SMITHSONIAN .MISCELLANEOUS COLLECTIONS
VOLUME 153, NUMBER 4
PuBLIcATION 4744

dee ww Pets Sa oath

Charies J DR. and Msep Saw Walcott
Research Fund

A STUDY OF THE EOCENE
CONDYLARTHRAN MAMMAL
HYOPSODUS

(Wirn 13 Prates)

By
Cc. LEWIS GAZIN

Senior var Nira Department oe brea
United States National M
VBruishacasan Tastitetion

CITY OF WASHINGTON
PUBLISHED BY THE ro er ory INSTITUTION PRESS

| mex AMERICAN MUSEUM
OF NATURAL HISTORY |

SMITHSONIAN MISCELLANEOUS COLLECTIONS
VOLUME 153, NUMBER 4
PUBLICATION 4744

Charles B. and Mary Vaux GAalcott
Research Fund

MLO y OF TRE BOCENE
CONDYLARTHRAN MAMMAL
HYOPSODUS

(WitH 13 PLATES)

By
C. LEWIS GAZIN

Senior Scientist, Department of Paleobiology
nited States National Museum
Smithsonian Institution

CITY OF WASHINGTON
PUBLISHED BY THE SMITHSONIAN INSTITUTION PRESS

NOVEMBER 27, 1968

PORT CITY PRESS, INC.
BALTIMORE, MD., U.S. A.

CONTENTS

Page

WAAL AESCELOIN ios avis, f’ade chin Se Rie in nel <a re rete Rete. ww aaatarsta wn wha) seer aval alee wala 1
PEN WIPE PXTIETIES 5 /c cine Oe ida RSG ie « GEOR Ged Poste dn) hee aioe aivisinle. a 2
PAISEOEU? Gi IVEStALION ae! wo skies da decid das fab ees ae hots erag sigteee we v 3
Georranhicsand) Peolopics Oceurren ce. yi a. aateintc nel <ioloien'aie)</s)s/els «lel «0.0 ale = 12
ABI ASSINICALION: a) rac tas seatet aial sieve ceo ebere dats) teaiavone ante ae ioe a eiciel a ssiele qctelet diate > 13
UOTE GEE sO se ene I ht Minky ae avd ee meni cary Maat nivie a inlets 31
EME S KCLELOM EOL FL POP SOUS soc Fostuicptteis eres ove clala erseeceete sie tickerelerataieterensis 34
PROM ch aren Sica aed ox Be dc, ah hates aia ac aude stlcltahcatier Game rears sete Socer ot ste La any 34
Birdocnatital cast <4 stele ocisidkac © sien cise sateen oeioiouatan Gicbie eich nekarsrecrereersiess 40
icant tpl Sa eee ates sees cves rae aici cea srovale taleve?ai eo) ssste vale oh le rave opyatre: Nae oie sissy eavene 43
DSS wo) s ereresees coche, MAURIE CRS FO A MeO cat aie ES aers BIS EIS Cre 44
Werte bra eee) oieiet ae oaper aos at alaein cree niece ior) sierere oie ool Pee e isi tei nies 52
PRICES AUN See cas rel Sk ao ah, do alanis wim idee Saas eal wake aegeecs & caries secle 54
PLDT e Le MANS ese con oo aston a ohapababe aaa ee oragmrante reyes rates vane ei ouak aye aisian Giaterer cle cle trmie cuca 55
FRAGA TSM PN he cpr ee vite ya hica ud car aueens an Site aval a seaes casbetens stot savor olay Sela celoerd 56
MEGAN RS a ieee ce ang Peed cise testa Manthens Aictiot es cuavalule.8 Siateromta aa ee 57
UMNINESSS bs CAS MENS al ces aoe ha Meek, Bek dae Reed ss ay cal CER eV oie du RISA Sih ah ane 58
Ate eae At ee: rh a bs hd ee bac ale We, war cis cos oes eet ee babe smal, Ria 63
ERMAN Na Bhs oA a tha ta ie hse cite, alofe sie! salable 2 odie) daa at aaa tiaras tye aie 64
MAYER U Ee Ree oe sear wets an a NaN Paeiate Cee wee Ud Cena d dele Mola yar tee ate 65
ME Urge ese artes ak rete cee iets CIOS ae eae ocak tenes 66
RR a te ahve otitis ck otic iy Sites ara es amet Miia) eae arta + hers SErabe wrerelwi 67
MANES AER CUR OEE TE SAS ENNIS aia) go ers geoya ass sade ee! into Siciauel ak Aibiaie’ aia’ Sie. taarecatait cae 73
Na AM IMU EIEN tale He eS NAL cheat esp ate ke alt kota asa orate a aie viata coh ig 76
PLAN AIAN CIE PUALOS 5 oe ee cnc wok ok wicta ise ae as DEW Tee nen eee wa enee 83
Explanation of abbreviations for plates’ 2.92 60 000 fear oe eed’ 90

Se)

a

ILLUSTRATIONS

PLATES
(All plates following p. 92.)

Hyopsodus skull from the middle Eocene of Wyoming.

Hyopsodus skull portions from the early and middle Eocene of Wyoming.

Hyopsodus skull portion from the middle Eocene of Wyoming.

Hyopsodus skulls from the early and middle Eocene of Wyoming.

Hyopsodus skull portion and endocranial cast from the early Eocene of
Wyoming.

Hyopsodus skull portion, endocranial cast, and deciduous teeth from the
Eocene of Wyoming.

Hyopsodus type-specimens from the middle Eocene of Wyoming.

Hyopsodus type-specimens from the early Eocene of Wyoming.

Hyopsodus type-specimens from the early, middle, and late Eocene.

Hyopsodus fore limb and foot material from the middle Eocene of Wyoming.

Hyopsodus skull, fore limb and foot material from the middle Eocene of
Wyoming.

Hyopsodus hind limb and foot material from the middle Eocene of
Wyoming.

. Hyopsodus vertebrae, ribs, scapula, and pelvis from the middle Eocene of

Wyoming.
TEXT FIGURES
Page
Frequency distribution for length of M, in San Juan Basin material
Of Hygbsoden: co dccdsniesss0inisapeab rads snebed santana ane 18
Comparison of frequency distributions for length of Mz in Hyopsodus
from typical sections of early Eocene in Wyoming..............4- 19
Comparison of frequency distributions for length of Mz in Hyopsodus
between Lysite horizons of Wyoming and San Jose of New
Mente <i adders toes nebed as spec dtus ons Reb Rees eee 20
Comparison of frequency distributions for length of Mz in Hyopsodus
from’ Lysite*horiazons:of “Wyoming. 5.0.06 i200 coe see selene 21
Comparison of frequency distributions for length of Mz in Hyopsodus
between Lost Cabin horizons of Wyoming and San Jose of New
MeXiGD.. <i dtininda dad tals nc dont abeea vas padeek idee 22
Comparison of frequency distributions for length of Ms in Hyopsodus
from areas oF the lower Brideee.\.-); -. goss ccc decodes pbeeaseeene 25
Comparison of frequency distributions for length of Mz and M? in
Hyopsodus from the upper Bridger. ........csceeccccecscceccess 26

Comparison of frequency distributions for length of Mz and M? in
Hyopsodus from upper and lower members of the Bridger fohmation 28

Hyopsodus skeletal drawings) fU3<.5,2.4ds ban ecueeckenec netics 32

Restoration of Hyopsodass 0 5 icgsses eden ca noennbeent ade Cee 33

lv

Charles BD. and Marp Waux Walcott Research Fund

A Stubby Obey THE“ EOGENE
CONDYLARTHRAN MAMMAL
HYOPSODUS'

By
C. LEWIS GAZIN

Senior Scientist, Department of Paleobiology
United States National Museum
Smithsonian Institution

(WitTH 13 PrLates)

INTRODUCTION

UNDOUBTEDLY THE MOST CHARACTERISTIC MAMMAL that existed dur-
ing Eocene time in North America was the small condylarth Hyopso-
dus. It is represented in the earliest to essentially the latest horizons
of this period, but is not recognized surely as such in the preceding
Paleocene, and evidently became extinct before the beginning of the
Oligocene. Significantly, moreover, remains, such as jaw fragments
and teeth, representing various species, while but sparsely encountered
in later Eocene horizons, demonstrate that Hyopsodus was one of the
most common of the land mammals in the early Eocene and quite the
most common in the middle Eocene. Nevertheless, well-preserved
skulls or comprehensive portions of skeletons are exceedingly rare.

Hyopsodus was first described (Leidy, 1870) nearly a hundred
years ago and closely followed the earliest of the fossil mammal
genera to be named from the Eocene of North America; preceded
only by Anchippodus (1868) from the New Jersey marls, and by
Omomys (1869) and Patriofelis (1870) from the Bridger formation
of Wyoming. In its subsequent history of investigation, interpreta-

1Study of early Tertiary mammals was aided by grant G10686 from the
National Science Foundation.

SMITHSONIAN MISCELLANEOUS COLLECTIONS, VOL. 153, NO. 4

2 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

tion of its relationships has been nearly as varied as that for its par-
tially contemporary Meniscotherium, and has been considered related
to such distinctive groups as artiodactyls, perissodactyls, probosci-
deans, and notoungulates, as well as allocated to the Primates, Insecti-
vora, Condylarthra, and Cope’s Bunotheria.

The only prior comprehensive study of Hyopsodus was that by
Matthew in 1909(b), as a part of a monograph on Bridger materials,
continued in 1915(b) to include the earlier Eocene collections. Men-
tion may also be made of brief reviews by Osborn in 1902 and Loomis
in 1905, and a statistical interpretation by Olson and Miller in 1958, to
be discussed more fully in the following pages. The writer’s interest
in the genus was spurred largely by newer materials of unusual quality
and better documented collections, permitting a more detailed study
and a much needed taxonomic revision of some 31 species names that
have been applied to the genus.

ACKNOWLEDGMENTS

The rather large collections of Hyopsodus material, particularly
from the Bridger formation, in the U. S. National Museum, were the
basis for the present study; nevertheless, various universities and
other museums aided immeasurably in permitting me to extend inves-
tigations to their collections and to borrow type-materials and certain
other specimens for illustration and further study in Washington.

The American Museum of Natural History (AM), through the
kindness of Drs. Edwin H. Colbert, Bobb Schaeffer, and Malcolm C.
McKenna, has permitted me to study Hyopsodus and related materials
in the various Eocene collections, to borrow certain specimens having
associated skeletal material, and has allowed me to re-illustrate the
several type-specimens in these collections. Drs. Elwyn L. Simons and
James A. Hopson permitted me to review Hyopsodus material in a
newly acquired Yale collection (YPM) from Lysitean beds in the
Bighorn Basin, and to borrow a Marsh type for illustration. Also
Dr. Peter Robinson while at Yale sent me for study the upper Eocene
specimens of Hyopsodus found in the Marsh collection. Information
on Hyopsodus was included in my study of faunal associations in the
Eocene materials from the De Beque formation through the courtesy
of Drs. Rainer Zangerl, Robert H. Denison, and William D. Turnbull
at the Field Museum of Natural History. Data on horizons for
localities yielding these latter materials were furnished by Mr. Bryan
Patterson, formerly at that institution. Dr. Glenn L. Jepsen graciously
made it possible for me to review the Hyopsodus materials at Prince-

NO. 4 A STUDY OF HYOPSODUS—GAZIN 3

ton University, in collections from the early Eocene of the Bighorn
Basin, made by his parties. Dr. Albert E. Wood made arrangements
for me to study the Lysitean materials at Amherst (AC) and to
borrow Loomis’ types for illustration. The upper Eocene materials
in the Carnegie Museum from the Badwater area in the Wind River
Basin and the Three Forks area of Montana were made available for
my study through the kindness of Drs. Craig C. Black and Mary R.
Dawson. Much appreciated loans of other type-specimens for re-
illustrating were graciously made by Dr. Alfred M. Bailey, director of
the Denver Museum of Natural History (DMNH), through the kind
offices of Dr. G. Edward Lewis of the U. S. Geological Survey; Dr.
Donald E. Savage of the University of California (UC); and Mr.
Bryan Patterson of the Museum of Comparative Zoology (MCZ).
Dr. Dale A. Russell of the National Museum of Canada (NMC)
very kindly prepared a cast for me of a type preserved in Ottawa.

Mr. Lawrence B. Isham, staff illustrator for the Department of
Paleobiology in the U. S. National Museum (USNM), made the
pencil shaded drawings for the plates accompanying this report. He
also drafted the frequency distribution charts and _ restorations
included with the text.

HISTORY OF INVESTIGATION

Discovery and description.—The original description of Hyopsodus
was made by Leidy in 18/70. The type of the first named species,
H, paulus, is a portion of a lower jaw with much worn molars, found
near Fort Bridger * and sent to Leidy by F. V. Hayden. In the follow-
ing year Marsh (1871) described a lower jaw portion with the better
part of three, somewhat less worn, anterior cheek teeth as Hyopsodus
gracilis. According to Marsh, “The specimens representing this species
at present were found by the writer at Grizzly Buttes, Wyoming.”
Only one specimen, however, was described. It is interesting to note
that Leidy (1872b), realizing that Marsh’s “H.” gracilis did not
belong to Hyopsodus, gave a new form, Microsyops, the species name
gracilis because he believed that Marsh’s “HH.” gracilis was the same.
Cope (1872), however, was more nearly correct in referring Marsh’s
species to Notharctus, although in 1873 he followed Leidy in referring
it to Microsyops. “Hyopsodus” gracilis was subsequently made the
type of the primate Smilodectes by Wortman (1903, vol. 16, p. 362).

2 According to Leidy, but according to Matthew (1909b, p. 518) the type came
from Church Buttes. This no doubt follows from Hayden’s mention of collecting
near Church Buttes on Sept. 10th and 11th, 1870 (Hayden, 1872, p. 41).

4 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

A second form described by Marsh (1872) as being near Hyopso-
dus, Stenacodon rarus, based on a third lower molar from near
Henrys Fork, he later (1894) considered as being possibly allied to
the artiodactyl Helohyus. Matthew (1899) tentatively retained it in
this implied relationship, but both Osborn (1902) and Loomis (1905)
regarded it as representing Hyopsodus. The specimen has since been
lost.

In 1873, Cope described Hyopsodus vicarius, as a species of Micro-
syops representing “an animal considerably smaller than the Hyopso-
dus paulus.” The species was defined from two jaw fragments, one
exhibiting the anterior molar and the other the second and third
molars, from “the Badlands of Cottonwood Creek” (lower Bridger).
The same year, but evidently somewhat later, Leidy described
Hyopsodus minusculus from a maxillary portion discovered by Dr.
Carter in the buttes of Dry Creek (also lower Bridger). This also
was characterized by its small size in comparison with Hyopsodus
paulus. In 1875, Cope realized that his M. vicarius was Hyopsodus
and pointed out that Leidy’s H. minusculus was a synonym. Matthew
(1909b) later resolved this somewhat differently, regarding slightly
larger H. vicarius as a small variant of H. paulus and retaining
H. minusculus as the name for the distinctly small contemporary of
H. paulus.

Cope (1874), with attention now turned to the early Eocene of
New Mexico, described H. miticulus as a species of Esthonyx, from
lower jaw portions of three or four individuals. In 1875, while recog-
nizing that his “Esthonyx”’ miticulus belonged to Hyopsodus, he
described a second species from these beds, somewhat larger H.
mentalis, but as a species of Antiacodon which he later included under
Sarcolemur. The type of this was a lower jaw with the first two
molars. The materials of these two species were figured by Cope in
1877 but do not now appear to be extant. They were not with the
associated materials in the U. S. National Museum at the time (1907)
the type-catalog was prepared.

A third Marsh (1875) name pertinent to this review, Lemuravus
distans, was based on skeletal portions described as found “. . . in
the lower Eocene of Wyoming, . . .” distinct from H vopeodie a ina
mistaken interpretation of the destal formula of the latter. He fur-
ther proposed the family name Lemuravidae to include both Hyopso-
dus and Lemuravus. The genus was regarded as a synonym of
Hyopsodus by Osborn (1902), Loomis (1905), and Matthew
(1909b), and the species identical to Hyopsodus paulus by Matthew
(1909b).

NO. 4 A STUDY OF HYOPSODUS—GAZIN 5

The first apparent indication that the range of Hyopsodus extended
into the upper Eocene was inclusion of the name “Hyopsodus gracilis”
in a list of the fauna of the Uinta beds by Clarence King in 1878.
This list was evidently furnished by Marsh, but there is no indication
of the specimen or specimens referred to. Therefore, it is not known
whether a true primate, as implied, or Hyopsodus was involved, pre-
sumably the latter, inasmuch as Smuilodectes does not occur so high
and there are three Hyopsodus specimens in the Yale collections from
the Uinta, cataloged as having been collected by Chew and Forshey
in 1877 at “White River, Utah.” King’s listing, however, accounts
for the citing of “Hyopsodus gracilis’ in the Uinta faunas by later
workers, including Scott (1890), Osborn (1895), Matthew (1899,
1909a), and Hay (1902).

Apparently the first mention of Hyopsodus in the early Eocene of
Wyoming was Cope’s preliminary report (1880a) on a collection from
the Wind River beds made by Wortman the same year. Ina later note
(1880b) he described as coming from these beds a jaw which he made
the type of “Hyopsodus” speirianus. In 1881 he transferred this
species to Microsyops and in 1915 Matthew made it the type of
Haplomylus. Matthew also showed that the specimen was from the
Bighorn Basin and not the Wind River. Unquestionable material of
Hyopsodus in Wortman’s Wind River collection, however, was
referred by Cope (1881) to H. paulus and H. vicarius.

The first new name to be applied to material of Hyopsodus
from the early Eocene of Wyoming, Cope’s Hyopsodus lemoinianus
(1882a, p. 149), was based on a lower jaw from the Bighorn Basin,
represented in all by “nine more or less fragmentary mandibles.” In
this same report, he referred eleven mandibles from the Bighorn
Basin to the New Mexican Paleocene form Phenacodus suniensis
(a synonym of Tricentes subtrigonus). These were the basis in 1884
for his Hyopsodus powellianus. Of further interest in the 1882(a)
report, Cope described as new Phenacodus laticuneus, to which later
in the year (1882b) he gave the new generic name Dtacodexts.
Matthew (1899) indicated that the type-material consisted of upper
premolars of Hyracotherium and upper and lower molars of Hyopso-
dus and referred the species to the latter genus. However, Sinclair
(1914) discovered that the lower molar (M;) belonged to a dicho-
bunid artiodactyl, and since Cope’s diagnosis (1882a, key, p. 179)
was based essentially on this tooth, he regarded it as the only portion
of the type to which the name is applicable, removing the species from
Hyopsodus. Finally, Cope (1882c) described as new Hyopsodus

6 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

acolytus based on materials from the Paleocene of New Mexico,
evidently the Torrejon horizon. He later (1888) included it in
Mioclaenus and Matthew in his revision of 1937 included it in
Ellipsodon.

Lydekker (1885a), in a review of Microchoerus, considered that
Hyopsodus was a synonym. This allocation seems to have been
ignored, no doubt because his outline of the characters of Micro-
choerus, together with the illustrations of the teeth, showed the two
forms to be quite unlike. Apparently the first direct application of
the generic name Hyopsodus to a European form was Rutimeyer’s
(1891) “Hyopsodus” jurensis, based on two upper teeth from the
Swiss Eocene. Schlosser (1894) noted the error of Rtitimeyer’s
assignment and regarded the form as a dichobunid artiodactyl. Stehlin
(1906) further showed “Hyopsodus” jurensis to be a synonym of
Mouillacitherium cartiert.

In 1902, Osborn reviewed the species of Hyopsodus, along with the
true primates of the Eocene, but in part confused with them the
artiodactyls Microsus and Antiacodon. Among the forms named as
new, Hyopsodus wortmani was based on a figured maxilla and jaw
of the smaller Wind River species that Cope (1881) had referred to
H. vicarius. Hyopsodus marshi, a relatively large form, was described
from maxillary portions found in the upper Bridger and the name
Hyopsodus uintensis was given to the upper Eocene form occurring
in the Uinta beds. The three specimens mentioned for the latter
species were collected in 1895 from the upper or “C” horizon and
evidently comprise the material referred to by Matthew as Hyopsodus,
sp. in his 1899 list of the Uinta fauna. It may be noted, moreover,
that Osborn (1902) first figured the Washakie Basin skull as
Hyopsodus paulus. This illustration has been repeated in nearly every
general textbook treatment since then.

A second review of the species of Hyopsodus was made by Loomis
in 1905, but limited to consideration of the early Eocene or Wasatch-
ian forms as represented in Amherst College collections from the
Bighorn and Wind River Basins. Included in the discussion are the
species H. miticulus, H. lemoinianus, H. powellianus, “H.” laticuneus,
and H. wortmani. He described as new H. simplex from the Gray
Bull beds, and H. minor, H. browm, and H. jacksoni from the Lysite
beds of the Wind River Basin. The name Hyopsodus lawsoni beneath
his figure 8 and in the table (op. cit., p. 424), not otherwise formally
proposed, is clearly an error (lapsus memoriae), inasmuch as the
figure and tabular information conform precisely with the text
description of H. jacksoni.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 7

Clearly the most critical and detailed prior treatment of Hyopsodus
was Matthew’s (1909b) revision of the Bridger forms. In this he
brought out details of the appendicular skeleton, so far as known at
that time, as well as further information on the skull. It may be noted,
however, that Osborn, Scott, and Speir described the pelvis and femur
of Hyopsodus as early as 1878. Matthew’s preference for Hyopsodus
minusculus instead of H. vicarius for the smaller of the two lower
Bridger forms has been cited. He (1909b) described as new H.
despiciens based on a skull from high in the upper Bridger (D) and
referred to it the Washakie Basin skull that Osborn had cited as
H. paulus. A smaller species, H. lepidus, was described as new from
a lower horizon (C) in the upper Bridger. He indicated, moreover,
a phylogenetic arrangement for the Bridger species which seems
reasonable except for the equivocal position of “Hyopsodus paulus
vicarius.”

In 1915(b), Matthew extended his revision of Hyopsodus to in-
clude the lower Eocene or Wasatchian forms. At this time the new
genus Haplomylus was proposed for the rather distinctive “Hyopso-
dus” speirianus from the lowest of the Gray Bull beds. Loomis’ small
Hyopsodus simplex was considered valid for an early Gray Bull or
Sand Coulee form, and the ranges of Cope’s New Mexican species
H. miticulus and H. mentalis were regarded as extending to the Gray
Bull and Lost Cabin horizons, respectively, of the Wyoming Eocene.
H. lemoinianus was placed in synonomy with H. mentalis. For the
smallest of the three Lost Cabin forms recognized Matthew retained
Osborn’s H. wortmant, and for the largest he proposed the new name
H. walcottianus. Matthew considered that the Lysite forms were, in
general, intermediate in character between those of the Gray Bull and
those of the Lost Cabin, and the smallest of the Lysite forms, Loomis’
H. minor, he regarded as a subspecies of H. wortmant. For the form
of intermediate size he proposed the new subspecies H. mentalis
lysitensis, and for the largest he considered that Cope’s H. powellianus
applied properly for the Bighorn Basin Lysite, but that in the Wind
River Basin Lysite a somewhat smaller variant was represented. For
the latter he used Loomis’ name H. brownti as a subspecies of H.
powellianus and included as synonyms Loomis’ H. jacksoni and
H. lawsoni. It should be noted that the Wasatchian horizon repre-
sented by the type of Cope’s H. powellianus, as well as of H. lemoinia-
nus, is not certainly known.

A second supposed occurrence of Hyopsodus in the Eocene of
Europe was reported by Teilhard de Chardin and Fraipont in 1921.
The specimen, a lower molar tooth, is from the Sparnacian at Vinal-

8 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

mont in Belgium. There are various references in the literature to
this occurrence but there does not appear to have been any critical
re-examination reported, other than that of Teilhard de Chardin in
1922. Examination of the illustrations, as well as review of the
description furnished, leads me to suspect that the relationship is not
close.

While visiting the United States in 1925, Abel, together with
Harold Cook, described (1925, p. 33) as new the species Hyopsodus
markmani. The material consisted of a maxilla and jaw fragment of
one individual in a collection of “early Eocene” remains “from a small
and isolated spot in Colorado, ...” The remarkably small “M’
described is clearly a Dp*. There does not appear to have been any
further report on the associated fauna. The occurrence, in Moffat
County, Colorado, is now considered to be late Bridgerian in age.

A second species of Hyopsodus named on material from the upper
Eocene, distinctly larger than H. uintensis, was described by Russell
and Wickenden in 1933 (see also Russell, L. S., 1965). The form,
H. fastigatus, was based on a lower molar from the Swift Current
beds in Saskatchewan. Three other lower molars from the same beds
were cited as paratypes, and a broken upper molar regarded as repre-
senting a somewhat smaller species. The associated fauna listed is
clearly Uintan in age.

Also from the upper Eocene, Hyopsodus egressus was named by
Stock (1934) from the Tapo Ranch locality in the Sespe formation
of southern California. In addition to the type lower jaw, four addi-
tional fragments were referred and three upper teeth were cited as
paratypes. The material represents an artiodactyl rather than Hyopso-
dus and McKenna (1959) proposed the new generic name Tapochoe-
rus for this species, allocating it to the Dichobunidae.

Comparatively recent studies involving Hyopsodus in the Wind
River Basin include a report by Denison (1937) on a small collection
of mammalian materials from early Wasatchian beds, presumably the
Indian Meadows formation, near the North Fork of the Wind River
in the western part of the basin. Among the specimens he recognized
Hyopsodus simplex, and to a somewhat distinctive jaw pcrticn with
the two posterior molars he gave the new name Hyopsodus latidens.
New collections made from somewhat higher in the section, the type
Lysite in the northeasterly part of the basin, justified a revision of
the Lysite fauna by Kelley and Wood (1954). Their treatment of
Hyopsodus, in part statistical, reduced to three the number of names
applicable, recognizing H. powellianus, H. mentalis, and H. minor in
decreasing size ranges, and discarding the subspecies arrangement

NO. 4 A STUDY OF HYOPSODUS—-GAZIN 9

proposed by Matthew (1915b). Still higher in the section, White
(1952) identified H. powellianus and H. wortmani in Lost Cabin
beds of the Boysen Reservoir area, and in 1956(b) I recognized
Hyopsodus, cf. uintensis in the upper Eocene fauna from the Hendry
Ranch member of the Tepee Trail formation at Badwater, farther
east in the basin.

Review of the late Paleocene and early Eocene mammalian faunas
by Van Houten (1945) includes information on the geographic and
geologic distribution of species of Hyopsodus during Wasatchian
time, and among my recent studies (1952, 1962) involving Hyopsodus
are the investigations of the Wasatchian faunas of southwestern
Wyoming. In the latter six species of early Eocene Hyopsodus are
recognized, but not more than three in any one assemblage, defined
essentially on frequency distribution of size of teeth. Hyopsodus
material from the same depositional basin but from an early Wasatch-
ian horizon represented in the adjacent part of Colorado, was recog-
nized by McKenna in 1960 to include H. miticulus and a new species
H. loomist. The latter was described in part as possessing primitive
characters attributed to H. simplex of the Bighorn Basin but not
actually exhibited in the type. A rather thoroughgoing statistical treat-
ment of Hyopsodus was made by Olson and Miller (1958) as a part
of a demonstration of principles and procedures for showing relation-
ships of characters, or statistically defining the morphology of the
organism. The results of this study, however, are not useful in
delineating or defining the species as this was assumed to have been
accomplished. Unfortunately, it would appear that some of the
population samples used in this genus are not homogeneous.

More recently Gazin (1965) has discussed many features of the
Hyopsodus skeleton, in comparisons made between Meniscotherium
and other condylarths; a review which, together with the acquisition
-of better materials and the taxonomic confusion noted for Hyopsodus,
prompted the present study.

Relationships.—Interpretations of Hyopsodus relationships were
discussed by Matthew (1909b, p. 508), but a brief review of the
history of these seems appropriate here, with interesting additional
details and later conclusions.

Leidy (1870, pp. 109-110) in his original description of Hyopsodus
considered it a “small pachydermous animal,” and “an animal prob-
ably allied to the suilline family.” Later (1872b, 1873), however,
after having seen many more specimens he still regarded it as a small
“pachyderm,” but an odd-toed form, listing along with it such genera

Io SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

as Notharctus and Microsyops, together with the true perissodactyls.
Cope (1875) also considered the teeth of Hyopsodus to be peris-
sodactyl in type, but listed it with a variety of small contemporary
forms as Incertae Sedis.

The idea that Hyopsodus was a primate originated with Marsh in
1875 (pp. 239-240) when he referred Hyopsodus and his new
Lemuravus (=Hvyopsodus) to the Lemuravidae under the Prosimia,
and stated that Hyopsodus “. . . proves on investigation to belong
to the Primates, and not to the Ungulates. This is shown by the close
correspondence of the skeleton with that of the lemurs, and by the
general structure of the skull.” Possibly he was influenced more by
the dental characters of the primate “Hyopsodus” (now Smilodectes)
gracilis, which he thought were representative of Hyopsodus. On the
other hand, the materials that he described as Lemuravus distans were
actually of Hyopsodus.

Cope, nevertheless, remained skeptical of this direct ordinal assign-
ment and in 1877 included Hyopsodus along with the pantolestids,
notharctids, etc., in the Mesodonta, which he had proposed in 1876
as one of the suborders of his new Bunotheria, and regarded as inter-
mediate between the Creodonta and Prosimiae. He felt, however, that
further investigation was needed to determine the relations of the
Prosimiae to the Bunotheria. In 1882(a) the Prosimiae were also
included as a suborder of the Bunotheria. Cope’s ordinal arrangement
with regard to Hyopsodus was generally followed by only a few, such
as Trouessart (1879) and Seeley (1886). Most authorities, including
Schlosser (1887, 1902) ; Osborn, Scott, and Speir (1878) ; Matthew
(1899) ; Osborn (1902) ; and Weber (1904) regarded Hyopsodus as
a primate. Earle (1898), however, referred to the hyopsodontids as
pseudo-lemurs.

Marie Pavlow (1887) was evidently the first to note the condylar-
thran affinities of Hyopsodus. In her study of the paleontological
history of the ungulates, but without actual reference to the order she
commented on the closeness of “Protogonia’”’ (Tetraclaenodon) to
Hyopsodus paulus which she evidently regarded as representing the
same genus (“‘n’est autre chose’), and considered it as belonging in
the Phenacodontidae. Cope (1887, p. 657) in reply to Pavlow stated
that “nothing but the teeth of Hyopsodus are as yet known, so that
its position is uncertain. It may be lemuroid or an artiodactyl.”
Schlosser (1903), however, was somewhat more emphatic in com-
ment on a later (1900) part of Pavlow’s ungulate study; with refer-
ence to Hyopsodus he stated, “ist ja ein Primate!”

NO. 4 A STUDY OF HYOPSODUS—GAZIN To

In a study of the Eocene primates in the Marsh collection Wortman
(1903) pointed out a number of reasons why Hyopsodus should not
be regarded as a primate and considered that it was much more like
the Insectivora. Such a relationship, it may be noted, was considered
rather close in Cope’s interpretations, as in 1876 (p. 88) he stated,
“T cannot find characters by which to distinguish this division [Meso-
donta] from the Insectivora as an order.” Lydekker (1885b) con-
sidered Cope’s Hyopsodus vicarius as decidedly insectivorine and
Seeley (1886) was also unable to separate Mesodonta from Insecti-
vora. Heilprin (1887) regarded the forms in the Mesodonta as so
closely linked to the Insectivora that they are barely, if at all, separa-
ble. Most writers following Wortman’s exposition, including Loomis
(1905), Matthew (1909b), Osborn (1910, with the new suborder
Hyopsodonta), Zittel et al. (1911, textbook), and Abel (1914), con-
curred in allocating Hyopsodus to the Insectivora. As late as 1914,
however, Bolk in a discussion of the morphology of primate teeth
included Hyopsodus among the primates, citing Osborn (1902) as
authority.

Matthew (1915a, 1915b) has been generally credited with recogni-
tion of the condylarthran affinities of Hyopsodus, and indeed strongly
leaned toward this interpretation in his 1909(b) study of the genus.
It is not certain that he was aware of Pavlow’s interpretation as I
find no reference to it in his discussion; nevertheless, his rather satis-
factory demonstration of this relationship was clearly the first. It is
surprising that, in view of this detailed exposition, we find Abel as
late as 1922 and Schlosser in 1923 (in Zittel et al.), while noting
Matthew’s work, still regarded Hyopsodus as an insectivore. Abel,
nevertheless, as a result of his study with Cook in 1925 of Hyopsodus
markmant, was convinced of the ungulate affinities of Hyopsodus and
considered the ancestry of the equids to be in the Hyopsodontidae
which, in 1926(a and b) Abel related to the Protoungulata (Condy-
larthra). Friant, as late as 1934(a and b), in a study of erinaceid
molars, discussed Hyopsodus, and while noting classification succes-
sively in the Primates, Insectivora, and Condylarthra, regarded its
position as uncertain. More recently, Simpson (1945) in his classifi-
cation of the mammals, Romer (1945) in textbook treatment, and
Lavocat (1958) in the “Traité de Paléontologie” have followed closely
Matthew’s interpretation.

Gregory (1920, p. 244), in a phylogenetic review of the vertebrates
included in his study of the lachrymal bone, suggested that “every
one of the specialized characters of the dentition of Moeritherium has

I2 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

been derived from the far more primitive conditions in some such
primitive procondylarth as Hyopsodus walcottianus . . .,” enumerat-
ing the dental features of Hyopsodus which he regarded as suggesting
such a potential relationship to the Proboscidea.

Further interesting sidelights in suggested hyopsodont relationships
include Ameghino’s (1906) reference of the notoungulate Seleno-
conus to the Hyopsodontidae, which he regarded as primate in affini-
ties. The actual resemblance, from Ameghino’s figures, does not
appear very close. I am more impressed with resemblance of Casa-
mayor condylarthran Asmithwoodwardia to Hyopsodus, which Paula
Couto (1952) considered as belonging in the same subfamily ; never-
theless certain features appear rather distinctive. Perhaps an even
closer approach is made by the Casamayor Oxybunotherium which
Pascual (1965) referred tentatively to the Didolodontidae.

GEOGRAPHIC AND GEOLOGIC OCCURRENCE

The known geographic occurrence of Hyopsodus is limited to the
western or Rocky Mountain region of North America from Sas-
katchewan to New Mexico. The bulk of the material, however, comes
from Wyoming, as it is here we have very widely distributed, evi-
dently better known, and certainly more persistently prospected
Eocene than elsewhere. Reported occurrences in the Focene of
Europe, as has been noted in preceding pages, are evidently not of
Hyopsodus. While not actually represented in South America, some
forms encountered in the early Tertiary of Argentina seem to be
closely related.

Hyopsodus is of relatively common occurrence in the earliest hori-
zons of the Eocene, as at Four Mile Creek in the Colorado extension
of the Washakie Basin, at Bitter Creek on the east flank of the Rock
Springs Uplift, and in the Sand Coulee level of the Gray Bull beds
in the Big Horn Basin. It has not been recorded, however, from the
latest Paleocene,® such as the Buckman Hollow Clarkforkian on the
western margin of the Green River Basin, nor in beds of this age in
the Clark Fork Basin proper of the northwestern part of the Big
Horn Basin.

8 A lower jaw of Hyopsodus which I understand was collected by a University
of Wyoming field party in the Bison Basin, appears to be correctly identified,
but if from this area must surely be derived from a remnant of Eocene on or near
the rim of the basin, probably to the west or southwest, rather than from one of
the earlier levels of Tiffanian Paleocene represented along the escarpment below
the southerly rim of the basin.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 13

While of universal occurrence in reasonably representative collec-
tions from Wasatchian and Bridgerian early and middle Eocene of
Wyoming, Colorado, and Utah, and early Eocene of New Mexico,
Hyopsodus’ proportion of the mammalian population apparently
increased during this interval. Although comparatively common in
the earlier or Graybullian substage, as represented in the Big Horn
Basin, it is evidently not as frequently encountered as, for example,
Hyracotherium and is closely approached or possibly exceeded by
certain other groups. In Lysitean and Lostcabinian portions of the
Wasatch it appears to at least equal the horse, while surpassing other
groups, but during early Bridgerian time and probably throughout the
middle Eocene it very considerably exceeds representation of any
other mammalian genus.

In later Eocene time there appears to have been a marked regres-
sion to a less abundant state, certainly so far as the Uinta formation is
concerned. Hyopsodus has been found very sparingly in Uinta “B” at
White River pocket in the Uinta Basin, in Uinta “C” at Myton pocket,
and at localities labelled “White River, Utah” (Marsh Coll.). Never-
theless, as a result of renewed collecting by the Carnegie Museum, a
better representation of Hyopsodus in upper Eocene time is noted for
the Hendry Ranch beds on Badwater Creek. Several specimens, more-
over, have been found at an upper Eocene locality near Three Forks,
Montana, and from the Swift Current Creek beds in Saskatchewan.
There is no record, however, of the occurrence of Hyopsodus in beds
of undoubted Oligocene * age.

CLASSIFICATION

Of the approximately 31 species names that have been applied to
the genus Hyopsodus, six, as discussed in foregoing pages, were er-
roneously referred to this genus, and among the 25 remaining, five
were originally described under other generic names. Results of the
present study suggest that about 12 species names may be regarded as
valid. Five of these are recognized for the Wasatchian early Eocene,
five for Bridgerian middle Eocene, and two for late Eocene Uintan
time. The synonymy is indicated in the following chronological list-
ing, showing also information on the occurrence of the probably valid
types and the interpreted range for the species.

4 An upper molar of Hyopsodus from an isolated locality on the Beaver Divide,
reported to be in the Beaver Divide conglomerate, adds another to the list of
controversial occurrences in this area (see Gazin, 1955, p. 7). The tooth appears
rather less typically upper Eocene than perhaps earlier.

14 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

Condylarthra Cope, 1881
Hyopsodontidae Trouessart, 1879 5
Hyopsodus Leidy, 1870
Synonyms.—(?) Stenacodon Marsh, 1872; Lemuravus Marsh, 1875.
Type-species—Hyopsodus paulus Leidy.
Hyopsodus paulus Leidy, 1870

Synonyms.—(?) Stenacodon rarus Marsh, 1872; Lemuravus distans
Marsh, 1875; Hyopsodus vicarius (Cope), 1873.

Type.—Right ramus of mandible. USNM 1176, with M:-Ms (pl. 7,
fig. 4).

Horizon and locality—Lower Bridger middle Eocene, near Fort
Bridger, Bridger Basin, Wyoming.

Range—Lower part of Bridger formation, Blacks Fork member,
Wyoming.

Hyopsodus minusculus Leidy, 1873

Type.—Left maxilla, ANS (Academy Natural Sciences) 10259, with
M*-M‘ and part of P* (Leidy, 1873, pl. 27, fig. 5).

Horizon and locality—Lower Bridger middle Eocene, “Buttes of Dry
Creek,” Bridger Basin, Wyoming.

Range.—Lower part of Bridger formation, Blacks Fork member,
Bridger Basin, Wyoming. Green River formation, Powder Wash
Occurrence, Uintah Co., Utah.

Hyopsodus miticulus (Cope), 1874

Synonyms.—H yopsodus mentalis (Cope), 1875; Hyopsodus lemoinianus
Cope, 1882a; Hyopsodus simplex Loomis, 1905; Hyopsodus lysitensis
Matthew, 1915b; Hyopsodus latidens Denison, 1937.

Type.—Left ramus of mandible, USNM (type not in collections since
before 1907), with M:—Ms (Cope, 1877, pl. 45, fig. 10).

Horizon and locality——Wasatchian early Eocene, San Jose formation,
San Juan Basin, New Mexico.

Range—wWasatchian early Eocene, New Mexico, Wyoming, and
Colorado.

Hyopsodus powellianus Cope, 1884

Synonyms.—Hyopsodus browni Loomis, 1905; Hyopsodus jacksom
Loomis, 1905; Hyopsodus lawsoni Loomis, 1905.

Type.—Right ramus of mandible, AM 4147, with M:-Ms (pl. 8, fig. 8).

Horizon and locality—Wasatchian early Eocene, Willwood formation,
Big Horn Basin, Wyoming.

Range.—Middle and possibly later Wasatchian early Eocene, Wyoming
and Colorado.

Hyopsodus uintensis Osborn, 1902

Type.—Right maxilla, AM 2079, with M*-M? and part of P* and M’

(pl. 9, fig. 2).

5 The spelling and authority here used follows the International Code of
Zoological Nomenclature adopted by the 15th International Congress of Zoology.
Trouessart’s “Hyopsodinae” of 1879 was the first usage derived from Hyopsodus
in the family group. Current spelling is as specified in Example 30, Table 2,
Part B, of Appendix D7.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 15

Horizon and locality—Upper or “C” horizon of Uinta formation, Uinta
Basin, Utah.

Range.—Late Eocene Uintan of Uinta Basin, Utah, and Wind River
Basin, Wyoming.

Hyopsodus wortmani Osborn, 1902

Synonym.—H yopsodus minor Loomis, 1905

Type.—Portions of maxillae, premaxillae, and both rami of mandible,
AM 4716, with I’, P*-M®, and P:-Ms; represented (pl. 9, figs. 7-9).

Horizon and locality—Late Wasatchian early Eocene, Wind River
Basin, Wyoming.

Range.—Middle and late (and early ?) Wasatchian early Eocene,
Wyoming, Colorado, and possibly New Mexico.

Hyopsodus marshi Osborn, 1902

Type—Right and left maxillae, AM 1706a, with P®-M? represented
Gol'9) fie 1).

Horizon and locality—Late Bridgerian middle Eocene, Bridger Basin,
Wyoming.

Range.—Upper part of Bridger formation, middle Eocene, Bridger
Basin, Wyoming.

Hyopsodus despiciens Matthew, 1909b

Synonym.—H yopsodus markmami Abel and Cook, 1925

Type.—Skull and left ramus of mandible, AM 11877, with P*-M® and
Ps-Ms represented (pl. 7, figs. 1, 2).

Horizon and locality—Late Bridgerian middle Eocene, Bridger “D,”
Henry’s Fork, Bridger Basin, Wyoming.

Range.—Late Bridgerian middle Eocene, Bridger “C” and “D,” Bridger
Basin, and “middle beds” Washakie formation, Washakie Basin,
Wyoming, and Sand Wash Basin, Moffat Co., Colorado.

Hyopsodus lepidus Matthew, 1909b

Type.—Right maxilla and left ramus of mandible, AM 11900, with
P*-M* (Matthew, 1909b, pl. 48, fig. 4) and PeMs and part of Ps
represented (pl. 7, fig. 3).

Horizon and locality—Late Bridgerian middle Eocene, Bridger ‘“‘C,”
Henry’s Fork, Bridger Basin, Wyoming.

Range.—Late Bridgerian middle Eocene, Bridger “C” and “D,” Bridger
Basin, Wyoming.

Hyopsodus walcottianus Matthew, 1915b

Type.—Portions of both maxillae, left premaxilla, both rami of mandi-
ble, AM 14654, with two upper incisors, P?"-M?, part of M*, and P:-M:
represented (pl. 8, figs. 1-3). Including also limb and hind foot
material.

Horizon and locality.—Late Wasatchian early Eocene, Lost Cabin beds,
Alkali Creek, Wind River Basin, Wyoming.

Range.—Late Wasatchian early Eocene, Wyoming and Colorado.

Hyopsodus fastigatus Russell and Wickenden, 1933

Type.—Left Mz, NMC 8654 (pl. 9, fig. 3).

Horizon and locality—Uintan late Eocene, near Swift Current, Sas-
katchewan, Canada.

Range.—Uintan late Eocene, Saskatchewan and Montana.

16 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

Hyopsodus loomisi McKenna, 1960
Type.—Right maxilla, UC 44781, with P*-M? (pl. 9, fig. 4).
Horizon and locality—Earliest Wasatchian early Eocene, Four Mile
Creek, Washakie Basin, Moffat Co., Colorado.
Range.—Earliest Wasatchian early Eocene, Wyoming and Colorado.

Species of Hyopsodus, it has been found, are rather difficult for the
most part to separate on characters available in teeth and jaws, other
than size, particularly contemporaneous forms, or those within the
same larger time stages of the Eocene. As Matthew (1909b, pp. 516-
517) noted, however, there is an observable trend in time. With re-
gard to the transition from Wasatchian to Bridgerian species he stated
that ‘“The teeth of the Bridger species as a whole, show but little ad-
vance over those of the Wind River; there is no general increase in
size ; the premolar crowns are usually somewhat more complicated and
the roots more crowded, P, is normally one-rooted, excepting in one
species, while it is, as far as I have seen, always two-rooted in the
Wind River. In the Wasatch the premolars are always considerably
more primitive, with simpler, more trenchant crowns, and less com-
pletely quadritubercular. In all formations, however, the larger species
are more advanced in tooth structure.”

While I am unable to corroborate the more complicated crowns of
the Bridger Hyopsodus premolars, I note that in the upper series P?
in the Bridger material is decidedly more triangular, looking somewhat
more like P* of the Wasatchian condition, and P* of the Bridger ma-
terials has come to look a little more like P*. With regard to the lower
premolars, P, is clearly two-rooted in the early Eocene, but in the
Bridger the condition is highly variable and the roots may be divided
or completely coalesced, but more often appear to be incompletely
divided at the margin of the alveolus, and no doubt separated in depth.
It seems rather general that the premolar series, above and below, is
relatively shorter, or more crowded appearing in Bridger materials
than in the earlier Eocene. I am unable to verify, however, the more
advanced teeth of the larger species in all formations, although this
may be true in the case of H. marshi and H. fastigatus.

Contrasted with the Bridgerian species, I note in the later Eocene
materials a distinct trend toward a more nearly lophodont condition
in the molars. In the upper molars the hypocone has become more
distinctly separated from the protocone and shows a somewhat
stronger union with the metaconule, a condition reminiscent of
Hyracotherium, although less progressive in this respect. In the lower
molars the crests are a little higher, the posterior crests from the
protoconid and hypoconid slightly more oblique, and the anterior crest

NO. 4 A STUDY OF HYOPSODUS—GAZIN 17

from the protoconid in the second and third molar each shows a
tendency to form a more nearly continuous crest with the hypoconulid
and entoconid of the preceding molar. These features as they pertain
to the lower teeth appear a little less demonstrable in some of the Uinta
Basin specimens (probably Uinta “B”’) than in the larger materials of
the more northerly occurrences.

The extremes may be observed in a comparison between early
Graybullian Hyopsodus loomisi and Uintan Hyopsodus fastigatus.
Nevertheless, through much of Wasatchian time and within the
Bridgerian interval the amount and nature of intraspecific variation
renders definition on morphological grounds infeasible for practical
application. The relative abundance of materials in most instances,
however, has lent itself well to statistical analysis, and the application
of these procedures to size and proportions of teeth has produced
rather interesting results. While various parameters have been tried,
it has been found that using the length of the second lower molar gives
representative results, which may be simply portrayed.

The possibility that recognition of more than one species at a single
horizon or locality may represent dimorphism within the species seems
remote, because there are some localities, where adequate material is
at hand, as at Grizzly Buttes in the Bridger Basin, the frequency
distribution in size of M, indicates but a single form. In other in-
stances, three may be demonstrated, and where two only are indicated,
there may well be a great disparity in numbers representing each.

Wasatchian species.—Directing attention first to the early Eocene
we find that the oldest names used are Cope’s Hyopsodus miticulus and
Hyopsodus mentalis, applied to materials from the San Jose beds in
the San Juan Basin of New Mexico. The types for these two do not
now appear to be extant, but considering the measurements given by
Cope (1877, pp. 151 and 149) of 4.0 and 4.4 mm., respectively, for the
length of M, doubt may be entertained as to the probability that two
forms are represented. Utilizing all of the San Juan Basin materials
known to me, a display has been prepared (fig. 1) showing the fre-
quency distribution for length of M,, with Cope’s measurements
superimposed. This shows an observed range of 3.5 to 4.5 mm. and
the coefficient of variation is found to be close to 6.5. The display
alone is rather convincing that but a single species is represented with
the type for the oldest name, H. miticulus, essentially at the mean, and
the type for the synonym, H. mentalis, comfortably within the range.
A frequency distribution for length of M, (see tops of figs. 3 and 4),
the parameter selected for comparison, using essentially the same

18 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

sample of H. miticulus, shows a slightly greater observed range of 3.8
to 5.0 mm., with the mean close to 4.4 mm., but the coefficient of
variation, at about 6.2, is slightly less.

With reference to the classic sections of early Eocene in Wyoming,
it is seen from comparison of frequency distributions for length of
M, (fig. 2) that more than one species is represented in the higher
levels, and that one of these evidently runs through from Gray Bull
to Lost Cabin time with but a small shift in mean from 3.89 in the
Gray Bull, 4.07 in the Lysite, to 4.18 mm. in the Lost Cabin, the
latter two representing the typical sections in the Wind River Basin.
These are a little under the mean of 4.41 mm. for the San Juan Basin
material of H. miticulus, but it is reasonable to consider that the
contemporary (in part) Wyoming form is the same species.

San Jose

San Juan Basin Fic. 1—Frequency distribu-

tion for length of M, in Hyop-

RS

3

=
2 g R Amer. Mus. & sodus miticulus material from
=I0 | g eerie the San Jose formation in the
& ro San Juan Basin. Dotted rec-
ws | (Length Mz) tangles represent positions for
a of AU HL measurements of types fur-
: ead aerate 5.0 nished by Cope.
=

Direct comparison of the histogram for San Jose H. miticulus with
those for the Lysitean stage in the Bighorn and Wind River Basins is
shown in figure 3. The mode for the San Jose material appears rather
closer to that for the Bighorn (Yale’s Buffalo Basin collection) ma-
terial than to that for the H. miticulus materials from the typical
Lysite. The skewness exhibited in the Buffalo Basin representation,
however, as well as the range for materials having M, less than 5 mm.
is rather unusual, appearing suspiciously heterogeneous. Grouping
these materials according to levels in the Buffalo Basin sequence, it was
found that there is a certain uniformity within the median 200 feet
of the Lysite zone with a clear separation between two species (see
lower part of fig. 4) and a noticeable shift to the left for the upper
approximately 115 feet (see middle part of fig. 4). Concurrent with
the shift a much larger species appears in the representation of the
hyopsodont population. The San Jose range and mean are more nearly
coincident with those for the midsection of the Buffalo Basin Lysite,
whereas the Wind River Lysitean H. miticulus display is more nearly
conformable with that for the upper zone in the Buffalo Basin.

NO. 4 A STUDY OF HYOPSODUS—GAZIN Ig

The comparison in figure 5 is between the San Jose histogram and
the display for Lost Cabin age populations in both the Green River
and Wind River Basins. The correspondence is somewhat better with
H. miticulus materials from the Knight member of the Wasatch than

Lost Cabin
Wind River Basin

Amer. Mus.,
Princeton &
U.S.N.M. collections

——H.wortmani

iu P-—H.walcottionus

NUMBER OF SPECIMENS

°35 30 SS. “400s 5 coon oon Teo) 6
MILLIMETERS
§
8 :
s Lysite
~ } Wind River Basin
Amherst, Amer. Mus.

Princeton & U.S.N.M.
collections

NUMBER OF SPECIMENS
°

§
Ss
x<
8
x
j

25 3.0 35 40 45 6.5

50 55 60
MILLIMETERS

40
a
iS
35 So
=
30 4
”
2a
= 25 Gray Bull
59 Princeton &
oO U.S.N.M.
= re collections
. »
a
lJ
=
= io
~-

2H. lemoinianu

°35 30 35 40 45 50
MILLIMETERS

Fic. 2—Comparison of frequency distributions for length of M, in Hyopsodus
from typical sections of early Eocene or Wasatchian time in Wyoming. Names
show positions of specimens that have been described as types. Dotted figure
superimposed on Gray Bull distribution represents Sand Coulee alone, except
for specimen designated H. lemoinianus which is from an unknown horizon. The
upper figure is interpreted as representing, left to right, H. wortmani, H. miticu-
lus, and H. walcottianus; the central figure, H. wortmani, H. miticulus, and H.
powellianus ; and the lower figure essentially all H. miticulus.

20 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

with the typical Lost Cabin which seems to have a somewhat lower
mean and range. Again, H. miticulus, in the latter, as in the upper
zone of Buffalo Basin Lysite, is accompanied by a distinctly larger
species, as well as a smaller form.

25 he San Jose
2 H.miticulus Son Juan Basin
oO
c .. Amer.Mus. &
us U.S.N.M.
a collections
WwW
=
re)
=) 2 5 40 45 5
MILLIMETERS
»
3 Lysite
ae 2 Big Horn Basin
re ~ (Buffalo Basin)
x
Pe | Yale collections
Z 30
Ww
=
& 25
a
”
% 20
c
wi $
2 15 §
2 :
10 3
Q
x
: |
°
25 30 35 40 45 50 55 60 65
MILLIMETERS
i
~ Lysite
Ze0 j Wind River Basin
= Amherst ,Amer.Mus..
os Princeton & U.S.N.M.
= collections
10 5
‘ :
mo 5 S
= x
z

ea 5p Ss 49 45 KO 5S” G0 8
MILLIMETERS

Fic. 3.—Comparison of frequency distributions for length of M, in Hyopsodus
from Lysite horizons of the Wind River and Big Horn Basins with that for H.
miticulus of the San Jose beds in the San Juan Basin. Names show positions of
specimens that have been described as types. The central figure is interpreted as
representing, left to right, H. wortmani and H. miticulus from mixed horizons,
and H. powellianus; and the lower figure, H. wortmani, H. miticulus, and H.
powellianus (subsp. browni?).

NO. 4 A STUDY OF HYOPSODUS—GAZIN 21

Among the names that appear synonymous with H. miticulus in the
Wyoming basins are Loomis’ H. simplex (pl. 9, fig. 10) of the Gray
Bull and presumably Cope’s H. lemoinianus (pl. 9, fig. 5) based on a
type thought to be from the Gray Bull. It seems unlikely that Cope
collected from the Lost Cabin levels in the Bighorn Basin, but if H.
lemoinianus came from the Lysite zone, its length of M, again falls at

&
3
2 5 Lysite
& : : :
Wiz ; Wind River Basin
o Amherst, Amer. Mus.
a 15 Princeton & U.S.N.M.
uw collections
10 ~
r 8
WwW x
a S
=e :
2 r

os 30 3.5 40 45 5.0 5.5 6.0 65
2 MILLIMETERS
3 15 Lysite, Big Horn Basin
S ( Buffalo Basin)
ae Upper section of approx. II5'
& Yale collections
« ° H. powellionus
ui {
=
)
=) £5) “age gs 40 aig) \'56)/ 55 Go . 65
MILLIMETERS
30
w
G25
=
B20
o Lysite
uw 15 Big Horn Basin
oS (Buffalo Basin)
c
tii Median section of
= approx. 200'
z 5

Yale collections

° 2.5 3.0 3.5

4.0 45 5.0
MILLIMETERS

Fic. 4.—Comparison of frequency distributions for length of M, in Hyopsodus
from the Lysite of the Wind River Basin with those for the middle and upper
zones of the Lysite in the Big Horn Basin. Names show positions of specimens
that have been described as types. The upper and central figures are interpreted,
left to right, as representing H. wortmani, H. miticulus, and H. powellianus
(possibly as subsp. browni in upper figure); and the lower figure only H.
wortmani and H, miticulus.

22 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

about the upper limit of the range for H. miticulus, as suggested
by the composite histogram for the Buffalo Basin materials. Clearly
synonymous is Matthew’s H. lysitensis (pl. 9, fig. 6), originally pro-
posed as a subspecies of H. mentalis for the Bighorn Basin Lysite
population. Denison’s H. latidens (pl. 9, fig. 12) for the Indian
Meadow materials of the Wind River Basin was based on characters
of the lower molars that appear relatively variable.

That a smaller species than the foregoing is present, at least in
middle and later Wasatchian time, is clearly indicated in several of
the histograms. The oldest name applicable to this is Osborn’s
Hyopsodus wortmani (pl. 9, figs. 7-9), originally described from the
Lost Cabin of the Wind River Basin. Its portrayal in the histogram for
the Knight beds of the Wasatch in the Green River Basin is even bet-
ter defined with an observed range there of from 3.4 to 3.9 mm. In the
Lysite of the Wind River Basin, representation is more meager but
includes the material described by Loomis as Hyopsodus minor (pl. 9,

a

H.miticulus
San Jose
San Juan Basin

Amer. Mus. &
U.S.N.M. collections

fo)

o

°o

0

35 40 45 5.
MILLIMETERS

a

Knight member
of Wasatch
Green River Basin

U.S.N.M. collections

3

a

NUMBER OF SPECIMENS NUMBER OF SPECIMENS
o
o

35 40 45 5.0
MILLIMETERS

»

>

Ss

Lost Cabin 3
Wind River Basin 3
x

3

= ,
Amer.Mus.,Princeton
& US.N.M. collections

30 3.5 4.0 60 65 7.0

45 50 55
MILLIMETERS

NUMBER OF SPECIMENS
a

Fic. 5—Comparison of frequency distributions for length of M, in Hyopsodus
from Lost Cabin horizons in the Wind River and Green River Basins with that
for H. miticulus of the San Jose beds in the San Juan Basin. Names show posi-
tions of specimens that have been described as types. The central figure is inter-
preted as representing, left to right, H. wortmanit and H. miticulus; and the
lower figure, H. wortmani, H. miticulus, and H. walcottianus.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 23

fig. 11). In view of the interpretation made regarding the continuity
of H. miticulus through the stages of the early Eocene, I can see no
justification for recognizing H. minor as distinct. No doubt the best
display for the small form in the Lysite is seen in the histogram for
the mid-section of the Buffalo Basin sequence (fig. 4), with an ob-
served range of 3.0 to about 3.8 mm. The species is also clearly in-
dicated for the late Wasatchian in the Green River (New Fork), and
Huerfano Basins. Moreover, there is evidence in the histograms,
though extremely limited, of a similar small form in the Gray Bull
and San Jose beds. The small Hyopsodus loomisi (pl. 9, fig. 4) of
McKenna in the Washakie Basin seems to fall within the range for
H. wortmant but comes from the base of the Wasatchian section and is
structurally more primitive than either this species or H. miticulus.

Hyopsodus powellianus (pl. 8, fig. 8) is the second of Cope’s names
for these Wasatchian Eocene species that can be defended as valid. It
is based on materials from the Bighorn Basin, and although the level
is not recorded, it is almost certainly from the Lysitean interval there
represented. The type falls very near the mean of 5.70 pertaining to
the larger species having an observed range of 5.2 to 6.2 mm. repre-
sented in the upper part of the Buffalo Basin sequence (see figs. 3 and
4).

With regard to the larger species represented in the Lysite of the
Wind River Basin, however, the situation is not so easily resolved,
and Matthew may have been justified in regarding the form which
Loomis named Hyopsodus browni (pl. 8, figs. 4, 5) as a subspecies of
H. powellianus, midway between the latter and H. mentalis (=H.
miticulus). In the Wind River Lysite display the mean for all the
materials above 4.5 mm. is 5.23 mm., much less than 5.70 cited above
for the Buffalo Basin H. powellianus. Moreover, from the histogram
it is seen that the observed range of about 4.6 to 5.9 mm. is a little
large in comparison with other species, and the frequency distribution
looks as though there might have been two species larger than H.
miticulus ; however, the coefficient of variation for this Wind River
representation is only 5.5. It is 4.8 for the Buffalo Basin H. powel-
lianus material. Synonymizing H. browni with H. powellianus may be
open to question; nevertheless, I seriously doubt the presence of
another line of large hyopsodonts in the mid-Wasatchian interval. It
seems probable that Matthew’s interpretation, that a geographic vari-
ant is represented, is the best solution and H. browni should not be
given full specific recognition. Loomis’ H. jacksoni (pl. 8, figs. 6, 7)

24 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

from the typical Lysite is more easily disposed of, as it is almost
identical in size to contemporary H. powellianus.

In the Lost Cabin stage of the Wind River Basin remains of a
limited number of outstandingly large individuals with a size range
widely separated from other Lost Cabin materials, and evidently
somewhat beyond the range of Lysitean H. powellianus, represent a
form Matthew named Hyopsodus walcottianus (pl. 8, figs. 1-3).
While this may well have been derived from earlier H. powellianus,
its distinctive size would seem to warrant separate recognition in the
latest Wasatchian interval in Wyoming. The form may well be
represented also in the late Wasatchian levels in the Plateau Valley
and Huerfano Basin in Colorado.

Bridgerian species—The Bridgerian materials lend themselves
particularly well to statistical analysis because of their relative abun-
dance in all levels of the middle Eocene, and so far not complicated
by problems of geographic correlation and variation. Moreover, I
have included in this study, for statistical purposes, only the relatively
large collections in the National Museum because of the more precise
information available on stratigraphic positions for the many collecting
localities.

The earliest name available for Bridger materials is, of course, that
for the type-species Hyopsodus paulus (pl. 7, fig. 4). The type-speci-
men was described by Leidy as having been found by Hayden in the
vicinity of Fort Bridger (Church Buttes according to Matthew and
Smiths Fork according to the National Museum type-catalog of
1907). No doubt the specimen is from the Blacks Fork member or
lower Bridger (“B” of Matthew). In its length of M, the type falls
essentially at the mode and close to the mean of 4.21 mm. determined
for the Grizzly Buttes materials shown in the lower histogram of
figure 6. The evidence is rather striking that but a single species is
represented in the Grizzly Buttes area, and the coefficient of variation
determined for this frequency distribution has a comparatively low
value of 4.3. A very similar display is shown for collections obtained
from the lower Bridger beds on the east side of the basin (see middle
histogram of fig. 6), localities for the most part very high in “B” to
the north of Cedar Mountain and around the lower part of Twin
Buttes, not far beneath the Sage Creek White Layer which separates
the Blacks Fork and Twin Buttes members. In the northerly part of
the basin, however, along the Bridger escarpment of middle and lower
“B” from near “Millersville” at the confluence of Blacks Fork and
Smiths Fork northward to the vicinity of Church Buttes and east-

NO. 4 A STUDY OF HYOPSODUS—GAZIN 25

ward toward Little America, the collections reveal a frequency distri-
bution shown in the upper part of figure 6. The coefficient of variation
for this display is about 11.2, demonstrating beyond doubt the inclu-
sion of a second and smaller species accompanying H. paulus. The
appropriate name for this form is Leidy’s H. minusculus. Cope’s
name, H. vicarius (pl. 7, figs. 5, 6), would have had priority, but in
selecting a type from between Cope’s two cotypes Osborn picked the

. “

2 15 Bridger B
2 Northern part of
io escarpment —
= "Millersville" north to
=p Church Buttes and
WJ east to Little America
=o
2 25 a9 35 45 45 5.0

25
wn
rr
eat Bridger "B"
iw
a 15 Eastern part of
. basin—
S10 N.of Cedar Mt.,
Summers Dry Cr.,
= and lower part of
5 Twin Buttes
=

"25 ap a5 40 45. 80
MILLIMETERS

30 H.paulus——
w
225
= . naw
= Bridger B
G20 |
a Grizzly Buttes
n”
alt
Oo
5 10
o
=
= 5

"25 “0, a4 . 40, 45, 60
MILLIMETERS

Fic. 6.—Comparison of frequency distributions for length of M, in Hyopsodus
in collections from the southwestern (Grizzly Buttes), eastern, and northerly
portion of the lower (B) or Blacks Fork member of the Bridger formation. The
upper figure is interpreted as representing a mixture of H. minusculus and H.
paulus. The middle and lower figures represent only the genotypic species H.
paulus.

26 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

larger specimen which falls more clearly within the lower part of the
range for H. paulus. A composite histogram for all of the Hyopsodus
material from the Blacks Fork member is shown in the lower part of
figure 8. For the figure on the left side showing the frequency
distribution for the length of M,, a coefficient of variation of only 7.8
is calculated, considerably less than above where the two species are
more equally represented. The display in the right lower part of figure
8 shows the position of the type of H. minusculus which was described
from an upper dentition. Its measurement, however, does not form a

nm
or

Bridger "C" and ''D"

oo
a
=20 2
Py 2 2 =
15 ia! M =
3 u :
«!° S =
& & }
o Zo ord
= 5.30 35 40 45 $80
z MILLIMETERS
)
3.0 35 40 45 50
MILLIMETERS
wy? & ° ” "
a g Bri dger D
=20 ‘Ss o
= $ rm]
a 8 =
15 x S
L a 2
wn
Sie ws M
o
x c
uu wi
a Qo
= 330 35 40 45 50
z — MILLIMETERS

5.0

35 40 4.5
MILLIMETERS

w
S
2 8 =
= s 3 2.
2° Mop a
& . | =
iL
Sin “5 ror
a fsa)
@ =
s a
a

0
30.35 40 43.156
MILLIMETERS ‘
Bridger '"C"

Fic. 7—Comparison of the frequency distributions for length of M, (left)
and M? (right) in Hyopsodus from Bridger “C” and “D,” and their composite
for the upper or Twin Buttes member of the Bridger formation. Names show
positions of specimens that have been designated as types. All six figures are
interpreted as representing, left to right, H. lepidus and H. despiciens, with the
addition of H. marshi in the top two figures.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 27

part of the histogram as the type-specimen is not a part of the collec-
tion displayed.

At an occurrence known as the Powder Wash locality in the Uinta
Basin, Dr. J. LeRoy Kay obtained a considerable number of small
mammal remains from a sandstone lense in the Green River formation.
Included was a good representation of Hyopsodus. A frequency dis-
tribution for length of M, very strongly suggests that the form repre-
sented is H. minusculus. A few upper teeth noted in this collection
seem rather large for this species so that possibly H. paulus is also
included.

In the upper or Twin Buttes member of the Bridger formation two
zones are represented, “C” and “D.” Frequency distributions for the
lengths of both M, and M? are shown (fig. 7), and those for the lower
teeth rather clearly indicate a continuity of the species represented
from one zone to the other with very little shift in the means but with
a considerable shift in the relative abundance of the forms. The smaller
form is more abundant in horizon “C” as represented principally in
the Sage Creek basin and in general to the north of Lone Tree,
whereas the larger species becomes relatively more abuandant in
horizon “D” of the same general area, but including also some ma-
terials from the Twin Buttes White Layer and above. The means for
these two species, determined from the total of materials used for
the histogram displayed for M, in the upper part of figure 8 are 3.87
and 4.54 mm. with both the mean and mode for H. paulus below at
4.2, precisely the nadir point between the modes of the upper graph.
It is interesting to note that the shift in means between the lower and
upper Bridger is rather abrupt, evidently taking place at the Sage
Creek White Layer, although H. minusculus is recorded only from
the lower levels of the Blacks Fork member. The larger form in “C,”
moreover, is rather sparsely represented in comparison with the rela-
tive abundance of H. paulus below. The widespread lacustrial unit
separating the two members evidently represents an interval of faunal
readjustment and I am inclined, because of the abruptness of the
change in situ, certainly so far as H. paulus is concerned, to regard
the species of Hyopsodus represented above as different from those
below. Applicable names here would be Matthew’s H. lepidus (pl. 7,
fig. 3) for the smaller species and H. despiciens (pl. 7, figs. 1, 2)
for the larger. Although Osborn’s species name Hyopsodus marsht
has priority over H. despiciens and would appear on the basis of size
to be questionably separable, I am tentatively retaining the distinction
because of the progressiveness of the upper premolars in the type of

28 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

H.marshi. None of the H. despiciens from the “D” horizon show, for
example, the characters of P* described by Matthew.

In a small outlier of Bridger beds in Moffat County, Colorado, a
locality known as the Sand Wash Basin, Dr. Mary Dawson obtained

Bridger Cand .D

25
o
2 r Zz
WwW % & WW
3 & =
= 20 3 q 510
s) q Ea ty
s ge | eS &5
15 x = us 5
S | &
10 amo
c = 29 3.5 4.0 4.5 5.0 5.5
Ww > MILLIMETERS
a 2
= 5
5
z=

oo 40 4.5
MILLIMETERS

nga

Bridger "B" (all)

45

49)

==

Z 40 30

=

3 35 Ses

a =

w -—

uw 30 20
”

25 uw 15

iJ

~ °

= fo

320 w 10
a
=

15 Ss

=

3.5 40 4.5 5.0

MILLIMETERS

25° 30 3.5 40 “45° 60° 6&5
MILLIMETERS

Fic. 8—Comparisons of frequency distributions for length of M, (left) and
M2 (right) in Hyopsodus in a composite of materials from localities in the lower
Bridger or Blacks Fork member with a composite of materials from the upper
Bridger or Twin Buttes member. Names show positions of specimens that have
been described as types. The top figures represent, left to right, H. lepidus, H.
despiciens, and H. marshi; the lower figures, H. minusculus and H. paulus.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 29

a collection of Hyopsodus materials which shows a frequency distribu-
tion for length of M, which corresponds very well with that figured
for H. despiciens. The area is not geographically remote and the
above strongly suggests representation of the Twin Buttes member
or upper Bridger. This is the same locality from which the Denver
Museum of Natural History obtained material described by Abel and
Cook as Hyopsodus markmani (pl. 9, figs. 13, 14). The latter is
regarded as a synonym of H. despiciens, as its size is entirely con-
sistent with this disposition. The small M? thought to characterize
H. markmant is a Dp’.

A locality known as Tabernacle Butte, within the Bridger Basin,
but separated by faulting from the main body of the Bridger forma-
tion is purported to be upper Bridger (McGrew, 1959) and the
Hyopsodus materials identified as H. lepidus. This collection was not
included in the present study.

Uintan species—Although material of Hyopsodus from the upper
Eocene is relatively scarce, the two species that have been named,
H. wintensis and H. fastigatus, both appear to be valid. H. uintensis
(pl. 9, fig. 2) was described by Osborn on a maxilla from the upper
or “C” level of the Uinta formation in the Uinta Basin of Utah, and
he referred to it two lower jaw fragments in the American Museum
collections. Although the type would appear from the size of M? to
be a little large (4.3 x 6.2 mm.), five lower jaws in collections at Yale,
Museum of Comparative Zoology, and U. S. National Museum show
an observed range of 3.8 to 4.1 mm. for the length of M,. This is
comparable to the better known upper Bridger materials of H. lepidus.
It should be noted, however, that the USNM and MCZ specimens are
from the White River pocket and hence represent Uinta “B.” The
levels for the specimens from the Marsh collection are not known,
as the information that accompanies them includes only ‘White River,
Utah.” Possibly they are also from the lower horizon and Uinta “B”’
material represents a smaller variant than the type. A maxilla from
the White River pocket in the Carnegie Museum collections is of a
size comparable to these lower jaws, distinctly smaller (M? is 3.85 x
5.2 mm.) than the type.

Hyopsodus uintensis was tentatively recognized in the upper Eocene
Badwater fauna of the Wind River Basin on the basis of an upper
molar (Gazin, 1956b). Considerably more material has been col-
lected by Carnegie Museum parties under Drs. Craig Black and Mary
Dawson. The combined collections include about 10 recognizable
M”’s showing an observed range in length of from 4.1 to 5.0 mm. The

30 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

type of H. uintensis (4.3 mm.) falls within the lower part of this.
Eleven M,’s in the Carnegie Museum collection show an observed
range of 4.3 to 4.9 mm., a little beyond that for the range thought to
represent Uinta “B” specimens. The Badwater teeth show progres-
siveness characteristic also of the larger H. fastigatus material, and
an incipient tendency toward the formation of transverse lophs in the
upper molars is seen in the figured Badwater tooth (Gazin, 1956b,
pl. 1, fig. 3) in which there is a distinctly deeper valley separation
between the protocone and hypocone, and these cusps are more
strongly united with the accessory cuspule anterolateral to each than
they are to each other. M? in the type of H. wintensis likewise shows
this tendency (see pl. 9, fig. 2). Moreover, the crescentic crests of the
lower molars, together with the anterior and posterior walls of these
teeth, are decidedly more oblique than in Bridger material.

The relatively large upper Eocene form described as Hyopsodus
fastigatus (pl. 9, fig. 3) by Russell was based on some isolated teeth
from the Swift Current Creek beds in Saskatchewan. Its size, as
indicated by the type lower molar, is rather close to that of H. marshi
in the upper Bridger; however, while the H. marshi type exhibits
progressive premolars, H. fastigatus is more advanced in a tendency
toward more lophodont upper molars and more obliquely crescentic
lower molars, as noted in referred materials and the Badwater
H. uintensis material mentioned above. Quite the best material be-
lieved to represent H. fastigatus has been found at an upper Eocene
locality discovered by G. D. Robinson near Shoddy Springs, approxi-
mately 8 miles to the northwest of Three Forks, Montana. The beds
here have been called the Climbing Arrow formation by Robinson,
but are, no doubt, the Thompson Creek beds of Douglass, at a lower
horizon, however, than that which produced Douglass’ Chadronian
material. Two maxillae in the Carnegie Museum collection and one
in the USNM show a range in length of M? of from 5.1 to 5.3 mm.,
about the size of earlier H. marshi, as noted above. A lower jaw in
the Carnegie Museum collection exhibits an M, with the dimensions
5.24.2 mm., about the same length but slightly broader than ob-
served in a cast of the type of H. fastigatus, regarded by L. S. Russell
as M,. Lower molars in the Montana jaw show the rather prominent
development of the metastylid noted by Russell. This cuspule is
usually present in the earlier materials, but is somewhat less conspicu-
ous. Moreover, the hypoconulid on the anterior molars is close to the
entoconid and together they form with the parastylid of the succeed-
ing tooth a better crest than in earlier forms.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 31

ENVIRONMENT

Unlike Meniscotherium, Hyopsodus appears to have been present
in essentially all local mammalian faunal assemblages within the
Eocene of the Rocky Mountain Region. For this reason the genus
has much less significance as an indicator of any particular habitat.
In consequence we are faced with the entire range of environments
suggested by the biota and characteristics of the enclosing sediments
for the various basins throughout the Eocene. These will, of course,
denote the surroundings in which these animals lived, whereas their
particular adaptation or habits are to be interpreted from details of
morphology, and this in turn by analogy in comparison with living
forms.

Considering first details of distribution for particular species, a
somewhat anomalous situation was noted (Gazin, 1965, p. 17) in the
earlier Eocene with regard to the larger species, H. powellianus and
H. walcottianus, in which it seemed that these, but not the smaller
species, may have been incompatible with Meniscotherium. A further
peculiarity was noted in plotting frequency distributions in tooth sizes.
Where one of these larger species is represented in an assemblage
there is a definite shift in the mean to a lower figure for the smaller
species in comparisons made between materials from beds of nearly
the same age, such as between the upper Knight of the Green River
Basin and the Lost Cabin of the Wind River Basin (fig. 5), or as
between succeeding zones of Lysite age in the Buffalo Basin (fig. 4).
Assuming that the pattern of species identification is correct, it would
appear as though a factor of incompatibility was here involved
between individuals of different species too near the same size, where
H. powellianus or H. walcottianus were concerned. Nevertheless, the
downward shift in range and mean for the smaller forms is actually
rather small.

With regard to the more general features of the earlier Eocene or
Wasatchian time, I (1965) have previously considered the pertinent
evidence for conditions as they related to the occurrence or absence
of Meniscotherium. The conditions prevailing would appear to be
resolved into a predominantly savannah-like environment on the one
hand, and a much more paludal or swampy situation on the other, but
with no dearth of trees in either as implied by the occurrence and
variety of primates, and in both of which Hyopsodus was common.
Likewise a somewhat open terrain seems evident from the peris-
sodactyls, with Hyracotherium—ungulate, of course, though not so

32 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

decidedly cursorial as later—as universal in occurrence as Hyopsodus
and actually exceeding it in numbers at many localities.

The advent of the extensive lake system in which the Green River
deposits were laid down no doubt altered the environment consider-
ably. The origin of the lakes was tied to orogenic activity, and in
southwestern Wyoming their development began in later Wasatchian
time. This seems, however, to have had no effect on the abundant
representation of Hyopsodus, although in areas in which the lake
advanced and retreated there would appear to have been some change
in the relative abundance of the different species, as from below to

Fic. 9.—Hyopsodus paulus Leidy. Drawing based for the most part on asso-
ciated skeletal material (caudal vertebrae conjectural) of USNM 23740, and in
part on USNM 17980, from the lower Bridger beds of southwestern Wyoming.
Approximately one-third natural size.

above the Tipton or Fontenelle tongue in the upper Green River
Basin, or an actual redistribution of species, as from below to above
the Sage Creek White Layer in the Bridger sequence.

The Green River formation itself has yielded the materials which
have been most pertinent to a better understanding of the physical and
floristic environment of much of Eocene time. The work of others,
particularly the limnological studies of Dr. Wilmot H. Bradley and
the paleobotanical reports of Dr. Roland W. Brown, both of the
U. S. Geological Survey, have been most enlightening. These have
been previously cited (in Gazin 1965 for the earlier Eocene and 1958
for the middle and later Eocene) and summarized. The studies
included demonstration of a warm temperate climate with a plentiful
rainfall, low basin altitude, and high relief for the surrounding moun-
tains. During the middle Eocene time, moreover, when Hyopsodus
achieved faunal supremacy in numbers of individuals there is evi-
dence of considerable volcanic activity in the form of ash falls with
much reworked ash throughout the fluviatile and lacustrine sequence.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 33

It is not until upper Eocene time that this supremacy in numbers
is lost, a time of increasing aridity as noted by Bradley (1936), but
the mammalian evidence for this is seen in the increasing hypsodonty
of associated ungulates, and almost explosive distribution of grazing
type artiodactyls. This was further accompanied by near extinction
or retreat of the primates, so well represented in the middle Eocene,
no doubt in a large measure resulting from floristic changes. During
upper Eocene time, moreover, a selective effect is evident in the
incipient trend toward a more lophodont and more hypsodont denti-
tion in Hyopsodus, as noted in a foregoing section, presumably in

Fic. 10.—Restoration of Hyopsodus by Lawrence B. Isham, based on skeletal
drawing (fig. 9).

response to increasing aridity and coarser food. Perhaps foretelling
extinction, at least so far as the record is known, is the striking
increase in the relative number of immature specimens encountered
in upper Eocene sediments, which are exceedingly rare in the early
and middle Eocene occurrences, except for a single nest of juvenile
specimens of H. lepidus encountered by Granger and Matthew in the
upper Bridger. I strongly suspect that, although Hyopsodus was
apparently so adaptable to the range of conditions prevailing in the
early and middle Eocene, the more drastic change in climate, and
inevitably the vegetation, during upper Eocene time eventually proved
too great for its particular adaptations. The possibility of more
efficient predators, however, cannot be ruled out.

With regard to the adaptive specializations, certain details of which
are noted in the following sections, Hyopsodus is seen as a somewhat
elongate, perhaps weasel-like, animal (figs. 9 and 10) approaching
the hyrax in the number of dorsal vertebrae. The limbs seem rela-
tively short, particularly the lower part of the limb with respect to the
upper. The somewhat elongate rostrum and nearly Erinaceus-like
anterior incisors suggest a rooting habit. This is further emphasized
by indications of neck and shoulder musculature involved in such a

34 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

habit. Features of the fore limb and scapula, moreover, strongly
suggest a digging habit as well, possibly in grubbing for food. The
pelvis and hind limbs show marked leverage for muscles pertinent to
both flexion and extension, but perhaps more noticeable are evidences
for importance of those which might be used in jumping when alerted.
The shortness of the limbs, relative to body size, would not, however,
suggest extended running or leaping, such as characterizes the longer
legged lagomorphs. Articulations in the limbs and feet, moreover,
would permit considerable flexibility or diversity of movement.

One may further speculate from the prominence of the corpora
quadrigemina of the exposed midbrain, as revealed in the endocranial
cast, that sight and hearing were relatively acute, particularly the
latter. Possibly, however, these were not too highly organized, inas-
much as the neocortex seems somewhat restricted. Matthew (1928)
was inclined to regard Hyopsodus as semiarboreal.

THE SKELETON OF HYOPSODUS
SKULL

The skull of Hyopsodus in overall appearance is comparatively
slender and elongate, rather more so than the much larger skulls of
the condylarths Phenacodus and Meniscotherium. In size the skull of
Hyopsodus paulus is rather close to that of the hedgehog Erinaceus
europeus and there is a resemblance between these in the general form
of the rostrum. The anterior incisor is enlarged (pl. 6, fig. 1), but
somewhat less so than in Erinaceus, and the length of the tooth row
is about half the length of the skull. Both lack postorbital processes,
but Hyopsodus is much narrower across the frontals, as it is at the
postorbital constriction. The cranial portion appears elongate and
slender, somewhat more didelphid-like than erinaceid, and like the
opossum, has much deeper zygomatic arches (pl. 11, fig. 1). The
temporal fossae, however, are more deeply excavated and the lamb-
doidal crest is more protruding than in Didelphis, while the sagittal
crest, more as in Erinaceus, is not nearly so well developed. Certain
details of the Hyopsodus skull were earlier (Gazin, 1965) discussed
in a comparison with Meniscotherium and Phenacodus. A part of this
is repeated and expanded.

Dorsal view.—In dorsal view the rostrum tapers forward noticeably
from the anterior margin of the orbital rim to the anterior narial
aperture. The nasals extend forward to this aperture, about as in
Erinaceus, but are much more broadly exposed than in that form.
They are relatively narrower and do not project so far forward as in

NO. 4 A STUDY OF HYOPSODUS—GAZIN 35

Meniscotherium. Posteriorly they terminate abruptly just back of the
frontomaxillary suture (pl. 2, fig. 2), not penetrating the frontal area
so deeply as in Meniscotherium. They broaden slightly at the narial
aperture but their greatest width appears to be at the frontomaxillary
suture.

Unlike Erinaceus, the dorsal surface of the skull tapers backward
sharply from the greatest rostral width, at about the anterior margin
of the orbits, to the postorbital constriction which is decidedly narrow
across the roots of the olfactory lobes of the brain. The frontals are
narrow and gently convex transversely over the dorsal surface, mak-
ing limited contact with the maxillae forward between the nasals and
lachrymals, the latter being noticeably expanded forward and medially
from the orbital rim. The weak temporal crests, in the absence of
postorbital processes, converge posteriorly from the orbital rim with
little or no flexure to form the low sagittal crest, which commences at
about the postorbital constriction. This is also at about the point
where the frontoparietal suture crosses the midline of the skull.

The cranial portion of the skull broadens more gradually posterior-
ward, toward its greatest width across the squamosal roots of the
zygomatic arches. The arches are moderately expanded and join the
cranium well forward of the lower extremities of the lambdoidal crest.
With the prominent and elongate upturn of the occipital crest, there
is produced a broad, more distinct dorsal concavity, just over the
midbrain, in the posterior portion of each of the temporal fossae, than,
for example, in the hedgehog. The depths of these fossae are pene-
trated by a somewhat irregular cluster of vascular foramina near and
at the parietosquamosal suture. The parietosquamosal suture runs
forward from the suture bounding the supraoccipital, from a point
about half way down the lambdoidal crest and a little above the upper
limit of the mastoid exposure on the occiput. The suture divides the
temporal fossae posteriorly about equally between the parietal and
squamosal but then descends rapidly on the lateral wall of the brain-
case just anterior to the zygomatic roots. The posteriorward flare of
the lamboidal crest is somewhat greater on either side of the posterior
extremity of the sagittal crest, somewhat as in Meniscotherium. There
is no evidence for an interparietal.

Lateral view.—In lateral view the premaxilla is broadly developed
ventrally along the alveoli for the incisors (see pl. 6, fig. 1) and tapers
upward and backward, wedging out posteriorly between the maxilla
and nasal at a point at least half way along the length of the nasal.
In this view also the relatively greater length of the first incisor is
evident, approaching the development in Erinaceus. The lateral

36 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

exposure of the maxilla is relatively elongate to accommodate the
long cheek tooth series, and moderately deep posteriorly. The infra-
orbital foramen is large, well forward, and close to the tooth row. Its
position is just above the posteroexternal root of P*. The vertical
development of the jugal is relatively great and its upper margin joins
the lachrymal forward, eliminating the maxilla from participating in
the orbital rim, not at all like Erinaceus. A process of the maxilla,
however, extends posteriorly for an appreciable distance along the
inner surface and lower margin of the arch (see pl. 4, fig. 1). The
lachrymal, forming a part of the anterosuperior margin of the orbit,
extends a short distance forward to the maxilla and upward or medi-
ally to the frontal. The large lachrymal foramen is concealed behind
the orbital rim, quite unlike Erinaceus. The considerable depth of the
zygomatic arch is maintained throughout its length (pl. 11, fig. 1),
posteriorly to a position just above the postglenoid process. The
superior margin from there descends above the external auditory
meatus, forming the lateral margin of the cranium to the ventral
extremity of the lambdoidal crest at the root of the mastoid process.
The jugal portion of the arch extends posteriorly beneath the squa-
mosal almost but not quite to the glenoid surface. Superiorly the
zygomatic process of the squamosal extends forward about half the
length of the arch.

Within the orbital fossa, the orbital plate of the maxilla appears
as a roughly triangular area, and near its medial margin can be seen
the irregular trace of the maxillopalatine suture. The suture extends
from just lateral to the small posteromedial notch well forward toward
the relatively large posterior aperture of the infraorbital foramen.
Medial to this suture, and to the posterior margin of the orbital plate
of the maxilla, the sphenopalatine foramen, as I have noted earlier
(Gazin, 1965, p. 26), is about even with or slightly posterior to the
hind margin of the last molar. The optic foramen is well in advance
of and a little higher than the sphenoidal fissure. Its position is just
ahead of the anteroventral margin of the surface for the temporal
muscle, and directly below the postorbital constriction. There is evi-
dently no alisphenoid canal, although this was earlier (loc. cit.)
thought possible, nor is there any certain indication that the foramen
rotundum is partitioned from the sphenoidal fissure. The latter
appears as a somewhat elongate (anterodorsal-posteroventrally ) open-
ing which, in turn, is situated in a deeply pocketed area well back and
beneath the crest bounding the inferior margin of the temporal fossa.

Occipital view.—In the occipital view of the Hyopsodus skull the
lambdoidal crest is seen, in rare instances where sufficiently well pre-

NO. 4 A STUDY OF HYOPSODUS—GAZIN 37

served (pl. 4, fig. 3; pl. 5, fig. 2, the crest here is supported by a fringe
of matrix on its posterior surface), to be high and generally upward
flaring, although slightly posteriorward on either side of the mid-
section. The crest is decidedly thin and but weakly buttressed by
upward diverging crests on the occipital surface. Its development,
though, appears rather unusual in so small a mammal, much more
impressive than in Erinaceus, suggesting good leverage for the sple-
nius and other muscles of the neck. If the trapezius is included this
may correlate with the remarkable development of the spine of the
scapula. The lower half of the lambdoidal crest is formed on the
squamosal; median to this on the occipital surface the mastoid is
exposed, but facing obliquely, and broadening downward to occupy
the space between the paroccipital process and the mastoid process
which it forms at the lower extremity of the lambdoidal crest. The
paroccipital process is conical and close to the occipital condyles,
evidently not nearly so elongate as in Meniscotherium.

Palatal view.—The Hyopsodus palate is relatively elongate between
a full complement of cheek teeth, and the lingual margins of the tooth
rows are nearly parallel, or slightly converging anteriorly. The ante-
rior margin of the palate, or premaxillary portion, is evenly rounded
lingual to the incisors, and the two lateral incisors have a more longi-
tudinal than transverse alignment posterolateral to the larger first
incisor. The anterior palatine foramina, though small, are conspicuous
and relatively elongate posterolaterally, extending from near the first
incisor to about a line between the third incisors. Except for a small
segment of the posterior margin of each they are essentially sur-
rounded by the premaxillae. The premaxillo-maxillary suture extends
anteromedially from the canine alveolus to the posterior tip of the
anterior palatine foramen, then continues posteromedially for a short
distance to the median suture. Small nutrient foramina in the palate
are noted irregularly scattered between the premolars.

The palatines are broadly exposed posteriorly and the maxillo-
palatine sutures on each side extend forward from the posterior mar-
gin of the palate to the lingual margin of the alveolus for the inner
root of M*. Continuing forward close to M? the sutures then con-
verge to the midline of the palate at a point about even with the
anterior margin of M?. Posterior palatine foramina are small and
relatively inconspicuous but are seen to occur at or near the maxillo-
palatine suture. The anterior margin of the posterior narial aperture
shows an everted, liplike rim or crest, evidently for the tendon of the
tensor palati, better developed than in Meniscotherium or Phenacodus,
but not so prominent as in Erinaceus or Didelphis. This margin, how-

38 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

ever, is more transverse and does not extend so far forward in the
palate as in Meniscotherium. It is about even with the posterior mar-
gin of the third molar. Moreover, the maxillary tuberosity is close to
the lateral margin of the narial aperture so that there is only a very
small notch between them in contrast with the deep and broadly open
saddle noted in Meniscotherium.

Basicranium.—The basicranium in Hyopsodus (pl. 1; pl. 3; and
pl. 4, fig. 1), as in Meniscotherium, is relatively elongate. This is
noticeable in the forward position of the glenoid surfaces with respect
to the occipital condyles and the length of the mesopterygoid fossa.
The basicranium is decidedly unlike that in Erinaceus. The elongate
basisphenoid and basioccipital area is gently concave in the mesoptery-
goid fossa and moderately convex posteriorly with its greatest width
close to the foramen magnum. An elongate ventral protuberance, con-
tributing to the posterior convexity on the basisphenoid and basioc-
cipital, reaches apices on both sides at about the suture between these
bones (pl. 3). These may be further emphasized by a transverse crest
at the suture (pl. 1; pl. 4, fig. 1). This condition evidently testifies to
the significance of the rectus capitis anticus major that functions in
depressing the snout. As in Phenacodus, this seems more important
than in Meniscotherium. The pterygoid fossa is well developed, pos-
sibly more so than in Meniscotherium, relative to size, but not so
broad and deeply excavated as in Erinaceus. More recently prepared
material (since Gazin, 1965) shows that the pterygoid proper, though
somewhat less elongate anteroposteriorly than the pterygoid plate of
the alisphenoid, projects downward more than the latter (not less
developed as stated in 1965), although this portion is not sufficiently
well preserved to exhibit the character of the hamular process. The
posterior margin of the pterygoid plate of the alisphenoid ascends
steeply to a point near or immediately in front of the foramen ovale.
There is no evidence of an alisphenoid canal, such as in Meniscothe-
rium, so that apparently the external carotid (internal maxillary)
artery remained outside the cranial wall or alisphenoid, although, of
course, some portion of the carotid system, such as one of the
meningeals, may well have occupied the foramen ovale, as well as
the inferior maxillary or mandibular nerve (V3).

There is a strong crest posterolateral to the foramen ovale, as in
Meniscotherium, the styloid process of Cope, made up of plates from
the alisphenoid and squamosal, but with somewhat greater participa-
tion of the squamosal than the alisphenoid, and is much closer to the
glenoid surface and postglenoid process leaving a relatively wider
separation between the crest and the foramen lacerum medium in

NO. 4 A STUDY OF HYOPSODUS—GAZIN 39

Hyopsodus. The position of the crest is near or about that of the
angular spine of the alisphenoid in man, which supports a portion of
the musculature of the soft palate and of the tympanum. Possibly its
prominence is to be correlated with the conspicuous lip-like rim at the
posterior margin of the palate for the tensor palati. Nevertheless, as
stated earlier (Gazin, 1965), I suspect that here it may be homologous
to a similar prominence in certain other mammals, such as the oreo-
donts, where it forms a pedicle for the support of the anterior portion
of the bulla. As in the case of Meniscotherium, however, no bulla has
been discovered for Hyopsodus. Its position also recalls somewhat
the alisphenoid bulla in didelphids but is differently oriented and very
much less developed. A broad groove in the alisphenoid for the
eustachian tube, close to the foramen lacerum medium is better sepa-
rated from the crest or pedicle, attributed to a possible bulla, than in
Meniscotherium.

The glenoid surface for articulation of the lower jaw in Hyopsodus
is transversely elongate and only slightly concave in this direction,
rather different in this respect from the more obliquely elongate and
deeply concave surface in Meniscotherium. The postglenoid process,
posterior to the inner half of the glenoid surface, is well developed,
and posterointernal to it the large postglenoid foramen has its aperture
completely surrounded by the squamosal. The broad arch of the
squamosal over the external auditory meatus extends posteriorly down
the anterior surface of the moderately developed mastoid process
which is anterolaterally well separated from the paroccipital process,
leaving the mastoid better exposed ventrally than in Meniscotherium.
A deep groove in the mastoid, extending dorsoventrally just median
to the mastoid process, is the stylomastoid foramen for the facial
nerve, but in the absence of a bulla does not appear to be closed
anteroventrally. The paroccipital process is a prominent conical form,
directed slightly backward but not nearly so elongate nor flattened as
in Meniscotherium. The condylar or hypoglossal foramen is located
decidedly medial to the paroccipital process, close to and partially
concealed by the anteroventral margin of the condyle. The foramen
lacerum posterius is a rounded, slightly elongate aperture immediately
anteromedial to the paroccipital process and seeming to penetrate its
root. It is bounded forward by the posterior margin of the petrosal
very near the fenestra rotunda.

Periotic—The petrosal in Hyopsodus appears long and slender in
ventral view, as a slender cone with its apex directed forward and
medially. The promontorium is not separately defined. The relatively
large fenestra rotunda faces backward, outward, and downward. Its

40 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

posterior rim is joined by a crest from the medial portion of the
ventrally exposed mastoid, which also forms an anterior root or but-
tress for the paroccipital process. This crest at the posterior rim of
the fenestra rotunda may also have supported a stylohyal. Just medial
to it is the comparatively large foramen lacerum posterius, and later-
ally the groove for the facial nerve. The relations here are closely
similar to those in Meniscotherium. Anterodorsal to the fenestra
rotunda is the smaller, outward facing fenestra ovalis. As in Menis-
cotherium the facial nerve would emerge from an aperture antero-
dorsal to the fenestra ovalis, descend to a position opposite the fenes-
tra ovalis, turn backward then downward to appear anterolateral to
the root of the paroccipital process, were the area covered by a bulla.

The medial margin of the petrosal in Hyopsodus shows a broad
longitudinal groove partially formed by the lateral margin of the
basioccipital. The posterior extremity is determined by the point at
which the petrosal more solidly abuts the basioccipital, close to the
foramen lacerum posterius. This groove clearly opens into the cranial
cavity medial to the anterior extremity of the petrosal where it abuts
the alisphenoid. It no doubt carried the internal carotid artery, as
interpreted for Mentscotherium.

The dorsomedial surface of the petrosal is partially preserved in
two specimens for which incomplete and somewhat distorted endo-
cranial casts are illustrated (pl. 5, fig. 1; and pl. 6, fig. 2). The details
of this surface of the petrosal are discussed on pp. 42 and 43.

ENDOCRANIAL CAST

It has been possible to prepare partial endocranial casts in latex
from two specimens of Hyopsodus. One of these (pl. 5, fig. 1) was
obtained from assembled cranial fragments (pl. 5, fig. 2) of a speci-
men of Hyopsodus miticulus found in the Knight beds of the Wasatch
north of Big Piney, Wyoming. Its identity is based on an included
rostral portion with most of the cheek teeth. The other (pl. 6, fig. 2)
was prepared from a skull of H. paulus in which the base of the
endocranium was exposed in a rock surface through weathering. This
specimen, including a nearly perfect palate (pl. 6, fig. 1), was found
in the lower part of the Bridger formation about 10 miles east of
Lyman, Wyoming. In a third specimen (H. miticulus), a weathered
rostrum only (pl. 2, fig. 1), a natural cast of the olfactory lobes is
preserved, together with bone traces showing the position of the
cribiform plate and the configuration of the turbinates. Also shown
are the rather deep roots of the nasals, normally concealed by the
maxillae.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 4I

The H. miticulus endocranial cast (pl. 5, fig. 1) is not complete
anteriorly, nor is the basal part included. Nevertheless, the dorsal
surface of the midbrain segment and much of the cerebellar repre-
sentation is preserved, also configuration of the surface adjacent to
the petrosal and the greater part of the surface of the medulla ob-
longata. In the dorsal view it is seen that the posterior limit of the
neopallium is widely separated from the lobes of the cerebellum, leav-
ing the tectum of the midbrain broadly exposed.* The most signifi-
cant feature here is clear delineation of the corpora quadrigemina.
The posterior pair of culliculi, for auditory stimuli, are appreciably
larger than the anterior or visual culliculi. There is an appreciable
exposure of the midbrain in Memiscotherium but the quadrigemina
are not evident, possibly because the tectum is rather obscured by the
large lateral sinuses. The longitudinal sinus in the Hyopsodus cast is
evident between the medial margins of the neopallium, and the trans-
verse or lateral sinuses separate just ahead of the anterior culliculi
and extend obliquely backward and downward, paralleling the occipital
lobes of the cerebral mantle. It is interesting to note that, at the point
of separation, the left lateral sinus is slightly higher than the right,
recalling the same situation, but more pronounced, in Meniscotherium.

The vermis of the cerebellum is relatively large and elevated about
to the extent of the cerebrum. The lateral lobes are moderately
developed and set off from the vermis by a broadly shallow para-
median fissure. The width across the cerebellum, however, is com-
paratively constricted, in part as a result of lateral compression of the
cranial portion from which the cast was made. Beneath the lateral
lobes of the cerebellum there may be seen in side view prominent
representation of the superior petrosal sinus, continuation of a part
of the transverse or lateral sinus system. On the dorsoposterior
margin of this there is evidence of a small foramen indicating vascu-
lar communication with the occiput at or close to the dorsomedial
margin of the mastoid. Ventrally the sinus curves slightly forward
beneath the inner margin of the petrosal to the foramen lacerum
posterius. Just posterior to this flexure, on the side of the medulla
oblongata, there is a noticeable protuberance representing the form
of the hypoglossal or condylar foramen. A subdued ridge between

6 Edinger (1964) did not regard the midbrain exposure in mammals as
necessarily primitive, but of secondary development. It should be noted,
however, that the early forms on which this judgment was based, the multi-
tuberculates and Triconodon, with an essentially concealed tectum, are not
eutherian, nor are they in the line or lines of descent of such mammals, and may
even have been independently derived from the therapsids.

42 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

this prominence and the sinus is evidently representation of a small
vascular structure participating with the hypoglossal nerve in use of
the condylar foramen. In the area covered by the petrosal a promi-
nently developed flocullus, nearly globular in shape, projects outward,
downward, and somewhat backward. Ventromedial to this the promi-
nence representing the internal auditory meatus, though less project-
ing, is of a little greater diameter. A division at its apex into the
foramen for the facial nerve forward and above, and the auditory
nerve posteroventrally, is only faintly discernible on the cast, but
clearly evident on the bone. It should be noted in this lateral view of
the cast that indication for the depth of the foramen magnum is
distinctly exaggerated (pl. 4, compare fig. 3 with fig. 2).

The cerebral portion of the H. miticulus cast is not complete and
it would appear that a considerable portion of the forebrain is not
represented in any of the material at hand. The rostral portion men-
tioned (pl. 2, fig. 1) of another specimen, however, shows the con-
figuration of the olfactory lobes as seen from above. These are clearly
of relatively large size. Their combined diameter is only a little less
than that across the lateral lobes of the cerebellum in the specimen
figured in plate 5.

The cast of the basal part of the endocranium, taken from the
specimen of Hyopsodus paulus (pl. 6, fig. 2) shows interesting detail,
but to a rather limited extent, as the more elevated structures of the
original specimen were partially obliterated by weathering; only the
depressed areas, shown as elevated in the cast, are at all well pre-
served. The olfactory lobe as seen on the right side is incomplete
anteriorly but extends downward, transversely somewhat compressed,
or longitudinally crested. This is almost immediately anterior to the
position of the optic foramen, also here preserved only on the right
side. Weathering, moreover, has obliterated all but the weakest trace
of the chiasmatic groove for the optic chiasma, which would have been
very close to the roots of the olfactory lobes at the postorbital con-
striction. Well back of this position, about midway on the cast, is seen
the well-rounded, moderately large, dome-like surface of the hypophy-
sis or pituitary body. ‘The original bone surface posterior to the
hypophysis was destroyed so that there is no trace or representation
in depth on the cast of the dorsum sellae. Posteriorly the medulla
oblongata appears broad and elongate. On either side of the hypophy-
sis are seen the decidedly prominent representation of the cavernous
sinus, terminating forward at the position of the posterior aperture
to the sphenoidal fissure, and comprising a complex of vascular struc-

NO. 4 A STUDY OF HYOPSODUS—GAZIN 43

tures and cranial nerves (III to VI, except V3). Except for the good
depth forward there would appear here no evidence of a separate
alisphenoid canal or foramen rotundum, with the contents normal for
these emerging into the orbital fossa through the somewhat elongate
sphenoidal fissure or foramen lacerum anterius. Well back on the
ridge there is indication for an elongate slit-like internal aperture of
the foramen ovale for the third branch of the trigeminal nerve.
Lateral to the cavernous sinus the cast shows, on the right side only
(observer’s left), the large and elongate pyriform lobe, not sufficiently
complete, however, to show the rhinal fissure, so that between the two
casts there is no information on the extent to which the lateral lobes
of the neopallium may have enveloped the rhinencephalon. Moreover,
in no part is representation of the sylvian fossa preserved. Posterior
to the pyriform lobe the cast represents only the damaged dorsomedial
surface of the petrosal, although the position of the flocculus and the
apex of the contents of the internal auditory meatus can be located,
and a trace of the cochlea just anterior to the latter can be recognized.
Median to the petrosal position the elongate foramen lacerum medium
is prominently portrayed, on the left as well as the right side, and this
appears connected by a posteriorly much subdued inferior petrosal
sinus to the foramen lacerum posterius. A short distance posterior to
this, on the side of the medulla oblongata as exposed, can be seen
representation of the contents of the hypoglossal foramen.

MANDIBLE

In lateral view the lower jaw of Hyopsodus (see pl. 2, fig. 3; pl. 11,
fig. 1; and various plates of type-specimens) is rather variable in the
amount of forward taper, and often this is rather slight beneath the
cheek teeth, but with an elongate taper through the symphysial por-
tion. Usually the rami are strongly ankylosed throughout the elongate
symphysis. The small but long rooted anterior incisors are decidedly
procumbent. The number and position of the mental foramina are
rather variable, but generally two or three are seen beneath from about
the first or second premolar to the fourth, slightly below the middle
of the jaw. On occasion, however, only one or even four have been
observed. Moreover, anteriorly two small foramina, one on each side,
are present adjacent to the symphysis about midway on its length.

Posteriorly on the jaw the masseteric fossa terminates forward in
a slight rugosity beneath about the posterior margin of M,. Above
this the rather well-defined crest limiting the masseteric fossa ante-
riorly merges with the steeply rising anterior margin of the ascending

44 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

ramus. The coronoid process, extending moderately well above the
level of the sigmoid notch, has a convex anterior margin but the
posterior margin is evidently more nearly vertical, so that the process
does not appear to be directed backward over the sigmoid notch so
much as in Meniscotherium, and may be relatively a little wider at
the base. Also beneath about the posterior margin of M; the lower
margin of the jaw shows a weak to moderately strong concavity, pos-
terior to which the angle of the jaw may, though not invariably, be
directed noticeably downward. While not actually complete in any
specimen at hand, the angle appears to be relatively large, but possibly
not as backward flaring as in Meniscotherium. Nevertheless, the
condyle sets well forward of the posterior margin of the angle and
has little or no neck. Its articular surface is broad medially and the
long axis is directed more transversely than in Meniscotherium and
is not so strongly convex.

On the medial surface of the lower jaw the mylohyoid crest is
clearly discernible from just above the partially divided pit for the
digastric muscle to a point nearly beneath M;. It is approached by a
weak crest extending downward and forward from the anterior mar-
gin of the ascending ramus from which arises a part of the superior
constrictor in human anatomy. The inferior dental canal opens pos-
teriorly in a moderately elongate aperture a little forward of a point
midway between the third molar and the condyle, at a level about even
with the alveolar margin of the ramus or a little lower, appreciably
lower than the condyle. Below this position the inferior margin of the
ramus curves inward slightly, beneath the rather large surface for the
pterygoid muscles, which in turn may be correlated with the develop-
ment of the pterygoid fossa in the basicranium.

DENTITION

Hyopsodus exhibits a full complement of 44 teeth. The incisors,
canine, and first premolar above and below are comparatively simple,
nearly spike-like, single-rooted teeth. They are somewhat like those
in Meniscotherium, but a little more conical. Moreover, the first upper
incisor is relatively larger and P* is evidently never two-rooted, as it
appears to be occasionally in the latter form. The nearly Erinaceus-
like enlargement of the first upper incisor, together with the follow-
ing simple and smaller, but subequal, anterior teeth has been noted;
however, this resemblance does not extend to the uniformly small
lower anterior teeth. Possibly, nevertheless, the relatively omnivorous
diet of the hedgehog may be indicated for Hyopsodus.

a

NO. 4 A STUDY OF HYOPSODUS—GAZIN AS

The cheek teeth seem a little less bunodont than in Phenacodus and
with much less tendency toward rugosity, extra cuspules, and styles.
They are decidedly less progressive in the achievement of a more
hypsodont and crescentic pattern characterizing Meniscotherium.

Upper dentition—The large I? with its elongate, curved root,
apparently determining the contour of the lateral margin of the narial
aperture, has a nearly erect, somewhat elongate and tapering, enamel
covered crown, with weak evidence of a cingulum at the medial and
posterolateral angles. In cross-section the crown is almost triangular,
but with a well-rounded anterior angle and a straight, relatively broad
posterior margin. The posterior bevel of this tooth clearly occludes
with both the first and second procumbent lower incisors. There is a
small diastema between the alveoli of the right and left first incisors,
not so great as in Erinmaceus, and the crowns converge slightly
downward.

The smaller I*, I°, C, and P? are very much alike, increasing slightly
in size posteriorly to the canine, although the canine crown does not
reach the length of I*. P? is smaller than C, about the size of I, but
with a slightly lower crown. These anterior teeth are all acutely
conical with a well-rounded anterior to lateral surface. There is a
somewhat compressed or crested anteromedial margin, slightly convex
in profile ; and a similarly crested but more nearly straight or slightly
concave posterior margin. The posteromedial surface, unlike I,
shows a prominent rib. The cingulum is very weak, except at the
upper extremity of the anteromedial and posteromedial crests.

P? is a two-rooted tooth, more elongate anteroposteriorly than P?,
often with a very weak anterior style and a somewhat more distinct
posterior style. The cingulum may be developed posterointernally. In
the earlier or Wasatchian materials this tooth is relatively narrow
transversely, although increasing somewhat in width posteriorly. In
the Bridger materials this tooth has become decidedly broader with a
triangular outline in occlusal view. It has the appearance of a three-
rooted tooth, but almost invariably the very broad posterior root is
undivided. Only in the type of H. marshi from the upper Bridger
have I observed conspicuous development of a lingual cusp or
deuterocone.

P* is invariably a three-rooted tooth with a prominent, single outer
cusp and a narrow lingual talon exhibiting a smaller but usually
prominent deuterocone. A crest may be developed from the apex of
the deuterocone to an anteroexternal style; posterolingually a cingu-
lum extends from the posterolingual wall of the deuterocone, or its
apex, to a posteroexternal style. The external cingulum may be weak

46 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. I53

or absent across the outer rib of the primary cusp, but is prominent
close to the styles. In the Wasatchian or early Eocene material the
outer wall of this tooth is relatively elongate, with generally better
developed styles, particularly the anterior, giving this tooth a more
decidedly triangular outline in occlusal view. By middle Eocene time,
however, this outer wall has become much shorter anteroposteriorly,
with the anterior and posterior walls approaching parallelism, and the
deuterocone is better developed, so that P* more nearly resembles P*.

In P* the primary or outer cusp and the deuterocone are about equal
in height or vertical dimension, but there is no tritocone and no evi-
dence of an hypocone. The outer cusp is conical but with anterior and
posterior crests to the styles, whereas the deuterocone is acutely
crescentic with its crests also joining the anteroexternal and postero-
external styles. In one instance (Bridger) an accessory cuspule was
noted on the anterior crest. In addition to the crests of the deutero-
cone there is an anterior cingulum, which may be very weak, and a
generally much stronger posterior cingulum. These tend to join the
crests laterally before reaching the styles. The cingulum generally
appears discontinuous across the lingual wall of the deuterocone, but
may be weakly defined. The cingulum on the outer wall may continue
across the outer rib of the primary cusp somewhat better defined than
in P*. There is rather less to distinguish between earlier and middle
stages of the Eocene in the character of P*, except that in the later
stages the tooth often appears somewhat more compressed antero-
posteriorly, with weaker styles.

The upper molars are low crowned bunodont teeth and the anterior
two are nearly quadrilateral with six well-defined cusps. M* and M?
are much alike except that the larger second molar is wider trans-
versely and the outer margin is slightly more oblique. M® is more
askew. In the first two the conical paracone and metacone are of equal
size and joined together and to the anteroexternal and posteroexternal
styles by a thin crest which in occlusal view is a nearly straight line,
except at the styles where there is a sharp but very short outward
flexure, and where this crest joins the prominent outer cingulum.
There is no mesostyle. Lingually the protocone has about the same
height as the outer cusps, but appears larger, exhibiting a more obtuse
conical form tending to be somewhat crescentic. An anterolateral
crest from the protocone joins the small protoconule and then con-
verges with the anterior cingulum near the anterolateral style. The
anterior cingulum is well developed, and usually somewhat crested
anterior to the protocone where it may be slightly cuspate. Pos-

a

NO. 4 A STUDY OF HYOPSODUS—GAZIN 47

teriorly, the protocone shows a small crest to the smaller and also
slightly crescentic hypocone in the early and the middle Eocene stages.
The posterolateral crest of the hypocone ascends to form the posterior
cingulum, continuing laterally to the style. There is no cingular crest
lingual to the hypocone although it may be weakly traced around the
lingual margin of the protocone. The metaconule is a small, isolated
cone about midway between the protocone and metacone in the early
and middle Eocene stages. In the late Eocene the metaconule has
become aligned with the hypocone, and the latter cusp is relatively a
little larger and more widely and deeply separated from the protocone,
giving the first and second upper molars a more lophodont appearance.

In M$ the outer wall is decidedly oblique and the metacone generally
a little smaller than the paracone. The anterior portion of the tooth
is much as in the first two molars but posteriorly the hypocone is much
less developed and often little more than a crested posterolingual por-
tion of the cingulum. In the upper Eocene this crest may form a
prominent posterolingual angle to the tooth, but is not joined with the
metaconule as in the anterior molars.

Lower dentition—The lower incisors are slender and with very
elongate roots. In an arcuate arrangement they are decidedly pro-
cumbent, although decreasingly so toward the canine. The first is a
little smaller than the second and both have narrowly spatulate crowns,
occluding at a high angle with the broad posterior bevel of I’. I, also
occludes laterally with the anterior margin of I?. The labial surface
of each is gently convex in both directions, but the lingual surface has
a strong longitudinal rib which is slightly concave in profile. The
nearly parallel and somewhat compressed lateral margins turn lin-
gually near the base of the crown to form a weak posterior (lingual)
cingulum. I; has a somewhat shorter, more tapering crown than I,
with a little broader base but a smaller, more nearly circular root. Its
occlusion is with the posterointernal surface of I? and the anterior
margin of I.

The lower canine and P, are much like I; with a relatively simple,
tapering crown, and a single circular root, but appear somewhat more
erect, and C is distinctly larger. The base of the crown in these
extends forward and upward so that the shorter, arcuate anterior crest
is more outstanding than the straight to slightly concave posterior
margin. A weak cingular crest may be developed lingually, at least
in the posterior portion, and at its union with the posterior crest a
small style is indicated for P,.

P,, as well as being larger than P,, is more elongate and relatively
broader posteriorly. The anterior crest is strongly developed and

48 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

turns decidedly inward as it descends to join the prominent lingual
cingulum. Posterolingually the cingulum becomes shelf-like and de-
velops a slight crest as it turns outward and upward to join the well-
defined posterior crest of the primary cusp, often exhibiting a small
cuspule at the posterior extremity. P, would appear to be invariably
two-rooted in all the Wasatchian material observed, although in some
instances this could not be verified without damage to the specimen.
In the Bridger, however, with the noted shortening of the premolar
series, P, of H. paulus, while not infrequently two-rooted, is often
single-rooted and in many instances the roots are not completely fused,
showing prominent inner and/or outer grooves. In H. minusculus,
and upper Bridger H. lepidus as well, P. appears more frequently
two-rooted or deeply grooved. In larger H. despiciens of the upper
Bridger this tooth seems almost invariably single-rooted.

The anterior portion of P; is very much like P., but posterolingually
it shows development of a third crest to the cingulum. Progressively
this exhibits a marked flexure or rudimentary metaconid on its lower
part. In Wasatchian materials the posterolingual crest may be very
weak or absent and the indication of a metaconid relatively slight or
rare. In Bridger materials, however, this crest is generally much
better defined and the metaconid or flexure of the crest in this position
seems almost invariable, much lower on the tooth, however, than in P,.
Posteriorly P; shows a usually distinct but variably developed shelf or
talonid, turned upward at the posterior rim so that a small talonid
basin is developed lingual to the posterior crest of the primary cusp.
In some instances the talonid rim is slightly cuspate, in positions sug-
gesting the hypoconid and entoconid. Possibly this was more rarely
encountered in Bridgerian than in Wasatchian materials, as the devel-
opment of a talonid in the lower premolars suffered somewhat in the
shortening of the premolar series observed for the middle Eocene. It
may be noted, moreover, that P; as well as P, is invariably two-rooted.

P, is larger and relatively broader anteriorly than P;, with a some-
what stronger, often more lingually directed anterior crest. It is dis-
tinctive in the development of the metaconid which is high, relatively
lingual to the protoconid and generally well separated from it, giving
the greater part of the tooth a decidedly trigonid appearance. The
talonid is, as would be expected, better developed than in Ps, and there
is a prominent cusp where the posterior crest from the primary cusp
or protoconid joins the strong posterior cingular crest. These crests
form a better defined talonid basin lingually than in Ps, and generally
there is a slight cingular shelf both posteroexternally and anteroexter-
nally. It is interesting to note that within Wasatchian time there

NO. 4 A STUDY OF HYOPSODUS—GAZIN 49

appears to be progressive development of the talonid of Py, that in
general, but not invariably, exhibits a more elongate, cuspate condi-
tion in the Lost Cabin stage. In the Bridger the relative shortening of
the premolar series appears to have affected the talonid of P, perhaps
somewhat more, with respect to the earlier Eocene stages, than was
noted for P;. As a consequence there is a less clearly definable pos-
terointernal cusp in the position of an entoconid than is often so well
defined in the more elongate P, of the late Wasatchian Knight
materials.

The Hyopsodus lower molars are rather distinctive teeth with com-
paratively high conical cusps tending toward a selenodont pattern.
The trigonid portion consists essentially of two cusps, the protoconid
and metaconid in a distinctly oblique arrangement. These are con-
nected by a sharply descending or notched crest from the postero-
lingual wall of the protoconid. A similar crest from the anterior wall
of the protoconid turns sharply inward and downward, tending to
become nearly parallel to the posterior wall of the trigonid. In the
earlier stages of Wasatchian time this anterior crest on M,, and
occasionally on M,, may rise again lingually to join a small paraconid
placed high on the anterior slope of the metaconid. In the later stages
of the Eocene this anterior crest of the trigonid on M, and Msg is
directed a short distance anterolingually where generally it more
abruptly abuts the hypoconulid of the preceding molar to form a
somewhat better defined crest from the protoconid to the entoconid
of the talonid ahead.

On the talonid portion of the anterior lower molars the hypoconid,
which is about the same height as the protoconid, and the somewhat
lower entoconid also show a slightly oblique transverse arrangement.
The crests from the hypoconid, however, give this cusp a distinctly
selenodont appearance. The anterolingual crest, or crista obliqua,
extends directly to the metaconid, joining this cusp below its apex and
adjacent to the posterolingual crest from the protoconid. This leaves
a steeply descending crevice or valley to the outer margin of the tooth,
well separating the protoconid and hypoconid. The posterolingual
crest from the hypoconid extends directly to the anterolateral wall of
the prominent, conical hypoconulid a little below its apex. The hy-
poconulid rises from the cingulum distinctly posterior to a line
between the hypoconid and entoconid, closer to the entoconid and
posterolateral to it. The entoconid is usually a nearly circular cone
which may show a crest to the adjacent hypoconulid. These cusps
appear more strongly joined and often closer together in the late

50 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

Eocene, and in H. fastigatus the entoconid is comparatively large.
Anteriorly the entoconid is well separated from the metaconid where
the talonid basin opens lingually. The metastylid noted by L. Russell
(1965) for H. fastigatus is not uncommon in Bridger material, and
has been observed very weakly developed in certain Wasatchian speci-
mens. In the earlier materials there is also a tendency for a slight
cuspule to be formed on the anterior slope of the entoconid. A slight
cingular shelf is developed anteriorly on the molars, at least at the
anterior angles, and may be seen posteriorly rising to the hypoconulid
on either side. Also, though not always present, it may be slightly
crested or serrate externally between the protoconid and hypoconid.

M; differs from the anterior molars only in the character of the
talonid, which is more elongate and tapering, with a very large and
posteriorly projecting hypoconulid, usually better separated from the
hypoconid and entoconid, although it may form a crest with the
entoconid, more usual in the Wasatchian materials, although noted in
a specimen of H. fastigatus.

Deciduous upper premolars—Upper milk teeth have been seen or
recognized only in the Knight, upper Bridger, and Uintan materials.
The best preserved is a sequence of three, Dp’-Dp*, belonging to
H. lepidus (pl. 6, fig. 3). Dp? is a small, nearly triangular tooth with
anterior, posterior, and lingual crests. The anterior crest is straight
and terminates at the cingulum in a small stylar cusp. The posterior
crest is slightly flexed or notched near its lower extremity. The lin-
gual crest or angle is directed somewhat posteriorly and also may
show a very small style at its basal extremity. A weak cingulum is
exhibited anterolingually and externally. The posterolingual face of
the primary cusp is flat and relatively smooth to the basal margin.

In Dp? the primary cusp, though larger, is rather like that in Dp?
and externally they look very much alike, except for a more promi-
nent anterior style on Dp*. A correspondence to P* is noted in the
well-developed and crested deuterocone, but in Dp® the talon is decid-
edly askew. In contrast to the somewhat elongate outer portion the
distinctly basined talon is anteroposteriorly constricted and deflected
posterolingually. The anterior crest from the deuterocone extends as
the cingulum along the anterolingual margin of the tooth to the
anterior extremity where it joins the prominent, outward deflected
style.

Dp‘ is decidedly molariform and might easily be mistaken for M?.
It differs from M1, nevertheless, in being relatively a little narrower
transversely in comparison with the length of the outer wall, and the
lingual portion is also a little more constricted anteroposteriorly.

NO. 4 A STUDY OF HYOPSODUS—-GAZIN 5I

Moreover, both the lingual and labial cusps are somewhat compressed,
giving them a distinctly more acute appearance. The outer pair are
flattened transversely, whereas the compression of the inner pair fol-
lows the alignment of the crests. In the very limited material of
H. miticulus and H. lepidus the compression of the lingual cusps is
largely transverse, but in the upper Eocene this is more oblique as a
protoloph tends to form, and the hypocone, better separated from the
protocone, appears more as a high crest of the cingulum, but some-
times with a slight crest to the metaconule.

Deciduous lower premolars——Lower milk teeth have been observed
in the materials from all but the earliest and latest stages of the
Eocene. No doubt, however, they are as well represented as upper
deciduous premolars in the late Eocene collections. Dp, is evidently
two-rooted, from very limited evidence in the middle as well as early
Eocene. I have observed the tooth itself only in H. lepidus where it
is relatively small. It resembles larger P, in the same species, although
the primary cusp seems projected somewhat more forward than in the
permanent dentition, and the short anterior crest is notched for a
prominent style that is joined by the well-developed anterolingual
cingulum. There is a posterolingual as well as a posteroexternal crest
on the primary cusp and a slight posterior cingular crest.

Dp; in H. lepidus is very much like Dp, but larger and relatively
broader posteriorly, and the parastylid is defined more as a sharp
inward flexure of the anterior crest. The triangular posterior surface
of the primary cusp is essentially smooth with little or no evidence of
a cingular crest below. In H. miticulus (pl. 6, fig. 4), Dps is much
more elongate with a more prominent style relatively high on the
anterior crest. Posteriorly the two crests of the primary cusp appear
to converge upward a little below the apex and there is a slight median
crest, which below joins a better defined crest of the cingulum that
extends between the lower extremities of the outer and inner crests.
A Dp; seen of H. paulus is relatively short as in H. lepidus but the
posterolingual crest shows a prominent flexure in the position of a
metaconid about midway on its length. As in H. miticulus, the pos-
terior cingulum is more crest-like and there is a median cuspule on
the very small talonid.

Dps, as noted for Dp*, is distinctly molariform. It is, however,
more easily recognized by its slender elongate form, and is particu-
larly characterized in comparison with M, by the relative elongation
of the trigonid with its crescentic cusp arrangement. The anterior
crest from the protocone sweeps widely forward and inward to a well-
developed parastylid or paraconid, which, together with the posterior

52 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

crest to the metaconid, defines a trigonid basin broadly open lingually,
much as the talonid basin. The much smaller trigonid basin in M,
opens forward or may be closed. Dp,, moreover, is distinctly lower
crowned than M,, and its roots, of course, are better separated and
more divergent.

VERTEBRAE

Representation of a significant portion of the vertebral sequence is
preserved in only one specimen. This is an individual of Hyopsodus
paulus (USNM 23740). It includes the cervicals, an articulated series
of 23 dorsolumbars (pl. 13, figs. 1-3), a separate sacral portion of
four coalesced vertebrae, and the incomplete first two caudals. A
number of ribs are preserved but none are complete, and many were
isolated and not identified as to position. It would appear that the
tubercle and capitulum blended or became coalesced at about the
eleventh or possibly the twelfth position. Of the sternum only three
somewhat flattened and moderately elongate elements, from the mid-
section or mesosternum, were recognized.

Cervical vertebrae.—The cervical vertebrae are not short, but
although somewhat telescoped posteriorly they appear, nevertheless,
to decrease in length from the axis to the seventh. They are, for
example, not nearly so shortened as in the hedgehog but have relative
proportions more nearly as ina rabbit. A portion of the atlas vertebra
was preserved attached to the skull in USNM 23740, but the trans-
verse processes as well as the lower margin are missing. The top por-
tion of the arch is missing or incomplete in nearly all the cervical
vertebrae, but the third is seen to lack a spine; in an isolated seventh
of another individual there appears to be very little development of a
neural spine. Ventrally, however, there is a sharp median ridge or
hypapophysis on the axis to at least the fourth cervical vertebra.
Posteriorly this may be more subdued. The transverse processes,
where visible, appear extended fore and aft, with that for the third
projecting well forward beneath that of the axis, rather like Sylvilagus.
In the fourth and fifth cervicals there is suggestion in broken surfaces
of a separation posteriorly of the transverse process, above and below
the posterior opening of the good sized vertebrarterial canal, into dia-
and parapophyses. The upper of these appears to be short and knob-
like. In the sixth cervical the upper process is broken off but the
inferior lamella is extraordinarily developed, extending greatly fore
and aft (see pl. 13, fig. 1). This would suggest rather strong develop-
ment of the longus colli, which would correlate with the development

NO. 4 A STUDY OF HYOPSODUS—GAZIN 53

of the hypapophysis on the anterior cervicals mentioned above. The
bending of the neck implied would possibly add to the indication of a
rooting habit suggested by the relatively large I?. Much of the seventh
vertebra is obscured by crushing but the upper process, or transverse
proper, is outstanding and somewhat compressed or flattened obliquely.

Dorsal vertebrae-—No doubt the most interesting feature of the
dorsal or thoracic sequence is its number. This is found to be
twenty in the H. paulus specimen at hand. Although equalled in
certain rhinos and elephants, it is apparently exceeded only in the
hyrax and two-toed tree sloths among living land mammals.

The spines of the anterior dorsals appear to be decidedly elongate,
although the dorsal portion of much of this sequence is obscured in
the matrix by a closely appressed scapula. Beyond the eleventh
vertebra of the postcervical series the dorsal portions of the vertebrae
were exposed to weathering so that most of the neural arches are not
preserved. The facets for the tubercle of the ribs are deeply pocketed
and laterally outstanding on the transverse processes of the first two
or three vertebrae, and remain separate from the facet for the
capitulum at least as far as the tenth, or possibly eleventh. The facets
for the capitulum are clearly discernible on the ventrolateral margin
of the centrum, fore and aft, to a rib position between the 19th and
20th. The metapophysis may be first distinguished on about the third
dorsal. It is clearly evident as far as the sixteenth, but not preserved
beyond this point. The centrum in the dorsal sequence maintains about
the same length throughout. It is, however, decidedly shallow or rela-
tively flattened dorsoventrally, except that the anterior seven or eight
are somewhat more V-shaped, with a more pronounced median angle
or hypapophysis.

Lumbar vertebrae.—The number of lumbars in Hyopsodus is not
known, as the H. paulus series is incomplete following the third, or
twenty-third postcervical. These three lumbars have decidedly flat-
tened centra with a broad surface above forming the floor of the
neural canal and a weak median ridge or hypapophysis ventrally.
The transverse process on the first is very weakly developed but on
the second and third, though broken off, appears anteroposteriorly
elongate and directed noticeably downward. The neural arches are
not preserved.

Sacrum and caudal vertebrae.—The very poorly preserved sacrum
was found separate from the foregoing sequence, but of the same
individual. It includes four elongate, coalesced vertebrae, but the
first is not complete anteriorly so that the full number is not known.
The coalesced outer extremities on the left side show at least a part

54 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

of the sutural surface for the ilium, which tapers backward from
broad contact opposite the first to a position opposite the anterior part
of the third element preserved. The last sacral element exhibits small,
closely appressed postzygapophyses for articulation with the first
caudal vertebra. Only two caudals were preserved, evidently the first
and second, and these are badly damaged. Their length, however, is
seen to be a little less than that of the last sacral element. The trans-
verse processes are broken away, but the root portions suggest that
they were strongly developed. The centra are narrow and not nearly
so flattened as in the dorsolumbar region.

PECTORAL GIRDLE

Scapula.—Both scapulae, though rather poorly preserved, are in-
cluded in the materials of the H. paulus skeleton (USNM 23740; see
pl. 13, fig. 4). The size is a little larger than in the Douglass ground
squirrel, and like it has an unusually well-developed spine. The height
of the spine and its flare toward the ventral extremity are perhaps
relatively greater than in this squirrel. The scapula is only a little
shorter than in the European hedgehog but the spine is better de-
veloped throughout its length, and the acromion, though widely ex-
panded, apparently does not project so far downward, nor is the
metacromial process so elongate as in the hedgehog. The prescapular
fossa is moderately expanded and slightly convex, although the cora-
coid border is very poorly preserved and its outline was determined
largely by its impression on the rock matrix. The postscapular fossa
is narrow, concave and much obscured by the posteriorward deflection
of the crest of the spine. There is a very small coracoid process,
separated by a suture or possibly just a groove from the anteromedial
extremity or margin of the glenoid surface. The character of the spine
is quite unlike that in the hedgehog, or in the rabbit, and would sug-
gest relative importance of those portions of the trapezius and del-
toideus muscles that have here their insertions and origins respectively.
No doubt Hyopsodus had an active digging habit as well as rooting.

Clavicle-——An incomplete clavicle, presumably the medial portion
from the left side, shows a strong curvature and the extremity ex-
hibits an enlarged, outward facing rugose convexity. The shaft is
essentially trihedral with well-rounded angles, which becomes some-
what narrower just short of the rugose extremity. Unfortunately
neither the manubrium nor the tip of the acromion are preserved so
that the nature of these articulations cannot be described.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 55

HUMERUS

The Hyopsodus humerus, particularly as noted in a recently ac-
quired specimen of H. minusculus (pl. 11, fig. 2) has somewhat the
general form noted in Cvtellus, but the deltoid ridge, though less
outstanding, is very much longer, with its flattened and slightly rugose
distal prominence for the deltoid muscle somewhat beyond the middle
of the shaft. This crest is not nearly so short and sharply flexed as in
Erinaceus, nor does it exhibit anything like the knobby development
seen in the gophers. In its lengthy extent the deltoid crest is much like
that in Meniscotherium.

The proximal extremity, as seen in H. paulus (pl. 10, fig. 1), shows
an anterolaterally much extended greater tuberosity, more so than in
Citellus or Erinaceus, but much more constricted anteroposteriorly
than in these forms. The greater tuberosity, however, it not nearly so
well developed as in Meniscotherium. Presumably the supraspinatus
was inserted along the short low crest of the greater tuberosity, rela-
tively less significant than in Mentscotherium with the infraspinatus
posterior to it. A depression on the posterior surface of the greater
tuberosity, much like that in Meniscotherium, was assumed to be for
the teres minor but may have included insertion of the infraspinatus
above as well. The lesser tuberosity is not outstanding or projecting,
appearing as a somewhat flattened but well-developed scar for the sub-
scapularis, posteromedial to the head, adjacent to and at a sharp angle
with its articular surface.

The distal portion of the humerus, known for H. minusculus and
H. lepidus as well as for H. paulus (pl. 10, fig. 2) and H. walcottianus
(see Matthew, 1915b, fig. 10), is relatively broad, due largely to the
prominent inner condyle which exhibits a well-developed entepicon-
dylar foramen. The prominence of the inner condyle surely denotes
importance of the various flexor muscles of the carpus and digits
having origin there, further emphasizing a digging capability. The
outer condyle, for the extensors, etc., is less prominent but supports
a supinator ridge which extends proximally nearly a third of the length
of the shaft. The development of the supinator ridge is about as in
Erinaceus, but perhaps a little more sharply defined. It is less con-
spicuous and less laterally flaring than in Citellus. Its development also
is relatively a little less than in Meniscotherium. The trochlea, as in
Meniscotherium, has an outstanding medial margin anteriorly and
distally, and a posteriorly raised lateral margin which arises from the
more central convexity or capitulum of the trochlea as it extends
around toward the posterolateral side. This articular convexity for

56 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

the radius, on the anterior portion of the trochlea, seems more promi-
nent than in the hedgehog and much better defined than in the ground
squirrels and gophers. There is a broadly open supratrochlear
foramen, evidently as a consequence of the prominently projecting
anconeal process or anteroproximal margin of the sigmoid notch of the
ulna, which it accommodates in extension of the forearm.

RADIUS

An essentially complete radius is known for H. minusculus (USNM
24891, pl. 11, fig. 3) and extremities for various individuals of H.
paulus and H. lepidus (pl. 10, figs. 4 and 5). The shaft is seen to be
relatively slender and slightly curved, increasing somewhat in diameter
distally. The more slender proximal portion shows little or no evidence
of a bicipital tuberosity, although there is a slight crest developed in
this position on the Meniscotherium radius. The more distal portion
of the shaft is rather flattened and the crest for the interosseous mem-
brane is but weakly developed.

The proximal extremity shows an oval to nearly bilobed surface
(pl. 10, fig. 4) for the trochlea of the humerus, which is deeply con-
cave posterolaterally for the capitulum and the anteromedial portion
is markedly deflected distally. The latter flexure participates with the
coronoid portion of the sigmoid notch of the ulna in articulating
against the prominent medial flange of the trochlea. The sigmoid
profile of the proximal surface is much more pronounced than in either
Erinaceus or Citellus, being more as in Meniscotherium although not
so elongate.

The distal extremity is relatively rounded and the articular surface
shows facets for the scaphoid and lunar and a low anteromedially
placed styloid process. The anterior surface exhibits a broad, shallow
groove for an extensor tendon, presumably the extensor digitorum
communis, which is bound laterally by a short but distinctive ridge
deflected toward the ulna and defining a sharper groove close to the
flattened surface of articulation with the ulna. This small, sharper
groove may well be for the tendons of an extensor digitorum lateralis
and an extensor indicis. The posterior surface of the distal extremity
is more evenly rounded. The grooves and ridge on the anterior sur-
face are much as in Meniscotherium, but possibly less pronounced on
the relatively somewhat more enlarged distal extremity of the Meni-
scotherium radius. The distal extremity, particularly the articular
surface, has little or no resemblance to that in Erinaceus.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 57

ULNA

The forearm in Hyopsodus, as in Meniscotherium, is relatively
short in comparison with the length of the humerus. The total length
of the ulna is actually a little less than that of the humerus. The
Hyopsodus ulna, known in H. minusculus (pl. 11, fig. 3) and H.
lepidus, as well as in H. paulus (pl. 10, fig. 3) and H. walcottianus, is
surprisingly like that in Meniscothertum, except for somewhat greater
curvature. Proximodistally the posterolateral margin of the ulna is
more convex through the greater part of the length, and the distal third
of this margin is a little more concave. As in Mentscotherium, the
shaft is flattened in an anterolateral-posteromedial direction and main-
tains a distinctive width distally with only a slight taper. In Erinaceus
and Citellus the shaft of the ulna is more slender and tapering distally,
as well as relatively much longer. The distal crest defining the in-
terosseous membrane medially is similarly developed, and on the lateral
surface the shaft shows the elongate median concavity and the pos-
terior bounding crest much as in Meniscotherium, which are con-
sidered related to extensors of the more median digits.

The proximal extremity has a well-developed olecranon with an
expanded rugose surface for the triceps insertions. Moreover, the
length of the olecranon gives good leverage for these extensors of
the forearm. The development of the olecranon is rather like that
in Erinaceus, as well as Meniscotherium, better developed than in
Citellus. The sigmoid notch also shows resemblance to that in the
hedgehog, but is possibly a little more convex transversely, with the
articular surface extending a little farther proximomedially, More-
over, the aconeal process is much more protruding.

The distal extremity is moderately expanded from the narrowest
part of the relatively wide shaft and shows a prominent styloid
process (missing from USNM 23740 shown in pl. 10, fig. 3) which is
the extremity of a small distolaterally directed, anteriorly flexed, semi-
cylindrical form articulating with the cuneiform and pisiform of the
carpus. In Meniscotherium the somewhat cylindrical articular surface
is straighter and relatively blunter, whereas in Erinaceus it is more
saddle-shaped, with the articulating surface extending well out onto
the lateral surface of the styloid process. The inner surface of the
distal extremity is somewhat flattened to slightly concave, whereas the
outer or anterolateral surface is more generally convex, with a distinct
groove extending down toward the styloid process. This groove may
be for the tendon of an extensor carpi ulnaris. A weaker, more medial
groove would appear to combine with that of the radius suspected

58 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

above as conducting the tendons of the extensor digitorum lateralis
and extensor indicis.

MANUS

The Hyopsodus fore foot is known from material representing three
of the Bridger species; H. paulus (USNM 23740; pl. 10, figs. 9-12),
H. lepidus (AM 11959; pl. 10, figs. 6-8), and H. minusculus (USNM
24891; pl. 11, fig. 3). The carpals, unlike the tarsals, show a certain
amount of overlap, about to the extent seen in Meniscotherium.
They show perhaps slightly less compression proximodistally, but are
not so elongate as in the phenacodonts. The lunar is separate from
the scaphoid and there is no central. Articulation of the fore foot
with the radius and ulna reveals that in a normal arrangement of the
elements of the fore arm and foot the palm is turned somewhat in-
ward rather than strictly pronate. No doubt considerable flexibility
was achieved in the fore limb and foot. A tendency toward supination
was noted also for Meniscotherium (Gazin, 1965, p. 20).

Scaphoid.—The scaphoid is one of the moderately large elements of
the carpus. It is proximodistally short as in Meniscotherium, but the
proximal surface has a more projecting convexity for articulation with
the radius. Ventromedial to the radial articulation the scaphoid pro-
jects prominently ventrad. Its distal surface, except toward the
dorsomedial margin, is somewhat less inflected, although showing
definable facets for the trapezium and trapezoid. The distomedial
portion of the scaphoid, in its more dorsal part, shows a small but
conspicuous projection toward the magnum, which exhibits an oblique,
triangular facet for articulation with the latter element. This process,
though evidently always present, varies somewhat in size between in-
dividuals, and, as noted in Mentscotherium, is in the position of a cen-
tral, were this element separate. Laterally the scaphoid articulates
broadly with the relatively small lunar.

Lunar.—The lunar is comparatively narrow and much shorter
dorsoventrally than the scaphoid. Its dorsal extremity is of moderate
depth, about comparable to the scaphoid and cuneiform, but ventrally
it rapidly becomes much thinner proximodistally. Its proximal surface
is slightly convex dorsoventrally and the oblong or nearly rectangular
facet for the radius covers essentially the entire surface of the lunar.
Medially the lunar appears somewhat triangular to slightly arcuate
with this surface evidently articulating for most if not its entire
length with the scaphoid. The lateral surface is similarly triangular,
slightly concave and articulates proximally with the cuneiform. More

NO. 4 A STUDY OF HYOPSODUS—GAZIN 59

distally the surface is tilted somewhat for articulation with the proxi-
momedial margin of the unciform. The distal surface has a slightly
lateral tilt and articulates with the magnum. This articulation is a
little constricted dorsally by the distolateral projection of the scaphoid.

Cuneiform.—The cuneiform is an elongate, somewhat bilobate
structure, nearly as large as the scaphoid. The greater part of the
proximal surface medially has a transversely elongate and dorsoven-
trally decidedly concave articular surface for the ulna. Ventral and
parallel to this there is a transversely elongate and slightly convex sur-
face, more ventrally oriented, for articulation with the pisiform.
Lateral to these the cuneiform projects prominently ventrad. The
dorsoventrally convex medial extremity of the cuneiform articulates
with the more proximal portion of the lunar for the entire length of
the latter. The greater portion of the distal surface of the cuneiform,
except for the ventrolateral prominence, shows a relatively large,
gently concave articular facet for the unciform. The cuneiform shows
a striking resemblance to that in Meniscotherium, but appears a little
less flattened and relatively not so deep dorsoventrally.

Pisiform.—The pisiform is relatively large, much the largest ele-
ment in the carpus. Its broad anterior extremity shows a large con-
cave facet for the ulna above and a transversely elongate and slightly
concave facet for the cuneiform below. The shaft is elongate and
the ventral or posterior extremity is much enlarged. Both, however,
are somewhat compressed transversely relative to the anterior portion.
The length of the shaft and the vertical expansion of the ventral or
posterior extremity surely denotes importance for such muscles as the
flexor carpi ulnaris which would have insertion above and the abductor
digiti quinti with origin below, for flexing and abducting at least the
outer part of the manus.

Trapezium.—The trapezium is known in only two specimens, one
of H. paulus and the other of H. lepidus. It is an irregularly shaped
bone, relatively much less compressed transversely than in Ments-
cotherium, but fairly deep dorsoventrally on its medial surface,
although narrowing ventrally. The proximal surface which articulates
with the medial portion of the scaphoid is dorsoventrally elongate and
appears to turn slightly distal ventromedially, below which the bone
projects more ventrally than in Meniscotherium. The distal articular
surface for the first metacarpal is somewhat broader ventrally and
generally concave dorsoventrally, except along the posterior margin
where it is slightly recurved, and turns to meet the converging proxi-
mal surface.

60 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

Trapezoid.—A single known trapezoid, belonging to H. lepidus, is
seen to be relatively short proximodistally, except on the dorsal surface
where a prominent lip is projected distally over the proximal extremity
of the second metacarpal. The proximal surface of the trapezoid,
which articulates with a more lateral portion of the scaphoid, is
triangular in shape, with its broad arcuate margin dorsal, and gently
concave dorsoventrally. The distal surface is also triangular and con-
cave dorsoventrally, but noticeably convex transversely. The medial
and lateral surfaces for articulation with the trapezium and magnum,
respectively, are proximodistally narrow and posteriorly convergent.

Magnum.—The magnum is a rather distinctive bone and has been
figured separately (pl. 10, fig. 6). It is a relatively narrow and highly
arched element with its short proximal and somewhat dorsally facing
surface divided by a longitudinal ridge. Medially this surface is
touched by the distolateral projection from the scaphoid and laterally
by the lunar. The lateral surface of the magnum is essentially quad-
rilateral in outline and anteriorly it shows its articular facet for the
unciform. The medial surface of the magnum, however, shows along
its distal and greater part an elongate somewhat concave surface for
its articulation with the lateral margin of the base of the second meta-
carpal. The more proximal contact of the medial surface, with the
lateral margin of the trapezoid, is more restricted dorsoventrally. The
distal surface for articulation with the third metacarpal is relatively
narrow and elongate, covering almost the entire length of the bone. It
is concave dorsally and slightly convex ventrally. Though much like
that in Meniscotherium, the magnum appears to be relatively a little
less extended ventrally.

Unciform.—The only unciform recognized in the Hyopsodus ma-
terials is incomplete laterally, but is evidently one of the larger ele-
ments of the carpus. The proximal surface for articulation with the
cuneiform is overall convex, reaching its highest point medially near
the narrow facet along the medial margin for the lunar. The unciform,
however, is relatively not so deep medially as in Meniscotherium and
the proximal and distal surfaces do not seem to converge so sharply
laterad. The distal surface is large, dorsoventrally concave, with little
or no separation showing for articulations of the fourth and fifth
metacarpals. The concavity, however, is not so strong as in Menitsco-
therium. The medial surface shows dorsodistally an oblique or some-
what laterally deflected facet tapering ventrally for the outer margin
of the base of the third metacarpal. Proximal and in part more
ventral to this is the larger facet for contact with the magnum.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 61

Metacarpal I—The first metacarpal is the smallest of the five, being
a little less than half the length of the third. The proximal extremity
is dorsoventrally constricted but relatively broad. It does not show
any smooth or clearly defined facet externally for the base of the
second metacarpal, but the proximal surface for articulation with
the trapezium is dorsoventrally very convex and somewhat saddle-
shaped, with a knob-like lateral portion. Evidently articulation with
the trapezium was highly flexible. The shaft of this element is slender
and the distal extremity narrow and oblique with a noticeable taper
medially.

Metacarpal II.—The second metacarpal is about equal to the fourth
in length and about 85 percent of the length of the third. The proxi-
mal extremity or base is moderately deep and obliquely truncate ven-
trally. The surface for articulation with the trapezoid is gently convex
dorsoventrally and distinctly concave transversely. The upturned
proximolateral margin shows an elongate facet for the magnum.
This facet faces proximolaterally and is somewhat tapering ventrally.
Distal to the facet for the magnum the base of the second metacarpal
is deeply concave for articulation with the proximomedial portion of
the base of the third metacarpal. The shorter medial margin of the
base of the second metacarpal is arcuate but not clearly faceted for
the first metacarpal. The shaft of the second metacarpal is sturdy
and broadens somewhat distally to the distinctly wider distal extremity.
The distal extremity is deep, prominently keeled ventrally and slightly
tapering medially.

Metacarpal III.—The proximal extremity of the third metacarpal,
the longest of the five, is dorsally broad, moderately deep, and the
ventral margin is truncated at about a right angle with the relatively
straight medial margin. The proximal surface for articulation with the
magnum and the concavity in the base of the second metacarpal is
nearly rectangular, convex dorsally, and very slightly concave ven-
trally. Transversely the portion of the surface for the magnum is
weakly concave. The surface in general is decidedly oblique to the
long axis of the shaft, having a distomedial slope. The base of the
third metacarpal projects strongly laterad in its more dorsal part,
exhibiting an oblique, ventrally tapering facet for articulation with the
unciform. Distal to this the lateral surface of the base is deeply
concave for articulation with a portion of the proximal surface of the
base of the fourth metacarpal. The shaft of the third metacarpal
broadens distally and the distal extremity is moderately deep, ventrally
keeled and without taper laterally or medially.

62 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

Metacarpal IV.—The fourth metacarpal has about the size and
sturdiness of the second, but because of the manner in which the prox-
imal extremities tend to overlap laterally, the fourth extends distally
a little more than the second, but not so far as the third. The proximal
extremity is broad dorsally and somewhat narrower ventrally, and
has a little less depth dorsoventrally than the third metacarpal. The
proximal articular surface is rather generally convex, more so dorso-
ventrally, and with but slight distinction between the surface for the
unciform and that for the lateral concavity in the base of the third
metacarpal. The portion of the surface for the unciform is broader
dorsally and that for the third metacarpal appears to be of rather
uniform width. The base of the fourth metacarpal, somewhat as
in the second and third, is deeply concave laterally, with an arcuate
distolaterally facing concave facet for the base of the fifth metacarpal.
As with the second and third metacarpals, the shaft broadens distally
to a relatively wide distal extremity which shows a moderately deep,
ventrally keeled articular convexity which has a noticeable taper
laterad.

Metacarpal V.The fifth metacarpal is about three quarters as
long as the fourth, but is a little larger and much more robust distally
than the first. The proximal extremity is relatively broad transversely
and decidedly convex dorsoventrally. The transversely broader
lateral portion of the proximal articular surface, which makes con-
tact with the unciform, is about as deep medially as the lateral margin
of the base of the fourth metacarpal but tapers abruptly laterad. The
more medial surface for the concavity in the base of the fourth meta-
carpal is distomedially oblique, more convex and less extended than the
outer. The distal extremity is only a little smaller than that in the
fourth metacarpal and the articular convexity tapers laterally a little
more.

Phalanges.—Identification of the various phalanges (pl. 10, fig. 12)
as to position is very tentative, although there would appear to be
some evidence to suggest that those with the relatively broader and
dorsoventrally shallower proximal extremities belong to the fore foot.
Iam unable, however, to distinguish phalanges belonging to the second
digit on one side from those of the fourth digit on the opposite side.
The proximal phalanges of digits II to IV appear to be approximately
two-thirds the length of the corresponding metacarpal, and the second
phalanges in turn are about two-thirds the length of the first. In the
first digit it may be noted that the proximal phalanx is nearer three-
fourths the length of the metacarpal. Each becomes a little narrower
and shallower distally. The distal phalanges, unlike those of Menis-

NO. 4 A STUDY OF HYOPSODUS—GAZIN 63

cothertum, are transversely compressed and decidedly unguiculate.
Allocation of the shorter distal phalanges to the fore foot is highly
tentative and based on their lesser depth dorsoventrally, although the
first and second phalanges, unlike the metacarpals, are slightly longer
than in the hind foot.

PELVIC GIRDLE

Significant portions of the Hyopsodus innominate bone have been
observed only in H. paulus (pl. 13, fig. 5), included in skeletal ma-
terials of two individuals (USNM 17980 and 23740). As previously
recorded (Gazin, 1965), this structure is elongate and slender. The
ilium shows the arcuate and flaring dorsal margin as in Menis-
cotherium, but the gluteal or outer surface may be a little less concave.
The anterior extremity is missing in the material at hand. The base or
posterior portion is a little less trihedral in cross section, with the
pubic border of the ilium much more subdued than in Menisco-
therium. There is little or no evidence for an iliopectineal eminence on
the pubic border, which is weakly developed in Meniscotherium. As
in the latter the acetabular border dominates as the inferior margin of
the ilium, and the anterior inferior spine of human anatomy on the
acetabular border, immediately anterior to the acetabulum, which
supports origin of the rectus femoris, is surprisingly well developed.
The rectus femoris acts through the patella as an extensor of the leg,
with comparatively low leverage as a flexor of the hip, permitting a
strong thrust, such as in saltation, although the short limbs do not
suggest the latter as a habit. This process for the rectus femoris is
prominently developed in lagomorphs, particularly Brachylagus, and in
squirrels. In contrast it is scarcely evident in Erinaceus.

The ischium is slender but possibly a little less elongate than in
Meniscotherium, although not nearly so short as in Erinaceus. The
ischial spine is moderately developed and markedly rugose along its
superior margin anterior to the apex, and seems relatively a little
larger than in Meniscotherium. This may have afforded origin for
one of the abductors of the thigh. The ischial tuberosity and the in-
completely preserved ramus of the ischium are prominently developed,
supporting origin for various flexors and abductors of the leg. Much
of the pubic bone is also missing but, as indicated by the preserved
portion, this element is distinctly slender. The cotyloid notch in
the acetabulum for the ligamentum teres is constricted but directed
along the ischium much as in Mentscotherium.

64 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

FEMUR

Femora of Hyopsodus are known principally from material of
H. paulus (pl. 12, figs. 1 and 2), although fragmentary portions were
found in the immature material of H. lepidus included in this study.
The straight or but slightly curved Hyopsodus femur is slender and
elongate and the shaft somewhat flattened anteroposteriorly throughout
the greater part of its length. The proximal extremity appears trans-
versely narrow in comparison with the sturdier but rather similar
Meniscotherium femur, as the head and slender neck do not extend
medially so noticeably. The head is well rounded, more nearly spher-
ical than in Meniscotherium, and the fossa for the ligamentum teres is
centrally located, rather than marginal as in that genus. The greater
trochanter, for insertion of a portion of the gluteus muscles, is
prominent but relatively less robust than in Meniscotherium and does
not project proximally beyond the head. The digital or trochanteric
fossa, for insertion of the obturator muscles, is deeply excavated but
is not so elongate as in Meniscotherium, and the trochanteric ridge
extends to a more proximal position relative to the lesser trochanter.
The lesser trochanter is not preserved in any of the Hyopsodus speci-
mens at hand but the character of its basal portion suggests prominent
though less elongate development than in Meniscotherium. The third
trochanter is well developed on the compressed outer margin of the
shaft of the femur and is surprisingly distal in position. It appears as
a somewhat elongate, flattened projection of the outer crest, at least
midway on the length of the shaft or slightly beyond. This position is
much as in Meniscotherium, or perhaps a little more distal, and gives
considerable leverage to the superficial gluteus for abducting the limb,
and together with others, as the iliopsoas inserted on the lesser tro-
chanter, in flexing the hip joint.

The distal extremity of the Hyopsodus femur is poorly preserved in
all specimens at hand, except for a fragment associated with the
type-material of “Lemuravus’’ distans. It shows a striking resemblance
to that in Meniscotherium but the patellar groove may be relatively a
little broader.

The femur in a general way resembles that in Erinaceus, particularly
in the relatively flattened appearance of the shaft. The latter, however,
is somewhat more curved and becomes relatively broader distally. The
proximal portion in Erinaceus is narrower with the greater trochanter
closer to the head. The trochanteric fossa is much shallower and more
medially placed. The outer crest-like margin of the shaft is moderately
projected into a decidedly elongate third trochanter, much more

NO. 4 A STUDY OF HYOPSODUS—GAZIN 65

proximal in position than in Hyopsodus. Distally the pateller groove
is very much broader than in Hyopsodus.

TIBIA

A nearly complete tibia is known for H. paulus (USNM 23740,
pl. 12, fig. 5), as well as the distal portions (Gazin, 1965) for this
species and H. walcottianus. As noted for Meniscotherium, the
Hyopsodus tibia is a little shorter than the femur, not ‘considerably
longer” as believed by Matthew (1909b, p. 516). It is relatively
slender and only slightly curved forward. The proximal extremity of
the tibia exhibits the two subequal articular surfaces complete only
in a tibial fragment belonging with the type-material of “Lemuravus”
distans (=H. paulus). The medial, somewhat smaller surface, proxi-
mal to the greater part of the shaft, is relatively flat for the most part,
though slightly concave transversely toward the spine, but the larger,
outer condylar surface is decidedly convex anteroposteriorly. Be-
tween the articular surfaces for the femur, the spine of the tibia or
intercondyloid eminence is prominent anteriorly, but otherwise dam-
aged. The outer portion of the proximal extremity extends a consider-
able distance lateral to the shaft, and distolateral to the outer condylar
surface is the anteroposteriorly somewhat elongate surface for the
fibula. Laterally this surface is transversely convex but closer to the
shaft it becomes concave or groove-like on the distal surface of the
head. The proximal extremity closely resembles that in Menisco-
therium but is a little less developed anteroposteriorly.

The proximal portion of the shaft is somewhat compressed trans-
versely, but more rounded distally. In Meniscotherium the proximal
half of the shaft is relatively deeper anteroposteriorly and transversely
more flattened. Except for the transversely flattened proximal portion
of the shaft, the Erinaceus tibia, with its co-ossified fibula, bears little
resemblance to that in Hyopsodus. The cnemial crest in Hyopsodus
is comparatively low proximally, more so than in Meniscotherium, but
roughened where the ligamentum patellae would be attached. It
shows, nevertheless, increasing prominence distally toward the middle
of the shaft. Its two surfaces would likely be involved in a complex
of muscles medially and laterally, its more distal prominence possibly
significant for the biceps femoris and might correlate with the de-
velopment of the ischial tuberosity. Perhaps the sartorius also ex-
tended this far on the medial side. Farther distally the crest becomes
much subdued as it extends toward the internal malleolus. The medial
surface of the shaft is gently convex anteroposteriorly throughout its

66 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

length. The lateral surface, however, has a broadly convex rib prox-
imally which, as support for the interosseous membrane, becomes
sharply acute in the midsection, but continues somewhat more bluntly
again toward the distal extremity. In Meniscotherium this crest is
acutely developed for the entire length.

The distal extremity of the Hyopsodus tibia is represented in H.
paulus and H. lepidus, as well as H. walcottianus. The distal articu-
lar surface is an oblong or nearly oval-shaped surface decidedly
oblique to the long axis of the shaft, although possibly not so much
so as in Meniscotherium. It is gently concave anteroposteriorly across
its short diameter, and transversely it is broadly concave toward the
inner malleolus and unflexed to but very weakly convex in the lateral
part. Unlike Meniscotherium there is almost no ridge for a trochlea
of the astragalus. The medial malleolus extends distally a little beyond
the articular surface for the astragalus. The medial surface of the
distal extremity is irregularly flattened, whereas the lateral surface
is more acute, representing the distal end of the ridge for the interos-
seous membrane. Unlike Meniscotherium, however, a facet for the
fibula is not clearly defined.

FIBULA

The fibula is known in only three specimens of H. paulus. One of
these (USNM 23740; pl. 12, fig. 5) is essentially complete. It is a
fairly straight, rather slender and fragile appearing bone with much
expanded extremities. The proximal extremity is decidedly flaring,
relatively more so than in Meniscotherium, with an anterodistally ex-
tending ridge prominently developed. It is suggested that because of
its prominence that possibly some part of the biceps femoris above may
have been inserted here, as well as the collateral ligament. Antero-
externally the prominence no doubt included origin of the peroneus
longus, and medially the tibialis posterior. Proximomedially the ex-
tremity exhibits a somewhat elongate and transversely recurved sur-
face for its articulation with the tibia. In lateral view the line of con-
tact of this surface with the external condyle of the tibia is noticeably
oblique and behind it there is a posteriorly directed knob, less promi-
nent, however, than the anterior flare. Presumably a strong soleus
muscle had its origin on the outer portion of this knob. The medial
surface distal to the articular surface is slightly convex anteropos-
teriorly with but weak indication of a crest for the interosseous mem-
brane. The external surface of the proximal extremity is distinctly
concave between the anterior and posterior prominences.

NO. 4 A STUDY OF HYOPSODUS—GAZIN 67

The distal extremity of the fibula is expanded, but somewhat less
so than the proximal extremity, more nearly comparable in relative
size to that in Meniscotherium. It shows an anteroposteriorly broad
external malleolus and an oblique surface for the astragalus. The
lateral margin of the distal surface is turned outward, evidently for
some articulation with the calcanium, but this marginal facet tends
to be anteroposteriorly convex rather than concave as in Menisco-
therium. The lateral tubercle of the malleolus, that bounds the groove
for the peroneus longus anteriorly, is prominent but somewhat more
posteriorly directed than in Meniscotherium, and the peroneal groove
though narrower is deep and well defined. The medial surface of the
distal extremity is rounded and slightly roughened proximal to the
astragalar facet and there is no evidence of a facet for the tibia.
In Erinaceus it may be noted that the fibula is ankylosed to the tibia
for about half its length, even more so in the rabbit, and in the ground
squirrels there is a fairly lengthy adhesion.

PES

The hind foot structure is known from materials of H. paulus (pl.
12, figs. 4, 6-12) and H. lepidus, as well as H. walcottianus. The
tarsals have the distinctly serial arrangement of the condylarths, such
as in Phenacodus, Meniscotherium, and Tetraclaenodon, not over-
lapping as in the arctocyonids, nor anything like the “taligrade” struc-
ture seen in the tillodonts. The hind foot is very much like that in
Meniscotherium, except for much less reduced first and fifth meta-
tarsals, and the decidedly unguiculate distal phalanges.

Astragalus—The astragalus (pl. 12, fig. 8) has a moderately
elongate neck, perhaps a little less oblique than in Meniscotherium,
and a transversely broad, well-rounded head for articulation with
the navicular. Laterally the head may make contact with the cuboid
but this must be very slight. Matthew (1915b) described an astragalar
facet on the cuboid (see p. 69); such an articulation, however,
is not evident on the head of the astragalus. Perhaps the most dis-
tinctive feature of the Hyopsodus astragalus is the absence of any
appreciable trochlear groove on the surface for articulation with the
tibia. Medially this surface is not raised into a crest but is gently
rounded onto the adjacent portion of the medial surface, which makes
a very obtuse angle with the dorsal tibial surface. Likewise the lateral
margin of the trochlea is not raised as a crest but makes a sharp 90°
angle with the outer surface that articulates with the external mal-
leolus of the fibula. The distoventral angle of the surface for the

68 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

fibula projects prominently laterad. This supports the distolateral
extension of the ectal facet on the ventral surface of the astragalus.
The ectal facet, laterally on the ventral surface of the body of the
astragalus, is obliquely elongate and deeply concave, and the rela-
tively large oval sustentacular facet on the ventral surface of the neck
is somewhat convex. Between these the groove for the interosseous
ligament is deeply impressed. This terminates posteromedially in the
ventral aperture of the astragalar foramen. The groove on the
posterior margin of the astragalus for the flexor hallucis longus is
broad and well defined and terminates above at the dorsal aperture of
the astragalar foramen, in an indentation of the posterior margin of
the tibial facet.

Calcaneum.—The calcaneum (pl. 12, fig. 10) is moderately elongate
and the posterior portion, beyond the astragalar condyle, comprises
about half the length of the bone. The shaft of the posterior portion
is transversely compressed anteriorly but broadens posteriorly to a
knob-like tuberosity. The posterior surface of the tuberosity is
dorsoventrally convex and transversely somewhat oblique. Excellent
leverage is afforded the tendo calcaneus (Achilles) in extending the
foot. Anterior to about the midpoint of the calcaneum the astragalar
condyle is situated diagonally across the dorsal ridge with its convex
articular surface facing anteromedially and somewhat dorsally. This
condyle does not project dorsally from the superior ridge so much as
in Meniscotherium. A narrow convex facet along the anterodorsal
margin of the astragalar condyle articulates with the distal extremity
of the external malleolus. A decidedly prominent peroneal tubercle
projects laterally from near the end of the ridge extending forward
from the anterolateral extremity of the astragalar condyle. Ventral
to this the groove for the peroneus longus is relatively broad and
well defined. The sustentaculum, medial to the astragalar condyle and
somewhat more anterior in position, extends prominently mediad. It
appears relatively a little more expanded anteroposteriorly than in
Meniscotherium, but not nearly so thick dorsoventrally. It exhibits a
slightly concave, oblique oval facet for the astragalus, facing antero-
dorsal and somewhat medial. The posteroventral surface of the sus-
tentaculum is smooth and broadly grooved for continuation of the
extensor hallucis longus. The articular surface on the anterior or
distal extremity of the calcaneum, for articulation with the cuboid is
more rounded, not so concave dorsoventrally and a little less oblique
than in Meniscotherium.

Navicular—The Hyopsodus navicular (pl. 12, fig. 9) is short
proximodistally and the proximal surface is deeply concave for articu-

NO. 4 A STUDY OF HYOPSODUS—GAZIN 69

lation with the head of the astragalus. The dorsal and medial margins
are evenly rounded and ventromedially the rim of the proximal con-
cavity rises to an acute process, relatively lower, however, than in
Meniscotherium. The lateral surface is more nearly straight and
shows an oval facet for articulation with the cuboid, extending up
on a low ventrolateral process of the proximal margin. The ventral
surface is notched for the tendon of the posterior tibialis, bounded
laterally by a small ventral knob. The distal surface of the navicular
is faceted for articulation with the cuneiforms. The medial portion
of the distal surface is generally convex, somewhat triangular in out-
line and articulates with the internal and middle cuneiforms. There
does not appear to be any distinction or separation of the areas for
these two. The surface for the external cuneiform, however, is
slightly tilted proximally from the more medial surface. It is gently
convex and more elongate dorsoventrally, and meets the lateral articu-
lar surface for the cuboid at a little less than a right angle.

Cuboid.—The cuboid (pl. 12, fig. 11) is a relatively elongate bone,
possibly less so than in Meniscotherium, but with more of the dorsal
surface exposed proximodistally. The proximal or calcaneal surface
is nearly oval but with a short, straight medial margin. The surface
is noticeably convex and distolaterally sloping, although not so much
so as in Meniscotherium. The distal articular surface is nearly tri-
angular or somewhat trilobed. The larger portion for the fourth
metatarsal, which includes the two more median lobes, is gently con-
cave dorsoventrally. The outer, more abbreviated area for the fifth
metatarsal is nearly flat and has a more proximal slope ventrally.
Both may show a short upward deflection at the ventral margin, sug-
gesting sharp deflection of the lateral digits. Ventral to these facets
the transversely directed peroneal groove is very deeply impressed,
partially covered ventrally by a distally extending flange from about
midway on the cuboid. This flange, however, is not nearly so rugged
as in Meniscotherium. The medial surface of the cuboid shows two
somewhat oval shaped facets broadly joined at a very obtuse angle.
The more proximal of these articulates with the navicular and forms
about a 90° angle with the calcaneal surface. Possibly it was this
facet for the navicular that Matthew (1909b, p. 516) thought articu-
lated with the astragalus, but this clearly does not happen in an articu-
lated foot of H. paulus at hand. The more distal of the two facets on
the cuboid, about midway on the medial surface, articulates with the
proximal portion of the lateral surface of the external cuneiform.
Two very small facets at the distal extremity of the medial surface of
the cuboid also make contact with the external cuneiform.

7O SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

Internal cuneiform.—The internal cuneiform (pl. 12, fig. 12) isa
proximodistally elongate and transversely flattened bone, with its
proximal portion in medial view a little narrower than the distal.
The proximal extremity shows a narrow and longitudinally concave
surface for articulation with the ventromedial portion of the navicular.
This surface, moreover, is not so oblique or dorsally oriented as in
Meniscotherium. The more elongate distal surface for articulation
with the first metatarsal is also slightly concave but in a more nearly
transverse direction. Most of the proximal half of the broad lateral
surface is faceted for the middle cuneiform, but more distally I see no
facet or evidence of an articulation with the second metatarsal.

Middle cuneiform.—The middle cuneiform is the smallest of the
tarsal elements. It is proximodistally short and transversely narrow
but with evidently a somewhat longer dorsoventral dimension. The
quadrilateral dorsal surface is almost square except for the somewhat
longer medial margin. The proximal and distal surfaces are dorso-
ventrally concave, but that for the navicular is more elongate and
shows an upturned ventral extremity. The distal surface for the
second metatarsal is broad dorsally but narrower and more rounded
ventrally. It is also very slightly convex transversely. The medial
surface shows an elongate, somewhat bilobed articular surface for
the internal cuneiform, extending obliquely from the proximoventral
angle to near the dorsodistal angle of the surface. On the lateral sur-
face there is a narrow facet, somewhat deeper dorsally, along the
proximal margin for articulation with the external cuneiform.

External cuneiform.—Of the two cuneiforms recognized, neither
that for H. walcottianus nor that in the immature materials of H. lepi-
dus are complete ventrally. The bone is much deeper proximodistally
than the middle cuneiform. The proximal surface for the navicular is
relatively broad and flat dorsally, but not represented ventrally. The
distal surface that articulates with the third metatarsal is elongate
and concave dorsoventrally. Its dorsal portion is transversely broad,
but about midway ventrad the surface is markedly constricted by a
lateral indentation. The medial surface is narrowly faceted along the
proximal margin for contact with the middle cuneiform and immedi-
ately distal to this the surface is rather deeply pocketed. Close to the
distal margin the medial surface shows two separate facets for lateral
surfaces on the head of the second metatarsal. The lateral surface of
the external cuneiform shows a large facet proximally for contact
with the cuboid, and distally at the extreme dorsal and ventral angles
are small facets, the ventral of which articulates laterally with the
proximal extremity of the fourth metatarsal. The other facet is dorso-

NO. 4 A STUDY OF HYOPSODUS—GAZIN 71

ventrally convex and seems to contact both the fourth metatarsal and
the middle cuneiform.

Metatarsal I—The first metatarsal though small is probably more
than half as long as the second. The proximal extremity shows a
broad and dorsoventrally convex articular surface for the internal
cuneiform. The base is somewhat expanded laterally and shows a
large rugose area but no facet for articulation with the second meta-
tarsal. The shaft is stout but tapers distally, and the ventral surface
is decidedly concave longitudinally. The distal extremity is slightly
enlarged and relatively deep dorsoventrally. The distal articular sur-
face is well rounded, keeled ventrally, and noticeably tapering medi-
ally. Moreover, the distal margin in dorsal view is distinctly oblique
to the long axis of the shaft.

Metatarsal II —The second metatarsal, as noted in H. walcottianus,
is only very slightly shorter than the third but does not project so far
distally because of the proximodistal shortness of the middle cunei-
form relative to the external cuneiform. The base is about the same
width as the shaft proximally, but has a strong ventral projection.
The proximal surface is dorsoventrally convex and slightly turned up
laterally, noticeably so at the ventrolateral angle, beyond the extent of
the middle cuneiform. The medial side of the base lacks articular
facets but the lateral side shows two well-developed surfaces for
articulation with the external cuneiform. Distal to these the base of
the second metatarsal is not faceted for contact with the third meta-
tarsal. The shaft of the second metatarsal is somewhat flattened
dorsoventrally and broadens a little distally. The distal extremity is
moderately deep and strongly keeled ventrally. It tapers medially
somewhat and the distal margin is only slightly oblique to the shaft.

Metatarsal IJJ,—The third metatarsal, as the second, distally com-
plete only in the material of H. walcottianus, is a sturdy elongate
element, the shaft becoming somewhat broader and perhaps more
flattened distally. The base has about the same width as the more
proximal portion of the shaft, but projects prominently ventrad. The
proximal surface is dorsoventrally convex and has a slight tilt distally
toward the medial side. It is broadest dorsally and about midway is
sharply constricted by a lateral re-entrant, a configuration quite like
that of the distal surface of the external cuneiform. The medial sur-
face of the base is slightly rugose with but weak marginal indication
of contact with the second metatarsal which extends more proximally.
The lateral surface, however, is deeply excavated and shows a concave
facet dorsally and a knob-like convexity ventrad articulating with the
fourth metatarsal. The distal extremity is distinctly broader than the

72 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

base and moderately deep dorsoventrally. The distal articular surface
is well rounded, ventrally keeled, and essentially symmetrical on the
two sides.

Metatarsal IV.—The fourth metatarsal, as seen in the material of
H. walcottianus, is a trifle longer than the third, but as a result of
the position of the bases in the proximal articulations, the third
extends slightly farther distally. It may be further noted that in a
comparison of the fourth metatarsal with the fourth metacarpal in
material of H. lepidus, sufficiently preserved to indicate relative
lengths, it seems evident that the second to fourth metatarsals are
appreciably longer and, possibly, a little less flattened through the
shaft than the corresponding metacarpals.

The base of the fourth metatarsal, unlike the second and third, is
slightly wider than the more proximal portion of the shaft. The
shaft, however, broadens distally about as in the other two. The
proximal surface, articulating with the cuboid, is dorsoventrally elon-
gate, convex, and tapers slightly ventrad. There is a slight median
constriction from the medial side but not so deep as the adjacent
indentation on the proximal surface of the third metatarsal. The rela-
tive width of the base of the fourth metatarsal is effected largely by a
prominent process dorsally on the medial side, somewhat distal, how-
ever, to the surface for the cuboid. It exhibits a convex facet, prox-
imomedially facing, for articulation with the concavity in the base of
the third metatarsal. Near the ventral extremity of the base the medial
surface articulates with the third metatarsal, and more proximally
with the external cuneiform. The lateral surface of the base is deeply
concave and the arcuate proximal portion of this concavity is faceted
for articulation with the fifth metatarsal, making a sharply acute angle
with the surface for the cuboid. The distal extremity has about the
proportions seen in the third metatarsal but with a slight taper later-
ally. It appears, however, to be a trifle wider than in the second.

Metatarsal V.—The fifth metatarsal is relatively unreduced, as
compared with this element in Meniscotherium. It is about 50 percent
longer than the first metatarsal and with larger extremities. It appears
to be only a little shorter than the fourth metatarsal and about as
sturdy. The proximal extremity is dorsoventrally (dorsolateral-ven-
tromedially) compressed and decidedly broad. Centrally on the proxi-
mal surface there is an oblique, slightly convex surface that turns up
posteriorly and articulates with the outer part of the distal surface
of the cuboid. Medial to the surface for the cuboid there is a more
convex and proximomedially facing facet for the concavity on the
base of the fourth metatarsal. Most noticeable on the base of the

NO. 4 A STUDY OF HYOPSODUS—GAZIN 73

fifth metatarsal is a very prominent ventrolateral process which, no
doubt, supported insertion of the peroneus brevis, significant in evert-
ing the foot as well as flexing the tarsus. The shaft of the fifth
metatarsal is relatively straight along its dorsomedial border but the
ventrolateral margin is decidedly concave. The distal extremity is en-
larged and relatively deep. Its articular surface is only slightly
oblique and much less tapering than on the first metatarsal.

Phalanges.—As noted in the discussion of the fore foot, the first
phalanges of the hind foot appear to be somewhat narrower and
deeper proximally than in the fore foot, and their length might be
slightly less. The second phalanges also appear to be slightly shorter
but their width does not taper distally so much as in the fore foot,
giving further credence to the suggestion that the larger claw-like
distal phalanges (pl. 12, fig. 4) belong to the hind foot.

SUMMARY OF RELATIONSHIPS

As noted in the introductory remarks, interpretations of relation-
ships for Hyopsodus have been nearly as varied as for Meniscothe-
rium, First described by Leidy as probably allied to the suillines,
which accounts for his selection of the name (hog-aspect-tooth), it
was also thought to be related to perissodactyls, proboscideans, and
notoungulates. It was long regarded as a primate and an insectivore
in turn, and then, as a result of the more detailed studies of Matthew,
was later properly allocated to Cope’s Condylarthra, a position further
supported by Simpson (1945) in his classification of the mammals.
Its closest relatives are, of course, the several genera that have been
included with it in the family Hyopsodontidae, all of which, except
for Hyopsodus, are Paleocene, although Haplomylus extends into the
early Eocene. Only of Hyopsodus, however, is any significant repre-
sentation of the skeleton known, other than jaws and teeth. Compari-
son of limbs and feet, as well as of skulls, is limited for this reason
to the previously better documented materials of genera in the closely
related condylarthran families Phenacodontidae and Meniscotheriidae.
Detailed comparisons of the genera Meniscotherium, Phenacodus, and
Hyopsodus, so far as then known, were made in 1965 and much of the
expanded discussion of Hyopsodus in this paper relates to comparisons
made with Meniscotherium, which on limb and foot structure appears
a little closer than Phenacodus. While all three are rather similar in
carpal and tarsal arrangement, unguiculate Hyopsodus is rather less
like subungulate Phenacodus, and shows a different direction of devel-
opment than indicated by the elongate hind foot structure recorded for

74 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

Tetraclaenodon. In cheek tooth structure Hyopsodus more nearly
resembles or parallels Ectocion, among phenacodonts, except for the
obvious difference in stylar development and character of the upper
premolars. A difference in food getting habit is seen in the relatively
larger upper canines in Ectocion, instead of the anterior incisor. The
skull of larger Ectocion, moreover, is relatively much broader. I have
earlier (Gazin, 1956a, pp. 10-12) described a partially preserved skull
of Ectocion, but postcranial material is very scant.

Although there is no authentic record of Hyopsodus in the early
Tertiary of Europe, as discussed in a preceding section of this study,
it may be noted that D. E. Russell (1964) has described the new
Condylarthra Paschatherium and Louisina which he included in the
Hyopsodontidae. These are represented in the early Eocene of Bel-
gium and the late Paleocene of France. The type of Paschatherium,
P. dollot of Dormaal, was originally described by Teilhard de Chardin
as a species of Adapisorex. Russell regards this as showing a closer
resemblance to Haplaletes of the North American Fort Union, and
which may be near its line of descent. These forms are not, however,
especially close to Hyopsodus itself. The condylarthran affinities of
the Cernaysian Pleuraspidotherium have been discussed (Gazin, 1965,
pp. 85-88) at length in comparisons made with Meniscotherium.

A rather closer approach to Hyopsodus seems evident in certain of
the South American Condylarthra. Paula Couto’s (1952) allocation
of Asmithwoodwardia, as recognized in material from the Paleocene
at Sao José de Itaborai, to the Hyopsodontidae has been noted and its
resemblance to Hyopsodus is impressive, although cuspation of the
upper premolars, the position of the hypoconulid, and the extension
(anteroposteriorly) of the trigonid in lower molars are rather dis-
tinctive. The procumbent arrangement of the lower incisors is sug-
gestive, but the canine though small is relatively larger than in
Hyopsodus. Also there appears to be more disparity between the
canine and first premolar in both size and shape. Pascual’s (1965)
Oxybunotherium from the Casamayoran beds in Chubut, which was
referred tentatively to the Didolodontidae, in many ways looks even
more like Hyopsodus. This is suggested in the anteroposteriorly
shortened trigonid of the lower molars, apparently lacking a para-
conid, and the oblique trigonid crest. The arrangement of the cusps
on the talonid is also rather similar to that in Hyopsodus. Didolodus
itself is generally regarded as more distinctly phenacodont in appear-
ance. The resemblance of Anisolambda to Meniscotherium has been
discussed (Gazin, 1965, p. 83).

NO. 4 A STUDY OF HYOPSODUS—GAZIN 75

Among other groups that have been assigned to the Condylarthra
I find Hyopsodus least like the Periptychidae. The tendency there
toward inflation and/or proliferation of cuspules in certain groups is
quite opposite to that in Meniscotherium, and Hyopsodus preserves
a more primitive or simple cuspate arrangement, but only slightly
crescentic or lophodont. The periptychid foot structure is rather
different from that in Hyopsodus, exhibiting the peculiar astragalar
articulation in the hind foot characteristic also of Pantolambda, and
a central in the fore foot, not present in Hyopsodus, Phenacodus, or
Meniscotherium. Inclusion of the periptychids in the Condylarthra
has never been a completely satisfactory arrangement.

The arctocyonid creodonts, while showing a basic resemblance to
the Condylarthra in the more primitive features of the molar struc-
ture, are probably closer than other groups outside the order and their
adaptive specialization distinguishing them from the condylarths may
well have been pre-Tertiary in origin. Their feet, moreover, are not
truly of the condylarthran type, with overlapping tarsal elements,
particularly the astragalus and cuboid.

The suggestion that tillodonts are condylarths is, of course, un-
warranted, and derivation from any of the claenodonts is in no way
demonstrated. Resemblances are not greater than may be seen be-
tween several of the orders of mammals in the early Tertiary. I
suspect that convergence with the pantodonts in still earlier times is
more likely, although premolar development has proceeded along quite
different lines. Their foot structures, moreover, are rather similar,
certainly not condylarthran. It also has been advocated that the
mesonychid creodonts are condylarths. This stretches the concept of
an order quite beyond orderly limits.

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NO. 4 A STUDY OF HYOPSODUS—GAZIN 79

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80 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

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NO. 4 A STUDY OF HYOPSODUS—GAZIN 81

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82 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

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EXPLANATION OF PLATES

PLATE 1

Hyopsodus paulus Leidy
Skull (USNM 17980), dorsal, lateral, and ventral views. Twice nat-
ural size. Blacks Fork member (B), Bridger formation, Green River

Basin, Wyoming.

PLATE 2

Hyopsodus miticulus (Cope)

1, Rostral portion of the skull (USNM 23746), dorsal view. Twice
natural size. Knight member, Wasatch formation, Green River Basin,
Wyoming. For explanation of abbreviations see p. 90.

Hyopsodus paulus Leidy

2, Rostral portion of skull (USNM 17421), dorsal and lateral views.
Twice natural size. Blacks Fork member (B), Bridger formation,
Green River Basin, Wyoming.

Hyopsodus minusculus Leidy

3, Rostral portion of skull and mandible (Webb School of Calif. coll.),
lateral view. Twice natural size. Blacks Fork member (B), Bridger
formation, Green River Basin, Wyoming.

PLATE 3

Hyopsodus paulus Leidy
Cranial portion of skull (USNM 23084), ventral, dorsal, and lateral
views. Twice natural size. Blacks Fork member (B), Bridger forma-
tion, Green River Basin, Wyoming. For explanation of abbreviations
see p. 90.

PLATE 4

Hyopsodus paulus Leidy
1, Skull (USNM 23740), lateral and ventral views.
2, Skull (USNM 17980), occipital view.
Twice natural size. Blacks Fork member (B), Bridger formation,
Green River Basin, Wyoming.
Hyopsodus miticulus (Cope)
3, Cranial portion of skull (USNM 23745), occipital view. Twice nat-
ural size. Knight member, Wasatch formation, Green River Basin,
Wyoming.

83

84 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

PLATE 5

Hyopsodus miticulus (Cope)
1, Endocranial cast (USNM 23745), dorsal and lateral views.
2, Cranium (USNM 23745), lateral and dorsal views.
Twice natural size. Knight member, Wasatch formation, Green River
Basin, Wyoming. For explanation of abbreviations see p. 90.

PLATE 6

Hyopsodus paulus Leidy
1, Palatal portion of skull (USNM 23747), lateral and ventral views
(Left P1 restored to normal position in occlusal view).
2, Endocranial cast (USN M 23747), ventral view.
Twice natural size. Blacks Fork member (B), Bridger formation,
Green River Basin, Wyoming. For explanation of abbreviations see
p. 90.
Hyopsodus lepidus Matthew
3, Left upper milk teeth, Dp?-Dp* (AM 11959), occlusal view. Twice
natural size. Twin Buttes member (C), Bridger formation, Green
River Basin, Wyoming.
Hyopsodus miticulus (Cope)
4, Right lower milk teeth, Dp,-Dp, (USNM 19606), occlusal view.
Twice natural size. Knight member, Wasatch formation, Green
River Basin, Wyoming.

PLATE 7

Hyopsodus despiciens Matthew

1, Skull (AM 11877), part of type-specimen, lateral and ventral views.
Natural size.

2, Left ramus of mandible (AM 11877), part of type-specimen. Lateral
view natural size. Occlusal view of lower cheek teeth twice natural
size.

Henry’s Fork, Twin Buttes member (D), Bridger formation, Green

River Basin, Wyoming.

Hyopsodus lepidus Matthew

3, Left ramus of mandible (A.M. 11900), part of type. Lateral view
natural size. Occlusal view of lower cheek teeth twice natural size.
Henry’s Fork, Twin Buttes member (C), Bridger formation, Green
River Basin, Wyoming.

Hyopsodus paulus Leidy

4, Right ramus of mandible (USNM 1176), type-specimen. Lateral view
natural size. Occlusal view of lower cheek teeth twice natural size.
Near Fort Bridger, Blacks Fork member (B), Bridger formation,
Green River Basin, Wyoming.

Hyopsodus vicarius (Cope)

5, Fragment of right ramus of mandible (AM 5004), one of original
cotypes. Lateral view natural size. Occlusal view of posterior two
molars twice natural size.

NO. 4 A STUDY OF HYOPSODUS—GAZIN

6, Fragment of left ramus of mandible (AM 5003), type-specimen
(lectotype). Lateral view natural size. Occlusal view of first lower
molar twice natural size.

Cottonwood Creek, Blacks Fork member (B), Bridger formation,

Green River Basin, Wyoming.

PLATE 8

Hyopsodus walcottianus Matthew
1, Upper cheek teeth (AM 14654), part of type.
2, Right ramus of mandible (AM 14654), part of type.
3, Left ramus of mandible (AM 14654), part of type.
Lateral views natural size. Occlusal views of cheek teeth twice natural
size. Alkali Creek, Lost Cabin member, Wind River formation,
Wind River Basin, Wyoming.
Hyopsodus browni Loomis
4, Upper cheek teeth (AC 3242), part of type.
5, Left ramus of mandible (AC 3232), part of type. Lateral view nat-
ural size.
Occlusal views of cheek teeth twice natural size. Bridger creek, Lysite
member, Wind River formation, Wind River Basin, Wyoming.
Hyopsodus jacksoni Loomis.
6, Upper cheek teeth (AC 3470), part of type. .
7, Right ramus of mandible (AC 3246), part of type. Lateral view
natural size.
Occlusal views twice natural size. Bridger Creek, Lysite member, Wind
River formation, Wind River Basin, Wyoming.
Hyopsodus powellianus Cope
8, Right ramus of mandible (AM 4147), type-specimen. Lateral view
natural size. Occlusal view of lower molars twice natural size. Will-
wood formation, Bighorn Basin, Wyoming.

PLATE 9

Hyopsodus marshi Osborn
1, Right and left upper cheek teeth (AM 1706a), type-specimen. Oc-
clusal views twice natural size. Twin Buttes or Henry’s Fork, Twin
Buttes member (C or D), Bridger formation, Green River Basin,
Wyoming.
Hyopsodus uintensis Osborn
2, Upper cheek teeth (AM 2079), type-specimen. Occlusal view twice
natural size. White River, Uinta formation, Uinta Basin, Utah.
Hyopsodus fastigatus Russell and Wickenden
3, Left second lower molar (NMC 8654), type-specimen. Occlusal
view twice natural size. Swift Current Creek beds, Saskatchewan,
Canada.
Hyopsodus loomist McKenna
4, Right upper cheek teeth (UC 44781), type-specimen. Occlusal view
twice natural size. Four Mile Creek, Wasatch formation, Washakie
Basin, Colorado.

85

86 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

Hyopsodus lemoinianus Cope

5, Left ramus of mandible (AM 4139), type-specimen. Lateral view
natural size. Occlusal view of lower cheek teeth twice natural size.
Willwood formation, Bighorn Basin, Wyoming.

Hyopsodus lysitensis Matthew

6, Portions of left ramus of mandible (AM 15621), type-specimen.
Lateral views natural size. Occlusal views of lower cheek teeth twice
natural size. 15 mile Creek, Willwood formation, Bighorn Basin,
Wyoming.

Hyopsodus wortmani Osborn

7, Portions of right and left maxillae and premaxillae with upper teeth
(AM 4716), part of type-specimen. Occlusal view twice natural size.

8, Left lower cheek teeth (AM 4716), part of type-specimen. Occlusal
view twice natural size.

9, Right ramus of mandible (AM 4716), part of type-specimen. Lateral
view natural size. Occlusal view of lower cheek teeth twice natural
size.

Probably Lost Cabin member, Wind River formation, Wind River

Basin, Wyoming.

Hyopsodus simplex Loomis

10, Left ramus of mandible (AC 2290), type-specimen. Lateral view
natural size. Occlusal view of lower cheek teeth twice natural size.
Gray Bull member, Willwood formation, Bighorn Basin, Wyoming.

Hyopsodus minor Loomis

11, Right ramus of mandible (AC 3492), type-specimen. Lateral view
natural size. Occlusal view of lower molars twice natural size.
Bridger Creek, Lysite member, Wind River formation, Wind River
Basin, Wyoming.

Hyopsodus latidens Denison

12, Left ramus of mandible (MCZ 9848), type-specimen. Lateral view
natural size. Occlusal view of posterior lower molars twice natural
size. North Fork of Wind River, Indian Meadow formation, Wind
River Basin, Wyoming.

Hyopsodus markmani Abel and Cook

13, Left upper Dp* and M1 (DMNH 486), part of type-specimen. Oc-
clusal view twice natural size.

14, Right lower molar (DMNH 486), part of type-specimen. Lateral
view natural size. Occlusal view twice natural size.

Middle Eocene deposits in Sand Wash Basin, Moffat Co., Colorado.

Hyopsodus distans (Marsh).

15, Right and left upper cheek teeth (YPM 12907), part of type-speci-
men. Occlusal views twice natural size.

16, Right ramus of mandible (YPM 12907), part of type-specimen.
Lateral view natural size. Occlusal view of lower cheek teeth twice
natural size.

Grizzly Buttes, Blacks Fork member (B), Bridger formation, Green

River Basin, Wyoming.

NO. 4 A STUDY OF HYOPSODUS—GAZIN
PLATE 10

Hyopsodus paulus Leidy

1, Proximal portion of right humerus (USNM 23740), proximal (left
above), medial (left below), posterior (middle), and lateral (right)
views.

2, Distal portion of right humerus (composite USNM 23740 and
17980), medial (left), anterior (right above), and distal (right be-
low) views.

3, Left ulna (USNM 23740), anterior (left), lateral (right), and
distal (right below, restored) views.

4, Proximal portion of right radius (USNM 23740), proximal (above)
and anterior views.

All twice natural size. Blacks Fork member (B), Bridger formation,

Green River Basin, Wyoming.

Hyopsodus lepidus Matthew

5, Distal portion of right radius (AM 11959, immature), posterior and
distal (anteromedial margin down) views.

6, Left magnum (AM 11959), medial (left) and lateral views.

7, Right articulated distal carpals (AM 11959, unciform incomplete
laterally), proximal view (left to right; unciform, magnum, trapezoid,
and trapezium).

8, Right articulated carpals (AM 11959, lunar and pisiform missing,
and unciform incomplete laterally) ; proximal view (upper figure, left
to right; cuneiform and scaphoid with magnum of distal row partially
exposed between), lateral view (figure to left, with cuneiform above
and incomplete unciform below; scaphoid and magnum partially ex-
posed), anterior or dorsal view (central figure; cuneiform and
scaphoid, left to right, in upper row; and unciform, magnum, trape-
zoid, and trapezium left to right, in lower row), medial view (figure
to right; scaphoid above and magnum, trapezoid, and trapezium left to
right in lower row) and distal view (lower figure, left to right;
incomplete unciform exposing part of cuneiform to left, magnum,
trapezoid, and trapezium).

All twice natural size. Henry’s Fork, Twin Buttes member (C),

Bridger formation, Green River Basin, Wyoming.

Hyopsodus paulus Leidy

9, Left metacarpals I to IV (USNM 23740; Mc V missing), proximal
view (left to right, IV tol).

10, Left carpals and metacarpals (USNM 23740; trapezium, trapezoid,
unciform and Mc V missing; lunar and Mc III incomplete), proximal
view (upper figure, left to right; scaphoid, lunar, and cuneiform par-
tially concealed by pisiform), medial view (figure to left; scaphoid
partially concealing pisiform, distomedial carpals missing), dorsal
view (central figure; left to right above, scaphoid, lunar, and cunei-
form partially concealing pisiform; only magnum, partially restored
from AM 11959, represented in distal carpal row; below, left to right,
metacarpals I to 1V, metacarpal III incomplete and V missing), and
lateral view (figure to right; cuneiform and pisiform left to right,
with magnum partially exposed below).

87

88 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153

11, Left articulated proximal carpals (USNM 23740), distal view (left
to right, scaphoid, lunar, and cuneiform).

12, Phalanges, probably all from third digit and believed to represent
fore foot (USNM 23740), dorsal and lateral views.

All twice natural size. Blacks Fork member (B), Bridger formation,

Green River Basin, Wyoming.

PLATE 11

Hyopsodus minusculus Leidy

1, Skull with mandible (USNM 24891), lateral view.

2, Left humerus (USNM 24891), lateral (left) and posterior views.

3, Right radius, ulna, scaphoid, lunar, and metacarpals I to V (USNM
24891), anterior or anterolateral view of fore limb with dorsal view of
fore foot (left), and medial or anteromedial view of fore limb with
medial view of fore foot (right).

Blacks Fork member (B), Bridger formation, Green River Basin,

Wyoming.

PLATE 12

Hyopsodus paulus Leidy

1, Proximal portion of right femur (USNM 17980), anterior (left),
proximal (right above), and posterior (right below) views.

2, Distal portion of left femur (USNM 17980, distally restored from
YPM 12907), anterior (right) and distal (left) views.

3, Left patella (USNM 23740), anterior view.

4, Phalanges, probably all from third digit and believed to represent
hind foot (USNM 23740), dorsal and lateral views.

5, Left tibia and fibula (USNM 23740); anterior (left), distal (left
below), proximal (right above, restored from YPM 12907), and
lateral (right) views.

All twice natural size. Blacks Fork member (B), Bridger formation,

Green River Basin, Wyoming.

Hyopsodus paulus Leidy and Hyopsodus lepidus Matthew

6, Composite left pes; astragalus, calcaneum, navicular, cuboid, internal
cuneiform and metatarsals I (reversed from right), III (incom-
plete), and V (reversed from right) of Hyopsodus paulus (USNM
23740, except Mt III, USNM 23748); middle cuneiform, external
cuneiform (incomplete), and metatarsals II and IV (both incomplete
and reversed from right) of Hyopsodus lepidus (AM 11959) ; dorsal
view.

7, Composite left metatarsals; I (reversed from right), III, and V
(reversed from right) of Hyopsodus paulus (USNM 27340; except
Mt III, USNM 23748) ; metatarsals II and IV (reversed from right)
of Hyopsodus lepidus (AM 11959) ; proximal views.

All twice natural size. Bridger formation, Green River Basin, Wyo-

ming.

NO. 4 A STUDY OF HYOPSODUS—GAZIN

Hyopsodus paulus Leidy

8, Left astragalus (USNM 23740) ; lateral, ventral, and medial (left
to right) views.

9, Left navicular (USNM 23740); proximal (above), medial (left),
dorsal (center), lateral (right), and distal (below) views.

10, Left caleaneum (USNM 23740); medial, dorsal, and lateral (left
to right) views.

11, Left cuboid (USNM 23740); proximal (above), medial, dorsal,
lateral, ventral (left to right), and distal (below) views.

12, Left internal cuneiform (USNM 23740); distal, medial, lateral,
and proximal (left to right) views.

All twice natural size. Blacks Fork member (B), Bridger formation,

Green River Basin, Wyoming.

PLATE 13

Hyopsodus paulus Leidy

1, Axis to second dorsal vertebra (USNM 23740), lateral view.

2, Third to thirteenth (right to left) dorsal vertebrae and rib portions
(USNM 23740), ventral view of vertebrae.

3, Fourteenth to twentieth (right to left) dorsal vertebrae and three
lumbars (USNM 23740), ventral view.

4, Right scapula (USNM 23740), lateral view (restored in part from
left).

5, Left innominate bone (USNM 17980), lateral view (partially re-
stored from right).

All twice natural size. Blacks Fork member (B), Bridger formation,

Green River Basin, Wyoming.

EXPLANATION OF ABBREVIATIONS FOR PLATES

It is understood that the annotations as applied to casts refer to position and
external form of soft parts, including their mantle, or representation of contents
where the name applies to a boney structure, such as a foramen or sinus.

a.c.
G
oh
C.D.

cav.s.

Anterior culliculi or corpora quadrigemina.

Impression of broken surface exposing cochlea.

Condylar foramen (incl. nerve XII and veins).

Cribiform plate.

Cavernous sinus.

External auditory meatus.

Infraorbital foramen.

Foramen lacerum medium.

Foramen lacerum posterius (incl. nerves IX, X, and XI, and in-
ternal jugular vein).

Foramen magnum.

Foramen ovale (incl. nerve V,).

Fenestra ovalis.

Fenestra rotunda.

Flocculus of cerebellum.

Glenoid surface.

Hypophysis

Internal auditory meatus (incl. nerves VII and VIII).

Inferior petrosal sinus.

Lateral lobe of cerebellum or cerebellar hemisphere.

Lateral or transverse sinus.

Longitudinal or sagittal sinus.

Maxilla.

Medulla oblongata.

Mastoid process.

Mesethmoid.

Remnants of inferior crests of nasals.

Neopallium.,

Olfactory bulbs.

Optic foramen,

Posterior culliculi or corpora quadrigemina.

Paramedian fissure.

Postglenoid foramen.

Postglenoid process.

Pyriform lobe.

Paroccipital process.

Superior petrosal sinus.

Sphenoidal fissure.

Stylomastoid foramen.

Impressions of turbinals.

Vermis cerebelli.

Aperture in facial canal for facial nerve.

Third division of trigeminal nerve.

PLATES, 1-5

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SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 1

Hyopsodus skull from the middle Eocene of Wyoming
(See explanation of plates on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 2

Hyopsodus skull portions from the early and middle Eocene of Wyoming
(See explanations of plates and abbreviations on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 3

_

fen.r. p.p. c.f.
fen.o. aj ie

has
YF
bs

Hyopsodus skull portion from the middle Eocene of Wyoming
(See explanations of plates and abbreviations on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 4

Hyopsodus skulls from the early and middle Eocene of Wyoming
(See explanation of plates on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 5

A yopsodus skull portion and endocranial cast from the early Eocene of Wyoming
(See explanations of plates and abbreviations on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 6

Hyopsodus skull portion, endocranial cast, and deciduous teeth from the Eocene
of Wyoming
(See explanations of plates and abbreviations on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 7

Hyopsodus type-specimens from the middle Eocene of Wyoming
(See explanation of plates on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 8

Hyopsodus type-specimens from the early Eocene of Wyoming
(See explanation of plates on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 9

Hyopsodus type-specimens from the early, middle, and late Eocene of Wyoming
(See explanation of plates on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 10

Hyopsodus fore limb and foot material from the middle Eocene of Wyoming
(See explanation of plates on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 11

a4 gto
, ACO EN EM
Be 7 NG ge | pr
pees tS YY,

Hyopsodus skull, fore limb, and foot material from the middle Eocene of
Wyoming
(See explanation of plates on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 12

Hyopsodus hind limb and foot material from the middle Eocene of Wyoming
(See explanation of plates on pp. 83-90.)

SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL. 153, NO. 4, PLATE 13

Hyopsodus vertebrae, ribs, scapula, and pelvis from the middle Eocene of
Wyoming
(See explanation of plates on pp. 83-90.)