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FIELDIANA
Geology

Published by Field Museum of Natural History

Volume 33, No. 16 December 19, 1975

This volume is dedicated to Dr. Rainer Zangerl

Ziphodont Crocodiles:1

Pristichampsus vorax (Troxell), New Combination,

From the Eocene of North America

Wann Langston, Jr.

Research Scientist

Texas Memorial Museum

and Professor, Department of Geological Sciences

The University of Texas at Austin

INTRODUCTION

In 1956 I speculated on the possibility that certain so-called
dinosaur-toothed crocodilians, the Order Sebecosuchia, had a world-
wide distribution during the Tertiary Period. It has now been
shown that whereas a true sebecosuchian, Bergisuchus Kuhn,
existed in Europe during the Eocene, most of the specimens to
which I referred probably belong to a eusuchian (Order Eusuchia),
which is best represented by a genus variously termed Pristi-
champsus or Weigeltisuchus in Europe. Specimens displaying
dental characters reminiscent of Pristichampsus are also known
from Eocene strata in North America. My suspicion, long held, that
these North American taxa were closely related to Pristichampsus
has been reinforced recently by the discovery of a magnificently
preserved skull from Washakie beds in Wyoming and now in Field
Museum of Natural History. This volume honoring Rainer Zangerl
seems a fitting place to offer a description of this specimen, for it
was Dr. Zangerl who first called it to my attention and then
generously placed it at my disposal.

'Ziphodont is the vernacular derived from the taxon ziphodon (nomen nudum)
proposed by 0. C. Marsh for a species of dinosaur-toothed crocodilians from
Wyoming. The term is descriptive of the principal distinguishing character state of
this group of crocodilians and is less clumsy and more precise than the term
"dinosaur-toothed" previously employed.

Library of Congress Catalog Card Number: 75-38177

r"e Library of the

Publication 1222 291

MAY 0 7 1976

292 FIELDIANA: GEOLOGY, VOLUME 33

During the course of this study other specimens of what I shall
term ziphodont crocodiles were located in other museums in the
United States. Space does not permit detailed consideration of this
additional material, but it is listed and some specimens are
mentioned when they supplement data available from the Field
Museum skull.

ABBREVIATIONS
AMNH — American Museum of Natural History
FMNH — Field Museum of Natural History
ME — Museum fur Erdgeschichte-Geiseltalsammlung, Halle
MNHN — Museum National d'Histoire Naturelle, Paris
USNM — United States National Museum
YPM — Peabody Museum of Natural History

TAXONOMIC NOTES ON ZIPHODONT CROCODILES

Study of the Field Museum specimen has led to a review of the
taxonomy of the ziphodont crocodiles which is confused by
typological problems and clouded by a number of possibly
synonomous taxa in both North American and European literature.
A brief summary of these problems will be helpful before
considering the Field Museum specimen in detail.

The first report of ziphodont crocodiles in North America dates
back more than a hundred years. O. C. Marsh (1871), in one of his
many "Notices of some new fossil reptiles, etc.," gave a brief
description of a new Eocene crocodilian from the Bridger Basin of
southwestern Wyoming. Marsh was impressed by its sharp,
laterally-compressed, curved, and doubly-serrated teeth, and he
named the species Crocodylus ziphodon. Marsh also included a
description of an unusual quadrate bone "found with one series of
the remains" assigned to this species, and indicated the existence of
cranial bones and osteoscutes. No holotype was designated, no
illustrations were provided, and catalogue numbers were not
mentioned. Later Marsh (1872) noted "new" but unspecified
material belonging to the species, which he transferred to a new
genus, Limnosaurus.1 Characteristically, a promised "full descrip-

'The name Limnosaurus makes three unrelated appearances (homonyms) in the
literature: Marsh, 1872 (L. ziphodon, the crocodile); Nopsca, 1899 (= the
hadrosaurian dinosaur Orthomerus); Aldrich & Jones, 1930 (Paleozoic ichnites).

LANGSTON: ZIPHODONT CROCODILES 293

tion" of this material was not forthcoming, and except for brief
mention by Leidy (1872) and a few others, L. ziphodon remained in
taxonomic limbo for almost 50 years. Then in 1925, as part of a
review of the Bridger crocodiles, Troxell listed as "holotype" of C.
ziphodon YPM 1347, which he believed to be the material of
Marsh's original description. It appears that this procedure is
inadmissible, for not only was there no assurance that the
specimens concerned were actually those referred to by Marsh, but
bones representing two distinct crocodilian taxa and at least three
individuals are included under No. 1347 in the Yale collection. If,
therefore, Limnosaurus ziphodon is to be retained, the typological
questions still must be resolved, but, as will appear, I believe this is
impossible.

An examination of records in the Peabody Museum reveals that
the material described by Marsh in 1871 was obtained by the Yale
party of 1870 at Grizzly Buttes, in the Bridger Basin. Specimens
numbered YPM 1347 comprise: the distal end of a right quadrate
subsequently assigned number YPM 5890 but believed by Troxell to
be the bone described by Marsh, a second right quadrate of similar
form but of smaller size, a pair of articulars, parts of a right angular
and surangular, some fragments of dermal roofing bones, four teeth,
a posterior cervical vertebra, parts of two rib heads, a few
incomplete osteoscutes, and some small fragments. Other specimens
bearing the same number, including a quadrate of Crocodylus form
noted by Troxell, are clearly different. In addition, the Yale
collection contains two teeth numbered YPM 1348, and two others
found in 1966 in trays containing fragments numbered 1347, but
which are unnumbered. They may have been included originally
with one or the other of the two assemblages referred to by Marsh.

Most of the specimens numbered YPM 1347 bear accession
number 249+. The latter number appears twice on the same page
of the Peabody Museum register, once for an anaspid fish from
Scotland and again for "limbs and two teeth" of a crocodilian
numbered 1343 (not 1347), which, according to the catalogue, was
collected by Marsh at Grizzly Buttes in 1871, not 1870. Specimen
YPM 1347, designated in the catalogue as the holotype of C.
ziphodon, if it is in fact the material originally described by Marsh,
should belong to accession 136, which is the appropriate number for
the Peabody Museum Bridger collection of 1870. No ziphodont
crocodilian specimens bearing this accession number have been
found in the collection despite careful search by several individuals.

294 FIELDIANA: GEOLOGY, VOLUME 33

One of the unnumbered teeth has the same crown length and
anteroposterior diameter as the tooth measured by Marsh in his
original description. But the transverse diameter of the base given
by Marsh as 2.6 lines, that is, about 5.5 mm., is .4 mm. greater than
in this specimen. The thin sides of the tooth are broken away near
the base, and if restored might yield a measurement close to the
figure given by Marsh. It could be argued therefore that this is in
fact the original tooth, and that part of its side has been chipped off
since the published measurements were made. But this cannot be
substantiated.

There is, therefore, no substantive evidence that any of the
original materials on which C. ziphodon was based have been seen
in the collection since 1871, and they may be presumed to be either
unrecognizable or lost. In this situation a lectotype cannot be
designated. Nor is assignment of a neotype appropriate because no
known specimens that might be sufficiently characteristic of C.
ziphodon have come from the same provenance as the original
sample and thus cannot be shown to be from the same geological
horizon [ICZN Rules, art. 75(c) (6)]. Taxonomic stability will best
be served by regarding C. ziphodon Marsh 1871 and Limnosaurus
Marsh 1872 as nomina nuda.

The earliest available name that can be applied to a North
American ziphodont crocodile is Crocodylus vorax Troxell (1925).
Holotype of this species is a crushed and incomplete skull (YPM
249) which, like Marsh's material, was collected in the Bridger
Basin, probably from the Bridger A horizon ("Greensand forma-
tion") of older authors (Wheeler, 1961). This specimen and the
material numbered YPM 1347 and 1348 are at hand. The ziphodont
teeth are essentially similar, and it is curious that Troxell failed to
notice this when he discussed the supposed Marsh specimens only a
few pages prior to his description of C. vorax. (To my own
embarrassment, it must also be recorded that owing to mistaken
identification, I reported erroneously in 1956 that the teeth of C.
vorax "are round . . . rather like those of other crocodiles.")

Neither Marsh nor Troxell seem to have been aware of
ziphodont teeth from Europe, long before attributed by Cuvier
(1824) to les Crocodiles des marnieres d'Argenton. Much additional
material, including complete skeletons (most recently reviewed by
Berg, 1966) has come to light, but the taxonomy of the European
ziphodonts is hardly less complicated than that of their American
relatives. Syntypes were established when Gray (1831) based the

LANGSTON: ZIPHODONT CROCODILES 295

new species Crocodylus rollinati Gray on two of Cuvier's specimens
(MNHM AG 3 and AG 4).1 Berg accepts Pristichampsus Gervais
(1853) as the valid generic name, and while expressing slight
reservations, he equates P. rollinati (Gray) with Weigeltisuchus
geiseltalensis Kuhn 1938, a conclusion not fully accepted by Kuhn
(1968). To my knowledge, no lectotype for P. rollinati has been
selected, and it is not at all certain that either of the "syntypes" is
sufficiently diagnostic to furnish the basis for more than a
monotypic taxon. It may well be that the earliest taxon of
diagnostic value will prove to be Weigeltisuchus geiseltalensis, but
pending solution of this problem, I shall follow Berg in using P.
rollinati for the European ziphodont.

DESCRIPTION

The Field Museum skull, FMNH PR 399, was collected in 1958
by a party led by Dr. W. D. Turnbull, from a "Sandstone rim just
below Dobytown Rim, Sweetwater County, Wyoming, about 7 miles
NE of Kinney Ranch." The horizon lies within Roehler's beds 614-
618 (see Roehler, 1973) and is thus high in the Washakie A of older
usage (e.g., Granger, 1909). Admirably preserved, the specimen has
suffered only slight dorsoventral crushing and loss of parts of the
right quadrate and left pterygoid, and most of the teeth. It was
imbedded in a green sandy pebble conglomerate which has not been
removed from the orbits and the temporal spaces.

A lengthy description is unnecessary as the general features of
the specimen are clearly shown in the accompanying illustrations. A
number of details are, however, worthy of emphasis. The skull is 452
mm. long (snout-quadrate) and 223 mm. wide (transquadrate). In
general, it conforms to the eusuchian pattern, although its
proportions differ from those of all existing crocodilians (table 1).
Dental occlusion appears to have been intermediate between the
alligatoroid "overbite" and the crocodyloid "interbite" as occlusal
pits occur in the palatal surface medial to several maxillary teeth.
There is nevertheless a crocodyloid notch in the upper jaw margin
between the premaxilla and maxilla. Lateral festooning of the snout

'Catalogue numbers for Cuvier's figured specimens (Cuvier, 1824, pi. 10) in the
Museum National d'Histoire Naturelle, Paris, have never been published. They are:
AG 1, tooth (fig. 16); AG 2, tooth (fig. 15); AG 3, tooth (fig. 14); AG 4, vertebra (fig.
24); AG 5, radius (fig. 21); AG 6, ulna (fig. 22); AG 7, ?lacrimal (fig. 18); AG 8,
dentary (fig. 17); AG 9, vertebra (fig. 23), AG 10, femur (fig. 19); AG 11, femur (fig.
20).

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LANGSTON: ZIPHODONT CROCODILES 297

is not marked in dorsal aspect, but from the side the rostrum
appears moderately festooned. The lateral outline of the cheek
region makes an angle with the rostrum below the middle of the
orbits (fig. 1A, B). The palatal surface is unusually vaulted,
reflecting elevation of the maxillary and anterior palatine roof and
the festooning of the jaw margins opposite the big maxillary teeth.
Of special interest is the relative height of the rostrum (fig. 1C, D),
particularly in its posterior half where the sides of the skull are
steeply inclined, and a strong angular relationship exists between
lateral and dorsal roofing bones. The postorbital bars are depressed
and ovate in transverse section. Posteriorly a thickened, deeply
emarginated transverse occipital crest overhangs the occiput.

Those sutures that can be seen are indicated in the drawings.
The incomplete but persistent median division between opposite
frontal and parietal elements is notable. The lacrimal makes a long
contact with the nasal; the prefrontals are separated by a narrow
anterior process of the frontals; nasals end posteriorly in a
transverse suture with frontals and prefrontals some distance
anterior to the orbits. Frontals do not enter the supratemporal
fenestrae but are excluded from them by sculptured surfaces of the
parietal and postorbitals. The supraoccipital appears to reach the
skull roof as a narrow median wedge lying in a deep triangular
notch at the posterior edge of the skull table. Premaxillae are
separated posterodorsally by a narrow continuation of the nasals
into the nares.

Osteodermal scuplture comprises mainly shallow pits and
grooves over most of the surface, but heavy pitting occurs on the
skull table and between the orbits. Edges bounding the orbits and
below the lateral temporal fenestra are thickened, as are the lateral
edges of the skull table; the superior orbital rims are slightly
elevated. A few deep longitudinal sulci appear on the jugals; one,
shorter and lateral to the other, parallels the ventral edges of the
orbit and the lateral temporal fenestra. A short but deep sulcus,
coaxial with the lateral temporal fenestra, is seen on the
dorsolateral surface of the quadratojugal. Except for some trans-
verse depression of the interorbital and parietal skull ioof, the
superior surface of the skull table is virtually flat, but a median
ridge lying between the anterior half of the orbits lends a wrinkled
appearance to this area. The facial ridges that are believed to
provide strength against deformational stresses in many crocodilian
skulls (Iordansky, 1973; Langston, 1973) are expressed as thickened

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300 FIELDIANA: GEOLOGY, VOLUME 33

crests extending from the anterosuperior corners of the orbits
anteriorly across the lacrimal and onto the maxilla. Ventrolateral
to these ridges the side of the face is broadly depressed, but the
surface within the depressed area is sculptured, and, except along
the lacrimal crest, its margins are not sharply defined. A few tiny
foramina emerge from within the depression, largely toward the
anterior tip of the jugal.

A long, faceted, and roughened surface at the anterosuperior
edge of the orbits, involving both prefrontal and lacrimal, is
probably evidence of the former presence of heavy palpebral bones.

The nares seem large for a skull of these proportions and are
subround; the vestibule opens upward and a little forward, giving
the end of the rostrum a slightly downturned, mesosuchian
appearance when seen from the side. In primitive fashion, the narial
rims are not raised above the level of the adjacent skull bones, nor
does the usual eusuchian paranasal roofing by premaxillae occur.
The nares were probably partly divided posteriorly by a projection
of the nasal bones, now broken off. The incisive foramen seems
exceptionally large for a narrow-snouted crocodilian. The orbits
look mostly to the side; if, as supposed, palpebral bones were
present, vision would have been largely restricted to the lateral
field. The lateral temporal fenestra is completely bounded
posterodorsally by a slender process of the quadratojugal; there was
no quadratojugal spine. Almond-shaped superior temporal fenestrae
seem small considering the length of the jaws. The undivided
choanae are large for the size of the pterygoid plate, are situated
well back in the plate, and boundaries are only weakly elevated at
the sides. A septum 7.5 mm. thick separates the choanae from the
median eustachian foramen, which is relatively large (almost one-
sixth the size of the choanae). Small lateral eustachian exits are
placed higher than usual in eusuchians, on the edges of the lateral
basioccipital crest. Posttemporal fenestrae are so tiny as to appear
occluded. The subtemporal fossae are long, reflecting the attenua-
tion of the ventral temporal arcade. Palatal fenestrae are unusual
in having an exceptionally wide pterygoid border posteriorly.

Pterygoids and ectopterygoids seem small for the size of the
skull, which thus appears relatively depressed in lateral view.
Viewed from behind (fig. 3), the occipital region appears deep for its
width. The paroccipital processes are exceptionally broad and
extend far out onto the quadrates, which as a consequence appear

LANGSTON: ZIPHODONT CROCODILES

301

Fig. a Pristichampsus vorax (Troxell). FMNH PR 399. Skull: occipital aspect.
Scale = 5 cm.

short and thick. The basioccipital plate is triangular and bears a
well-developed saggital crest. The occipital condyle is relatively a
little wider and less convex than in Crocodyhis skulls of comparable
size, and the articular surface curves onto the posteroventral side
somewhat more than usual so that the major area of articulation
with the atlas slants downward and forward at an angle of about
39°.

The jaw joint was peculiar; the axis of breadth across the jaw
articulation is approximately transverse, but the trochlear surfaces
are slightly inclined so that the lateral quadrate condyle reaches a
lower plane than the medial one (see fig. 3, left side). Viewed from
above or below, the quadrates have an inwardly-hooked appearance
distally so that their medial edges are widest apart at midlength.
This condition is reflected in the horizontal arching of the
suspensorium (fig. 1A, B).

Owing perhaps to a rather complicated geometry, crocodilian
jaw articulations are rarely described in detail, and occasional
statements of authors that there is nothing unusual about a
particular quadrate may be misleading because certain aspects of
quadrate architecture are often distinctive. The shape of the

302 FIELDIANA: GEOLOGY, VOLUME 33

trochlear surface in Pristichampsus is peculiar and may best be
understood by comparison with the trochlea of other more
"conventional" crocodilians (fig. 4). A brief description of the
trochlea and associated features in Crocodylus acutus will be useful
here.

Viewed perpendicular to the hinge surface (fig. 4a), the outline
of the distal end of a medium-sized C. acutus quadrate appears
irregularly rhomboidal and about twice as wide as it is long (fig.
4D). The long superior and inferior sides are concave, in conformity
with a broad, saddle-shaped intercondylar fossa that separates the
two almost equal but differently-shaped condyles. The joint surface
is continuous across the fossa. The trochlea is helicoid, with its
twist passing from ventromedial to dorsolateral (the torsion can be
visualized by holding a strip of paper in both hands and twisting
the ends in opposite directions between 35° and 45°). The axis of
breadth for the jaw joint is inclined to the horizontal and vertical
planes (fig. 4b, c). Planes bisecting the greatest arc of each condyle
differ in position, that of the medial condyle slanting more strongly
outward above than the other (fig. 4c). Thus lines drawn along the
greatest arcs of the condyles pass from in front and below,
backward, upward, and outward at different angles, and if projected
will intersect at a point beyond the lateral tangential plane of the
skull. A line similarly drawn about the deepest part of the
intercondylar fossa will approximately bisect the angle formed by
intersection of the other two lines. Except in very young
individuals, the lateral condyle tends to be hemispherical, with joint
surfaces extending from below, upward across the posterior end of
the bone and, narrowly, onto the superior surface. The joint also
extends over a small, roughly-triangular area on the side of the

Fig. 4. Crocodilian quadrate architecture. Trochlear outlines are drawn
perpendicular to the hinge surface, i.e., with longitudinal axis of skull inclined about
65° as in (a). The axis of breadth of the jaw joint is inclined both to the horizontal
(b) and the vertical (c). Planes bisecting the greatest arcs of the condyles as described
in the text are shown in (c) where the black dot is in the line of sight indicated by the
arrow in (a).

Trochlear surfaces of various crocodilian right quadrates are figured below (all
figures drawn from photographs; lateral edge to right, superior edge at top). A,
Pristichampsus vorax, YPM 5890; B, P. vorax, AMNH 2090; C, P. rollinati, AMNH
2406 (left quadrate reversed); D, Crocodylus acutus (medium-sized individual); E, C.
acutus (small individual); F, C. mloticus (medium sized); G. C. porosus (small); H,
Alligator mississippiensis (large); I, A. mississippiensis (medium size). All figures
drawn to same transverse diameter. Scale = 1 cm.

H
303

304

FIELDIANA: GEOLOGY, VOLUME 33

Plate 1. Pristichampsus vorax (Troxell), YPM 249. Crushed holotype skull of
Crocodylus vorax. Vertebrae at upper left are those of a mammal. Approximately
one-fourth natural size.

quadrate below the posterior tip of the quadratojugal. The medial
condyle appears less tumid, its ventral surface extends farther
forward than the lateral condyle, and its flattened joint surface
does not pass so far onto the superior surface of the quadrate. Thus
the working surface is but slightly visible from above. Much of the
joint surface of the medial condyle can, however, be seen in lateral
view; it ends abruptly along the sharp medial edge of the quadrate.

In existing crocodiles, the shape of the trochlear surface varies
somewhat among individuals of similar size within one species, and
considerable differences may exist between individuals of different
species of one genus (compare figs. 4D and F; E and G). Generic
differences are pronounced (fig. 4D and I; F and H). Changes
mainly affecting the relative size and convexity of the medial
condyle, expecially in various species of Crocodylus, occur ontoge-
netically (fig. 4D, E).

Trochlea of FMNH PR 399 are damaged, but their essential
qualities can be discerned. They clearly resemble the articular end
of a right quadrate YPM 5890 (which may have been the bone

LANGSTON: ZIPHODONT CROCODILES

305

Plate 2. Pristichampsus vorax (Troxell), YPM 5890. Distal end of right
quadrate formerly included with YPM 1347. A, superior; B, inferior; C, trochlear
aspects. Natural size.

referred to by Marsh in 1871). This specimen (pi. 2) is excellently
preserved and, though smaller than PR 339, furnishes a better idea
of the structure than can be obtained from the Field Museum
specimen. It differs greatly from the quadrate of C. acutus. The
posterior outline of the distal end (fig. 4A) is much less rhomboidal,
the joint surface is relatively flat with a wide and shallow
intercondylar fossa. Anteriorly, where the fossa is deepest in C
acutus, the bridge between the condyles is only a little excavated in
the fossil. Nevertheless, the medial condyle projects forward beyond
the lateral one, which is relatively undeveloped and virtually
without any of the hemispherical expansion that is characteristic of
other eusuchian quadrates. Instead of the small triangular joint
surface that appears on the side of the quadrate below the
quadratojugal in C. acutus, the lateral condyle comes to an obtuse
point just beyond the end of the quadratojugal. What is probably
the homologue of the lateral joint area occurs as a larger, smoothly-
rounded surface of triangular outline at the anteroventral corner of
the trochlea. It would hardly be visible from the side.

The helix of the joint of YPM 5890 is more pronounced than in
C. acutus, and the condylar planes are less inclined. They are also
more nearly parallel and hence lend a more regular appearance to

306

FIELDIANA: GEOLOGY, VOLUME 33

Fig. 5. Pristichampsus vorax.
Tendon crests on ventral side of left
quadrate, based on FMNH PR 399.

the screw-shaped hinge. The strong edge of the medial condyle is a
little thickened and relatively longer than in the C. acutus
quadrate. It ends above the center of the trochlea at the thickest
part of the joint. Just lateral to the edge and immediately in front
of the joint surface, on the superior face of the bone, there is a small
but distinct tubercle. This does not occur in any living crocodilian
known to me — instead, the corresponding area is distinctly
excavated parallel to the dorsal edge of the trochlear surface.
(Troxell's statement that the dorsal surface of YPM 5890 is divided
by a dominating ridge is puzzling, as a transverse section of the
quadrate about 2 cm. above the trochlea has only a slightly convex
upper outline.) Ventrally, about 1.5 cm. above the joint, there is a
sculptured area which is better seen in PR 399 where it comprises a
small ovate elevation. This corresponds to tendon crest D of
Iordansky (1964; 1973). Other tendon crests (A, B, B1 ) are sharply
defined in PR 399 (fig. 5), but crests A1 and C are apparently
undeveloped. These crests, related to the M. adductor mandibulae
posterior group, exhibit some variation, but are believed to be
distinctive in the different species of existing crocodilians(Ior-
dansky, 1964).

The transverse diameter of the distal end of the quadrate is
33.2 mm., and the vertical diameter at the middle of the trochlea is

BL * 193 mm.

421 mm.
' BL = 461 mm.

BL = 608 mm.

Fig. 6. Tooth size based on fore-and-aft diameters of cranial alveoli in various
crocodiles. Upper graph, Pristichampsus roUinati ME 5346 and 5671 compared with
P. vorax FMNH PR 399 and YPM 249; lower graph, C. acutus continuous line and
C. porosus, broken line. BL = basal length of skull.

307

308 FIELDIANA: GEOLOGY, VOLUME 33

16.9 mm. in YPM 5890; corresponding dimensions in FMNH PR
399 are 48.5 and 22.5 mm., respectively.

A quadrate belonging to AMNH 2090 is a little smaller than
YPM 5890 but is otherwise similar to it (fig. 4B). The tapering part
of the lateral condyle is a little shorter, the tubercle on the superior
surface above the middle of the trochlea is larger, and tendon crest
D is a depression instead of an elevation. To judge from the
variability observed in quadrates of existing crocodilians, such
differences which may reflect individual variation in muscle
architecture, may have little taxonomic significance.

There are apparently 22 alveoli on the left side of the Field
Museum skull, but only 21 are present on the right. The dental
pattern as determined from alveolar measurements is distinctive
(fig. 6) and seems closer to that of existing crocodiles than to
alligators or caimans. Of the four teeth remaining in the skull, only
left pmx 2 and right mx 2 are represented by more than truncated
roots, and only the maxillary tooth retains any serrations. This
tooth by itself would be indistinguishable from several teeth in the
Yale collection including those of the holotype of C. vorax Troxell
(YPM 249) or from some that may have been among the
"Crocodylus ziphodon" material of Marsh. There are about six
serrations per millimeter on the leading edge of the crown (the
posterior edge is not preserved). This tooth has a fore-and-aft
diameter of 10.1 mm. at the base of the crown, where it is 7.0 mm.
wide. It appears distinctly inclined posterodorsally, a feature
characteristic of Pristichampsus, which is somewhat accentuated by
the fact that the leading edge of each tooth is longer than the
trailing edge. The second premaxillary tooth was less blade-like but
nevertheless has principal diameters of 6.0 and 8.25 mm. In section
its edge-to-edge diameter is oriented about 45 degrees of the
midsaggital plane, whereas that of the second maxillary tooth
deviates by about 20 degrees, its trailing edge being laterad of the
leading edge. Left pmx 4, represented by the base of the crown, has
principal diameters of 11 and 6 mm.

SYSTEMATIC POSITION AND RELATIONSHIPS OF
ZIPHODONT CROCODILES

A comparison of the holotype of C. vorax and the Field
Museum skull shows them to be of nearly the same size, YPM 249
being slightly the smaller. Otherwise they seem very similar. The
only differences to be noted are in the alveolar patterns (fig. 6) and

LANGSTON: ZIPHODONT CROCODILES 309

what seems to be slightly coarser sculpture on the side of the
maxilla in the Yale skull. Also in that specimen the jaw edge is a
little more deeply festooned. These differences are best attributed to
individual variation, if we may be guided by conditions in existing
crocodilians.

Excellent photographs of some of the referred Pristichampsus
rollinati specimens are available to me through the courtesy of Dr.
Berg. Also at hand is a cast of the quadrate of a Geiseltal skull at
Halle (ME D.-5894) which was generously provided through Dr.
Berg by Prof. Dr. H. W. Matthes, Director of the Museum fur
Erdgeschichte-Geiseltalsammlung. A posterior part of a skull,
probably of P. rollinati (AMNH 2406, Poissier Collection), stated to
be from the "Eocene of France" has also been available for
comparison with the North American material.

Agreement between European and North American specimens
appears close, but some differences involving cranial proportions
and the dentition patterns are significant. The snout of the Field
Museum specimen is neither so long nor as slender as indicated in a
reconstructed Geiseltal skull (Berg, 1966, fig. 7), and the pre-
maxillary rostrum is distinctly shorter in the American skull. The
external nares are less, the supratemporal fenestrae more, elongate
than in the Geiseltal skull. Berg concluded that a snout of P.
rollinati described by Weitzel contained 13 maxillary teeth whereas
16 to 17 were clearly present in PR 399 and probably also in YPM
249. The alveoli of P. rollinati are shown more oval and are more
widely spaced than in PR 399 (Berg, 1966, fig. 6a), and the occlusal
pits in the palate are indicated as more regularly arranged medial to
the tooth row. The dental pattern as reflected by alveolar diameters
differs mainly in the posterior third of the series (fig. 6), but this is
the region where alveolar partitions are least well formed and
measurements tend to vary more here than farther forward in all
crocodilian species. The main differences in the patterns have to do
with the relative size of the larger teeth which are known to
increase disproportionately with growth of the individual in C.
acutus and other living species. The larger P. vorax specimens
might therefore be expected to display greater variation in the teeth
than P. rollinati.

The Field Museum skull of P. vorax confirms the eusuchian
palatal construction of ziphodont crocodiles previously suggested by
Berg's study of Geiseltal specimens. Combining a eusuchian palate
and procoelous vertebrae, Pristichampsus is by definition elimi-

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LANGSTON: ZIPHODONT CROCODILES 311

nated as a possible sebecosuchian. Nevertheless the question may be
asked whether the eusuchian palate and eusuchian vertebrae may
not have been acquired by sebecosuchians in the course of their
evolutionary history (Langston, 1973). In this event, it might be
possible to regard Pristichampsus as an advanced sebecosuchian of
"eusuchian grade." The best counter to such a proposal is a
comparison of Pristichampsus with the character states that define
the Sebecosuchia and Eusuchia, respectively (table 2). This reveals
that the principal areas of agreement between Pristichampsus and
the sebecosuchians are related to the feeding mechanism. It seems
easier to view the tooth design (apparently the most efficient
shearing mechanism possible for large carnivorous reptiles and
mammals) and the elevation of the face, and similar jaw joints as
evolving by convergence in a primitive eusuchian in the direction of
the sebecosuchian condition than to suppose the opposite. Indeed,
the overall appearance of the Pristichampsus skull is so much that
of an eusuchian crocodile that there is no alternative at present to
following Kuhn (1968) and Steel (1974) in assigning the taxon to
the Crocodylidae, as that family is currently drawn by these
authors.

The North American ziphodont crocodiles as presently known
may be summarized as follows:

Order Crocodylia
Suborder Eusuchia Huxley, 1875

Crocodylidae Cuvier, 1807 (sensu Kalin, 1933)
Pristichampsus Gervais, 1853 (sensu Berg, 1966)

P. vorax (Troxell, 1925) new combination
Crocodylus ziphodon Marsh, 1871, p. 453
Limnosaurus ziphodon Marsh, 1872, p. 309
Crocodylus vorax Troxell, 1925, p. 42

Type. — YPM 249, an incomplete crushed skull and mandible
with associated postcranial elements.

Locality. - " . . . near Red Dog Butte" (Troxell, 1925, p. 42).

Horizon. — " . . . Greensand formation", "Bridger (Eocene)"
(ibid. )

Referred specimens. — A skull, FMNH PR 399, from within
Roehler's beds 614-618, close to common corner of sections 17, 19,
and 20, T.16N, R.97W, Sweetwater Co., Wyoming; a crushed skull
and associated skeletal scraps, FMNH PR 479, from Granger's bed 1
(i.e., near base of Washakie A), from within the sequence of

312 FIELDIANA: GEOLOGY, VOLUME 33

Roehler's beds 571-580, from within area limited by SE V*, Sec. 22,
and NE Va, Sec. 27, T. 16N, R. 95W, Sweetwater Co., Wyoming; an
incomplete right quadrate, YPM 5890, from the Bridger Basin, at
Grizzly Buttes, probably in Sec. 28, T.14N, R.113W, Uinta Co.,
Wyoming (Bridger B), and various teeth and bone fragments
numbered YPM 1343 and 1347 from the same general area; a
fragmentary skeleton, AMNH 2090, from the upper White Layer
(Bridger D) at Henry's Fork Hill (= Cedar Mountain), presumably
in sections 25-30, T.13N, R.112W (Wheeler, in litt.); a more
complete skeleton, USNM 12957, from "Bridger D horizon," 2 miles
N of Lone Tree P. O., Bridger Basin, Uinta Co., Wyoming.

Amended diagnosis. — Larger than P. rollinati, with slightly
wider and shorter snout, and a greater number of teeth in the
maxilla (16 vs. 13).

Distribution. — Eocene of the Bridger and Washakie Basins,
Wyoming.

ACKNOWLEDGMENTS

I am indebted first of all to Rainer Zangerl for generously
offering the Field Museum skull to me for study. Drs. J. H. Ostrom
and J. S. Mcintosh have been indispensable in reconstructing the
history of the Marsh specimens at Yale; stratigraphic and locality
data on North American Eocene localities has been furnished by
Drs. W. A. Wheeler, P. O. McGrew, and W. D. Turnbull. The
counsel and assistance of Drs. E. H. Colbert, D. E. Berg, D. E.
Russell, and Mme. F. de Broin are gratefully acknowledged.
Drawings are by Mrs. Doris Tischler (Figure 4 by Edwina
Traverso).

REFERENCES

Aldrich, T. H. and W. B. Jones

1930. Footprints from the coal measures of Alabama. Alabama Geol. Surv., Mus.
Paper, no. 9, pp. 1-64.

Berg, D. E.

1966. Die Krokodile, insbesondere Asiatosuchus und aff. Sebecus? aus dem Eozan
von Messel bei Darmstadt/Hessen. Abhandl hess. L.-Amt. Bodenforsch., 52, pp.
1-105.

Cuvier, G.

1824. Recherches sur les ossemens fossiles. Nouvelle edition, 5, part 2, Paris, Dufour
& d'Ocagne, 547 pp.

LANGSTON: ZIPHODONT CROCODILES 313

Gervais, P.

1853. Observations relatives aux reptiles fossiles de France (premiere partie). C. R.
Acad. Sci. Paris, 36, pp. 374- 377.

Granger, W.

1909. Faunal horizons of the Washakie formation of southern Wyoming. Bull.
Amer. Mus. Nat. Hist., 26, pp. 13-24

Gray, J. E.

1831. Synopsis Reptilium or short descriptions of the species of reptiles, Vol 1,
Cataphracta. Truettel, Wurtz, & Co., London, 88 pp.

lORDANSKY, N. N.

1964. The jaw muscles of the crocodiles and some relating structures of the
crocodilian skull. Anat. Anz., Bd. 115, pp. 256-280.

1973. The skull of the Crocodilia, pp. 201-262. In C. Gans, ed., Biology of the
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Kalin, J. A.

1933. Beitrage zur vergleichenden Osteologie des Crocodilidenschadels. ZooL Jahrb.
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Kuhn, O.

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1968. Die vorzeitlichen Krokodile. Krailling bei Miinchen, Verlag Oeben, 124 pp.

Langston, W., Jr.

1956. The Sebecosuchia: cosmopolitan crocodilians? Amer. Jour. Sci., 254, pp. 605-
614

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Leidy, J.

1872. On the fossil vertebrates of the early Tertiary formation of Wyoming. U. S.
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Marsh, O. C.

1871. Notice of some new fossil reptiles from the Cretaceous and Tertiary
formations. Amer. Jour. Sci. (ser. 3), 1, pp. 447-459.

1872. Preliminary description of new Tertiary reptiles. Parts 1 and 2, Amer. Jour.
Sci., (ser. 3), 4, pp. 298-309.

Nopsca, F.

1899. Dinosaurierreste aus Siebenburgen. I. Schadel von Limnosaurus. Denk. Akad.
Wiss. Vien, 68, pp. 559-591.

314 FIELDIANA: GEOLOGY, VOLUME 33

ROEHLER, H. W.

1973. Stratigraphy of the Washakie Formation in the Washakie Basin, Wyoming.
U. S. Geol. Surv., Bull. 1369, pp. 1-40.

Steel, R.

1974. Part 16, Crocodylia, in Kuhn, O., ed. Encyclopedia of Paleoherpetology,
Stuttgart & Portland, U.S.A., Fischer Verlag, 116 pp.

Troxell, E. L.

1925. The Bridger crocodiles. Amer. Jour. Sci., 9, pp. 29-72

Wheeler, W. H.

1961. Revision of the uintatheres. Bull. Peabody Mus. Nat. Hist., 14, pp. 1-93.