 
therefore very small. Just below the ciliary lobes the 
gizzard was seen, with its toothed hammers working one 
against the other. The masticatory organ differs from 
the typical form, as represented in the Brachion; and Mr. 
Gosse observes of Limnias that ‘‘ each uncus forms, with 
its ramus, a well-defined mass of muscle enclosing the 
solid parts, and in form approaching the quadrature of 
a globe. Across the upper surface of the mass the 
uncus is stretched like three long parallel fingers, 
arched in their common direction, and imbedded in the 
muscular substances, their points just reaching the 
opposing face of the ramus, and meeting the points of 
the opposite wncus when closed.’’* 

There is no connection between Limnias or Cephalo- 
siphon and their tubes, except that of simple adhesion, 
which takes place by means of the end of their foot- 
stalks. : 
In a former chapter we have described an interesting 
relation of the Vorticella, the Cothurnia, whose elegant 
crystal vases form a very artistic abode, characterised 
by possessing a distinct foot. Other species of the 
same family inhabit vases which have no foot or stalk, 
or live in gelatinous sheaths less accurately fashioned. 
Sometimes these creatures are obliging enough to 
conform to the. specific descriptions which eminent 
naturalists have given of them, and also to the cha- 
racters which the authorities have assigned to the 
different genera in which they have been grouped, but 


* The term uncus, ramus, etc., have been explained in Chapter II, 
page 28. 


Marvels of Pond-Life. 115 


the microscopist will often meet with difficulties in the 
way of classification. 

Attached to a piece of weed were a number of cylin- 
drical masses of brownish jelly, with rounded tops, and 
situated in an irregular and very transparent sheath, 
about twice as high as themselves. Presently they all 
rose up to four times their previous height, put forth a 


240 


Vaginicola (?) (A, elongated; B, retracted.) 


beautiful crown of vibrating cilia, and opened a sort of 
trap-door to their internal arrangements. In this 
position they had a long cylindrical form, gracefully 
curved, but of nearly equal width from the mouth to 
the base, and they readily imbibed particles of carmine, 
which tinged sundry little cavities with its characteristic 
hue. The slightest disturbance caused the ciliary 


116 Marvels of Pond-Life. 


wreaths to be drawn in, and the bodies to be retracted, 
and descend into their house like a conjuring toy, until 
the appearance first described was reproduced. 

The general form and structure of these objects was 
like the drawings usually given of Vaginicola, which is 
said not to exist in groups, although two individuals 
are commonly found in one well-shaped cell. These 
creatures, however, did not taper towards the base as 
Vaginicole generally do, and perhaps they became 
aware of this defect in their figures, for after a day or 
two a change appeared, and they assumed a more 
graceful form by swelling out in the middle, and then 
growing slender down to the bottom, very much like 
the pattern given by glass-blowers to little vases of 
flowers. 

It is very important to note the changing appearance 
of animalcules, and where the same individuals can -be 
observed from day to day, these will often be found 
considerable. It is probable that when such particulars 
are fully known, the number of species will be greatly 
reduced, and the study of these organisms considerably 
simplified. I have called the animals just described 
Vaginicole, but the reader must be prepared to find 
similar bodies, inhabiting well-formed vases, either 
solitarily or in couples, the latter condition arising 
from the fission of one individual without a corre- 
sponding division of the abode. 

For a few weeks I continually met with groups living 
as I have described, in what may be called amorphous 
cells, which were often so nearly like the surrounding 
water in refracting power, as to be discerned with some 


Marvels of Pond-Life. Li7 


difficulty. No trace could be seen of divisions into 
separate cells, but they all appeared to live happily 
together in one room, and if one went up all went 
up, and if one went down all went down, as if their 
proceedings were regulated by a community of sensa- 
tion or will. 

Another little curiosity was a transparent cup upon a’ 
slender stem, which stood upright like a wine-glass, 
and supported on its mouth a transparent globe. By 
removing a leaf which prevented the stalk being traced 
to its termination, it was found to be a Vorticella, and 
after two hours the globe was partially drawn in, and 
reduced in size. Why the creature was engaged in 
blowing this bubble I do not know, and have not met 
with another instance of such conduct. 


Heapess awe eS 


118 Marvels of Pond-Life. 


CHAPTER XI. 


NOVEMBER. 


Characteristics of the Polyzoa—Details of structure according to 
Allman—Plumatella repens—Its great beauty under proper illu- 
mination—Its tentacles and their cilia—The mouth and its guard 
or epistome—lIntestinal tube—How it swallowed a Rotifer, and 
what happened—Curiosities of digestion—Are the tentacles capable 
of Stinging >—Resting Eggs, or “ Statoblasts ’—Tube of Pluma- 
tella—Its muscular Fibres—Physiological importance of their 
structure. 


some AEE of a new creature among 
some bits of Anacharis, from the Vale of 
Heath Pond, and searched for complete and intelligible 
specimens without effect. Luckily one evening a 
scientific neighbour, to whom I had given some of the 
plant for the sake of the beautiful Stephonoceri which 
inhabited it, came in with a glass trough containing a 
little branch, to which adhered a dirty parchment-like 
ramifying tube, dotted here and there with brown oval 
masses, and having sundry open extremities, from 
which some polyp-shaped animals put forth long pearly 
tentacles margined with vibrating cilia, and making 
a lively current. The creatures presented an organiza- 
tion higher than that of polyps, for there was an 


Plumatella repens. 


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Marvels of Pond-Life. 119 


evident differentiation and complication of parts. They 
belonged to the Polyzoa or Bryozoa,* a very important 
division of the mollusca. The Polyzoa are chiefly 
m rine, and the common “ sea-mat,” often erroneously 
trcated as a sea-weed, is a well-known form. A species 
of another order often picked up on our coasts is the 
Se: tularia, or Sea-Fir, composed of delicate branching 
steus of a horny-looking substance, which, under a 
pocket-lens, is found to contain an immense number of 
small cells inhabited by Polyps. It is instructive to 
compare the two and note how much more advanced in 
structure is the Polyzoon than the polyp. 

Polyzoa were formerly associated with the polyps, to 
which they bear a strong superficial resemblance; but 
they are of a much higher degree of organization, as 
will be seen by comparing what has been said in a 
former chapter on the Hydra, with the description 
which we now proceed to abridge from Dr. Allman’s 
splendid monograph on the fresh-water kinds. In 
order to get a general conception of a Polyzoon, the , 
Professor tells us to imagine an alimentary canal, 
consisting of cesophagus, stomach, and intestine, to be 
furnished at its origin with long ciliated tentacles, and 
to have a single nervous ganglion on one side of the 
ceso; hagus. We must then conceive the intestine bent 
back till its anal orifice comes near the mouth; and 
this curved digestive tube to be suspended in a bag 
containing fluid, and having two openings, one for the 


* Polyzoa means “many animals,” in allusion to their habit of living 
in association. Bryozoa, “moss-animals,’ from some forming cells 
having that appearance. 


120 Marvels of Pond-Life. 


mouth and the other for the vent. A system of 
muscles enables the alimentary tube to be retracted or 
protruded, the former process pulling the bag in, and 
the latter letting it out. The mouth of the bag is, so 
to.speak, tied round the creature’s neck just below the 
tentacles, which are the only portions of it that are 
left free. The investing sack has in nearly every case 
the power of secreting an external sheath, more or less 
solid, and which branches forming numerous cells, in 
which the members of the family live in a socialistic 
community, having, as it were, two lives, one individual, 
and the other shared in common with the rest. 

The whole group of tubes and cells, whatever may be 
the form in which they are aggregated, is called the 
Polypary, or, as Dr. Allman prefers, the Cancecium 
(common house) ; the creature he names a Polypide* 
(polyp-like) ; and the disk which bears the tentacles 
Lophophore (crest-bearer). There are some more hard 
words to be learnt before the student can enjoy himself 
scientifically among the Polyzoa, and we shall be 
compelled to employ some of them before we have 
done; but will now endeavour to describe what was 
presented to our view by the specimen obtained from 
the Hampstead Pond. 

The general aspect of a branch of Plumatella repens 
—the creature we have to describe—is given in the 
drawing annexed. When all was quiet, the mouths of 
the bags belonging to each cell were slowly everted, 
and out came a numerous bundle of tentacles, which 


* Polyzoon is preferable, as avoiding confusion with polypite, used 
for another class of object. 


Marvels of Pond-Life. 121 


were either spread like the corolla of a flower, or 
permitted to hang dishevelled like the snake-locks of 
Medusa. We will suppose these organs symmetrically 
expanded, and that we are looking down upon them 
with a magnifying power of sixty diameters, the light 
having been carefully adjusted by turning the reflecting 
mirror a little on one side, to avoid a direct glare. 
The tentacles, each of which curves with a living grace, 
and displays an opaline tint in its glassy structure, do 
not form a complete circle, for at one place we discern 
two slightly diverging arms of the disk, or frame 
(Lophophore) from which they grow. 

These arms support tentacles on each side, and leave 
a gap between, so that the whole pattern is crescentic, 
or crescent-shaped, and not circular. Extending as far 
as the points of the arms, and carried all round the 
crescent, is an extremely ‘delicate membrane, lke the 
finest gauze, which unites all the tentacles by their 
basal portions, and makes an elegant retreating curve 
between every two. Each tentacle exhibits two rows 
of cilia, which seintillate as their vibrations cause them 
to catch the light. The motion of the cilia is in- 
variably down one side and up the other, the current 
or pattern being carried on from one tentacle to the 
other, all through the series. This characteristic, and 
the facility with which each cilium can be distin- 
guished, gives great interest and beauty to the spec- 
tacle of this wonderful apparatus, by which water- 
currents are made to bathe the tentacles, and assist 
respiration, and also to carry food towards the mouth, 
over which a sort of finger or tongue is stretched to 


122 Marvels of Pond-Life. 


guard the way, and exercise some choice as to what 
particles shall be permitted to pass on. This organ is 
called the epistome, from two Greek words, signifying 
“upon the mouth.” 

If the cell is an old one, it may be covered with so 
much extraneous matter as to obscure the economy — 
within; but we are fortunate in having a transparent 
specimen before us, through which we can see all that 
goeson. The alimentary tube, after forming a capacious 
cavity, much longer than it is broad, turns round and 
terminates in an orifice near the mouth, and just below 
the integuments. When refuse has to be discharged, 
this orifice is protruded; and after the operation is 
over, it draws back as before. Long muscles, composed 
of separate threads or fibres, pull the creature in and out 
of its cell, and at the part where the stomach ends, and 
the intestine turns round, is attached a long flexible 
rope, called the funiculus, which goes to the bottom of 
the cell. The passage of the food-down to the stomach, 
its digestion, and the eviction of the residue, can all be 
watched ; and when a large morsel is swallowed, the 
spectacle is curious in the extreme. 

One day a polyzoon caught a large rotifer, (R. vul- 
garis,) which, with several others of its tribe, had been 
walking over the cenecium, and swimming amongst 
the tentacles, as if unconscious of danger. All of a 
sudden it went down the whirlpool leading to the mouth, 
was rolled up by a process that could not be traced, 
and without an instant’s loss of time, was seen shooting 
down in rapid descent to the gulf below, where it looked 
a potato-shaped mass, utterly destitute of its charac- 


Marvels of Pond-Life. 123 


teristic living form. Having been made into a bolus, 
the unhappy rotifer, who never gave the faintest sign of 
vitality, was tossed up and down from the top to the 
bottom of the stomach, just as a billiard-ball might be 
thrown from the top to the bottom of a stocking. 
This process went on for hours, the ball gradually 
diminishing in size, until at last it was lost in the 
general brown mass with which the stomach was filled. 
The bottom of the stomach seems well supplied with 
muscular fibres, to cause the constrictions by which 
this work is chiefly performed, and by keeping a colony 
for a month or two, I had many opportunities of seeing 
my Polyzoa at their meals. 

When alarmed the tentacles were quickly retracted, 
but although these creatures are said to dislike the light, 
and usually keep away from it in their native haunts, 
my specimens had no objection to come out in a strong 
illumination, and seemed perfectly at their ease. They 
were indeed most amiable creatures, and never failed to 
display their charms to admiring visitors, who rewarded 
them with unmeasured praise. Twice I had an oppor- 
tunity of observing an action I cannot explain, except 
by supposing either that the tentacles of the Plumatella 
have some poisonous action, or that rotifers are 
susceptible of fear. On these occasions the common 
rotifer was the subject of the experiment. First one 
and then another got among the tentacles, and on 
escaping seemed very poorly. One fellow was, to borrow 
a phrase from Professor Thomas Sayers, “ completely 
doubled up,” and two or three seconds—long periods in 
a rotifer’s life—elapsed before he came to himself again. 


124 Marvels of Pond-Life. 


By keeping a colony of the Plumatella for a few weeks 
in a glass trough, and occasionally supplying them with 
fresh water from an aquarium, containing the animal- 
cules, they are easily preserved in good health, and as 
they develop fresh cells, the process of growth may be 
readily watched. This production of fresh individuals 
enlarges the parent colony, but could not be the means 
of founding a new one, which is accomplished by two 
other modes. A little way down the eells Professor 
Allman discovered an ovary attached to the internal 
tube by a short peduncle, or foot stalk, while a testis or 
male generative organ is attached to the funiculus, or 
“little rope,’’ we have already described. 

July and August are the best times for observing the 
Ovaries, and they are most conspicuous in the genera 
Alcyonella and Paludicella. True eggs are developed in 
the ovaries in a manner resembling this mode of mul- 
tiplication in other animals; but there is another kind 
of egg, or, perhaps to speak more properly, a variety of 
bud, which is extremely curious. In looking at our 
specimens we noticed brown oval bodies in the cells ; 
these, on careful examination, presented the appearance 
of the sketch. The centre is dark, covered with a net- 
work, which is more conspicuous im the lighter coloured 
and more transparent margins. These curious bodies 
are produced from the funieulus, and act as reserves of 
propagative foree, as they are not hatched or developed 
until they get out and find themselves exposed to ap- 
propriate circumstances. Professor Allman names 
them Statodblasts, or stationary germs, and they bear 
some resemblance to what are called the “ winter eggs” 


Plumatella repens on a leaf. 


Marvels of Pond-Life. 125 


of some other creatures. The Professsor was never able 
to discover any mode by which they were permitted to 
escape from the cells, and in our colonies none were 
allowed to leave their homes until the death of their 
parent, and the decomposition of its cell had taken 
place ; a process which went on contemporanecously with 
the growth of new cells, until the plant on which the 
cenecium was situated, rotted away, and then unfortu- 
nately the whole concern went to pieces. 

The tubes of the Plumatella, and of most other Poly- 
zoa, are composed of two coats, called respectively 
endocyst and ectocyst, that is, “inner case” and “ outer 
ease.” ‘The first is vitally endowed, and exhibits vessels 
and muscular fibres. The second or outer case is 
thrown off by the first. It is a parchment-like substance, 
strengthened by the adhesion of dirt particles, and does 
not appear to exercise any vital functions, but to be 
merely a covering for protection. The inner layer 
terminates in the neck of the bag before described, as 
exserted when the polypide comes out, and inverted 
when it goes in. This mode of making a case or sheath 
by inversion of a bag is technically called invagination, 
and is readily seen in new and transparent cells. 

The movement of eversion, or coming out, is chiefly 
produced by the contraction of the endocyst ; while the 
inversion, or getting in again, is performed by the long 
muscles, which, when the animal is extended, are seen 
attached to it like ropes. Upon these muscles Pro- 
fessor Allman remarks that they are “ especially in- 
teresting in a physiological point of view, as they seem 
to present us with an example of true muscular tissue, 


126 Marvels of Pond-Life. 


reduced to its simplest and essential form. A muscle 
may here be viewed as a beautiful dissection far sur- 
passing the most refined preparation of the dissecting 
needle, for it is composed of a bundle of elementary 
fibres, totally separate from one another through their 
entire course.’ He further adds, ‘‘ The fibres of the 
great retractor muscle are distinctly marked by trans- 
verse strize ;—a condition, however, which is not at all 
times equally perceptible, and some of our best ob- 
servers have denied to the Polyzoon the existence of 
striated fibre.” 

We can confirm the fact of this sort of fibre being 
present, but we fancy a reader not versed in the 
mysteries of physiology exclaiming, ‘What does it 
matter whether his fibres are striped or not ?’ 

Physiologists used to suppose there was a strong and 
marked distinction and separation between striped 
muscles, that 1s, muscles the fibres of which exhibit 
transverse stripes when magnified, and those which do 
not. Kolliker, however, says this decided separation 
can no longer be maintained,* and he gives instances 
in proof of the connections that can be traced between 
the two forms. In the higher animals the striped 
muscles are the special instruments of wa//, and of move- 
ments that follow, or are accompanied by, distinct sensa- 
tions. Striped fibre must. be regarded as the highest 
form; and as a muscle of this sort contracts in length 
it increases uniformly in breadth. 

There are many other genera and species of fresh- 
water polyzoa besides the Plumatella repens, and they 


* «Manual of Human Microscopic Anatomy,’ p. 63. 


Marvels of Pond-Life. 127 


are found attached to sticks, stones, or leaves, generally 

to the under surface of the latter. They are all objects 

of great interest and beauty, which, whatever their diver- 
sity, conform sufficiently to one type that the student 

who has observed one, will easily recognise the zoological 

position of another. They should be viewed by trans- 

mitted and by dark-ground illumination, which produces 

very beautiful effects. ‘To observe them in the perform- 
ance of their functions, they require more room than 

the live-box can afford, but are well shown in the glass 

trough, whose moveable diaphragm enables them to be 

brought near enough to the object-glass, for the use of 
a power of about sixty linear for general purposes, and 

of from one to two hundred for the examination of 
particular parts. For a more detailed examination 

dissection must be employed, but all that we have men- 

tioned can be seen without injury to the living animal, 

if specimens are kept till new cells are formed in water, 

which does not contain enough dirt to render their in- 

_ teguments opaque. 


128 Marvels of Pond-Life. 


CHAPTER XII. 


DECEMBER. i 


Microscopic Hunting in Winter—Water-bears, or Tardigrada—Their 
comical behaviour—Mode of viewing them—Singular gizzard 
—A compressorium — Achromatic condenser— Mouth of the 
Water-bear—Water-bears’ exposure to heat—Soluble albumen— 
Physiological and chemical reasons why they are not killed by 
heating and drying—The Trachelius ovam—Mode of swimming— 
Method of viewing—By dark-ground illumination—Curious diges- 
tive tube with branches—Multiplication by division—Change of 
form immediately following this process—Subsequent appearances. 


Fas HERE is always satisfaction in finding a work 
e 4% accomplished; but the attempt to delineate 

=28i some of the marvels of minute creation has 
been a pleasant one, and we approach the completion of 
our task of recording a Microscopic Year with some- 
thing like regret. The dark, dirty December of the 
great metropolis may not seem a promising time for 
field excursions, but some ponds lie near enough to 
practicable roads and paths to render an occasional dip 
in them, not of ourselves, but of our bottles—an 
easy and not unpleasant performance; and if the 
weather is unusually bad, we can fall back upon onr 
preserves 10 bottles and tanks, which seldom fail to 
afford something new, as we have been pretty sure to 
bring home some undeveloped germs with our stock of 


Marvels of Pond-Life. 129 


pond-water and plants,.and even creatures of con- 
siderable size are very likely to have escaped detection 
in our first efforts at examination. 

When objects are not over abundant, as is apt to be 
the case in the cold months, it is well to fill a large vial 
with some water out of the aquarium or other large 
vessel, and watch what living specks may be moving 
about therein. These are readily examined with a 
pocket-lens, and with a little dexterity any promising 
creature can be fished out with the dipping-tube. It is 
also advisable to shake a mass of vegetation in a white 
basin, as the larger infusoria, &c., may be thrown 
down; and indeed this method (as recommended by 
Pritchard) is always convenient. Even so small a 
quantity of water as is contained in a glass cell, ap- 
propriated to the continual examination of polyps or 
polyzoa, should be frequently hunted over with a low 
power, as in the course of days and weeks one race of 
small animals will disappear, and another take their 
place. 

Following these various methods in December, we 
obtained many specimens; but the most interesting was 
found by taking up small branches of the Anacharis 
with a pair of forceps, and putting them into a glass 
trough to see what inhabitants they might possess. 
One of these trials was rewarded by the appearance of 
a little puppy-shaped animal very busy pawing about 
with eight imperfect legs, but not making much pro- 
gress with all his efforts. It was evident that we had 
obtained one of the Yardigrada (slow-steppers), or 
Water-Bears, and a very comical amusing little fellow 

\ s, 


130 Marvels of Pond-Life. 


he was. The figure was like that of a new-born puppy, 
or “unlicked”’ bear cub; each of the eight legs were 
provided with four serviceable claws, there was no 
tail, and the blunt head was susceptible of considerable 
alteration of shape. He was grubbing about among 
some bits of decayed vegetation, and from the mass of 
green matter in his stomach, it was evident that he was 


Water-Bear. 


not one of that painfully numerous class in England— 
the starving poor. 

A power of one hundred and five linear, obtained 
with a two-thirds object-glass, and the second eye-piece, 
enabled all his motions and general structure to be ex- 
hibited, and showed that he possessed a sort of gizzard, 
whose details would require more magnification to bring 
out. Accordingly the dipping-tube was carefully held | 
just over him, the finger removed, and luckily in went 
the little gentleman with the ascending current. He 
was cautiously transferred to a Compressorium,* an 


* The best forms of this instrument are made by Messrs. R. & J. 
Beck, the glass plates being held in their places by flat-headed screws, 
and not by cement. This plan was devised by the author, and makes 
it easy to renew the glasses when broken. 


Marvels of Pond-Life. 131 


apparatus by which the approach of two thin plates 
of glass can be regulated by the action of a spring and 
a screw; and just enough pressure was employed to 
keep him from changing his place, although he was 
able to move his tiny limbs. Thus arranged, he 
was placed under a power of two hundred and forty 
linear, and illuminated by an achromatic condenser,* to 
make the fine structure of his gizzard as plain as pos- 
sible. It was then seen that this curious organ contains 
several prominences or teeth, and is composed of mus- 
cular fibres, radiating in every direction. From the 
front of the gizzard proceed two rods, which meet in a 
point, and are supposed to represent the maxille or 
jaws of insects, while between them is a tube or channel, 
through which the food is passed. The mouth is 
suctorial, aud the two horny rods, with their central 
piece or pieces, are protrusile. They were frequently 
_ brought as far as the outer lips (if we may so call the 
margins of the mouth), but we did not witness an actual 
protrusion, except when the lips accompanied them, 
and formed a small round pouting orifice. The skin of 
the animal was tough and somewhat loose, and wrinkled 
during the contractions its proprietor made. The in- 
terior of the body exhibited an immense multitude of 
globular particles of various sizes in constant motion, 
but not moving in any vessels, or performing a distinct 
circulation. 

* The achromatic condenser is a frame capable of supporting an 
object glass, lower than that employed for vision, through which the 
light passes to the object in quantities and directions determined by 


stops of various shapes. The appearances mentioned can be seen 
without it, though not so well. 


182 Marvels of Pond-Life. 


My specimens had no visible eyes, and these organs 
are, according to Pritchard’s book, “ variable and fuga- 
cious.” The same authority remarks, “In most vital | 
phenomena they very closely accord with the rotatoria ; 
thus like these they can be revived after being put into 
hot water at 113° to 118°, but are destroyed by immer- 
sion in boiling water. They may be gradually heated — 
to 216°, 252°, and even 261°. _ It is also by their capa- 
bility of resuscitation after being dried that they are 
able to sustain their vitality in such localities as the 
roofs of houses, where at one time they are subjected to 
great heat and excessive drought, and at another are 
immersed in water.” 

When vital processes are not stopped by excess of 
temperature, as is the case with the higher animals, the 
power of resisting heat without destruction depends 
upon the condition of the albumen. Soluble albumen, 
or, as it should be called, Albuminate of Soda (for a 
small quantity of that alkali is present and chemically 
united with it), after having been thoroughly dried, may 
be heated without loss of its solubility ; although if the 
same temperature was applied before it was dry, that 
solubility would be destroyed, and it would no longer 
be a fit constituent of a living creature. As Dr. Car- 
penter observes, this fact is of much interest in ex- 
plaining the tenacity of life in the Tardigrada. 

The movements of the water-bears, although slow, 
evince a decided purpose and ability to make all parts 
work together for one common object; and as might 
be expected from this fact, and also from the 
repetition of distinct, although not articulated limbs, 


Marvels of Pond-Life. 133 


they are provided with a nervous apparatus of con- 
siderable development, in the shape of a chain of a 
ganglia and a brain, with connecting filaments. From 
these and other circumstances naturalists consider the 
Tardigrada to belong to the great family of Spiders, 
of which they are, physiologically speaking, poor 
relations. Siebold says “they form the transition 
from the Arachnoide to the Annelides.’* Like 
the spiders they cast their skin; and, although I 
was not fortunate enough to witness this operation— 
called in the language of the learned ecdysis, which 
means putting its clothes off—I found an empty hide, 
which, making allowance for the comparative size of 
the creatures, looked tough and strong as that of a 
rhinoceros, and showed that the stripping process ex- 
tended to the tips of the claws. The ‘ Micrographic 
Dictionary’ states that the Tardigrada lay but few eggs 
at a time, and these are “ usually deposited during the 
ecdysis, the exuvie serving as a protection to them 
during the process of hatching.” ‘Thus Mrs. Water- 
Bear makes a nursery out of her old skin, a device as 
ingenious as unexpected. The water-bears are said to 
be hermaphrodites, but this is improbable. 

The Plumatella repens, described in a former chapter, 
was kept in a glass trough, to which some fresh water 
was added every few days, taken from a glass jar that had 
been standing many weeks with growing anacharis in it. 
One day a singular creature made its appearance in the 
trough; when magnified sixty diameters it resembled 
an oval bladder, with a sort of proboscis attached to it. 

_ * ‘Anatomy of the Invertebrata,’ Burnett’s trans., p. 364. 


134 Marvels of Pond-Life. 


At one part it was longitudinally constricted, and 
evidently possessed some branched and complicated 
internal vessel. The surface was ciliated, and the neck 
or proboscis acted as a rudder, and enabled the creature 
to execute rapid turns. It swam up and down, and 
round about, sometimes rotating on its axis, at others 
keeping the same side uppermost, but did not exhibit 
the faintest sign of intelligence in its movements, ex- 
cept an occasional finger-like bend of the proboscis, 
upon which the cilia seemed thicker than upon the 
body. It was big enough to be observed as a moving 
white’ speck by the naked eye, when the vessel con- 
taining it was held to catch the light slantingly ; but a 
power of one hundred and five was conveniently em- 
ployed to enable its structure to be discerned. Under 
this power, when the animal was resting or moving 
slowly, a mouth was perceived on the left side of the 
proboscis, which was usually, though not always, curved 
to the right. The mouth was a round or oval orifice, 
and when illuminated by the parabola, its lips or 
margin looked thickened, and of a pale blue, and 
ciliated, while the rest of the body assumed a pinkish 
pearly tint. 

Below the mouth came a funnel-shaped tube or 
cesophagus, having some folds or plaits on its sides, and 
terminating in a broad digestive tube, distinct from the 
nucleus, and ramifying like a tree. The constriction 
before mentioned, which was always seen in certain 
positions, although it varied very considerably in depth 
and width, drew up the integument towards the main 
trunk of the digestive tube, and thus the animal had a 


Marvels of Pond-Life. 135 


distinct ventral and dorsal side. The branches of the 
tube stopped somewhat abruptly just before reaching 
the surface, and were often observed to end in small 
round vacuoles or vesicles. 

At the bottom of the bladder, opposite the mouth, in 
some specimens were large round cavities or cells, filled 
with smaller cells, or partially transparent granules. 
These varied in number from one to two or three, and 
were replaced in other specimens by masses that did 
not present the same regular form or rounded outline. 
In one instance an amorphous structure of this kind 
gradually divided itself, and seemed in the course of 
forming two cells, but the end of the process was un- 
fortunately not seen. The annexed drawing will readily 


f £ , 


Trachelius ovum Glietty flattened). 


enable the animal to be recognised. It shows the mouth 
very plainly, and a current of small particles moving 


136 Marvels of Pond-Life. 


towards it. The cesophagus terminates in a digestive 
tube, like the trunk of a tree, from which numerous 
branches spring. This arrangement is probably analo- ' 
gous to that of the phlebenterous mollusks described by 
Quatrefages, in which the ramifications of the stomach 
answer the purpose of arteries, and convey the nutrient 
fluid to various parts of the body. It is also likely 
that they minister to the function of respiration. 

The cilia on the surface, which are arranged in 
parallel lines, are best observed when the animal is 
slightly flattened in a live-box; but this process pro- 
~ duces a considerable derangement in the relative position 
of the internal parts, and they can only be well seen 
when it is immersed iu plenty of water, and is polite 
enough to stand still, and submit his digestive economy 
to a steady gaze. The only way to succeed in this 
undertaking is to have a large stock of patience as well 
as a convenient cellor trough. The table must be kept 
steady, and the prisoner watched from time to time, 
and at last he will be found ready for display. 

Pritchard says this animal, whose name is T7achelius 
ovum, is an inhabitant of stagnant bog water, and has 
been found encysted. My specimens could not be 
called plentiful, but for several weeks I could generally 
find two or three, by filling a four-ounce vial from the 
glass jar, and examining its contents with a pocket-lens. 
If none were present, another dip was made, and usually 
with success. 

One evening I caught a good specimen by means of 
the dipping-tube, and cautiously let it out, accompanied 
by a drop of water, on tlie glass floor of the live-box. 


Marvels of Pond-Life. 137 


A glance with the pocket-lens showed all was right, and 
the cover was very gently put on, but it had scarcely 
touched the creature when it became crumpled up and 
in confusion. On one or two former occasions I had 
been unfortunate enough to give my captives a squeeze 
too much, with the usual result of a rupture of their 
integuments and an escape of globules and fluids from 
_ the regions within. Now, however, there was no such 
rupture and no such escape, but instead of a smooth, 
comely surface, my Trachelius had lost all title to his 
specific designation, ovum, for instead of bearing any 
resemblance to an egg, it was more like an Irishman’s 
hat after having a bit of a “shindy” at Donnybrook 
Fair. 

I was greatly puzzled with this aspect of things, and 
still more so when my deranged specimen twirled and 
bumped about with considerable velocity, and in all 
directions. Presently a decided constriction appeared 
about half-way below the mouth and proboscis, and in 
transverse direction. The ciliary motion became very 
violent in the lower half just below the constriction, 
while the proboscis worked hard to make its half go 
another way. For some minutes there was a tug of war, 
and at length away went proboscis with his portion, 
still much crumpled by the fight, and left the other 
bit to roam at will, gradually smooth his puckers, 
and assume the appearance of a respectable well-to-do 
animalcule. 

Three hours after the “ fission” the proboscis half 
was not unlike the former self of the late “ entire,” but 
with diminished body and larger neck; while the re-— 


138 Marvels of Pond-Life. 


maining portion had assumed a flask form, and would 
not have been known by his dearest acquaintance. The 
portraits of the dis-United States were quickly taken, 


Trachelius ovum, three hours after division. 


and, as bed-time had arrived, they were left to darkness 
and themselves. The next morning a change had come 
over the ‘ spirit of their dream.” Both were quiet, or 
sedately moving, and they were nearly alike. The 
proboscis fellow had increased and rounded his body, 
and diminished his nose; while Mr. Flask had grown 
round also, and evinced an intention of cultivating a 
proboscis himself. Twenty-seven hours after the 
separation, both had made considerable progress in 
arranging and developing their insides, which had been 
thrown into great confusion by the way in which the 
original animal had been wrenched in half, and in both 
a granular mass was forming opposite the mouth end.- 
The proboscis portion, which may perhaps be termed 
the mother, was more advanced than her progeny, but 
both had a great deal to do if they meant to exhibit the 
original figure, and develope a set of bowels as elegantly 
branched. Whether they would have succeeded or not 
under happier circumstances I cannot tell, but unfor- 


Marvels of Pond-Life. 139 


tunately the Fate who carries the scissors cut short their 
days. 
In all other animalcules in-which I had observed the 
process of multiplication by self-division, it seemed to 
go on smoothly, and with no discomfort to either the 
dividend or the quotient, and it may be that in the 
fission of the Trachelius ovum I witnessed what the 
doctors would call a bad case. Indeed it may have 
been prematurely brought on, and aggravated by the 
squeeze in the live-box. It is, however, probable, from 
the stronger texture and greater organic development 
of this animalcule, that it does not divide so easily as 
the softer and simpler kinds. 

Frequent examination of this animalcule has created 
a strong doubt in my mind whether it is rightly placed 
in our “systems.” My own impression is that it 
belongs to a higher class. 


140 Marvels of Pond-Life. 


CHAPTER XIII. 
CONCLUSION. 


ez ea creatures described in the preceding pages 
h38 P44 range from very simple to highly complicated 

=| forms, and in describing them some attention 
has been paid to the general principles of classification. 
The step is a wide one from the little masses of living 
jelly that constitute Amcebe to the Rotifers, supplied 
with organs of sensation—eyes, feelers (calcars), and the 
long cilia in the Floscularians, which seem to convey 
impression like the whiskers of a cat—together with 
elaborate machinery for catching, grinding up, and 
digesting their prey, and which are also well furnished 
with respiratory and excretory apparatus, ovaries, &c. 
In the polypi and polyzoa may be observed those 
resemblances in appearance which induced early natura- 
lists to group them together, and also the wide dif- 
ference of organization which marks the higher rank 
to which the latter have attained. Amongst the ciliated 
infusoria important gradations and differences will also 
be noticed, some having only one sort of cilia, others 
two sorts, and others, again, supplied, in addition to 
cilia, with hooks and styles. No perfectly satisfactory 


Marvels of Pond-Life. 141 


classification of the infusoria has yet been devised, and 
. the life history of a great many is still very imperfectly 
known. On the whole, the tendency of research is to 
place many of them higher than they used to stand 
after Ehrenberg’s supposition of their having a plurality 
of distinct stomachs, &c., was given up. Balbiani and 
others have shown numerous cases of their forming 
their eggs by a process analogous to that of higher 
animals. Some really are, and others closely resemble, 
the larval conditions of creatures higher in the scale, and 
the contracted vesicle with its channel bears resemblance 
to what is called the “water vascular system” of 
worms. 

Zoological classification depends very much on mor- 
phology, that is, the tracing of particular structures, 
or parts, through all their stages, from the lowest to the 
highest forms in which they are exhibited. In this 
way the swimming bladder of a fish is shown to bea 
rudimentary lung, though it has no respiratory func- 
tions, and Mr. Kitchen Parker has found in the imper- 
fect skull of the tadpole a rudimentary appearance of 
bones belonging to the human ear. The comparative 
anatomist, after a wide survey of the objects before 
him, arranges them into groups. - He asks what are the 
characteristic things to be affirmed concerning all the A’s 
that cannot be said of all the B’s; or of all the C’s that 
marks their difference from the A’s or the D’s. Careful 
investigation upon these methods shows affinities where 
they were not previously expected—birds and reptiles 
being close relations, for example, instead of distant 
connections—and they lessen the value for purposes of. 


142 Marvels of Pond-Life. 


classification of peculiarities that might have been 
deemed of the highest importance. 

Professor Huxley divides the vertebrates into Iruy- 
corps, comprising fishes and amphibia, which, besides 
other characteristics, have gills at some period of their ex- 
istence; Savurorps (reptiles and birds), which have no 
gills, and possess certain developmental characteristics in 
common ; and, lastly, Mammats. The Insecta, Myrio- 
poda, Arachnide, and Crustacea, he remarks, “ without 
doubt present so many characters in common as to 
form a very natural assemblage. All are provided 
with articulated limbs attached to a segmented body 
skeleton, the latter, like the skeleton of the limbs, 
being an ‘exoskeleton,’ or a bordering of that layer 
which corresponds with the outer part of the verte- 
brates. In others, at any rate in the embryonic con- 
dition, the nervous system is composed of a double 
chain of ganglia, united by longitudinal commissures, 
and the gullet passed between two of these commissures. 
No one of the members of these four classes is known 
to possess vibratile cilia. The great majority of these - 
animals have a distinct heart, provided with valvular 
apertures, which are in communication with a peri- 
visceral cavity containing corpusculated blood.” These 
four classes have constituted the larger group or 
“province” of Articulata or Arthropoda. Professor 
Huxley thinks that, notwithstanding ‘“ the marked dif- 
ferences” between the Annelida (worms) and the pre- 
ceding Arthropods (joint-foots), their resemblances out- 
weighing them—* the characters of the nervous system, 
and the frequently segmented body, with imperfect 


Marvels of Pond-Life. | 143 


lateral appendages of the Annelida, necessitates their 
assemblage with the Arthropoda in one great division, 
or sub-kingdom, of ANNULOsa. 

Tracing analogies between the Echinodermata (sea 
urchins, star-fish, &c.) and the Scolecida (intestinal 
worms), he places them together as Annuloida. 

Cephalopoda, Pteropoda, Pulmo-gasteropoda, and 
Branchio-gasteropoda, having resemblances of nervous 
system, and “all possessing that remarkable buccal 
apparatus, the Odontophore,” are placed together by 
him asOpontorHora. The Odontophores (tooth-bearers) 
are familiar to microscopists as the so-called palates of 
mollusca. Placing with the above the lamellibranchial 
mollusks (mollusks with gills formed of lamelle or 
little plates), Ascidioida (ascidians), Brachiopoda (lamp- 
sheds), and Polyzoa, in spite of their differences, he 
forms another great group, ANNULOIDA. 

The Actinozoa (anemonies, &c.) and the Hydrozoa 
(polyps) constitute the CaLenTERa of Frey and Leuckart. 
“In all these animals,” says Professor Huxley, “the 
substance of the body is differentiated into those histo- 
logical elements which have been termed cells, and the 
latter are previously disposed in two layers, one external 
and one internal, constituting the ectoderm and endo- 
derm. Among animals which possess this histological 
structure the Ceelenterata stand alone in having an 
alimentary canal, which is open at its inner end and 
communicates freely by this aperture with the general 
cavity of the body,” and “all (unless the Ctenophora 
should prove a partial exception to the rule) are provided 
with very remarkable organs of offence or defence, — 


144 Marvels of Pond-Life. 


called thread-cells or nematocysts.”? In describing the 
Polyps we have given illustrations of these weapons. 

The remaining classes, which have been roughly 
associated as Protozoa, must evidently be rearranged. 
Sponges, Rhizopods (Ameebe, &c.), and Gregarines, 
have strong resemblances, but recent researches 
may place the former higher. The Infusoria compre- 
hend creatures too various to remain under one head, 
and very many of them too highly organized to be 
called ‘‘ protozoons,”’ or first life-forms. | 

Those who wish to pursue this subject further may 
consult Professor Huxley’s ‘ Elements of Comparative 
Anatomy,’ from which the preceding quotations have 
been taken. 

A system of classification founded upon anatomical 
and developmental considerations frequently differ con- 
siderably from one we might arrive atif all the crea- 
tures were arranged according to the perfection of their 
faculties and the extent and accuracy of their relations 
to the external world. Such a classification would not ~ 
in any way supersede the former, but it would prove 
very instructive and offer many valuable suggestions. 
Some years since, Professor Owen proposed to divide the 
Vertebrates according to the perfection of their brains, 
but other anatomists did not find his divisions suffi- 
ciently coincident with facts. Very little has been done 
towards an exact science of human phrenology. The 
difficulties remain pretty much as they were many years 
ago, and our comparative phrenology, if we may use such 
a term, is in a very imperfect state. When we come to 
the lower animals we do not know what peculiarities 


Marvels of Pond-Life. 145 


of the brain of an ant make it the recipient of a higher 
instinct, or give its possessor greater capacities for 
dealing with new and unexpected difficulties than are 
possessed by most other insects, and if any reader has 
a marine aquarium, and will make a few experiments 
in taming prawns, and watching their proceedings, he 
will discover symptoms of intelligence beyond what the 
structure of the creature would have led him to expect. 

Animals usually possess some one leading charac- 
teristic to which their general structure is subordinated. 
Man stands alone in having the whole of his organiza- 
tion conformed to the demands of a thinking, ruling 
brain. To pass at once to the other extreme, we 
observe in the lower infusoria a restless locomotion, 
probably subservient to respiration, but utterly in- 
consistent with a well developed life of relation, or 
_ with manifestations of thought. The life of an ani- 
malcule may be summed up as a brief and restricted, 
but vigorous organic energy, and if the amount of 
change which a single creature can make in the ex- 
ternal world, is inconceivably small, the labours of the 
entire race alter the conditions of a prodigious amount 
of matter. Microscopic vegetable life is an important 
agent in purifying water from the taint of decomposing 
organisms.. By evolving oxygen it brings putrescent 
particles under the influence of a species of combustion, 
which, though slow, is as effectual as that which a 
furnace could accomplish. In this way minute moulds 
burn up decaying wood. 

Microscopic animal life helps the regenerative pro- 
cess, and, together with the minute vegetable life, — 

10 


146 Marvels of Pond-Life. 


restores to the organic system myriads of tons of 
matter, which death and decay would have handed 
over to the inorganic world. In a very small pond 
or tank the quantity of this kind of work is soon 
appreciable, and if we reflect on the amazing amount 
of water all over the globe, including seas and oceans, 
which swarm with infusoria, the total effect produced in 
a Single year must seem considerable, even when com- 
pared with that portion of the earth’s crust that is 
subject to alteration from all other causes put together. 
If we add to the labour of the Infusoria those of other 
creatures whose organization can only be discovered 
by the microscope, and take in the foraminifera, polyps, 
polyzoa, &c., we shall have to record still larger obli- 
gations to minute forms of living things. The coral 
polyp builds reefs that constitute the chief characteristic 
of certain regions in the Pacific; foraminifera are 
forming or helping to form strata of considerable 
extent, while diatoms are making deposits many feet in 
thickness, composed of myriads of their silicious shells, 
or adding their contributions of silex, very large in 
the aggregate, to all sedimentary rocks. Testimony of 
this kind of work is found by the navigator who 
examines the ice in arctic seas, and it comes up with 
soundings from the ocean depths. : 

On the surface of the earth the amount of change 
produced is equally remarkable, although it leaves less 
permanent traces behind. As a rule no decomposition 
of organized matter takes place, no death of plants or 
animals, without infusorial life making its appearance, 
and disposing of no small portion of the spoil. Even 


Marvels of Pond-Life. 147 


in our climate the mass of matter thus annually 
affected is very large; but what must it not be in 
moist tropical lands, where every particle seems alive, 
and the race of life and death goes on at a speed, and 

to an extent scarcely conceivable by those who have 
* not witnessed it. 

Thus, if we look at the world of minute forms which 
the microscope reveals, there opens before us a spec- 
tacle of boundless extent. We see life manifested by 
the specks of jelly containing particles not aggregated 
into structure, and we see it gradually ascending in com- 
plexities of organization. In creatures whose habits and 
appearance seem most remote from our own, we find 
the elementary developments of the organs and powers 
that constitute our glory, and give us our power. Such 
studies assist us to conceive of the universe as a 
Cosmos, or Beautifully Organized Whole; and, al- 
though we cannot tell the object for which a single 
portion received its precise form, we trace everywhere 
relations of structure to means of existence and en- 
joyment, and are led to the conviction that all the 
actions and arrangements of the organic or inorganic 
worlds are due to a definite direction and co-ordination 
of a few simple forces, which implicitly and unerringly 
obey the dictates of an Omniscient Mind. 


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LOTTIE’S HALF-SOVEREIGN ; ano otHer stories. 


BY MRS. ROSSELI GRAY. 
Tllustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


“‘The story before us is a most delightful one, and such as may be placed in 
the hands of any child with the utmost confidence.” —Hull Advertiser. 


THE SHEPHERD LORD: ano otner stories. 


BY JULIA CORNER. 
Tilustrated with 15 Wood Engrayings. Foolscap 8vo, cloth gilt, 1s. 


“‘ We cannot imagine a better book for children educated at home; it com. 
bines the fascination of romance with the truth of history, and will be eager!y 
devoured by the youth of both sexes.’’—Somerset County Herald. 


GROOMBRIDGE & SONS, 5, PATERNOSTER ROW, LONDON. 


SHILLING GIFT BOOKS FOR YOUNG PEOPLE. 


Each Book sent Post Free for 12 Stamps. 


THE CAPTIVE’S. DAUGHTER: anp otner stories. 


BY W. HEARD HILLYARD. 
Illustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


“¢ Tf one were asked to select a series of stories most snitable for presents to 
children, and affording real pleasure in their perusal to ‘children of a larger 
growth,’ very few would hesitate to name this series as the very first and best of 
the class.”—Ooventry Herald. 


THE ORPHANS OF ELFHOLM ; ano otuer srorics- 


BY FRANCES BROWNE. 
Illustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


** A book to be prized by the young, for its seyeral tales are well written and 
fall of touching interest.” —City Press. 


WHEN WE WERE YOUNG: anp otner stories. 


BY THE AUTHOR OF “A TRAP TO CATCH A SUNBEAM.” 
Illustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


“‘The precept of moral courage which it inculeates, coupled with its excellent 
tone throughout, stamps it at once as being of the right sort.” —LEnglish Churchman, 


NOT CLEVER: AND OTHER STORIES. 


BY FRANCES M. WILBRAHAM. 
Llustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


‘* Pure in tone, full of interest, well got up, and cheap.”—Tlereford Times. 


DEAR GHARLOTTE’S BOYS: anv oruer stories. 


BY EMILY TAYLOR. 
Illustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


“We are glad to receive a volume of these pretty stories. There is something 
refreshing in them, scarcely to be found in any other publication,”’—City Press. 


THE STORY OF NELSON: ano otueRr stories. 


BY W. H. G. KINGSTON. 
Hllustrated with 15 Wood Engravings. Foolscap 8yo, cloth gilt, 1s. 
““Mr. Kingston, with great skill, brings out the stirring events of the great 
Admiral's life from the lips of an old Greenwich pensioner. The story is told with 


all the enthusiasm of a true ‘Salt,’ and has the further merit of capital descrip. 
tive writing.”’—Piymouth Journal. 


SHILLING GIFT BOOKS FOR YOUNG PEOPLE. 


Each Book sent Post Free for 12 Stamps. 


BLIND URSULA: ano otner stories. 


BY MRS. WEBB. 
Tlustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


** A domestic tale of humble life, which will well repay perusal. There is an 
excellent tone, moral and religious, throughout the narrative.” —Leeds Intelligencer. 


SEA-SHELL ISLAND; ano ower srontes. 


BY G. E. SARGENT, 
Illustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 
** An exceeding pretty story.”——Somersetshire County Herald. 


WHICH WAS THE BRAVEST ? ano otner stories. 


BY L.A. HALE, 
Illustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


‘© A tale of the Christmas holidays on the banks of the Shannon, intended to 
show, by the conduct of a party of young people, that rashness and disobedience 
are no proofs of courage. It should be widely spread, for the spirit of the little 
book is excellent, The engravings are appropriate and pleasing,’’—Plymouth 
Journal, 


THE GLOGKMAKER OF LYONS: ano orner stories. 


BY E. M. PIPER. 
Iilustrated with 15 Wood Engravings. Foolscap 8yvo, cloth gilt, 1s. 


‘*An interesting tale, forming one of Messrs. Groombridge’s) Series of Gift 
Books, and by no means the worst of the series.”»—Cheltenham Journal. 


THE ANGEL UNAWARES ; ano otuer stories. 


BY MARY HOWITY. 
Illustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


‘‘ A pretty story of kindness rewarded by suceess. The principal actors are 
children, and the teaching of the story, while it is full of point for older learners, 
is adapted especially to the capacity of youth.” —Plymouth and Devonport Journal. 


HISTORICAL DRAMAS. 


BY THE AUTHOR OF “THE HEIR OF REDCLYFFE.” 
Illustrated with 15 Wood Engravings. JFoolscap 8yvo, cloth gilt, 1s. 


‘* Combines amusement with instruction in a way that must please the rising 
generation,”—Lenfrewshire Independent, 


SHILLING GIFT BOOKS FOR YOUNG PEOPLE. 


Each Book sent Post Free for 12 Stamps. 


LOST IN THE WOOD; ano otner stories. 


BY MRS. GILCHRIST. 
Lilustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


‘* Perfectly healthy in tone, and highly interesting, these tales are indeed 
most suitable for family reading.”—-Gloucester Mercury. 


RAINBOW’S REST; ano otner stories. 


BY THOMAS HOOD. 
Illustrated with 15 Wood Engravings. Foolscap 8vo, cloth gilt, 1s. 


‘‘ These are excellent stories for children, and nicely got up and illustrated.”— 
Paisley Herald, 


° 


*A COMPLETE SET OF THE TWENTY VOLUMES, VIZ. :— 


UNION JACK. By Mrs. S.C. Hatt. 

TOWN OF TOYS. By Sara Woop. 

NO MAN’S LAND. By T. Miter. 

SEA SPLEENWORT. By Author of “ The Heir of Redclyffe.” 

LOTTIE’S HALF-SOVEREIGN. By Mrs. Russert Gray. 

THE SHEPHERD LORD. By Jutta Corner. 

THE CAPTIVE’S DAUGHTER. By W. Heap Hittyarp. 

THE ORPHANS OF ELFHOLM. By Frances Browne. 

WHEN WE WERE YOUNG. By Author of “A Trap to Catch 
a Sunbeam.” 

NOT CLEVER. By Frances M. WitBRAHAM. 

DEAR CHARLOTTE’S BOYS. By Emity Taytor. 

STORY OF NELSON. By W. H. G. Kinesron. 

BLIND URSULA. By Mrs. Wess. 

SEA-SHELL ISLAND. By G. E. Sareenr, 

WHICH WAS THE BRAVEST? By L. A. Hatt. 

THE CLOCKMAKER OF LYONS. By EH. M. Piper. 

THE ANGEL UNAWARES. By Mary Howirr. 

HISTORICAL DRAMAS. By Author of “The Heir of Redcly fe.” 

LOST IN THE WOOD. By Mrs. Gitcurist. 

RAINBOW’S REST. By Tuomas Hoop. 


Enclosed in a Box, 20s. 


‘* We have read most of them with great care, for we are very watchful over 
books for the young, and can assure our readers they are well worth a mother’s 
attention. ‘They vary in interest and in moral value, but all of them are calcu- 
lated both to amuse and instruct, Some convey valuable historical information, 
others lessons in natural history, and most of them convey a healthy moral in- 
fluence, All are subservient to religion as well as morals, but they are not tinc- 


tured with any ism, nor do they inculcate any peculiar tenets,’’—British Mothers’ 
Jourial, 


GROOMBRIDGE’S 
SHILLING PRACTICAL MANUALS. 


Each Book sent post free for 12 stamps. 


1, HOME-MADE WINES. How to Make and Keep 
them, with Remarks on preparing the Fruit, fining, 
bottling, and storing. By G. Vinz. Contains Apple, 
Apricot, Beer, Bilberry, Blackberry, Cherry, Clary, 
Cowslip, Currant, Damson, Elderberry, Gooseberry, 
Ginger, Grape, Greengage, Lemon, Malt, Mixed Fruit, 
Mulberry, Orange, Parsnip, Raspberry, Rhubarb, Rai- 
sin, Sloe, Strawberry, Turnip, Vine Leaf, and Mead. 


2. CARVING MADE EASY;; or, Practical Instruc- 
tions, whereby a Complete and Skilful Knowledge of 
the Useful Art of Carving may be attained. Illustrated 
with Engravings of Fish, Flesh, and Fowl, together 
with Suggestions for the Decoration of the Dinner 
Table. By A. MerrytHoucHrt. 


3. COTTAGE COOKERY. Containing Simple In- 
structions upon Money, Time, Management of Pro- 
visions, Firing, Utensils, Choice of Provisions, Modes 
of Cooking, Stews, Soups, Broths, Puddings, Pies, Fat, 
Pastry, Vegetables, Modes of Dressing Meat, Bread, 
Cakes, Buns, Salting or Curing Meat, Frugality and 
Cheap Cookery, Charitable Cookery, Cookery for the 
Sick and Young Children. By Esruzr Copuey. 


4, COTTAGE FARMING; or, How to Cultivate from 
Two to Twenty Acres, including the Management of 
Cows, Pigs, and Poultry. By Martm Dovir. Con- 
tains, On Enclosing a arm, Land Drainage, Manures, 
Management of a Two-Acre Farm, Cow Keeping, The 
Dairy, Pig Keeping, Bees and Poultry, Management 
of a Ten-Acre Farm, Flax and Rape, Management of a: 
Farm of Twenty Acres, Farm Buildings, etc. 


GROOMBRIDGE & SONS, 5, Paternoster Row, London. 


-_GROOMBRIDGE’S 
SHILLING PRACTICAL MANUALS. 


Hach Book sent post free for 12 stamps. 


5. SINGING MADE EASIER FOR AMATEURS, 
explaining the pure Italian Method of Producing and 
Cultivating the Voice; the Management of the Breath; 
the best way of Improving the Har; with much other 
valuable information equally valuable to Professional 
Singers and Amateurs. 


6. MARKET GARDENING, erp in detail the 
various methods adopted by Gardeners in growing the 
Strawberry, Rhubarb, Filberts, Early Potatoes, Aspa- 
ragus, Sea Kale, Cabbages, Cauliflowers, Celery, Beans, 
Peas, Brussels Sprouts, Spinach, Radishes, Lettuce, 
Onions, Carrots, Turnips, Water Cress, etc. By Jamus 
Corum, F.R.H.S. 


7. CLERE’S DICTIONARY OF COMMERCIAL 
TERMS ; containing Explanations of upwards of Three 
Hundred Terms used in Business and Merchants’ Offi- 
ces. By the Author of ‘Common Blunders in Speak- 
ine and Writing Corrected.” 

“An indispensable book for all young men entering 
a counting-house for the first time.” 


8. THE CAT, its History and Diseases, with Method 
of Administering Medicine. By the Hon. Lapy Cust. 


9. ELOCUTION MADE EASY for Clergymen, Pub- 
lic Speakers, and Readers, Lecturers, Actors, Theatri- 
cal Amateurs, and all who wish to speak well and 
effectively in Public or Private. By Cuarnrs Harriey. 
Contents: Cultivation of the Speaking Voice, Manage- 
ment of the Voice, Pausing, Taking Breath, Pitch, Ane 
ticulation, Pr onunciation, The Aspirate, The Letter R, 
Emphasis, Tone, Movement, Feeling and Passion, 
Verse, Scriptural Reading, Stammering and Stutter- 
ing, Action, Acting, Reciting, etc. 


GROOMBRIDGE & SONS, 5, Paternoster Row, London. 


| GROOMBRIDGE’S 
SHILLING PRACTICAL MANUALS. 


Each Book sent post free for 12 stamps. 


10. ORATORY MADE EASY, A Guide to the Com- 
position of Speeches. By Caarntzs Harrisy. Con- 
tents: Introduction, Power of Art, Various Kinds of 
Oratory, Prepared Speech, Constructing a Speech, 
Short Speeches, Command of Language, Reading and 
Thinking, Style, Hasty Composition, Forming a 
Style, Copiousness and Conciseness, Diction or Lan- 
guage, Purity and Propriety, Misapplied Words, 
Monosyllables, Specific Terms, Variety of Language, 
Too Great Care about Words, Hpithets, Precision, 
Synonymes, Perspicuity, Long and Short Sentences, 
Tropes and Figures, Metaphor, Simile, &c. , 


11, THE GRAMMATICAL REMEMBRANCER; 
or, Aids for Correct Speaking, Writing, and Spelling, 
for Adults. By Cuartes Hartisy. Contents: Intro- 
duction, Neglect of English Grammar, Divisions of 
Grammar, Parts of Speech, The Article, The Silent 
H, Nouns, Formation of the Plural, Gendersof Nouns, 
Cases of Nouns, Comparison of Adjectives, Personal - 
Pronouns, Relative Proncuns, Demonstrative Pro- 
nouns, Regular and Irregular Verbs, Shall and Will, 
The Adverb, Misapplication of Words, Division of 
Words, Capital Letters, Rules for Spelling Double / 
and p, A Short Syntax, Punctuation, &c. 


12. THECANARY: Its History, Varicties, tlanage- 
ment, and Breeding, with Coloured Frontispiece. By 
Ricuarp Avis. Contains, History of the Camary, 
Varieties of the Canary, Food and General Manage- 
ment, Cages, Breeding, Hducation of the Young, 
Mules, Diseases, &e. 


13. BIRD PRESERVING and Bird Mounting, and 
the Preservation ‘of Birds’ Eggs, with a Chapter on 
Bird Catching. By Ricuarp Avis. 


GROOMBRIDGE & SONS, 5, Paterncster Row, London. 


GROOMBRIDGE’S 
SHILLING PRACTICAL MANUALS. 


Each Book sent post free for 12 stamps. 


14. WINE GUIDE; or, Practical Hints on the Pur- 


chase and Management of Foreign Wines, their His- 
tory, and a complete catalogue of all those in present 
use, together with remarks upon the treatment of 
Spirits, Bottled Beer, and Cider. To which is ap- 
pended Instructions for the Cellar, and other informa- 
tion valuable to the Consumer as well as the Dealer. 
By Frepericx C. Mitts. 


15. PIGHONS: their Varieties, Management, Breed- 
ing, and Diseases, with Coloured Frontispiece. By 
H. Pirer. Contains full instructions upon Lockers, 
Pole-houses, Dovecotes, Pigeon Lofts, Traps, Nesting 
Places, Choosing Stock, Mating, Eggs and Hatching, 
Young Ones, Food, Water, Salt Cat, Parasites, Dis- 
eases, Pigeon Law, Varieties and Origin, The English 
Carrier, Messenger, or Homing Pigeons, The Horse- 
man, Ponting Horseman, Dragoon and Skinnum, 
The Question of Instinct in Flight, Training Messen- 
ger Pigeons, The Pouter, The Old English Tumbler, 
The German Tumbler, The Common Flying Tumbler, 
The Short-faced Tumbler, The Almond Tumbler, 
Training Tumbler, &. 


16. POULTRY. A Practical Guide to the Manage- 


ment of Domestic Poultry, describing the different 
varieties with full instructions upon Management, 
Breeding, and Diseases, with Coloured Frontispiece. 
By H. Pirzrr Contents: Houses and Runs, Choosing 
Stock, Feeding and Management, Nests, Eggs and 
Hatching, Chickens, Rearing and Fattening, Diseases 
and Varieties, Brahma Pootras, Cochin-chinas, Malays, 
Spanish, Dorking, Game, Hamburgh, Polands, Ban- 
tams, Aylesbury and Rouen Ducks, &e. 


17. DOG AND GUN; or, Hints to Young Sportsmen. 
- By Carrarn Fettowers. Illustrated with Wood En- 


gravings. 


GROOMBRIDGE & SONS, 5, Patemoster Row, London, 


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