Peabody Museum

of Natural History

Yale University

New Haven, CT 06511

Postilla number iss

29 July 1983

Osteology and

Functional Morphology

of Dimorphodon macronyx
(Buckland) (Pterosauria:
Rhamphorhynchoidea)

. Based on New Material

in the Yale Peabody Museum

4& =
4 ONOA

Kevin Padian | >

(Received 18 February 1982)
Abstract

Two incomplete skeletons and other isolat-
ed bones of Dimorphodon macronyx
(Buckland), an early rhamphorhynchoid pte-
rosaur from the Lower Lias (Hettangian) of
England, have remained undescribed in the
collections of the Peabody Museum of
Natural History since their acquisition by O.
C. Marsh over a century ago. Some of this
material comes from Aust Cliff near Bristol,
and therefore constitutes the first record of
Dimorphodon outside the Lyme Regis area
of Dorset. The two individuals are smaller
than those in the British Museum (Natural
History) described by Owen, and juvenile
proportions characterize both cranial and
postcranial remains. Much of the material is
three-dimensional and has been prepared
from its matrix; it provides some of the
fullest structural and functional information
available for any pterosaur. A particularly
well-preserved humerus gives insight into
the articulations and folding of the wing,
and two sets of distal tarsals demonstrate

© Copyright 1983 by the Peabody Museum of Natu-
ral History, Yale University. All rights reserved. No
part of this publication, except brief quotations for
scholarly purposes, may be reproduced without the
written permission of the Director, Peabody
Museum of Natural History.

the mesotarsal flexion of the ankle. Com-
parison with more extensive but less fully
prepared material in the British Museum
(Natural History) allows some osteological
identifications to be established or
corrected; it also provides the basis for a
new assessment of structure and function
in pterosaurs. The forelimbs could not have
moved parasagittally but were well suited
for an active flight stroke. The hindlimbs
were positioned and moved like those of
bipedal dinosaurs and birds. The feet were
digitigrade and were not adapted to hang
from trees or cliffs. Comparative osteology
indicates that these features and abilities
conform very well to an “advanced archo-
saurian” Bauplan seen in dinosaurs and
birds.

Key Words

Pterosauria, functional morphology,
Dimorphodon, Archosauria.

Abbreviations

The following institutions are referred to in
the text:

BMNH _ British Museum of Natural History
(London)

Peabody Museum of Natural
History, Yale University

YPM

2 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

Introduction

O. C. Marsh was the first American paleon-
tologist to write extensively on pterosaurs.
He did most of this work in the 1870s, con-
centrating on the giant Cretaceous ptero-
dactyloids of the western United States. By
1872 he had already found enough material
to name two new species, Pterodacty/us
ingens and Pt. occidentalis. In 1876 he
separated these and several other new
large American forms into two new genera,
Pteranodon and Nyctosaurus, and named
a new suborder of the Pterosauria
(Pteranodontia). These strange forms with
their bizarre crests were larger than any Eu-
ropean finds, and their discovery attracted
worldwide attention. In his publications
over the remainder of the decade, Marsh
wrote on the general characters of Creta-
ceous pterosaurs, and also described the
first record of a Jurassic pterosaur from
North America, Pterodacty/us montanus
(1878), from the Morrison Formation; he
changed its name to Dermodactylus in
1881. In 1884 he began a description of the
skull of Pteranodon, but this work was left
unfinished. The study of American ptero-
saurs was later taken up by Williston, who
began in the 1880s, and by Eaton (1910),
who resumed work on the Yale Pteranodon
material after Marsh's death in 1899.
Marsh did not confine his research to
American pterosaurs, although his efforts
with European forms were less successful.
In 1873, he made two purchases of Euro-
pean pterosaur material for the Yale College
Museum. One was the fine specimen of
Rhamphorhynchus phyllurus from the
Upper Jurassic of Bavaria, the first ptero-
saur to be discovered with impressions of
the wings still intact. The circumstances of
its acquisition have been described by
Schuchert and LeVene (1940). The second
European pterosaur was Dimorphodon
macronyx, from the Lower Lias of Lyme
Regis, Dorsetshire, which Marsh purchased
from the fossil shop of Bryce M. Wright in
London. Despite the value of this European
material, however, Marsh postponed work

on it. He did not publish his description of
Rhamphorhynchus phyllurus until 1882,
claiming ‘““embarras de richesses nearer
home,” and when he finally did, his study
was only cursory. The Dimorphodon mate-
rial was never described.

The aim of the present work is to de-
scribe the material, which has remained in
the Yale collections for a hundred years.
Dimorphodon has not been studied exten-
sively since 1870, when Sir Richard Owen
described the material in the collections of
the British Museum (Natural History).
Owens evolutionary beliefs greatly colored
his choice of anatomical comparisons and
his conclusions about the functional
morphology and physiology of
Dimorphodon. His description brought
strong objections in the form of a detailed
reply from H. G. Seeley (1870), who chal-
lenged nearly every aspect of Owen's
monograph (Padian 1980). The resulting
confusion still needs clarification, and
recent discoveries have provided much
better evidence on which these questions
can be assessed.

Historical Background and Inventory of
the Material

The specimens in the Yale collections
referred to Dimorphodon were acquired in
three accession lots. All of them were
bought from the shop of the fossil dealer
Bryce M. Wright, 90 Great Russell Street,
Bloomsbury, London, probably between
1873 and 1882. The accession numbers in
the Yale catalogue are 456, 462, and 1503.
It is difficult to learn much about the
histories of these specimens. The material
was not collected systematically, and the
locality datum “Lyme Regis” is probably
general, like the usual designation of
“Solnhofen” for much of the pterosaur
material from the Upper Jurassic of Bavaria.
It is unlikely that most of the Dimorphodon
material was collected far from Lyme Regis
itself, but the fossiliferous localities there
extend for several miles, and are dozens of

Correction

Padian, Kevin. Osteology and Functional Morphology of Dimorphodon
macronyx (Buckland) (Pterosauria: Rhamphorynchoidea) Based on New
Material in the Yale Peabody Museum. POSTILLA (Peabody Museum of
Natural History) 189.

P. 11. Legend should read:

Fig. 4

Dimorphodon macronyx. a, YPM 9182, detail of slab, showing left maxilla
and part of jugal. b, detail of the same slab, showing dentigerous part
of right maxilla and possible radius-ulna fragment. Scale is in mm. c,
detail of the same slab, showing left femur lacking proximal end. 4d,
detail of the same slab, showing isolated metatarsal. e, YPM 9175, rib.
Scale bars = 1 cm. -

3 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

meters thick in places. Beyond this, there is
the problem of correlating Wright's own
catalogue numbers with the numbers on
his packing lists. In a letter to Marsh dated
21 June 1873, Wright expresses regret that
Marsh has found some of the unsolicited
material sent him unsatisfactory, and adds,
“| will not forget to procure if possible the
pterodactyle remains and other of your
desiderata and will confine myself solely to
those specimens you desire.” But we do not
know exactly what Marsh returned to

Wright and how it may have affected inven-

tory listings. It is unlikely that he sent back
anything pterosaurian, because Wright
refers to Marsh's requests for pterosaur
material in at least twelve letters. He is
always reminding Marsh of how scarce it
is, but promising to send whatever he can.
Thirty letters from Wright to Marsh, cover-
ing the years 1871-77, are preserved in the
Yale University Archives (Series |, Box 36,
Folder 1556), but unfortunately we do not
have Marsh’s letters to Wright.

Lot 456 is inventoried in a packing list
from Bryce Wright dated 21 March 1873. It
includes 87 separate items, for which
Marsh paid a total of £ 91. The first item
on the list is the pterosaur material, which
consists of a slab and several smaller
pieces. Wright listed it as follows: “No. 1.
Humerus, ulna, and radius, etc., of ptero-
dactyle in case and wing bones—1 rib and
1 other. Lias. £ 5.10.0.” Wright evidently
meant the main slab when he said “in
case,” which leaves the “wing bones, 1 rib
and 1 other.” Four other small pieces of
Lyme Regis matrix also have the accession
number 456 and “No. 1” on their labels.
Two are isolated wing bones, another is the
rib, and the fourth, labeled simply “bone of
Dimorphodon...” is the distal end of a
right humerus.

Two other pterosaur bones from Lyme
Regis have the accession number 456. One
is a shattered third wing-phalanx labeled
“No. 26" on the back of the slab. This
number does not correspond to Wright's
listing in his letter of 21 March 1873 (No. 26
on his list is “Head and jaw of Be/enos-

tomus anningiae"), but it may have been a
misprint of a number in Wright's catalogue.
There is also a left wing-metacarpal, which
has been prepared from its matrix. It is
identified by a label that corresponds to
Wright's No. 81 in the list for lot 456, which
reads simply “bone of pterodactyle.”

Lot 462 is inventoried in a letter from
Wright to Marsh dated 29 May 1873. This
lot contains 37 items, including material of
cave bear, plesiosaurs, turtles, mosasaurs,
and many other vertebrates, for which
Marsh paid £ 76.15.6. One piece of bone
is labeled “No. 27. Pterodactyle bone, Lyme
Regis,” and is evidently the distal end of
another right humerus. The No. 27 on
Wright's packing list does not correspond
to pterosaurian material; however, his No.
26 does.

The third accession lot (1503) containing
Dimorphodon material is represented by a
slab of black limestone (commonly called
“Blue Lias”) with fragmentary cranial and
postcranial remains. The label is Wright's
stationery, but the handwriting may be
Marsh’s; the locality given on the label is
“Lyme Regis, Dorset, England.” Accession
number 1503 was received 16 September
1881 and contains European fossils donat-
ed by Marsh, probably received or bought
by him during his European trip of that year
(Marsh 1881b). The material is listed in only
two parts in the accessions catalogue: “(a)
casts of monkeys from Prof. A. Gaudry,
Jardin-des-Plantes, Paris,” and “(b) Tertiary
fossils from Prof. A. Julien, Clermont-
Ferrand, France.” However, under entry
1503 in the original receipt book from
which the listings in the accessions cata-
logue had been copied, there are not two
items, but five. The first two correspond to
(a) and (b); the last two include various
fossils bought in Germany, but the third
reads “(c) slab of Bone Bed rock from Aust
Cliff, Gloucester, England, bought of B. M.
Wright, London.”

How can the discrepancy in locality data
be explained? All the known material of
Dimorphodon comes from the cliffs of
Lyme Regis, Dorset, on the southern shore

4 Dimorphodon macronyx (Buckland) Postilla 189
New Material

Aust ee,
Cliff oe}
Chepstow,
~Aust
ek

Cardiff , et
os Bristol 2, node!

BRISTOL
CHANNEL

miles
AS T T T 2
0 S10". 16: 2.0

ENGLISH CHANNEL

Fig. 1

Map of the southwest of England and Wales,
with Lower Liassic horizons stippled. Based on
1958 Ordnance Survey Map of Great Britain.

5 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

of England; the first two specimens were
collected by Mary Anning. Aust Cliff is not
in Dorset, but in Gloucester, on the south
bank of the River Severn (Fig. 1). However, a
thin outcrop of Liassic deposits runs north
from Dorset to the region of Aust, and the
top of Aust Cliff consists of three feet of
Lower Lias (Geological Survey of Great
Britain, Map 250, Scale 1:63660, 1958).
Beneath this is 25 feet 6 inches of Rhaetic, —
22 feet 9 inches of “Tea Green Mar|” (Upper
Keuper), and 97 feet of red marl. The black
limestone slab is typical “Blue Lias,” so it
could indeed have been collected from the
top of Aust Cliff—although not from the
“Bone Bed" of Aust Cliff listed in the YPM re-
ceipt book, because the latter is a light con-
glomerate of basal Rhaetic age, much
lower in the section (Reynolds 1947). This
specimen therefore marks the first occur-
rence of a Lower Liassic (Hettangian) ptero-
saur from a region in England other than
Dorset.

In Table 1 all YPM specimens referred to
Dimorphodon have been tabulated and
identified, and their principal measure-
ments given. The only part of the

Dimorphodon material to receive a Yale
Peabody Museum catalogue number was
the main slab of accession lot 456, which
was Catalogued as YPM 350 in 1927. This
included a right humerus (YPM 350 F), a
right lateral carpal (YPM 350 H), two meta-
carpals of the series I-IIl (YPM 350 A and L),
two phalanges from the manus (YPM 350 E
and J), a pair of contiguous second and
third wing-phalanges (YPM 350 D and C),
and what may be part of a fourth (YPM 350
K). Of the hindlimb there is preserved the
complete right tibia-fibula (YPM 350 B),
two distal tarsal elements (YPM 350 M and
R), metatarsals II-IV of the right pes (YPM
350 P), metatarsals Ill and IV of the left pes
(YPM 350 1), and two pedal phalanges
(YPM 350 G and N). All of these have been
removed from the slab (Fig. 2), and except
for the fragile long bones (YPM 350 B, C,
and D), are completely free of matrix.

Fig.2 V

Dimorphodon macronyx (Buckland), YPM 350,
slab showing presumed original positions of
the bones, which have been removed from the
matrix. Restored from photographs; dimen-
sions approximate. For identification and mea-
surements of lettered elements, see Table 1.
Scale bar = 5 cm.

6 Dimorphodon macronyx (Buckland) Postilla 189
New Material

Table 1
Inventory and Measurements (in mm) of YPM Dimorphodon Material

Item Description Length Width Width Median
Prox. End Dist.End Width

Accession Number 456: YPM 350
(Bryce M. Wright's “No. 1” of 21 March 1873)

350 A Metacarpal 30 4 2.5 1.5
350 B_ Right tibia-fibula 104 Ss) 6.5 15
350 C_ Third wing-phalanx 105 ip 6.5 5
350 D_ Second wing-phalanx o7 g TL5) 4
350 E_ Phalanx of right manus 10.5 3.5 3 2
350 F Right humerus 78 BE) Wwe 5-6
350 G_ Phalanx of pes 10 2:9 2 Om
350 H_ Right lateral carpal 6 _ — 2)
350 | Metatarsals Ill and IV of left pes
inc 35 — (2
350 J Phalanx of right manus 7. 28 20 eZ
350 K _ ? partial fourth wing-phalanx
or phalanx of fifth toe (23.5) (2.5) (1.8) (1.0)
350 L_ Metacarpal OZ 4 1
350 M Left lateral distal tarsal 6 — Z.
350 N_ Phalanx of pes 7 Z 1:5 1
350 P- Metatarsals II-lV of right pes
Il oY pp 2 1.2
Ill O25) 1.5 2 1.2
IV 2 105) iz. eZ
350 R_ Left medial distal tarsal 4 _ _ 4
YPM 9175 — Rib("No. 1”) 40 9 1 2
YPM 9176 — Second wing-phalanx
(“No. 1”) (78) 8.5 (7) 4
YPM 9177 — ?UIna(“No. 1”) 70 4 4 Sil5)
YPM 9178 _ Distalend of right
humerus (No. 1”) (31) 10.5 4
YPM 9179 _ Third wing-phalanx
("No. 26"?) 107 4 4 <)
YPM 9180 Left wing-metacarpal
("No. 81’) 36 125 8 5

Accession Number 462: YPM 9181
(Bryce Wright, 29 May 1873, No. 26 or 27
YPM 9181 Distalend of right
humerus o/ _ 12 f;
Accession Number 1503: YPM 9182
(Bryce Wright, 16 September 1881)

9182 A Left maxillary and jugal 87 — _ 4-5
9182 B Upper jaw fragment AS) _ —
9182 C Right humerus 63 21.5 15 (crushed)
9182 D Distal end of first

wing-phalanx 18 — 18, \e)/9)
9182 E Second wing-phalanx 74 vA 6 oo
9182 F Left femur, missing

proximal end (60) _ S) 5
9182 G Right femur 59 TS 8 45
9182 H_ Right tibia-fibula 85 8 BH) 4
9182 | Fused right distal tarsals 6 _ 4
9182 J Metatarsal (22) 1.8 _ 08
9182 K Unidentified shaft fragment

near B 45 10 6 8

7 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

The other material under lot 456 has
been left uncatalogued until now. Of these
specimens, the rib listed under “No. 1” has
been designated YPM 9175; the nearly
complete wing-phalanx is YPM 9176; the
presumed ulna is YPM 9177; and the distal
end of the right humerus is YPM 9178. All
of this material and the main slab represent
Wright's “No. 1” on his original list. “No. 27”
on his list (“No. 26” on the specimen label)
is the shattered third wing-phalanx, now
numbered YPM 9179; the isolated left
wing-metacarpal ("No. 81”) is YPM 9180.
The partial bone from lot 462, evidently a
distal end of another right humerus, has
been given YPM 9181.

All the material on the slab from Aust
Cliff (accession number 1508) is now YPM
9182. The slab of matrix is in the shape of a
rough trapezoid measuring about 25 cm
along the base, 8 cm along the top, 32 cm
in height, and 2.5-4 cm in thickness (Fig. 3).
The Dimorphodon material includes two
dentigerous parts of the upper jaws, the
right humerus, the left femur (without the
proximal portion: Fig. 4c), the complete
right femur, the right tibia-fibula, the distal
end of a first wing-phalanx, the entire
second wing-phalanx adjacent to it, two
contiguous distal tarsal elements, a single
metatarsal, a possible fragment of the
radius and ulna, and a small bone scrap,
probably the hemicentrum of a fish. Of
these bones, the humerus, right femur
and tibia-fibula, first and second wing-
phalanges, and tarsals have been prepared
out of the matrix. All bones are typically
crushed flat and, except for the humerus,
afford little three-dimensional relief.

Description

The osteology of pterosaurs has been well
known for over 120 years, due largely to the
many works of Hermann von Meyer, who
concentrated his research on the Upper
Jurassic forms of Bavaria. The discoveries
and advances of the following century
made necessary an extensive anatomical

and systematic revision of the Pterosauria,
which has been expertly carried out by
Wellnhofer (1970, 1974, 1975, 1978). The
recent discoveries of pterosaurs in the
Triassic of Italy (Zambelli 1973) and their
detailed descriptions (Wild 1978) have also
contributed greatly to an understanding of
the anatomy and diversity of the earliest
members of this group. The purpose of the
present work, accordingly, is not to provide
detailed analysis of pterosaurian osteology,
but to point out those features in the Yale
specimens that cast new light on an impor-
tant early pterosaur and on the functional
mechanics of pterosaurs in general.

Skull

Two fragments of the upper jaws are pre-
served in YPM 9182. The smaller (Fig. 4b) is
from the right maxilla, seen in lateral view.
It is 19 mm long and 4.5-8.0 mm high, and
bears three slightly recurved, sharply point-
ed teeth approximately 6 mm apart. The
shape of this fragment and the size of its
teeth appear to correspond to a part of the
other fragment of the jaw preserved on the
slab. Neither piece contains either the very
enlarged laniaries found in the premaxilla
and foremost part of the dentary, nor the
minute “lancet-shaped” teeth found along
most of the dentary, for which Dimorpho-
don was named.

The second fragment (Fig. 4a) is larger
than the first. It consists of most of the
lower border of the left side of the skull,
seen in lateral view, including nearly the
entire maxillary bone and most of the jugal.
In Dimorphodon the orbit sits higher in the
skull than both the preorbital opening and
the nares. The lower border of the orbit is
formed by the upper edge of the jugal
bone; the middle ascending process of the
jugal separates the orbit from the preorbital
opening. This process is incomplete in YPM
9182, but its configuration is clear. The
entire lower border of the preorbital open-
ing is outlined; it is approximately 33 mm
at its widest point. A small thin flange of
bone protrudes anteriorly at a low angle

Dimorphodon macronyx (Buckland) Postilla 189
New Material :

9 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

from the lower border of the preorbital
opening. This may be the thin lateral flange
of the pterygoid, which articulates with the
ectopterygoid in the region just medial to
the jugal in Campylognathoides and
Rhamphorhynchus (Wellnhofer 1974;
1978, Abb. 3).

The suture between the jugal and
maxilla, like most skull connections in
pterosaurs, is unclear. Owen (1870) did not
even identify a jugal bone in his description.
Von Meyer, the 19th-century German
authority on pterosaurs, succinctly summa-
rized the problem in Zur Fauna der Vorwelt
(1859: 15, translated by Seeley 1870).

In Pterodactyles, as in birds, the bones of
the skull blend together so imperceptibly
that their sutures at best are only indistinct-
ly seen, and are sometimes obliterated;
while even in full-grown reptiles they are
all to be made out with great distinctness.
There is the more difficulty in ascertaining
the structure of the Pterodactyle skull,
since generally only the lateral aspect is
exposed, and hence we get scarcely any in-
formation about its upper and under
surfaces. Among the skulls which are ex-
posed from the side, information is at times
afforded by those in which the parts have
suffered some displacement; but the sepa-
rations so produced are to be accepted
with great caution, for they do not always
coincide with the real boundaries of the
bones.

Pterosaur bone is so delicate that it is
easily checked and shattered. There are at
least four different reconstructions of the

Fig. 3

Dimorphodon macronyx, YPM 9182, slab.
Abbreviations: fv, hemicentrum of a fish, possi-
bly Pholidophorus; /f, left femur; 7 uy left
upper jaw; mt metatarsal; rf right femur,
rhum, right humerus; rt right distal tarsals;
rt-f right tibia-fibula; ? r-u, possible portion of
a radius and ulna; ruj right upper jaw; woh 7,
first wing-phalanx; wph 2, second wing-
phalanx. Scale in mm; measurements given in
Table 1.

skull of Dimorphodon, all drawn from the
same specimen, and all with different inter-
pretations of sutural connections (Fig. 5;
see also Seeley 1901 and von Huene 1914).
Figure 6 illustrates the portion of the skull
of Dimorphodon represented by YPM
9182, based on the skulls in the British
Museum (Natural History), described by
Owen (1870). There is no clear connection
between the maxilla and premaxilla, but
bearing in mind von Meyer's cautionary
remarks, the approximate extent of the
nares may be inferred from the basal length
of the preorbital opening. The fragment of
bone preserved here ends at a point just
short of the hypothetical anterior limit of
the nares. This is the case for most
rhamphorhynchoids, as Wellnhofer (1978,
Abb. 2) shows. The usual reconstruction of
this suture in Dimorphodon differs from
the rhamphorhynchoid pattern (Fig. 5), but
the evidence for this is not clear. It seems
equally possible that the anterior end of the
Yale specimen represents the natural break
between maxilla and premaxilla. Seven
maxillary teeth are preserved, and there are
alveoli for one or two more; this corre-
sponds to Owen's assignment of eight or
nine teeth to the maxilla. The premaxilla,
bearing the four large laniaries, would form
the snout and the anterodorsal border of
the nares, as in other rhamphorhynchoids
(Wellnhofer 1978, Abb. 2). As no evidence
of a large alveolus for the fourth laniary is
preserved, no portion of the premaxilla ap-
pears to be represented in this specimen.
The size and proportions of these cranial
remains imply that the specimen is a
juvenile; this assessment is further support-
ed by the dimensions of the hindlimb,
which will be discussed below.

Dentition

Three teeth have been preserved in the
smaller jaw fragment of YPM 9182, and
seven in the larger. Although none of the
teeth in the larger fragment is complete,
they are clearly the same size as the three
teeth in the smaller fragment, as deter-

10 Dimorphodon macronyx (Buckland) Postilla 189
New Material

Dimorphodon macronyx. a, YPM 9182, detail
of slab, showing left maxilla and part of jugal.
6, detail of the same slab, showing dentigerous
part of right maxilla and possible radius-ulna
fragment. Scale is in mm. ¢ detail of the same
slab, showing isolated metatarsal. e YPM
9175, rib. Scale bars = 1 cm.

11. Dimorphodon macronyx (Buckland) Postilla 189
New Material
4 Fig. 4 Fig. 5 VW

Four restorations of the skull of Dimorphodon
macronyx. A, Owen 1870; & Arthaber 1919;
C. Wellnhofer 1978; D, Wiman 1923. Paren-
thetical symbols in A represent Owen's
terminology. Abbreviations: a/ adlacrimal;~
ang, angular; av, articular; d dentary; f
frontal; /, jugal; / lacrimal; ™, maxilla;
mimalar; ms, mastoid; 7, nasal; £, parietal:
pm, premaxillary; pf por, postfrontal; po,
postorbital; poc, paroccipital; prt prefrontal;
g, quadrate; gj, quadratojugal; s@, surangular;
so, supraorbital; sp/ splenial; sg, squamosal;
tym, tympanic. Length of reconstructed skull
about 20 cm.

<q Fig. 6

Tentative restoration of the skull of the small
and presumed juvenile Dimorphodon
macronyx, based on skull fragment of YPM
9182. Abbreviations as in Figure 5. Length of
reconstructed skull about 14 cm.

12 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

mined from the size of their roots. The
placement of these teeth along the upper
jaw permits an approximation of the dental
configuration of the juvenile Dimorphodon.
The adult has four large laniaries widely
spaced at the front of the jaw, correspond-
ing to the premaxilla. The maxilla bears
seven or eight smaller teeth of this form, ac-
cording to Owen (1870), although Arthaber
(1922) figured nine in his reconstruction
(Fig. 5B). The upper jaw fragment described
here has fragments of seven teeth, of which
the last two are very close together. There
is a crushed alveolus midway between the
third and fourth teeth preserved here, and
also a large space (possibly an alveolus)
just in front of the first tooth. This tooth is
not quite parallel to the others, and it may
have been dislodged; the space that separ-
ates it from the second tooth is smaller
than in most of the series. This region of the
maxilla is also badly preserved in the other
Dimorphodon skulls. | regard the effective
number of maxillary teeth at this growth
stage to be eight, including the last two,
which are smaller and more closely spaced.
Additional teeth seem to have been formed
at the back of the jaw, and were progres-
sively smaller than those in front.

The most complete teeth are in the smal-
ler jaw fragment. The best preserved of
these is partly disengaged from Its natural
position in the alveolus, and all but the tip
of the root is visible. From comparison with
the complete root portions of other teeth,
the entire length of this tooth was approxi-
mately 7.0 mm. The form is identical to that
of the larger laniaries, only proportionately
smaller, as the isolated teeth figured by
Owen (1870, plates XVII and XVIII) show.

Owen described the large premaxillary
laniaries as “subcompressed, subrecurved,
and sharp-pointed” (p. 43), with the maxil-
lary laniaries becoming gradually smaller
and less curved towards the back of the
maxilla. The size and shape of the three
teeth in this smaller jaw fragment thus
show that it belongs to the fore or middle
part of the right maxilla. In the lower jaw of
Dimorphodon, which is deeper than this

fragment, there are three rather large laniar-
ies in the front, followed posteriorly by only
two of the size of the maxillary teeth, and
finally by a long row of “small, lancet-
shaped, close-set teeth” (Owen 1870:42). It
is therefore likely that this fragment belongs
to the lower jaw, unless the relative size of
some of the teeth changed during growth
and replacement.

Postcranial Material

As frequently happens with disarticulated
pterosaur skeletons, there are no remains of
the pectoral or pelvic girdles or of any verte-
brae among the Yale Dimorphodon
specimens; almost all preserved material is
of long bones. A single rib (YPM 9175; Fig.
Ae) has been preserved and is tentatively
referred to this taxon. It is double-headed,
wide at the proximal end between the two
heads, which are separated by 9 mm, and
slender along its length (40 mm). A hollow
channel in the proximal part of the shaft be-
tween the heads is revealed by crushing of
the surface bone. There is a slight curvature
at the proximal end, but the shaft is quite
straight for 80% of its length. The distal end
is slightly expanded and rounded.

Two complete humeri are preserved.
One right humerus (YPM 9182 C; Fig. 7c)
measures 63 mm from the saddle-shaped
articular surface of the head to the tip of the
ulnar condyle. The proximal articular sur-
face is well preserved and shows the
characteristic lip that articulated with the
glenoid fossa. The natural torsion of the
shaft has been distorted by crushing, but
the deltopectoral crest still preserves some
of its natural curvature. The angle made by
the head and crest of the humerus is slight
when compared to less distorted
specimens, in which the head and crest
may curve anteroventrally to form a semi-
circular silhouette in proximal view
(Lawson 1975, fig. 1). A bulblike terminal
thickening of the expanded crest has been
preserved; it shows, as Owen (1870:51)
noted, that the deltopectoral crest was not
simply a thin flat plate of bone, as speci-

13 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

mens often appear to indicate. The distal
end of the humerus is well preserved, par-
ticularly the articular condyles for the
radius and ulna, although this area is even
better preserved in the following specimen.
The other complete right humerus (YPM
350 F, Figs. 8 and 9) is exceptionally well
preserved, and its fine condition allows
new insight into the structural and function-
al details of the forelimb (see Discussion).
The head and neck were separated from
the shaft, which itself had been broken in
three places. These portions were all pre-
served in three dimensions, however, and
were completely repaired. The deltopectoral

Fig. 7

Dimorphodon macronyx, YPM 9182, material
removed from slab. a, second wing-phalanx; 6,
distal end of first wing-phalanx; ¢, right
humerus; d right tibia-fibula in posterior view;
e, right femur.

crest was also separated from the main
shaft and slightly crushed in its proximal
area; this portion has proven more difficult
to restore to its original form, and the crest
as repaired has less than the natural
curvature.

The head of the humerus |s the typical
saddle-shaped facet with a pronounced
medial lip. A deep notch at the neck separ-
ates the lateral (= external or greater) tube-
rosity from the head of the humerus. The
deltopectoral crest has a pronounced ex-
pansion at its distal extremity, as in the
humerus described above and in BMNH
41212. The crest extends nearly 19 mm
from the midline of the shaft, and is
more similar to the narrow form of
Rhamphorhynchus than to the
platelike form of Eudimorphodon and
Campylognathordes.

The presence of a pneumatic foramen
cannot be ascertained because the central

14 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

Fig. 8

Dimorphodon macronyx, YPM 350 F, right
humerus. Head of humerus at upper left, delto-
pectoral crest at upper right. Scale = 1 cm.

proximal region of the humerus is fractured
and crushed, but it does not appear to have
been located in the same position as in
birds. A deep channel near the head of the
humerus runs for a short distance parallel
to the axis of the shaft. Whether this repre-
sents a pneumatic channel is conjectural.
Most perforations taken for pneumatic
foramina have been in uncrushed but worn
and fragmented specimens from the Cam-
bridge Greensand, described by Seeley and
others (see Seeley 1901). Von Meyer,
Owen, and Seeley found pneumatic forami-
na in many parts of the skeleton, but this
work has not been extensively studied by
later authors, and the whole problem needs
further investigation.

The curvature of the shaft of the
humerus is sigmoid. Seen from the proximal

Fig. 9

Dimorphodon macronyx, YPM 350 F, right
humerus. Obverse view of Figure 8. Head of
humerus at upper left, deltopectoral crest at
upper right. Scale = 1 cm.

end, the distal end of the shaft is twisted
nearly 45° posterodorsally (see Fig. 10). Pro-
nounced ridges run along the shaft from
the greater tuberosity to the medial supra-
condyloid tubercle, and from the edge of
the deltopectoral crest to the lateral supra-
condyloid process. The paths of these
ridges further outline the torsion of the
shaft, and establish the lines indicative of
muscular attachment. They are instrumen-
tal in understanding the movement of the
humerus during the flight stroke (see
Discussion).

The distal end of the humerus is well pre-
served in YPM 9182 C and exceptionally so
in YPM 350 F. The distal condyles and the
adjacent ridges for muscular attachment
are clearly delineated, and Figure 10 points
out some of these comparable features in

15 Dimorphodon macronyx — (Buckland)

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Postilla 189

Dimorphodon and an eagle. In pterosaurs,
as in birds, the radial condyle articulates
with part of the ulna as well as with the
radius, whereas the ulnar condyle articu-
lates only with the ulna. In birds, the main
extensor muscles of the distal segment of
the wing originate from the lateral epicon-
dyle of the humerus, while the principal
flexors of the outer wing originate from the
medial epicondyle (Hudson and Lanzillotti
1955). The comparable development of
these sites of origin in pterosaurs argues for
a similar functional pattern. Two other
distal ends of right humeri are preserved in
the YPM Dimorphodon material (YPM
9178, Fig. 11a; YPM 9181, Fig. 11d), but are
more poorly preserved than the other
humeri and yield no additional information.

YPM 9177 (Fig. 11e) is a slender, slightly
bowed bone 70 mm long, and is tentatively
identified as an ulna. It is preserved ona
small slab of matrix of which the borders
are encased in cement. A long crack in the
slab, filled with glue, indicates that there
were originally two pieces of matrix. Where
the crack intersects with the bone, a section
of the shaft is missing and has been filled in
with cement. Unfortunately, the cement
that encases the perimeter of the specimen
also abuts against the articular ends of the
bone, making further preparation very
difficult. There is no other diagnostic mate-
rial of radius or ulna among the Yale
specimens, although an unidentified shaft
fragment 45 mm long, preserved adjacent
to the smaller jaw fragment on the slab of
YPM 9182 (Fig. 4b), may pertain to one of
these bones.

YPM 350 H (Fig. 12a, 13a) is a right later-
al carpal. This is a rather robust element
with a concave surface that articulated
with the distal carpal. A convex surface
opposite to this with a round flattened area
supported a small round sesamoid bone on
which the medially directed pteroid bone
rested (Wild 1978, Taf. 9f). Ironically, al-
though this carpal is called “lateral,” it is ac-
tually located on the medial (radial) side,
and was held in front of the wing when the
wing was outstretched. This medial carpal

is marked by several tubercles and depres-
sions to which attached the ligaments and
tendons that helped to manipulate the
propatagium. Its form and proportions
correspond closely to those of
Eudimorphodon, Dorygnathus, and
Campylognathoides.

Two isolated metacarpal bones of the
series I-III have been preserved (YPM 350 A
and L; Figs. 14c, d; 15c, d). They are ex-
tremely delicate and fragile. In comparison
with the metatarsal elements discussed
below, they are thinner and more rounded
in cross-section than the metatarsals of the
same length, and they are slightly bowed in
the lateral direction. Their proximal ends
are widened and flattened into shallow, U-
shaped spatulate surfaces that articulated
with the medial condyle of the proximal
end of the large wing-metacarpal (=mc IV).
Distally the metacarpals expand into round-

Fig. 10 >

Comparisons of the right humeri of the eagle
Aquila (above in each pair)) and Dimorphodon
(below in each pair). A, proximal view, oriented
with the distal ends parallel as in C. Note the
differences in angle of orientation of the heads
and deltopectoral crests. Drawn to the same
size. B complete humeri in palmar (left) and
anconal (right) views. Scale = 1 cm. C distal
ends in palmar view, drawn to the same size.

7, Processus supracondyloideus lateralis; 2.
Epicondylus lateralis; 3 Trochlea radialis; 4
Vallis intertrochlearis; 5, Trochlea ulnaris; 6
Epicondylus medialis; 7 Tuberculum supra-
condyloideum mediale; & Fovea supratroch-
learis ventralis. dp, deltopectoral crest; gt
greater tuberosity; 4, head; 7, neck.

Fig. 11>

Dimorphodon macronyx. a, YPM 9178, distal
end of right humerus; 6, YPM 9180, left wing-
metacarpal, lateral view; c YPM 9180, medial
view; @ YPM 9181, probably the distal end of
aright humerus; e, YPM 9177, ?ulna; £ YPM
9176, second wing-phalanx; g, YPM 9179,
shattered third wing-phalanx. Scale bars = 1
cm.

16 Dimorphodon macronyx (Buckland) Postilla 189
New Material

Fig. 10 ig

pterosaur

bird q {
h

gt

dp

pterosaur

17 Dimorphodon macronyx
New Material

(Buckland)

Postilla 189

Fig. 11

18 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

ed bulbs with ventral ligamentous grooves;
this expansion was necessary for the recep-
tion of the much stouter proximal pha-
langes of the first three fingers.

Two of these phalanges were preserved
(YPM 350 E and J; Figs. 12c, g; 13c, g).
They are more robust than the correspond-
ing elements of the pes, and their flexor
tubercles are more pronounced. Marked
ginglymal grooves characterize their distal
ends. Viewed from the proximal end, the
flexor tubercles are subtriangular, not
keeled, and distinctly set off to the medial

Fig. 12

Small skeletal elements of Dimorphodon
macronyx, YPM 350, prepared from matrix. 2,
350 H, right lateral carpal; 6, 350 G, pedal
phalanx; c, 350 J, phalanx of right manus; d@
350 R, left medial distal tarsal, distal view; e&
350 M, left lateral distal tarsal, distal view; f
350 N, pedal phalanx; g, 350 E, phalanx of
right manus: #, coalesced right distal tarsals of
YPM 9182, distal view; / YPM 350 K, possible
fragment of fifth pedal phalanx (or fourth wing-
phalanx?). Scale = 1 cm.

side. This corresponds to the condition
seen in the first two digits of the dromaeo-
saur De/nonychus (Ostrom 1969: 106). In
both YPM 350 E and 350 J this tubercle is
deflected to the left side, which indicates
that both phalanges belong to the right
manus. They are probably proximal
phalanges, and if so, 350 J probably be-
longs to digit II, while 350 E may represent
digit Ill, based on comparison with BMNH
41212. YPM 350 G (Figs. 12b, 13b) is more
slender than these two, and has no
tubercle. It more closely resembles the
proximal phalanges of the pes in BMNH
41212, as does the long gracile element
YPM 350 N (Figs. 12f, 13f), which is incom-
plete at the dorsal end of its proximal facet.
YPM 350 G and N are accordingly assigned
to the hindfoot, but cannot be further identi-
fied with certainty.

A left wing-metacarpal (YPM 9180; Figs.
11b, c) 36 mm long is badly crushed and
retains little relief even at its articular ends.
It is a typical broad, flat rhamphorhynchoid
wing-metacarpal, with a well-developed,
laterally placed bicondylar joint at the distal
end, on which the enormous wing-finger

19 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

pivoted. This isolated metacarpal is 4mm
longer than the two medial ones catalogued
as YPM 350 A and L. While it is unlikely
that it came from the same animal, the dis-
crepancy in size is not great. Galton’s
(1981b) recent description of a superb
rhamphorhynchoid wing-metacarpal from
the Morrison Formation of Wyoming obvi-
ates further discussion of YPM 9180 since,
although the relative proportions of this
bone in rhamphorhynchoids are variable,
there are no morphological features diag-
nostic below the subordinal level.

The distal end of the first phalanx of the
wing-finger (YPM 9182 D), and the com-
plete length of the second phalanx (YPM
9182 E: 74 mm), were preserved in conti-
guity (Figs. 3, 7a, 7b). The identification of
these wing elements can be made on the
basis of several features. In Dimorphodon,
the second wing-phalanx is shorter in

Fig. 13
Obverse views of the same elements of Figure
12, minus /(350 K). Scale = 1 cm.

length and broader in cross-section than
the third. The distal expansion of YPM 9182
E is too wide for the reception of the proxi-
mal end of the fourth phalanx, when com-
pared to this element in other specimens of
Dimorphodon and in other pterosaurs. The
ratios of the various bones of the wing to
each other (except the metacarpal and the
terminal phalanx) are diagnostic, at least to
the generic level (Padian and Wild, unpu-
blished data). In the two British Museum
specimens of Dimorphodon (BMNH 41212
and R 1035), the length ratios of the second
wing-phalanx to the humerus are 1.38 and
1.23; in YPM 350 C and F this ratio is 1.20.
These specimens have been ranked in de-
creasing order of size (the second pha-
langes are respectively 124, 102, and 97
mm), and it can be seen that the ratio de-
creases with growth. In YPM 9182, the
smallest of the group, the ratio of the pre-
sumed second phalanx to the humerus is
only 1.18. By contrast, the ratios of the third
phalanx to the humerus in the specimens
mentioned above are 1.54, 1.33+, and 1.30,
respectively; these values are significantly
higher.

20 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

a b

Fig. 14

Dimorphodon macronyx, YPM 350, isolated
metapodials. a, 350 P, metatarsals Il-lV of right
pes, dorsal view; 6,350 |, metatarsals III and IV
of left pes, dorsal view; c, 350 L, metacarpal,
ventral view; a 350 A, metacarpal, ventral
view. Scale is in mm.

At least two segments of the wing-finger
are represented on the main slab of acces-
sion number 456 (YPM 350); they are the
complete second and contiguous third pha-
langes (YPM 350 D and C), and possibly
part of a fourth (YPM 350 K). The second
and third (Figs. 16b, c) are of typical form
and proportion for Dimorphodon, they ar-
ticulate snugly, but are unfortunately flat-
tened and yield no new information. The

C d

same is true for YPM 9176 (Fig. 11f), an
isolated, mostly complete second wing-
phalanx with a preserved length of 76 mm;
and YPM 9179 (Fig. 11g), a shattered third
wing-phalanx 101 mm long. The articular
ends of the wing-phalanges show the typi-
cal ovoid ball-and-cup arrangement: the
proximal facet of each phalanx is concave
and the distal end is convex. The shafts are
quite straight and there seems to have
been little movement possible between the
phalanges.

YPM 350 K (Fig. 12’) is an incomplete,
flattened, slightly tapering fragment ovoid
in cross-section. A faint impression on the
slab corresponds roughly to a further exten-
sion of the wider (proximal) end, about 5
mm away from it and continuing for a

21 Dimorphodon macronyx
New Material

(Buckland)

Postilla 189

d .

Fig. 15
Dimorphodon.macronyx, YPM 350, obverse
views of isolated metapodials in Figure 14.

length of 10 mm. This evidence may sup-
port the identification of the bone fragment
as belonging to the fourth wing-phalanx,
since almost no other element of the skele-
ton would be so long, straight, and slender.
There is no indication of an articular facet
at either end. A shallow fracture runs along
the exposed surface of the shaft, as it does
in the other two wing-phalanges. The
width of the shaft supports the inference
that it comes from the distal half of the
fourth wing-phalanx, but it lacks the curva-
ture that usually accompanies the tapering
of this element. The preserved bone is also

b a

light and straight enough to belong to the
first phalanx of the odd fifth toe, and this
possibility must be considered.

From the few elements that are
preserved, the wingspan of these speci-
mens can be roughly estimated, based on
the proportions of other Dimorphodon
material. The individual represented by
YPM 350 had a wingspan of about 1200
mm, while the wingspan of YPM 9178
would have been about 960 mm. The lar-
gest nearly complete specimen of
Dimorphodon (BMNH 41212) had a wing-
span of almost 1450 mm.

The right femur (YPM 9182 G; Fig. 7e) is
bowed, but not sigmoid. Its length from the
tip of the head to the lateral condyle is 59
mm. The head is set off at an angle of about

22 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

Fig. 16

Dimorphodon macronyx, YPM 350, long
bones removed from matrix. 2, 350 B, right
tibia-fibula, anterior view; 6 350 D, second
wing-phalanx; c, 350 C, third wing-phalanx.

120° from the axis of the proximal region of
the shaft. The articular surface is rounded
and smooth; the neck is slightly constricted
but rather robust, much like the configura-
tion in bipedal dinosaurs such as Coe/urus
and Di/ophosaurus. There is evidence of a
greater trochanter, although most of this
region is crushed. The distal end of the
femur curves slightly laterally and the later-
al condyle extends slightly farther distally
than the medial, which is larger and more
pronounced. The expansion of the distal
condyles of the femur, in the two
Dimorphodon specimens described here
and in all known pterosaurs, is mainly
subterminal. The articular surfaces of these
condyles are oriented 90° ventral to the
shaft axis.

The right tibia-fibula (YPM 9182 H: Fig.
7d) has been preserved adjacent to the
femur, and almost in natural position,
except that the tibia-fibula has been rotated

to lie with the anterior side down. Both

bones have been removed from the slab,
and their natural articulation can be deter-
mined (Fig. 17). It is evident that the medial
condyle of the femur articulated with the
tibia, whereas the lateral condyle articulat-
ed with the fibula, as Seeley (1901) stated,
contrary to Owen (1870:52). The tibia and
fibula of rhamphorhynchoids were fused at
their proximal ends. The tibia is convex and
the fibula concave at the surface where
they meet. YPM 350 B, a complete right
tibia-fibula (Fig. 16a), was preserved with
the anterior face up, unlike YPM 9182 H.
The entire proximal joint surface of YPM
350 B is well preserved, and slopes poste-
riorly at an angle nearly 50° to the long axis
of the shaft. The femur, therefore, did not
normally meet the tibia-fibula in columnar
fashion. However, a range of movement of
about 135° appears to have been possible
at the knee, and the femur and tibia-fibula
probably met at an angle of 75-90° in
normal stance, with the femur more or less
horizontal and the tibia-fibula nearly
vertical, as in birds (Fig. 17).

There is no sign of a patella in any
pterosaur. An incipient expansion similar to
the cnemial crest of modern birds, but

23 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

much less pronounced, has been noted in
specimens from the Cambridge Greensand
(Seeley 1901), and more recently by Galton
(1981a). This tuberosity is present in
Dimorphodon as well, and, as Seeley
noted, it does not appear to represent a
separate center of ossification.

The reduction of the fibula in rham-
phorhynchoids (Fig. 18a, b) resembles in
many respects the same pattern seen in
birds. YPM 9182 H (Fig. 7d) is a right tibia-
fibula 85 mm long. 7 mm from the proximal
end, the shafts of the tibia and fibula
separate, and continue for a length of 20
mm spaced by a distance of approximately
1 mm before fusing again. The line of fusion
is at least 12 mm long, and as the fibula
gradually tapers along this length its distal
extent becomes indistinguishable from the
tibia, partly as a result of crushing. The total
length of the fibula is thus at least 39 mm,
or approximately 46% of the tibia, in this
specimen. The other right tibia-fibula (YPM
350 B; Fig. 16a) in this collection is nearly
20 mm longer, but the proximal contact be-
tween tibia and fibula is only 5 mm, the in-
terosseal space is at least 28 mm long, and
the distal fusion of the two bones appears
to extend for another 28 mm, although

crushing is again a problem. Like pterosaurs,

birds have an interosseal space between
the tibia and the fibula; the latter bone is re-
duced to a splint and usually merges into
the tibia at some distance before the distal
end.

The distal end of the right tibia-fibula
(Fig. 18c, d, e) is exceptionally well pre-
served in both YPM 350 B and YPM 9182 H.
This area, like the distal end of the humerus,
shows many remarkable similarities to the
homologous area of birds (Fig. 19). The
distal ends are comparable in the extent of
the anterior expansions of the bicondylar
surface that forms the joint. This distal ex-
pansion in pterosaurs has been taken to
represent the fusion of the proximal tarsal
elements (astragalus and calcaneum) with
the tibia, as in birds and small bipedal dino-
saurs (Seeley 1901; Wellnhofer 1978). The
two condyles are of comparable size, but

bird

pterosaur

Fig. 17

Comparison of the knee joints of the Golden
Eagle Aquila chrysaetos (above) and
Dimorphodon macronyx (below). In both, the
right femur and tibia-fibula are shown in lateral
(left) and anterior (right) views. Not drawn to
scale.

the lateral condyle is larger and rounder in
side view, while the medial condyle is
somewhat broader in anterior view. This
contrasts slightly with the situation in
birds, where both condyles are of approxi-
mately equal transverse width, but the la-
teral (external) condyle may extend farther,
and the groove between them is wider and
shallower than in pterosaurs (Currie and
Padian, in press). The ligamentous groove is
deep in pterosaurs, although not as deep as
in birds, and there is no bony supraligamen-
tous bridge.

The distal tarsal elements preserved in
the two slabs (YPM 350 M and R and YPM
9182 |) are exceptional for the detail and

24 Dimorphodon macronyx
New Material

(Buckland) Postilla 189

a

11cm
Occeestanieninnnncemiisomannsenial
Cc

25 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

4 Fig. 18

Dimorphodon macronyx. a, anterior views of
proximal ends of right tibiae-fibulae of YPM
9182 E (left) and YPM 350 B (right); & posterior
views of the same; ¢ anterior views of distal
ends of right tibiae-fibulae of YPM 350 B (left)
and YPM 9182 E (right); d posterior views of
the same; e, distal ends of tibiae: YPM 350 B

in lateral view (left), YPM 9182 Ein anterior
view (right).

Fig. 19 V

Anterior views of distal ends of right tibiae-
fibulae of Dimorphodon macronyx (left) and
the Golden Eagle Aquila chrysaetos (right),
drawn to the same size. In both, astragalus
and calcaneum are indistinguishably fused to
the bases of the long bones. Abbreviations: 6r,
bony bridge of transverse ligament; cond ext
external or lateral condyle; cond int, internal
or medial condyle; gr Ed, groove for M. Exten-
sor digitorum longus; gr Pp, groove for M.
Peroneus profundus; /nc, incisura; Z, lateral
ligamentous prominence; L /o, lower attach-
ment of Ligamentum obliquum; M, medial
ligamentous prominence; U /o, upper attach-
ment of Ligamentum obliquum. Not drawn to
scale.

Lilo

| coos -M
gr gr
Pp Ed|

cond INC cond int

ext
pterosaur

the information they yield about the ptero-
saurian ankle. These elements must be con-
sidered the lateral and medial tarsals, since
the astragalus and calcaneum are fused to
the tibia-fibula. YPM 350 M (Figs. 12c, 13c)
is the left lateral distal tarsal. YPM 350 R
(Figs. 12d, 13d) is the left medial distal
tarsal, and the two right tarsal elements are
preserved in their natural articulation with
each other in the smaller specimen YPM
9182 | (Figs. 12h, 13h). The correspondence
of detail between these two specimens in-
dicates that neither has suffered either
wear or distortion, although there is a break
in the flat, quadrangular medial distal tarsal
of YPM 9182 |, which has been repaired.
The lateral distal tarsal is a short stump
nearly 6 mm in length and roughly 2 mm in
cross-section, with a complex topography.
The medial distal tarsal is a flat quadrangu-
lar plate 5 mm at the widest edge and 4
mm across, with two raised ridges on its
distal face (Fig. 12d, h) that match the corre-
sponding metatarsals, The surfaces of
these tarsal elements are finely porous,
which suggests a cartilaginous covering.
The tarsal unit is roughly wedge-shaped. It
thins anteriorly to a slight degree, but much
more so medially, especially on the distal

|
cond int

bird

26 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

surface. The distal view of these tarsals (Fig.
12d, e, h; Fig. 20) clearly shows the articular
facets for the metatarsals. The large aber-
rant fifth metatarsal articulates laterally and
slightly posteriorly with the lateral face of
the lateral tarsal. The other four metatarsals
are oriented normally. The articular surface
for the fourth metatarsal appears to be
shared by the lateral and medial tarsals,
while the third and second are carried en-
tirely by the medial tarsal. There is no space
for the first metatarsal to articulate, which
is consistent with observations on other
pterosaurs (Wellnhofer 1978, Abb. 17).

The lateral distal tarsal corresponds in
both shape and topography to distal tarsal
4 of the lower Jurassic theropod dinosaur
Syntarsus (Raath 1969: 19, his fig. 6b): “Its
proximal and medial surfaces are concave,
and its distal and lateral surfaces are
convex. The lateral surface also has a small
notch to accommodate the proximal end of
metatarsal V.” In Syntarsus the lateral
distal tarsal is fused to the metatarsals, but
in theropods this element, when free, is uSu-
ally identified as a fusion of distal tarsals 2
and 3 (Ostrom 1969) because it covers
metatarsals II and Ill, as the corresponding
element does in pterosaurs.

The proximal surfaces of the distal tar-
sals (Figs. 13d, e, h; 20) show very clearly
the rounded depressions which served as
the articular facets for the tibia. The larger
fossa is on the correspondingly wider
medial tarsal, because the medial condyle
of the tibia is the larger of the two. A tuber-
ous posterior process of the lateral tarsal
partly overlaps the posterior face of the
medial tarsal, and may have been the site
for tendinous attachments of muscles that
extended the foot.

The metatarsal elements preserved on
this slab include metatarsals II-IlV of the
right pes (YPM 350 P: Figs. 14a, 15a) and
metatarsals Ill and IV of the left pes (YPM
350 |: Figs. 14b, 15b). The elements of both
are preserved in a coalesced state. The
proximal ends interlock and may have been
fused; metatarsals Il and lV meet at the
dorsal surface near the proximal end of the

metatarsus, displacing metatarsal Ill ven-
trally to a slight degree. The distal ends of
the metatarsals are separated and splay
slightly, recalling the situation in birds and
some theropod dinosaurs (Osmolska 1981).
The two metatarsals of YPM 350 | are not
completely fused along their length, and
lack 5 mm at their distal ends, compared to
the complete members of YPM 350 P. The
third metatarsal is slightly longer (about 1
mm) than the second and fourth; the first,
when it is preserved, is about 1 mm shorter
than these (Owen 1870). A slight lateral cur-
vature at both ends, and a gradual swelling
at the proximal end, identifies the fourth
metatarsal. There are ginglymal grooves on
the ventral and distal sides of the distal
ends of the metatarsals, which are not as
pronounced as in birds, but are comparable
to those of theropod dinosaurs. The first
four metatarsals seem to have functioned
as a unit; the toes flexed in the same plane
as the tarsus, and diverged distally to a
slight degree, as in birds. Two phalanges
(YPM 350 G and N) have been identified as
pedal, and were discussed earlier. No re-
mains of the odd fifth digit, or of any other
phalanges or unguals, have been preserved
among these specimens. An extremely deli-
cate metapodial (Fig. 4d) approximately 22
mm long but only 0.8 mm in diameter is
preserved in one corner of the slab of YPM
9182. From its uniform width and straight-
ness it appears to be a metatarsal, but one
articular end is unfortunately missing and
there are no other metapodials preserved of
this specimen.

Fig. 20 >

Four views of the right distal tarsals of
Dimorphodon macronyx, reconstructed from
YPM 350 M and R and YPM 9182. The bottom
picture shows the facets for medial (left) and
lateral (right) condyles of the tibia, shown in
Figure 26. Scale = 1 mm.

mr 5

27 Dimorphodon macronyx
New Material

(Buckland)

Postilla 189

ANT

distal

rises

PROX
posterior

tS F

HPS
anterior

PROX

ANT

proximal

POST

28 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

Referral of the Specimens to
Dimorphodon macronyx (Buckland)

postcranial proportional differences led
Wellnhofer (1978) and Wild (1978) to
place Eudimorphodon in a separate

Through the first half of the 19th century all family, the Eudimorphodontidae, and to
pterosaurs were Classified as Pterodacty/us, deny a strict phyletic connection to

following the example of Cuvier. In 1846
von Meyer recognized the genus
Rhamphorhynchus, but it was not until
the turn of the century that Plieninger
(1901) established these two forms as
representatives of separate suborders
within the Pterosauria. When Buckland
(1829, 1835) described the first pterosaur
specimen from Lyme Regis, at the time
the largest known representative of the
Order, he accordingly identified the
genus as Pterodacty/us and added the
specific epithet macronyx (“large claw’).
When a skull was finally found in 1858,
however, it proved to be so different from
those of other pterosaurs that Owen im-
mediately erected a separate genus for It.
The name Dimorphodon referred to the
two types of teeth in the lower jaw: the
“long, slender, trenchant and sharp-
pointed laniaries” seen in other pterosaurs,
followed posteriorly by a unique “series of
small, lancet-shaped, close-set teeth”
(Owen 1870: 42). A mysterious, isolated
dimorphodont jaw found some years ear-
lier had been supposed by Owen to
belong to a fish, contrary to Buckland’s
opinion that it actually pertained to the
pterosaur of which Buckland had pre-
viously described postcranial remains.
The presence of these two forms of
teeth in the dentary, therefore, was the
principal autapomorphic feature defining
Dimorphodonas a distinct taxon. In the
past decade, however, two new pterosaur
taxa with dimorphodont dentition were dis-
covered in the Norian horizons of northern
Italy. The first is Euci/morphodon ranzit

Dimorphodon on the basis of the many
derived characters of the former. Wild
(1978) suggested instead a closer rela-
tionship between Euadimorphodon

and the later rhamphorhynchoid
Campylognatho/des, from the Upper Lias
of Germany. He based this view on several
skull characteristics, the quadrangular
form of the deltopectoral crest of the
humerus, the quadrangular sternal plate,
and the number and topology of the
carpal bones, which are variably ossified
and preserved in rhamphorhynchoids.
Pete/nosaurus is smaller and known from
less complete material than Eudimorphodon,
but is clearly a distinct taxon. No cranial
material is known but most of the lower
jaw has been preserved, and its dimorpho-
dont dentition is also unique. The anterior
laniaries, of which there are an uncertain
number, are known only from impressions
on the counterslab of one of the two
specimens. The posterior teeth, which
appear unicuspid, are small and close-set,
but they point backward sharply, in con-
trast to the simpler, smaller, peglike lan-
cets of Dimorphodon. Wild (1978) sug-
gested that Pete/nosaurus was ancestral
to Dimorphodon and placed it in the
Dimorphodontidae Seeley 1870 on the
basis of dental configuration and postcra-
nial proportions.

Assignment of the Yale specimens de-
scribed here to any known pterosaur taxon
is uncertain because of the absence of the
lower jaw: no assessment of dimorphodon-
ty can be made. However, the preserved
skull fragments correspond to those of the

Zambelli 1973: the second is Pete/nosaurus two skulls of Dimorphodon in the British

zambellii Wild 1978. Eudimorphodon,
the larger of the two, had the basic plan
of large anterior laniaries followed by
smaller close-set teeth in the lower jaw,
except that the latter were variably 1-, 3-,
or 5-cusped. These and other cranial and

Museum (Natural History) (Owen 1870,
plates XVII and XVIII). Furthermore, the den-
titions of the midmaxillary portions of these
skulls, while not recognized as diagnostic
for the genus, are topographically identical
and differ from those of Eudimorphodon

29 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

and Pete/nosaurus. Compared to pterosau-
rian genera of the Upper Lias in England
and Germany, the maxillary portion is not
so deep as in Dorygnathus, the antorbital
fenestra is much shorter than in
Parapsicephalus, and the base of the orbit
is not rounded as in Campylognathoides.
However, the Yale material matches
Dimorphodon in all these respects. The
preserved portion of the skull at hand is not
preserved in Pete/nosaurus, but the pro-
portions of the postcranial material are
more similar to Dimorphodon than to
Peteinosaurus. These specimens also
come from the same Hettangian horizons
as the known specimens of Dimorphodon,
the only pterosaur from that area or strati-
graphic level. This is not a good criterion of
taxonomic placement, but is strong circum-
stantial evidence. No pterosaur is reliably
reported from more than one stratigraphic
horizon, and geographically the genera are
highly endemic. On these bases there
seems to be adequate justification for as-
signing these specimens to Dimorphodon
macronyx.

Reconstruction of the Skull

The sutural connections of pterosaur skulls
are often obscured, and conflicting interpre-
tations have resulted. Four reconstructions
of the skull of Dimorphodon are repro-
duced in Figure 5. Of these, Arthaber’s is
perhaps most nearly correct in several im-
portant features, including the dentition,
the jugal, and parts of the lower jaw. He
shows that, while the posterior maxillary
teeth do become progressively smaller,
they do not become as fine or as numerous
as the lancet-shaped teeth of the lower jaw.
But the lower jaw is not as deep as Arthaber
figured it: most of what he, and probably
the other authors, perceived as the lower
posterior part of the left ramus is actually
both rami, compressed together and slight-
ly displaced. Again, the configurations of
the bones of the roof and back of the skull

are hypothetical, since they are only partly
preserved in known specimens.

The reconstruction in Figure 6 attempts
to incorporate the preserved YPM skull
material into the general plan of the BMNH
skulls. YPM 9182 is considerably smaller
than YPM 350, and this is slightly smaller in
turn than the three specimens in the British
Museum, which are complete enough to
give some indication of total size.
Accordingly, the Yale specimens can be
considered juvenile, and the maxillary por-
tion of YPM 9182 gives some insight into
juvenile characters of the skull that differ
from those of the adult form. This skull frag-
ment is not congruent with those portions
of the two British Museum skulls. When
scaled upward isometrically, either the
upper jaw becomes too deep, or the width
of the preorbital opening becomes too
short. The juvenile form of the skull appears
to be relatively shorter and higher than the
adult form. As reconstructed, the ratio of
the length of this skull to its maximum
height is approximately 2.5. In the larger
British Museum skulls (41212, R 1035), the
length is at least three times the maximum
height. The restoration of the skull of YPM
9182 suggests a length of approximately
142 mm, about 55% of the larger British
Museum skulls, whereas the tibia (YPM
9182 H) is 65% of that of BMNH 41212 and
the humerus (YPM 9182 C) is 70% of the
same specimen. Thus, not only is the size
difference considerable, but different re-
gions of the skeleton grow at different
rates. A similar tendency can be seen in
juveniles of Pterodacty/us (Wellnhofer
1970) and birds, which have relatively
shorter, higher skulls than adult forms. This
appears to be generally true among
tetrapods.

The skull of Dimorphodon has some-
times been compared to a bicycle in
lightness, economy, and strength of con-
struction in the strutlike facial bones. The
Cranial vault and snout are not nearly so
high in later pterosaurs. The remarkable
lightness and delicacy of construction in
the pterosaur skull are evident even from

30 Dimorphodon macronyx
New Material

(Buckland)

Postilla 189

the few fragments preserved in YPM 9182.
The thickness of the maxilla cannot have
exceeded a few millimeters, even in the
larger specimens of Dimorphodon. Its
structure consisted of two paper-thin lami-
nar veneers separated by a spongiose layer
of cancellous bone, the whole structure
scarcely wider than the diameter of the lar-
gest teeth. When crushed, the laminar
layers around the larger teeth have often
been abraded away, and the alveoli
destroyed, which results in separation of
these teeth from the jaw. In life, however,
these must have been firmly anchored, as
the remaining teeth show (Fig. 4a). The con-
struction of the pterosaur skeleton is tes-
timony that the strength of a skeleton is not
dependent solely on the thickness of bone,
but rather on the interaction and arrange-
ment of both hard and soft tissues in
response to the forces of stress most
frequently encountered by the animal.
Pterosaurs show how far the limits of reduc-
tion of hard tissues can be taken without sa-
crifice of essential functions. This observa-
tion has been explored in detail with regard
to the postcranial skeleton, particularly as it
relates to flight (Hankin and Watson 1914:
Bramwell and Whitfield 1974), but has
never been considered with regard to the
construction of the skull.

Identification of Small Bones in the
British Museum Dimorphodon
Specimens

The importance of the Peabody Museum
specimens of Dimorphodon is that they
are largely uncrushed. Some bones, like the
humerus, are better preserved than in any
other specimens of Dimorphodon; other
bones, like the distal tarsals, can be studied
for the first time. Reference to the speci-
mens of Dimorphodon in the British
Museum (Natural History) helps to identify
previously unrecognized elements among
the latter material, including carpal and
tarsal bones.

The only carpal element preserved in the
Yale material of Dimorphodon is the right
medial (usually called “lateral”) carpal of
YPM 350 H (Figs. 12a, 13a). However, it has
not been generally appreciated that most of
the elements of both wrists are preserved
in the type specimen of Dimorphodon
(BMNH R 1034). The left wrist is in place,
but partly obscured by the overlying first
wing-phalanx. This specimen was recently
damaged when the collections were
moved to the new wing of the British
Museum (Natural History), and the
metacarpal-phalangeal region shattered.
The proximal end of the pteroid, identified
by Owen (1870:44, as “styloid’), is now
broken off. Of the right wrist, the proximal
carpals are represented by the piece
marked /in Buckland’s (1835) plate (Fig.
21). This piece, along with bones marked k
and /, Buckland included in the right
carpus. kis the medial carpal, identical to
YPM 350 H, but /is a lateral distal tarsal. A
small sliver of bone in the same area of the
slab, labeled by Buckland e, was identified
as a rib, but it is in fact the right pteroid
bone and its supporting sesamoid base.

Owen did not identify this bone, but he
claimed to find both pteroids in the jumble
of wing bones that covers the back of the
skull of BMNH R 1035. He did not, however,
indicate thenvin his plate, and | have been
unable to verify his identification. Neither
pteroid is clearly visible in BMNH 41212.

Wild (1978) described for the first time
small sesamoid bones dorsal to the distal

Fig. 21 >

The type specimen of Dimorphodon macronyx
(BMNH R 10384), as illustrated by Buckland
(1835, plate XXVII). Buckland did not realize
that the features labeled 3”and /in his figure 1
belonged to the same bone (the wing-
metacarpal), and therefore his reconstruction
of the wing in figure 2 is missing a joint at the
wrist. The jaw shown in figure 3 was not asso-
ciated with other material; Buckland guessed
correctly that it pertained to the pterosaur he
had first described in 1829.

—— : | ; Ceol: Frans: 2° Series, Ved Il FL, 27,
oe hr Teeth, magnified : :

Se aoa AERO,

jeualey,\) MEN

XAUOIIEW UOPOYAJOUIG. LE

(pue|yONg)

#7

681 BFlINSOdg

" ; y 0? Cy Je, We hed
hat dices Ftercdacylus macvnys found inthe lias, Lyne Regis Dec Vis. Scaler Nabe

(Buckland)

32 Dimorphodon macronyx
New Material

Postilla 189

ends of the penultimate phalanges of the
hand of Eudimorphodon. |t should be
noted here, in light of this most interesting
discovery, that these elements have also
been preserved in Dimorphodon. |n the
type specimen (BMNH R 1034) there is one
behind the third claw of the left hand, while
in BMNH 41212 they are visible behind the
claws of the first and second digits of the
right hand (Fig. 22). Dr. Wild (personal
communication) has since recorded an-
tungual sesamoids in a Dorygnathus speci-
men in the collections of the Institut fur
Paldontologie und historische Geologie in
Tubingen, a finding | can confirm from
casts sent to me by Dr. Frank Westphal. |

have been unable, however, to find evi-
dence of them behind the claws of the foot
in Dimorphodon (BMNH 41212) or any
other pterosaur.

Fig. 22

Detail of Dimorphodon macronyx, BMNH
41212, showing right manus and left pes, the
latter in plantar view. Abbreviations: /dt lateral
distal tarsal; /t left tibia; mc, metacarpal; mat,
medial distal tarsal; mz, metatarsal; rt right
tibia; ses, sesamoid; woh, wing-phalanx.
Large Roman numberals designate phalanges,
except for wing-phalanges. Scale = 1 cm.

33 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

Articulations and Function of the
Forelimb

The fine preservation of many prominences
and articular surfaces in the Yale material is
crucial to the interpretation of functional
morphology of the appendicular skeleton of
Dimorphodon. From these remains, certain.
hypotheses about how pterosaurs walked
and flew may be presented for the first
time, subject to corroboration by compara-
tive functional anatomy and aerodynamic
requirements.

YPM 350 F, the right humerus described
earlier, is probably the best-preserved bone
of this kind among pterosaurs. Several nota-
ble features have been clarified, especially
the pronounced torsion of the shaft, the
ridges showing attachments of muscles
along the shaft, and the features of the
distal end, particularly in palmar view.

The movement of the humerus cannot
be understood without reference to the pec-
toral girdle. Pectoral elements are absent
from the Yale Dimorphodon material, and
the sternum is not recorded in any
specimen. The bones Buckland (1835) took
for the sternal plate in BMNH R 1034 are
cervical vertebrae. However, a well-
preserved platelike sternum is known in the
earlier pterosaur Eudimorphodon, from the
Norian of Italy (Zambelli 1973, Wild 1978),
and in all later forms; so there is no reason
to doubt its presence in Dimorphodon. The
pectoral girdle in Dimorphodon (BMNH
41212) is of typical form and extremely
birdlike (Fig. 23). The coracoid is elongated
and stout, and is fused to the bladelike, at-
tenuated scapula. It has a prominent pro-
cess similar to the acrocoracoid of birds
located anterior to the glenoid fossa, which
is bounded anteriorly and posteriorly by
raised bony knobs. These served as the site
of origin for several forelimb muscles, and
restricted the humerus from slipping out of
its socket. The concave, saddle-shaped
head of the humerus otherwise moved
freely, and was capable of being retracted
against the body to fold the wing as in
birds. This action was further supplemented

Fig. 23

Right pectoral girdles in lateral view. Above,
Dimorphodon; below, Aquila chrysaetos.
Abbreviations: 2, acrocoracoid process; ¢,
coracoid; f furcula; s, scapula. Scale bar =
einer

by flexion of the elbow and metacarpal-
phalangeal joints.

The primary action of the humerus was
in the flight stroke. The mechanics of the
flight stroke can be approached in three
ways: (1) joint mobility and articular
limitations; (2) comparative functional anal-
ysis with other flying vertebrates; and (3)
aerodynamic requirements for flight, to
which the flight apparatus must conform.

34 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

Only the first approach will be considered
here.

It was stated above that the humerus
could be fully retracted to close the wing
against the body. It could be protracted ap-
proximately 90°, or to the point where the
axis of the shaft would be perpendicular to
the plane of the glenoid fossa (Fig. 24). Fur-
ther protraction was prevented by the bony
knob anterior to the glenoid fossa. The
humerus could also have been raised and
lowered through an arc of approximately
oOr,

Because radius and ulna are not suitably
preserved in any rhamphorhynchoid ptero-
saur described thus far, the limitations of
movement at the elbow can only be
estimated. The elbow is a hinge joint that
corresponds in mechanical detail quite
closely to the elbow of birds. The similarities
of the processes and areas of muscular at-
tachment at the distal end of the humerus
have already been noted (Fig. 10c). A mobil-
ity approximately equivalent to that of
birds, i.e., somewhat less than 180°, can be
fairly assumed. The joint separating the
fourth metacarpal and wing-finger is a
hinge joint of great mobility, very similar to
the outer joint of the bird wing (Bramwell
and Whitfield 1974). The principal structur-
al difference, of course, is that this joint is
the carpometacarpal in birds, whereas in
pterosaurs it is the metacarpophalangeal
joint of the fourth (wing) finger (Fig. 25).
This articulation is well preserved in several
BMNH specimens, though not in the Yale
material. ln Dimorphodon there is some
slight movement possible between the zeu-
gopodials and the proximal carpal, and be-
tween the distal carpal and the metacarpals,
but the proximal and distal carpals interlock
snugly. It is difficult to assess the amount of
movement between the phalanges of the
wing-finger. These joints are flattened ball-
and-cup articulations, never anchylosed
but also without clearly developed collater-
al ligament fossae or any other evidence of
restricted motion. The only indication that
movement was restricted between these
phalanges comes from relatively undis-

Fig. 24

Right pectoral girdle and articulated humerus
of Dimorphodon. Above, in retracted position:
below, protracted as in flight. Note down-
and-forward rotation of humerus during flight
stroke. Scale = 1 cm.

turbed articulated specimens, in which the
wing-finger always forms a taut, bowlike
structure. Hence, the majority of movement
in the wing occurred at three joints: the
shoulder, the elbow, and the base of the
fourth finger. The first had a wide range of
movement in several planes, while the
second and third were simple hinges with
extensive mobility in only one plane. It is
evident that the wings of birds and ptero-
saurs are divided into equivalent functional
units, analogous in a mechanical sense but
not homologous in structure.

It is curious that in rhamphorhynchoid
pterosaurs, as in theropods, the phalanges
of the manus are generally more robust
than those of the pes, and the claws are
larger and more trenchant (Fig. 22). Larger
theropods often tended to reduce the
forelimbs, while pterosaurs enlarged them.
It is possible that the first three digits of the

35 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

pterosaur

Fig. 25

Comparison of the right forelimb skeletons of a
generalized rhamphorhynchoid pterosaur
(above) and a bird (below): only the proximal
portion of the pterosaur’s first wing-phalanx is
shown. Abbreviations: c carpus; 4, humerus;
me, metacarpus; pt pteroid: r radius; u, ulna.
I-IV, digits.

pterosaur hand were enlarged mainly as a
developmental consequence of the hy-
pertrophy of the fourth finger. Only the pha-
langes of the first three digits were
movable, because the first three metacar-
pals were appressed and bound, probably
ligamentously, to the fourth. But the well-
developed flexor tubercles of the
phalanges, especially the claws, seem to in-
dicate considerable movement was
possible. Ginglymal grooves are deep and
allow a wide range of flexion and
extension; one is reminded on examination
of the unguals that Buckland did not idly
name this species macronyx. The enor-
mous flexor tubercles of the claws suggest
strong powers of grasping, perhaps in
climbing, but equally possible for manipula-
tion or gouging, perhaps in predation. A
common function of sesamoid bones in
Such situations is to sustain tensile forces
around the extensor site of a joint where
much flexion occurs (Hildebrand 1974),
and this would be expected in cases where
flexion is indicated by such well-developed
Ungual tubercles. If so, it can be suggested
that some type of grasping function was
highly probable. In the past, suggested uses
of these digits have included grooming,
feeding, hanging from cliffs, and moving be-

tween the branches of trees. Of these, none
can be logically excluded, but there is no
direct evidence for any. Pterosaurs were
not necessarily arboreal, but they were
predators. | would suggest that a function
in predation is more likely than climbing or
hanging. It should be remembered, though,
that flight was the primary function of the
forelimbs. No movement that contradicted
the requirements of joint mobility and artic-
ulation for the flight stroke would have
been possible: this seems to be the only
caution.

Articulations and Function of the
Hindlimb

The hindlimb of Dimorphodon is better pre-
served in the Yale specimens than in any
other early pterosaur, and allows considera-
ble insight into the stance and gait of the
limb as well as particulars of its kinematics.
No pelvic bones are preserved, however.
These are known from the BMNH speci-
mens and are of more or less standard pte-
rosaurian type. The ilium is low and
bladelike, with rodlike processes anteriorly
and posteriorly. The acetabulum is
imperforate, and ilium, ischium, and pubis
seem to contribute to it. The ischium and
pubis are fused in a continuation of the
platelike form seen in the ilium. Most of this
broad expansion is generally identified as
the ischium, with the pubis consisting of a
vertical, stalklike element incorporated into
the pelvic plate. The two separate stalks of
the pubis were joined medially by a paired
element regarded as the prepubis. Its form
is variable in pterosaurs: it is rodlike and
divided distally in Rhamphorhynchus
(Wellnhofer 1975), but in earlier forms it is
flatter and roughly spatulate, with a
diamond-shaped median blade in place of
the prepubic “prongs” seen later in
Rhamphorhynchus. The edges of these
blades are irregular and rugose, and sug-
gest extensive cartilaginous attachment as
in the pelvis of crocodiles. Pterosaurs
lacked a mammalian diaphragm, but it is

36 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

possible that the prepubis in pterosaurs
served as the origin of a muscle similar to
the M. diaphragmaticus of the crocodile,
which via its insertion on the liver acts as a
piston mechanism for inspiration by pulling
air into the lungs (Gans and Clark 1976). In
flight, respiration may have been accom-
plished in part by expansion and contrac-
tion of the chest along with the flight
stroke. These suggestions, however, are
offered only by analogy with birds and
crocodiles.

The puboischiadic plates were fused to
some extent along their ventral borders.
This statement is contrary to the traditional
view (Wellnhofer 1970, 1975, 1978), but
there are notable examples in which the
median synthesis has been preserved.
These include the Carnegie Museum speci-
men of Campylognathoides liasicus, the
type specimen of C. z/tte//in the Staat-
liches Museum fur Naturkunde Stuttgart,
and a slightly distorted but otherwise fully
articulated and uncrushed pelvis of Pteran-
odon in the Peabody Museum (Eaton
1910, plates X and XI). The consequence of
this arrangement is that the acetabulum is
made to face downward and outward, not
upward and slightly backward as in Welln-
hofer’s reconstructions (Padian 1980).

The rest of the pterosaur hindlimb is
functionally analogous to bipedal dinosaurs
and birds, not to bats or other arboreal
mammals as traditional reconstructions
imply. It will be recalled that the head of the
femur is set off to the side of the main axis
of the shaft, not central to the shaft as in
bats. This limits movement of the femur to
protraction and retraction in a nearly para-
sagittal plane. The orientation of the distal
articular surfaces with respect to the axis of
the femoral shaft indicates that the articula-
tion of the femur with the tibia and fibula
was normally much closer to a right angle
than a straight line, when viewed from the
side. The knee joint was, therefore, a hinge
allowing no significant rotation during
normal locomotion. Schaeffer (1941) ob-
served that a well-offset femoral head cor-
responds to the role of the tibia as the main

bearer of weight, and went on to suggest
that the movement of the pterosaur hind-
limb must have been largely restricted to
the parasagittal plane, as in birds. This
agrees with the idea that a large medial
condyle is a primary indicator of parasag-
ittal locomotion (D. Brinkman, personal
communication.) The length of the fibula is
variable in proportion to the tibia in both
birds and pterosaurs, and this is to be ex-
pected of an element that is so reduced in
size and function. The expected position of
the tibia would be more or less vertical
when the animal was at rest. In motion, the
tibia would have swung through a wide
parasagittal arc while the femur remained
ina more horizontal position. The motion of
the distal end of the femur would have
been more up-and-down than back-
and-forth, like the knees of birds but unlike
the knees of humans.

The tarsal region of pterosaurs, detailed
here for the first time, demonstrates the
movements within the ankle region. The
proximal tarsal bones (astragalus and
calcaneum) can only be fused to the tibia-
fibula, as they are here and in birds and
theropods, when there is no movement be-
tween these limb elements. The formation
of a highly developed double condylar joint
emphasizes the restriction of motion to a
fore-and-aft plane, and the distal tarsals
show clearly on their proximal faces the de-
pressions that receive the medial and lateral
condyles of the tibiotarsus. The distal end
of the tibiotarsus has many topographic
features that correspond to insertions and
grooves for tendons and ligaments of the
main flexor and extensor muscles of the
avian foot (see Fig. 19). The distal end is ex-
panded anteriorly in birds, bipedal
dinosaurs, and pterosaurs, not distally as In
sprawling forms. This shows that the axes
of the tibia and the elongated metatarsals,
as viewed from the lateral side, did not form
a stright line but a sharp angle. Most flexion
and extension of the distal tarsals and meta-
tarsals against the tibiotarsus occurred
within a range of about 90°to 150°, approx-
imating the range in birds.

37 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

The distal tarsals preserved in the Yale
Dimorphodon material also provide greater
insight than before possible into the artic-
ulations of the distal tarsal elements with
the metatarsals (Fig. 26). On their distal
faces a series of grooves mark where the
distal tarsals receive metatarsals II-IV, the
fifth offset sharply in a distinct, diagonally
placed channel of its own. As with the knee
and tibiotarsal joints, there was little possi-
bility of rotation here.

The entire ankle assembly is less rigidly
constructed than those of birds in the
sense that the latter group has more fusion
and definition of bony elements that form
the articulations of the ankle. However, soft
tissues such as cartilage, tendons, and liga-
ments still play an extensive part in the
function of the avian foot, as Cracraft
(1971) has shown. This situation in ptero-
saurs compares favorably with that of the-
ropod dinosaurs, where, although some
fusion of the metatarsals may occur, the
distal tarsals are poorly defined when com-
pared to the pterosaur’s (see Ostrom 1969
for comparison with De/nonychus).
Therefore, because rotation at the ankle is
not assumed to have been a significant
component of gait in theropods, it is unlike-
ly to have been important in pterosaurs.
The pterosaurian tarsal bones do not bind
the joint rigidly, but suggest strongly from
their features that the normal range and
extent of motion was primarily parasagittal,
like the movement of the knee. The ptero-
saurian ankle is properly regarded as
mesotarsal, as in birds and dinosaurs,
because the primary flexion is between
proximal and distal tarsals and there is no
movement between the proximal tarsals.

The function of the fifth metatarsal and
its long, aberrant toe remains a mystery, al-
though it seems clear that digit V did not
operate like the other digits. Wild (1978)
has suggested the idea of stretching a web
of skin between digits IV and V for paddling
through the water, by analogy with a possi-
ble function in the foot of the Triassic
marine reptile 7anystropheus (Wild 1973).
This is certainly a possibility, although the

variable form of this digit in rhamphorhyn-
choids and its eventual loss in pterodacty-
loids (Wellnhofer 1978, Abb. 17) should
also be considered. The fifth metatarsal,
which is not preserved in the Yale speci-
mens but which is well shown in BMNH
41212, has a variety of prominences and
tuberosities indicative of complex motion.
An especially well-marked groove, for
instance, is located on the plantar surface
between two pronounced tuberosities. Ten-
dons running along this groove evidently in-
serted on a rugose prominence at the distal
end, and would have produced strong flex-
ion of this digit (Fig. 26). The function of
digit V in posture and locomotion, whether
terrestrial or aquatic, is still not established,
but the fifth metatarsal of Dimorphodon is
the largest known among pterosaurs (in
Campylognathoides it is also quite large;
in Eudimorphodon it is unknown), and its
robustness in these early forms may indi-
cate a primitive function that was reduced
or lost in later rhamphorhynchoids.

The ginglymal grooves of the distal ends
of metatarsals II-IV describe an arc that
begins approximately in line with the axis
of the metatarsal shafts and continues be-
tween the ginglymal condyles to the shaft
axis (Fig. 27). This is comparable to the con-
dition in birds and dinosaurs and unlike the
condition in crocodiles, lizards, and turtles.
The latter reptiles are plantigrade and nor-
mally do not walk with a great deal of flex-
ion between metatarsals and phalanges. In
these groups the distal ends are normally
not bicondylar and the joint facets are
terminal, not subterminal. Nor in these
groups do the metatarsals function as a
coalesced unit, as they do in birds and
dinosaurs, and pterosaurs. Instead, as Brink-
man (1980) has shown for the caiman, each
metatarsal lifts in sequence (I-IV) and the
main extension and flexion of the foot
occurs at the ankle. In pterosaurs a great
deal of flexion occurred at the phalangeal
joints, as their ginglymal facets show, be-
cause the metatarsus was raised off the
ground as it is in birds and theropods. The
main axis of support of the hindlimb, then,

38 Dimorphodon macronyx (Buckland) Postilla 189
New Material

Fig. 26 ib
Right ankle assembly of Dimorphodon

macronyx. The tibia and metatarsals are

shown in anterior view. Spaces for the recep-

tion of metatarsals II-IV are indicated. Scale =

1mm.

POST
proximal

ANT

ANT
distal

POST

39 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

Fig. 27A

Distal ends of metatarsals in distal (left), lateral
(center), and plantar (right) views. @, turtle; &
caiman; © theropod dinosaur; a Dimorphodon
macronyx, e, tarsometatarsus of a bird.

Arrows indicate the limits of the ginglymal
grooves. Not drawn to scale.

Fig. 28 V

Right pelvis and hindlimb of Dimorphodon
macronyx,restored in erect position, slightly
extended, in lateral view. Scale = 5 cm.

was through the two distal condyles of the
tibiotarsus, through the two distal tarsals to
the second, third, and fourth metatarsals
(Fig. 28). These properties suggest quite
strongly that pterosaurs were not planti-
grade walkers, but digitigrade, contrary to
Wellnhofer’s (1978) conclusions. No fea-
tures suggest a plantigrade mode of
locomotion. Furthermore, all available evi-
dence speaks for a completely upright,
parasagittal stance and gait in Dimorpho-
don and all other pterosaurs. In all skeletal
features that reflect the mechanics of limb
movement, pterosaurs agree with birds and
bipedal dinosaurs, not with crocodiles,
thecodonts, or any sprawling reptiles.

Reconstruction of Dimorphodon

The skeletal reconstruction of Dimorphodon
given in Figure 29 reflects the conclusions
of this work. When the actual articulations
and possible actions of the bones compris-
ing the appendicular skeleton are
examined, the traditional picture of ptero-
saurs as clumsy quadrupeds does not make
sense. Pterosaurs had well defined joints in
the limbs, and their movements can be
reconstructed with a high degree of
confidence. The mechanics of these joints
cannot be compared with those of
crocodiles, thecodonts, or living reptiles,
but in many cases are virtually indis-
tinguishable from those of birds and bipedal
dinosaurs, as the preceding analysis has
shown. Some articular surfaces, like the
head of the humerus, the area of the wrist
and hand, and the distal tarsals, are not pre-
cisely like those of any known animals, al-
though functionally analogous. Even so,
these joints are all well defined enough to
allow a confident approximation of the di-
rection and range of their movement, and
in every case are functionally analogous to
the corresponding joints in birds or
dinosaurs.

Dimorphodon has been restored in
Figure 30 as arrapidly moving terrestrial
biped. The hindlimbs were apparently quite

jeualeyy Man

XAUOIIEW UOPOYAIOWIG Ob

(pue|yjong)

681 BlLSOd

Fig. 29

Restoration of Dimorphodon macronyx in bipe-

dal terrestrial progression. Skull about 20 cm

in length; wingspan about 120 cm. Scale = 10 cm.

Fig. 30

Life-restoration of Dimorphodon macronyx, by
J. Kevin Ramos. Wing configuration inferred
from Rhamphorhynchus, “furry” covering
from Sordes pilosus. The horny covering
shown on the rostral area is based on an infer-
ence by Wellnhofer (1975) regarding
Rhamphorhynchus.

jelaley\y MEN

XAUOIIEUI UOPOYA/OWIIG

Lv

(Pue|yonNg)

681 BIINSOd

42 Dimorphodon macronyx — (Buckland)

New Material

Postilla 189

adequate to support the body without the
aid of the forelimbs. In fact, the forelimbs
could not have “walked” in the typical reptil-
ian manner because of limitations on the
rotational and protractional capabilities of
the humerus, and the fact that the elbow is
a simple hinge. The proportions of the hind-
limb of Dimorphodon and all other ptero-
saurs are unusual among reptiles: the meta-
tarsals are elongated, and the tibia is ap-
preciably longer than the femur. This situa-
tion is found in no thecodonts except
Lagerpeton, Lagosuchus, and
Scleromochlus, and in no crocodiles, but is
characteristic of small bipedal dinosaurs
and birds. These proportions are assumed
to correlate with agility, rapid movement,
and possible cursoriality (Coombs 1978),
and are certainly typical only of advanced
archosaurs.

Acknowledgments

It is my great pleasure to thank Dr. A. J.
Charig of the British Museum (Natural
History) for his kind permission to study,
photograph, and refer to specimens in his
care. For their cooperation and help | am in-
debted to the preparators and staff of the

British Museum (Natural History), including
Ron Croucher, Sandra Chapman, and Cyril
A. Walker. It is also a pleasure to acknowl-
edge the achievement of Rebekah Smith,
who prepared the fragile specimens in the
Peabody Museum by hand; Mary Ann
Turner, for her incomparable sleuthing of
the Peabody Museum records; and the
staff of Manuscripts and Archives, Sterling
Memorial Library, Yale University, for
access to Marsh's correspondence. Advice,
help, and facilities for the photographs in
this paper were provided by Professor
David E. Schindel of the Division of Inverte-
brate Paleontology at the Peabody
Museum, and Paul Morris provided
darkroom help. Previous drafts of the
manuscript were greatly improved by the
suggestions of Professors Bruce H. Tiffney,
J. David Archibald, John H. Ostrom, and
David E. Schindel. Finally, my deepest
thanks are due to Professors Keith S. Thom-
son and John H. Ostrom for allowing me to
describe the Yale material, and for all their
helpful discussion. This work was support-
ed by the National Science Foundation
(Grant No. DEB-780211) and by a Yale Uni-
versity Graduate Fellowship, and is based
on part of a Ph. D. dissertation at Yale
University.

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The Author

Kevin Padian, Department of
Paleontology, University of California,
Berkeley, CA 94720.