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,t> FIELDIANA • GEOLOGY

Published by
CHICAGO NATURAL HISTORY MUSEUM

Volume 14 February 28, 1966 No. 10

Relationships of Diadectes^

Everett Claire Olson

Research Associate, Division of Paleontology
Professor of Vertebrate Paleontology, University of Chicago

SCOPE OF THE STUDY

Diadectes, a genus of reptile from the low^er Permian, has had a
varied career with respect to its taxonomic position and has played
a prominent role in controversies about origin and phylogeny of the
reptiles. Confusion has arisen from tv^o sources. First, the skull
Diadectes is difficult to study because of the spongy texture of the bone
as emphasized by Watson (1954), among others. Second, it is quite
distinct morphologically from its contemporaries and predecessors,
except for some rather poorly know^n genera that, together w^ith the
name genus, constitute the Family Diadectidae. The stock is an-
cient, going well back into the upper Carboniferous. It is only the
rather late member, Diadectes, that can be studied in detail.

Watson (1954) surveyed the history of the genus. Prior to that
time several roles had been suggested for Diadectes. It was the basis
of the group of primitive reptiles termed cotylosaurs, and, of course,
is the name bearer of the suborder Diadectomorpha, including the
diadectids, procolophonids, and pareiasaurids.

Diadectes has been considered to be fairly close to the ancestry of
the Chelonia (see, for example, Olson, 1947). Its morphology has
been compared with that of seymouriamorphs, and relationships have
been suggested. These supposed relationships to chelonians and to
seymouriamorphs have led to speculations upon possible multiple
origins of the reptiles (Olson, 1947, Watson, 1954).

^ This study was supported in part by National Science Foundation Grants
B19093 and B2453.

No. 1003 199

Library of Congress Catalog Card Number: 66-171t68 .._ iQO^^V I^F ^^'"^

200 FIELDIANA: GEOLOGY, VOLUME 14

Watson (1954) looked at Diadectes somewhat differently from
anyone who had considered it previously, including himself. He
placed the genus with the Sauropsida, using Goodrich's (1916) basic
reptilian dichotomy of Sauropsida and Theropsida. So conceived,
Diadectes is a very early representative of the sauropsids and, through
its relatives, carries this stock very far back in reptilian history. In
his study Watson gave a fairly detailed analysis of the skull, with
interpretation at variance with earlier interpretations on some points.

Since 1954 Diadectes has been mentioned in a number of papers.
Its phylogenetic position has been treated in particular by Vaughn
(1955), Hotton (1959), Parrington (1962) and Olson (1962). Most
of the recent studies have been concerned primarily with the auditory
structures, following up Watson's (1954) interpretation of the middle
ear as sauropsid. A most recent, published while this paper was in
press, suggests that Diadectes should be considered an amphibian
(Romer, 1964) . The present paper has not been modified to conform
to this assignment, although the suggestion has obvious merit.

For all that has been done, fully satisfactory knowledge of the
skull of Diadectes is still wanting. This is especially true for the brain
case and the ear region. The current investigation was undertaken
in an effort to overcome this deficiency by a study of serial sections
of the posterior part of an excellent skull. The right posterior quad-
rant of CNHM UR 27 was sectioned with an interval of .75 mm.
between sections and records were made by nitrocellulose peels.
Transverse sections were cut. They were numbered successively from
posterior to anterior. Both graphic and model reconstructions were
made, the latter in both wax and bioplastic.

A great deal of detail has emerged. Some of it clarifies old prob-
lems and some of it introduces new ones. A complete restudy of
possibly related genera appears to be in order, using this new infor-
mation as a starting point. This, however, will take a long time.
In order not to hold up the information now at hand, this present
article with more limited aims has been prepared.

The study of relationships is largely restricted to those between
Diadectes, Chelonia and Seymouria. Data are presented in the form
of reconstructions, descriptions, and figures of serial sections. Where
possible, interpretations have been made, but there are structures
revealed by the sections for which no explanations have as yet been
found. A brief account of some of the data and some of the figures in
the present paper was published while this paper was in press (Olson,
1965).

OLSON: RELATIONSHIPS OF DIADECTES

201

Fig. 99. Sketches of the left posterior portion of the skulls of A, Seymouria;
B, Diadectes; and C, Chelydra, showing general features in ventral aspect. Not
to scale.

For the comparisons between Diadectes and Seymouria, the poste-
rior right quadrant of a specimen of Seymouria (USNM 17046) was
sectioned in a comparable manner. An interval of .50 mm. between
sections was used. This specimen was supplied by Nicholas Hot-
ton III of the U, S. National Museum. I am grateful to the museum
and to Dr. Hotton for permitting me to section part of it.

Modern Chelonia have been used for studies of the otic region and
cranium. Rather thick sections of a skull of Chelone were cut and, for
comparison, a head of this same genus was sectioned. Prepared ma-
terials of Chelydra provided additional information and various other
turtles were used as they proved of help.

MORPHOLOGY AND COMPARISONS

General

Figures 99-101

The cited figures show comparable views of Diadectes, Chelydra,
Triassochelys (fig. 100) and Seymouria. They speak for themselves
with respect to the gross resemblances and differences of these
genera. The palate and temporal regions of Diadectes and the illus-
trated turtles are clearly somewhat similar, although there are im-
portant differences. Other genera of Chelonia show varying degrees
of similarity to Diadectes. Some are much less similar than the ones

202

FIELDIANA: GEOLOGY, VOLUME 14

•0 40 20

Fig. 100. Sketches of the left posterior portion of skulls of A, Diadedes;
B, Triassochelys [Stegochelys]; and C, Seymouria, showing general features of tem-
poral regions. The ossified "stapedial" plate is removed in Diadedes. Numbers
1, 20, 40, etc., refer to approximate positions of serial sections in the sequences
1-87 in Diadedes and 1-77 in Seymouria. Not to scale.

figured. Seymouria is rather different from the other two in both
palate and temporal regions.

The brain cases, seen in median, longitudinal section in figure 101,
show resemblances which conform in general to the basic reptilian
pattern. Seymouria, although quite distinct in the temporal and pal-
atal areas, conforms rather closely to the others in this view. Com-
parisons such as those possible from these figures at a somewhat less
detailed level, as far as the brain cases are concerned, have provided
the primary bases for interpretations of relationships. They have
been the best available, and thus useful, but it is now clear that they
were less than sufficient for definitive interpretations. Details to be
seen in the sections presented in the following pages of this paper by
no means answer all of the questions. They give a basis for checking
previous suggestions, offer some promising leads concerning the phy-
logenetic position of Diadedes, and they point to areas that should be
studied among possible relatives of this genus.

The Middle Ear and the Stapes

Figures 102-107

The jaw mechanisms in Diadedes and many of the chelonians
seem to have been basically alike. Very strong crushing action with
little lateral movement is characteristic. There are many structural
similarities. These are reflected in the quadrate bones and in their
mode of participation in auditory structures. Somewhat similar ar-
rangements are found elsewhere among the reptiles: in Rothia, among

OLSON: RELATIONSHIPS OF DIADECTES

203

Fig. 101. Posterior part of skulls of A, Diadectes; B, Seymouria; and C, Che-
lydra. Skulls shown looking at midplane as exposed by longitudinal section.
Seymouria and Diadectes reconstructed from bioplastic models and serial sections.
Not to scale.

captorhinomorphs, in some of the placodonts, in Trilophosaurus, and
in some of the mosasaurs.

There is a wide range of structural variation in the turtles. The
two used for detailed comparisons, Cheyldra and Chelone, are closer in
structure to Diadectes than most. They also have retained many of
the general skull characteristics of Triassic turtles. Along with the
similarities, however, there are basic differences. The quadrates in
chelonians are strongly fixed to the squamosal and periotic, forming
a massive structure which results in the enclosure of the middle ear
and various associated blood vessels and nerves. This does not occur
in Diadectes. Rather, the quadrate articulates with the skull roof in
a fairly well developed ball and socket joint as shown in figure 102,

204

FIELDIANA: GEOLOGY, VOLUME 14

and also described by Watson (1954). There is an enclosure of parts
of the ear and related structures, but it is accomplished differently,
as will be described later.

The middle ear in the Chelonia is distinctive in the presence of a
pericapsular sinus^ — a sinus that carries perilymph to the outside of
the otic capsule in a space that normally would be considered the
tympanic cavity (figure 103). The stapes,^ or columella, penetrates

ART.

Fig. 102. The ball and socket arrangement of the articulation of the quadrate
and periotic in Diadectes. The left side of the quadrate portion of the skull
(CNHM UR 28) is shown with the periotic somewhat rotated to reveal the socket
into which the ball of the quadrate fits.

this sinus in its passage to the fenestra ovalis. Lateral to the sinus,
the stapes proper meets a short extrastapes which, in some cases,
flares to produce a large, flat, ovoid tympanic plate. The stapes in
Mo is long, slender, and partially encased in a trough-like tympanic
cavity formed by the quadrate and squamosal bones. The otic struc-
ture is definitive. Similar structure in Diadectes, if this could be
demonstrated, would provide strong evidence of relationship to the
Chelonia.

In an earlier study (Olson, 1947), I indicated that there appeared
to be important resemblances between the otic region of Diadectes
and turtles. Superficially, this is the case. Now that more details
are available, however, the evidence argues, at least for the most
part, to the contrary. The structures that are important for com-

1 The term stapes will be used throughout for consistency. Where differentia-
tion of the inner and outer portions is used, these will be called the stapes and
extrastapes respectively.

Fig. 103. Otic structures and related features in Diadectes and Chelonia.
A, Diagrammatic reconstruction of the otic region of Diadectes, for comparison
with B and C. Structures which have considerable anterioposterior spread have
been brought into the same plane to show their general pattern. B, Diagrammatic
reconstruction of otic region of the box turtle (Terrepene). C, More detailed recon-
struction of otic region of the pond turtle (Emys). In A, B and C, various struc-
tures have been brought into the same plane. D, Reconstruction of the cast of the
inner ear of Diadectes, drawn in lateral aspect from wax model based on serial
sections. E, Posterior view of reconstruction of cast of brain cavity and otic region
of Diadectes, based on wax model constructed from sections. B, after Wever and
Vernon (1956); C, after deBurlet (1934). Not to scale.

205

Fig. 104. Transverse serial sections of the posterior part of the skull of Dia-
dedes through the right tympanic cavity and associated areas. A through P go
from posterior to anterior. The sections in A through P are 23-27, 29, 31, 32, 34,
37, 39, 42, 45, 50, 54, 56 respectively. For approximate locations see figure 100, A.

206

OLSON: RELATIONSHIPS OF DIADECTES 207

parisons are intricate and complex. They are most clearly shown in
the serial sections, many of which are presented in illustrations. Re-
constructions, which are somewhat easier to follow, also portray much
of the detail. The following descriptions and discussions lean heavily
upon this illustrative material to avoid the long and tedious descrip-
tions that would otherwise be needed.

1. Pericapsular Sinus

Diadedes does not seem to have a pericapsular sinus comparable
to that present in living Chelonia. There are, however, two points
of some significance. First, it is not clear whether or not there was
such a sinus in primitive turtles. Even in extremely well preserved
fossil materials it would be difficult to demonstrate positively that a
pericapsular sinus was developed, although it could be shown that
the arrangement of the hard structures was permissive. The fact is,
of course, that no studies of this region in the earliest turtles have
been made. The middle ear of chelonians could have arisen by a series
of fairly straight-forward changes from the primitive reptilian ear.
Whether this took place within Chelonia or before the group became
established is not known.

The second point is that the tympanic cavity of Diadedes, while
not like that of a turtle, also is not at all close to the type of structure
found in generalized reptiles. It is highly specialized in a direction
not commonly found among reptiles, although possibly recognizable
in a few. There may have been an extra-capsular development of the
perilymph sac, but, if so, this was different from that found in the
turtles. These points can best be brought out by a detailed descrip-
tion of the pertinent parts of the tympanic cavity.

The essential details are shown in the reconstruction of the cavi-
ties in figure 103D, E and the sections in figure 104. There is a long
tube, which we will call the otic canal (OC), leading posterolaterally
from the saccular recess of the inner ear and opening into the tym-
panic cavity (fig. 103 and fig. 104, A-I) . This opening, which has
been considered to be the fenestra ovalis, is rimmed above by the
periotic and below by the parasphenoid. Much of the tube, however,
hes within the periotic, not floored by the parasphenoid as was thought
previously. The periotic floor is thin, but distinct (see fig. 104, E-I).

Just where the fenestra ovalis lay is not completely clear. It was
suggested (Olson, 1947, Watson, 1954) that it was at the postero-
lateral termination of the otic canal. This still seems to be the most
likely location, but it is not out of the question that the stapes passed

208 FIELDIANA: GEOLOGY, VOLUME 14

part way up the tube to a membrane at some undeterminable posi-
tion. Watson (1954) noted a shelf near the termination of the otic
canal. He believed that this marked the site of contact of the stape-
dial foot and the periotic. In this event, the fenestra ovalis is repre-
sented by the termination of the otic canal. The "shelf" does not
show up in any of the specimens studied in preparation of this article,
but this may merely be the result of the excessive variation of struc-
ture characteristic of Diadectes. Until such time as a fully ossified
stapes is found, and, of course, one may never have existed, the posi-
tion of the fenestra ovalis probably cannot be fixed beyond question.

Lateral to the otic canal is a second tubular cavity (fig. 104, D-L).
This cavity has been variously interpreted. Most probably it carried
the lateral head vein. The evidence for this is best considered in con-
nection with the interpretation of the stapes and will be deferred until
that time (see p. 212) .

Near the anterior end of the otic canal, the basal septum, which
separates the otic canal from the recess between the periotic and para-
sphenoid, becomes reduced for a distance of about 1.5 mm. (fig.
104, I, J). A slot-like foramen provides an avenue of communication
from the otic canal into the recess. At about this same level the peri-
otic sends out a more ventral process (fig. 104, J) which forms a par-
tially ossified septum between the recess floored by the parasphenoid
and the floor of the otic canal. Thus a second recess is formed. There
is less than full ossification of the cartilage in this region and some,
but certainly not all, of this recess results from this circumstance.

It cannot be shown that the slit-like foramen and the recesses de-
scribed above were related to the perilymph system. It is merely
possible that they were. If this were the case and a partially extra-
capsular perilymphatic sinus were present in Diadectes, it would be
necessary to conclude that its development was completely different
from that known in turtles. It seems impossible that this hypotheti-
cal recess could have had any connection with the recessus scala tym-
pani. Unless the perilymph duct followed a remarkably sinuous
course within the otic capsule, it could not have had access to both
the cranial cavity and the region where an extracapsular perilym-
phatic recess might have been present.

The recessus scala tympani probably was closely associated with
the jugular canal (fig. 103, A-D). The canal leaves the brain case in
partial confluence with the recess of the inner ear, as it does in many
reptiles. The condition is quite similar, it would seem, to that found

Fig. 105. Successive transverse serial sections of the posterior part of the skull
of Seymouria. A through L, passing from posterior to anterior are sections 7
through 18, respectively. For approximate positions see figure 100, C. 1, A pas-
sage from the recess of the inner ear (D, E) leading to the external surface of the
periotic as shown in B and C. This passage may have resulted from incomplete
ossification, but also it may have had some unknown function.

210 FIELDIANA: GEOLOGY, VOLUME 14

in lizards. There is no indication in this area of development of a
perilymph system like that found among the Chelonia.

The complexities of this part of the otic region in Chelonia and
Diadectes have produced resemblances that are superficially similar.
Basically, however, they are very different. The condition in turtles
appears to be associated with the specialized development of the
quadrate, periotic, and squamosal. In Diadectes the complexities are
related, it would seem, to the remarkable development of the para-
sphenoid and its involvement in the otic structures.

Seymouria, as described in detail by White (1939), has some fea-
tures of the otic region, as seen superficially, that resemble those found
in Diadectes (figs. 105-107). This resemblance is largely confined to
the expanded parasphenoid, the lateral position of the fenestra ovalis,
and the involvement of the parasphenoid in the formation of the
fenestra (figs. 105, G-K, 106, A-E and 107). Some details deter-
mined from the sectioned specimen used in the current study have a
bearing on the possible relationships of these two genera.

The nature of the fenestra ovaHs as revealed in sections is shown
in figures 105, J and 107. It is not clear from the sectioned specimen
whether or not the parasphenoid actually formed part of the rim of
the fenestra ovalis, but it did, at least, lie just anterior to it. What-
ever the exact relationships, it is clear that there is a rather long otic
canal and that, as in Diadectes, this lies almost wholly within the peri-
otic (fig. 105, G-J).

Posterior to the otic canal (fig. 105, F-H), as it enters the recess
of the inner ear, the saccular recess is confluent with the exit of the
jugular canal. There seems little doubt that the perilymphatic duct
entered the recessus scala tympani in a manner very similar to that
inferred for Diadectes. There is, however, no foramen in the floor of
the otic canal, as there is in Diadectes. More anteriorly there is an
opening in the base of the saccular recess and cranial cavity (fig.
106, B-E, symbol 2). This passes ventrally into the parasphenoidal
recess between the periotic and basisphenoid above and the para-
sphenoid below. This part of the parasphenoidal recess is floored by
what White termed the "basal tuber." Undoubtedly this complex
was functional and something either entered or left the cranial cavity
through the opening. Just what this may have been is uncertain and
whether this structure has any relationship to the connection of the
inner ear and the parasphenoidal recess in Diadectes is also unknown.
The relationships of the parasphenoidal recess and its contents will

Fig. 106. Transverse serial sections through the posterior part of the skull of
Seymouria. A through passing from posterior to anterior, the sections are 20,
22, 23, 24, 27, 28, 29, 31, 33, 35, 38, 39, 44, 47, 51 respectively. For approximate
positions see figure 100, C. 1, A notch or foramen in the postero-ventral margin
of the parasphenoid. This leads into the mesial parasphenoidal recess. 2, An
opening from the mesial parasphenoidal recess into the cranial and otic cavities.
3, A notch and canal in the inner margin of the parasphenoid and (?) basioccipital.
See explanations in text and reconstruction in figure 107.

211

212

FIELDIANA: GEOLOGY, VOLUME 14

F.JU. OPISTH

Fig. 107. A portion of the left posterior part of the skull of Seymouria in
ventral view. Based upon bioplastic models and serial sections. 1, A notch on
the inner margin of the parasphenoid leading to canal in (?) basioccipital (see fig-
ure 106, D-G, symbol 3). 2, A notch or foramen in the postero- ventral part of the
parasphenoid (see figure 106, B-E, symbol 1).

be considered more fully later, with the aid of the stapes as a guide
to the position of some of the soft structures.

2. The Stapes (Figures 103, 104, 108 and 109)

A most important contribution of Watson's (1954) study of Dia-
dectes was his analysis of the flat, bony plate that occupies the otic
notch. Previously this had been ignored or called a part of the quad-
rate. Watson showed that it was part of the otic complex. He called
it an ossified tympanic membrane, noting however, that it might be
in part or wholly stapedial. While not always preserved, this ossified
membrane does occur in a number of specimens. For convenience,
in view of the question of its affinities, it will be termed here merely
the "ossified plate."

This plate is well preserved in CNHM UR 27, sectioned in this
study. Watson had examined this specimen (fig. 108, A and B) very
briefiy in the course of his study, but at that time preparation was
incomplete. Later, it was possible to give a general description from
the prepared specimen including remarks on some of the features of
the stapedial shaft (Olson, 1962). The sections have revealed much
additional detail and corrected some of the interpretations based on
the prepared specimens. The stapes as now revealed proves to be
quite unlike that of any other reptile in which this area is well known.

The ossified plate is roughly ovoid as seen in lateral aspect, but the
posterior margin swings postero-medially and is somewhat thickened
(fig. 108, A) . The ventral portion of this inflected margin fits closely

OLSON: RELATIONSHIPS OF DIADECTES 213

over the quadrate tuberosity. It appears to have been attached to it,
presumably by a ligament. On the inner surface of the flat portion
of the ossified plate there is a deep groove which has the shape of an
inverted V (fig. 108, E and F, also fig. 104, A-G) . This runs horizon-
tally for about one-third of the width of the plate. Anteriorly, the
groove passes into a poorly defined trough, marked dorsally by a thick-
ening of the ossified plate (fig. 108, G).

The stapedial shaft, as preserved, is short and thick. This, and
what appears to be the stapedial part of the ossified plate (see fig.
108, B), constitute the extrastapedial portion of the stapes (fig.
108, A-G). The more medial portions, the stapes proper, are
almost absent, presumably being largely cartilaginous. As shown in
figures 104 and 108, part of the shaft makes broad contact with the
periotic by means of a rounded process. This is the dorsal process of
the stapes. There is a well developed stapedial foramen and canal.
Presumably this carried the stapedial artery. Below it, on the ven-
tral surface of the shaft, is a well defined groove, between the dorsal
process and the process that passes toward the fenestra ovalis. Prob-
ably this carried the facial nerve (VII) and the lateral head vein.
Traced forward, the presumed passage of the facial nerve lies between
the periotic and a dorsal spur of the parasphenoid. This passageway
leads to the "facial foramen" (fig. 104, P).

The stapedial process that leads to the fenestra ovalis is repre-
sented only by a short, slender spur. As noted earlier, there is no
basis for precise location of the fenestra or for interpreting the nature
of the stapedial foot.

In figure 108, D a second canal in the stapes is shown. This runs
for a short distance through a lateral part of the shaft, opening pos-
tero-ventrally in a foramen that lies near the posterior end of the
V-shaped groove in the ossified plate.

The various structures of the stapes just described — dorsal proc-
ess, the V-shaped groove of the ossified plate, the second stapedial
foramen, and the groove between the dorsal process and stapedial
shaft^ — all may have been involved, among other things, in the course
of the seventh cranial nerve. That this was so cannot, of course, be
demonstrated and must remain conjectural. Figure 108, B illustrates
the hypothetical course of the nerve as reconstructed under this inter-
pretation. The chorda tympani, after its separation from the hyoid-
ean branch of VII, is interpreted as swinging around the thick dorsal
process, passing ventrally into the short "second" stapedial canal,
issuing from this to pass forward in the V-shaped groove, continuing

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214

OLSON: RELATIONSHIPS OF DIADECTES 215

beneath the swelled dorsal portion of the plate to the quadrate, and
then swinging down and backward to follow the quadrate to its artic-
ulation with the lower jaw. Here, presumably, the chorda tympani
passed medially in a course over the posterior part of the quadrate to
enter the lower jaw through a postcondylar foramen.

So interpreted, the chorda tympani, in spite of the complexities
of its course, is pre-tympanic and basically similar to the chorda in
modern lizards. The course across the plate, however, is subject to
more than one interpretation. If the whole ossified plate is tympanic
membrane, or if it is all stapes, then the chorda cuts across one or the
other, as the case may be. The best evidence now available, how-
ever, suggests that the plate may be part stapedial and part tym-
panic membrane. The thickened and inflected posterior part (fig.
108, A-C) which reaches the quadrate tuberosity seems best inter-
preted as the quadrate process of the stapes (possibly including the
ceratohyal part as well) . Near the posterior and anterior ends of the
V-shaped groove, the ossified plate appears to be double (fig. 108, D).
A slender wing of the more ventral part passes upward outside of the
more dorsal part of the plate. Near the anterior end another division
is present (fig. 108, H) . Here, however, the ventral part passes me-
dially to the more dorsal portion. It seems at least reasonable to
suppose that the lower portion is tympanic membrane and the upper
portion stapes.

If this is correct, then the chorda tympani, as reconstructed,
passed along the inner, upper margin of the tympanic membrane,
and along the ventral margin of the stapedial plate. It was not, how-
ever, ventral to the shaft of the stapes, since it reached this position
by passing through the short canal on the margin of the shaft after
swinging over and around the dorsal process, but it might be consid-
ered in part post-tympanic. This position, then, while distinctive,
is not fundamentally different from the general reptilian structure.
It seems somewhat more sauropsid and theropsid, but shows notable
departures from the conditions in either major group.

The stapedial artery presumably passed forward through the large
stapedial foramen and canal (fig. 108, A and B). Beyond the stapes.

Fig. 108. The stapes of Diadectes. A, Posterior view drawn from wax models
and from serial sections. B, Medial view with reconstruction of suggested positions
of nerves and vessels. Drawn from wax models and serial sections. C-H, Se-
lected transverse serial sections of the stapes passing from posterior to anterior;
respectively, numbers 16, 20, 22, 26, 30, 42. For approximate positions see fig-
ure 100, A.

216 FIELDIANA: GEOLOGY, VOLUME 14

anteriorly, its course cannot be traced. It must have entered into
the recess between the periotic and the pterygoid -quadrate complex.
If it supplied the adductor musculature, as is the case in many rep-
tiles, it must have found some exit from this recess. There is no evi-
dence of such an exit. In turtles, where a "trapping" of the artery
occurs, there is a large foramen which provides for access to the ad-
ductor region (fig. 103, C). It seems probable that there was a dif-
ferent circulatory arrangement in Diadectes. The modification seen
in crocodiles, with a major part of the circulation going through the
cranial cavity, does not seem to have been followed, for no access of
the stapedial artery to the cranial cavity is evident. Thus, while
there seems to have been modification of the arterial circulation, there
is no evidence in material at hand as to the pattern of the modification.

The Parasphenoidal Recess and Related Structures

The parasphenoidal recess is defined here as the space between
the expanded parasphenoid and the bones of the basicranial axis and
otic region. It occurs in Seymouria and Diadectes. The analogous
structure in Chelonia is formed by the exoccipitals, quadrate, squa-
mosal, and periotic. Although this cavity in turtles contains some
of the same structures as those which presumably lay in the para-
sphenoidal recess, it is completely different in development. The
similarities must be considered the results of structural convergence.

The parasphenoidal recess in Diadectes and Seymouria is most
clearly revealed in sections (fig. 104, Diadectes, and fig. 106, Sey-
mouria). Its extent and internal details tend to be obscure in pre-
pared specimens. Several specimens of Diadectes, however, have split
through the recess and have shown the presence of the two major
canals related to it — the otic canal and the more lateral one, here con-
sidered as the passageway for the lateral head vein.

Diadectes: The nature of the parasphenoidal recess in Diadectes is
shown in sections in figure 104 and in reconstruction in figure 103.
The lateral head vein is shown as lying near the lateral margin of the
central portion of the recess. More medially, separated from the re-
cess by a thin septum, is the otic canal. The lateral head vein appears
to have entered the parasphenoidal recess at the antero-lateral mar-
gin of the main chamber. In some specimens of Diadectes a clearly
defined foramen occurs, but in others, such as the one sectioned, the
opening is not distinct enough to appear as a foramen in prepared
specimens. Anterior to the recess, the course of the lateral head vein

OLSON: RELATIONSHIPS OF DIADECTES 217

cannot be traced for more than the short distance through which it
lay in a groove on the base of the periotic (fig. 104, K, L).

Just what occupied the rest of this central cavity of the recess in
Diadedes is not clear. The possibility of an extracapsular perilym-
phatic sinus was noted earlier, but as pointed out, there is no good
aflEirmative evidence. There may have been a venous sinus, related
to the presumed passage of the lateral head vein, but again, positive
evidence is lacking. It is possible, also, that the internal carotid ar-
tery traversed this space, for this is a reasonable place for it to have
been. There is, however, no evident exit for the artery. It has, in
fact, not been possible to find any trace of the course of this artery
in Diadectes. It was noted earlier (Olson, 1947) that the course was
not evident in prepared specimens, but it seems reasonable to suppose
that it would be found in the basisphenoid in serial sections. This is
usually the case, as in Seymouria, Captorhinus, Chelonia, Lacertilia
and many pelycosaurs and therapsids. It is just possible that lack
of ossification has obscured the course in Diadectes, but this seems
unlikely in view of the pattern of unossified areas. Rather, it is more
reasonable to assume that there was some specialization in the arte-
rial circulation, a specialization that at present at least has defied
detection except in the lack of evidence of a "normal" internal caro-
tid artery.

The central portion of the parasphenoidal sinus is the most prom-
inent. There is, however, a more mesial part, partially confluent with
the central portion, and a small, but important dorso-lateral part
(fig. 104, G and K) . The mesial division is floored by a heavy flange
of the parasphenoid. Presumably the posterior part of this bone
formed an area of insertion of strong, ventral cervical muscles. Dor-
sal to the central portion of the recess, the parasphenoid swings past
the ventro-lateral margin of the periotic, making contact with it, and
then rises to create an extracranial space between itself and the lateral
wall of the periotic (figs. 104, J-M and 109, A). At the posterior end
of the recess the parasphenoid forms only a small spur. This lay just
ventral to the most anterior part of the stapes and apparently served
as a continuation of the conduit for the facial nerve which was car-
ried to this point by the stapes (fig. 104, G-J).

More anteriorly (figs. 104, J-P and 109, B-D), the parasphenoid
is enlarged, and develops a second dorsal arm that excludes the canal
of the facial nerve from the margin of the periotic. Farther forward,
the facial canal penetrates through this second dorsal arm. Just what
function this enlarged part of the parasphenoid played is unclear.

(?-~PAS.

J-BO PT

o"^

\J

218

OLSON: RELATIONSHIPS OF DIADECTES 219

It flanks the area where the anterior semicircular canal makes lateral
exit from the brain case. This does not help much in arriving at an
explanation of its function, for the emergence of the canal represents
an equally aberrant circumstance. In a following section more de-
tails concerning the anterior extension of the parasphenoid will be
given, when its relationships to the formation of the wall of the brain
case are taken up.

Seymouria: The parasphenoid and parasphenoidal recess are less
well developed in Seymouria than in Diadectes but are extensive as
compared to development in most other reptiles or amphibians. There
are many similarities between the structures in the two genera. The
relationship to the otic canal in Seymouria has already been discussed.
The central portion of the recess in Seymouria (fig. 106, A-E) is later-
ally extensive but narrow dorso-ventrally. The dorso-lateral portion
of the recess is present, but only very slightly developed. There is no
massive anterior increase of the parasphenoid as in Diadectes. The
mesial portion is most fully developed and forms the "basal tuber"
of White (1939).

The central portion could have carried the lateral head vein, as
has been suggested for Diadectes. There is an adequate area of en-
trance and a possible exit. There are no well formed foramina and
there is no evident tube in the recess. The facial nerve probably lay
medial to the short spur of the dorso-lateral portion of the para-
sphenoid but, in the absence of a stapes, it is difficult to define a pre-
cise position. In these respects, Seymouria probably was similar to
Diadectes, although this is far from definite.

The mesial portion of the parasphenoidal recess has some distinct
differences from its counterpart in Diadectes. Interpretations of the
structures are difficult and problematical. The details of this portion
are shown in sections in figure 106, B-G. The mesial parasphenoidal
recess is deep, and the posterior margin of the parasphenoid bone un-
doubtedly served for muscle insertion as in Diadectes. A short dis-
tance anteriorly, however, there is a rather large foramen, or deep
notch, which penetrates the parasphenoid and enters into the para-
sphenoidal space from a ventral and slightly lateral position. At the
level of this foramen there is the large opening into the cranial cavity
noted earlier (see fig. 106, B-E, symbol 2). This latter structure

Fig. 109. Transverse serial sections of the posterior part of the skull of Dia-
dectes showing the anterior part of the sectioned region. A through L passing from
posterior to anterior. Sections in sequence A to L are 48, 56, 57, 61, 63, 67, 70,
74, 76, 80, 82, 85 respectively. For approximate positions see figure 100a.

220 FIELDIANA: GEOLOGY, VOLUME 14

seems to pass mostly into the auditory recess, but ossification is
rather poorly developed, and it may be that it passes into the cranial
cavity as well. The opening through the parasphenoid seems to lead
across the parasphenoidal recess in the direction of the second foramen.

Anteriorly to the opening into the brain case the floor of the
cranial cavity is again closed, but a strong, inverted trough carries
forward, eventually issuing from the parasphenoidal recess to the side
of the otic part of the brain case (figs. 106, E-G and 107). The
trough heads in the general direction of the more anteriorly placed
foramen for the internal carotid artery.

At the level of the latero-ventral foramen in the parasphenoid, on
the medial part of the parasphenoid, there is a hook-shaped structure
that forms a partial recess, open dorso-medially but closed ventrally
and laterally (fig. 106, D-G) . Carried forward, this recess passes into
a fully formed canal in the basisphenoid. After a distance of several
millimeters, however, the canal simply disappears. There is no evi-
dence of passage to the surface of the bone or of continuation in
smaller canals. Almost certainly this structure was functional. Pre-
sumably it carried either arterial or venous circulation.

In one way or another all of the structures just described seem to
have been related to the circulatory rather than to the nervous sys-
tem, the two most reasonable associations. It is not impossible, of
course, that the opening between the parasphenoidal recess and the
brain case carried a perilymphatic structure, but it seems unlikely in
view of the associated structures. The most suggestive feature is the
course of the trough (fig. 106, E-G, symbol 1) leading forward after
the closure of the foramen which passes into the cranial cavity. As
indicated, this trough seems to go toward the foramen of the internal
carotid artery. It is possible that the internal carotid, after separa-
tion from the stapedial artery, entered the parasphenoidal recess and
then passed through it, anteriorly, to emerge prior to its entrance into
the carotid foramen. This would be a fairly "normal" course for tet-
rapods at this general level of development.

It is further possible that within the recess it divided and sent a
branch into the brain case through the opening between the otic and
basisphenoid. This is not a "normal" situation, but certainly can't
be ruled out. However, there is some evidence that the lateral head
vein passed through the recess, although this is less clear than in Dia-
dectes. It could be that venous drainage of the posterior part of the
brain case issued from the foramen in question, rather than through

OLSON: RELATIONSHIPS OF DIADECTES 221

the jugular canal which is high and closely associated with the sac-
cular recess of the inner ear.

These are little more than suggestions, highly speculative. Irre-
spective of the interpretations, it is evident that there are some notable
similarities in this general area between Diadectes and Seymouria.
Each has its own peculiarities, but resemblances are such that they
do suggest a common ancestor with some of the properties common
to the two.

Inner Ear and Brain Case

The osseous labyrinth and associated structures of the inner ear
of Diadectes are well preserved. For the most part the patterns, as
shown in figure 103, D and E, are those found in reptiles in which
this region is not specialized. The backward swing of the saccular
region, presumably marking the extension of a lagena into the otic
canal, and the opening of the anterior vertical semicircular canal to
the outside of the brain case, are the only marked departures from
the generalized condition. The latter, as noted earlier, seems unex-
plainable at present. Possibly it is the result of an individual aber-
rancy, but this can't be determined without studies of more specimens.

The lagena in Chelonia (de Beer, 1937; Nick, 1912) projects back-
ward, somewhat as it seems to have done in Diadectes. In Chelonia
this has resulted in a modified structure of the recessus scala tympani.
The detail involved in this determination is much greater than that
available in Diadectes, so no comparison is possible. Almost nothing
can be said about the inner ear of Seymouria. As White (1939)
pointed out, ossification is such that little detail is preserved. There
is an otic canal as in Diadectes. It passes somewhat more laterally
and reflects a somewhat different position of the contained structures.

There are several points of special interest in the brain case. Some
of these are shown in the medial views in figure 101. Although com-
parable structures, for the most part with the same general positions
and relationships, can be identified in each genus, they do not indi-
cate particularly close relationships. Each genus departs in its own
way from the general reptilian conditions from which the resem-
blances stem.

Seymouria, if allowances are made for the lack of ossification,
comes closest to a generalized reptilian pattern, such as that shown
by Captorhinus, lizards, and such rhynchocephalians as Sphenodon.
Chelydra is strongly ossified and is modified in particular by the in-

222 FIELDIANA: GEOLOGY, VOLUME 14

corporation of the parietal in the osseous lateral wall of the brain case.
The epipterygoid is correspondingly reduced in height.

Diadectes is highly distinctive in many features. The brain case
is long and low. As seen in the median section, the most striking fea-
ture is the very large pleurosphenoid. Otherwise in medial view it
appears somewhat more "orthodox" than it does when studied in
successive transverse sections. Representative sections, shown in fig-
ure 109, tell a fairly complete story. The complexities are clear.
Some are the result of poor ossification, but for the most part they
relate to peculiarities of the structure of Diadectes.

Figure 109, A shows a thin sHp of bone (PER), closing the inter-
nal auditory meatus. This sharply reduces the cross-sectional area
of the brain case over what it would appear to be in the absence of
this ossification of the brain case wall. The slip of bone appears to
be periotic, properly a portion of the prootic. In this section the dual
character of the dorsal extension of the wing of the parasphenoid is
just becoming evident. There is evidence of lack of ossification in
the basicranial axis, possibly between the basisphenoid and basioc-
cipital.

Figure 109, B shows the parasphenoid enlarged and double, and
also records the opening of the anterior vertical semicircular canal to
the exterior of the brain case. The opening passes into the space be-
tween the inner part of the parasphenoidal wing and the periotic.
Figure 109, C shows strong reduction of the ossification of the peri-
otic. This section lies just anterior to the opening of the facial canal
through the parasphenoid (see fig. 104). Figure 109, B, C and D
illustrate the great enlargement of the parasphenoid and then its dis-
appearance. The slip of periotic, noted in the first section and con-
tinuing forward, is seen to enlarge rapidly to form a rather massive
bone (fig. 109, C-G). Also, it appears, this ossification passes to the
mid-line, ossifying trabecular cartilages near the dorsum sellae, much
as occurs in pelycosaurs (Romer and Price, 1940) and some therap-
sids (Olson, 1944).

In figure 109, G-L, the pterygoid and quadrate (omitted from
drawings of the earlier sections) are added. These sections show the
massive development of the pleurosphenoid and the structure of the
sutural cranio-palatal joint.

As far as I am aware, the cranial structure of no other reptile
closely resembles that just described and figured for Diadectes. It is
sufficiently different that even determination of the identities of some
of the bones is not completely certain. Both the dual nature of the

OLSON: RELATIONSHIPS OF DIADECTES 223

periotic, and the interpretation of the large anterior element as pleu-
rosphenoid may be questioned. The very great extent of the para-
sphenoid undoubtedly raises legitimate doubts about the identity of
the bone so designated.

This cranial structure finds no counterparts in the Chelonia. Sey-
mouria is certainly much more "orthodox," yet it does show some of
the same pecularities in incipient stages, and this suggests develop-
ment in the same general direction as Diadectes.

SUMMARY OF RELATIONSHIPS

The structures of the middle ear and brain case of Diadectes are
in many respects very different from those known in any other rep-
tiles. Presumably, of course, they are approximated in other mem-
bers of the Family Diadectidae. They appear to set this family well
apart from any other well understood reptilian stocks.

As far as the supposed relationship of Diadectes to turtles is con-
cerned, this now seems out of the question. The apparent resem-
blances are superficial and due to convergence. This appears to apply
as well to the rather vague similarities of Diadectes and some of the
reptiles grouped as sauropsids by Watson (1954) . It is true that some
features of the otic and quadrate regions of Diadectes are of the pat-
tern considered characteristic of sauropsids by Watson. In fact, they
were strongly involved in the formulation of the diagnosis. The more
or less vertical quadrate, with its concave posterior margin and ex-
posed lateral surface, and the high position of the stapes fall within
this category. The preponderance of otic and cranial features of
Diadectes, however, conforms neither to the patterns of the so-called
sauropsids nor theropsids. The massive stapes, with its two fora-
mina, is a far cry from the slender stapes of sauropsids. Most fea-
tures seem to be strictly diadectid. Resemblances to one or another
group of reptiles are due to convergence, related largely, it would ap-
pear, to similar adaptive modifications of the masticatory apparatus.

The vast morphological difference between Diadectes and any of
the reptiles grouped as "sauropsids" clearly removes it from any close
taxonomic association with them. A cornerstone of the concepts of
dichotomy of the reptiles, either as sauropsids or theropsids or as
parareptilians and eureptilians (Olson, 1947) is thus removed. Wat-
son (1957) softened his views on the intimate relationship of Diadec-
tes to other reptiles, suggesting that it might be quite isolated. Par-
rington (1958) made a strong case against the sauropsid-theropsid

224 FIELDIANA: GEOLOGY, VOLUME 14

dichotomy. Removal of Diadecies from its role as a supporter of con-
cepts of dichotomy, necessary in view of the new evidence on its
cranial morphology, seriously weakens the already tottering frame-
work of dichotomy and leaves both the sauropsid-theropsid concept
(Goodrich, 1916; Watson, 1954) and the parareptilian-eureptilian
concept (Olson, 1947) with little or no support as far as the evidence
of osteology is concerned.

The current study has added nothing to an understanding of the
possible relationships of Diadectes to procolophons and pareiasaurs,
often grouped with diadectids in the Diadectomorpha. As far as is
known, the special features of the basicranium, otic region, and brain
case of Diadectes do not occur in either of these two groups. Only a
detailed analysis of skulls of representatives of each of these groups
would permit the necessary comparisons. As things now stand, it
seems probable that there is no very close relationship of Diadectes
to either of them.

Of the well known tetrapods of the late Paleozoic only Seymouria
has structures in the basicranium brain case and middle ear that are
at all similar to those of Diadectes. Both Diadectes and Seymouria
are late and fairly specialized members of their respective groups.
As would be expected under such circumstances, even though there
was a fairly close relationship, there are many marked differences
between the two.

It seems probable that Diadectes and Seymouria stemmed from a
common stock in which the unusual features shown in both were at
least incipient. 1 The stock that each represents had a fairly long his-
tory, dating back at least into the early part of the upper Carbonif-
erous. Both had radiations in the upper Carboniferous, known,
however, only from rather fragmentary remains. Seymouria, Kot-
lassia, and Lanthanosuchus are representatives of the better known
Permian radiation of the seymouriamorphs or batrachosaurs. All
seem to have had a pattern of otic and cranial features similar to
that best known from Seymouria, Diadectes, Diasparactus; perhaps
Bolosaurus, Stephanospondylus, and Phanerosaurus represent the
diadectid radiation near the end of its history. From these repre-

* Since this was written, Vaughn (1964) has described a new reptile from the
Cutler Group, Tseajaia campi Vaughn. The skull has both diadectid and sey-
mourid features. This new creature seems to offer support to the proposed rela-
tionship of Diadectes and seymouriamorphs. Also, as noted in the introduction,
Romer (1964), suggested that Diadectes was an amphibian, which may cast addi-
tional light on the discussion in this section.

OLSON: RELATIONSHIPS OF DIADECTES

225

tatives it is clear that the adaptive patterns in the diadectids and
seymouriamorphs were very different.

At present it seems reasonable to think of diadectids and sey-
mouriamorphs as two early stocks that evolved into the reptilian
habitus from a common amphibian ancestry, each along somewhat
different lines. Some Seymouriamorphs had larval stages and thus
are technically amphibians. Nothing is known of the ontogeny of
Diadedes. It is possible that other reptilian groups arose from one
or both during the early phases of their radiations. There exist,
however, no actual data which can either confirm or deny this. Al-
most certainly no known reptilian lines descended from either group
as represented by the end members of their radiation.

LIST OF ABBREVIATIONS

A.AMP.

anterior ampulla of inner ear

AMP.

ampulla of inner ear

ART.

articulation of quadrate and periotic

A.ST.

stapedial artery

A.V.S.C.

anterior vertical semicircular canal

BO.

basioccipital bone

BPT.

basipterygoid process

BS.

basisphenoid bone

C.FA.A.

canal for facial artery

CH.T.

chorda tympani, part of cranial nerve VII

C.I.C.

canal for internal carotid artery

CNHM UR.

collection designation, Chicago Natural History Museum,

University Reptiles

EPIPT.

epipterygoid bone

EXO.

exoccipital bone

Ex.St.

extrastapedial (extracolumella)

F.F.

facial foramen, for cranial nerve VII

F.I.C.E.

external foramen for internal carotid artery

F.I.C.I.

internal foramen for internal carotid artery

FI.MET.

metotic fissure

F.JU.

jugular foramen

F.OV.

fenestra ovalis

F.ST.

stapedial foramen

H.S.C.

horizontal semicircular canal

HY.

hyoidean branch of cranial nerve VII

I.A.M.

internal auditory meatus

I.e.

internal carotid artery

JU.C.

jugular canal

LAG.

lagena

N.

notch in ossified plate of stapes

226

FIELDIANA: GEOLOGY, VOLUME 14

O.C. otic canal

O.P. ossified plate of stapes and tympanic membrane

OPISTH. opisthotic bone, posterior part of periotic

PA. parietal bone

PAS. parasphenoid bone

PER. periotic bone

PI. pineal opening

PL.SPH. pleurosphenoid bone

PR.CUL. cultriform process

PRO. INC. prootic incisure

PT. pterygoid bone

P.V.S.C. posterior vertical semicircular canal

QJ. quadratojugal bone

QU. quadrate bone

QU.P.ST. quadrate process of stapes

QU.T. quadrate tubercle

REC. secondary recess in central parasphenoidal recess in Diadedes

R.PAS. parasphenoid recess: C, central part; D, dorsal part; M, mesial part

R.SAC. saccular recess

R.SC.T. recessus scala tympani

SE.T. sella turcica

S.PERI sinus perilymphaticus, the extracapsula perilymphatic sinus in Che-
Ionia

St. stapes

ST. (FT.) foot of stapes

ST.C. stapedial canal

S.ST. shaft of stapes

S.UT. sinus urticulus

TY. tympanic

TY.M. tympanic membrane

USNM. collection designation. United States National Museum

V.C.L. vena capitis lateralis, the lateral head vein

VII the seventh cranial nerve, the facial

XII the twelfth cranial nerve, the hypolossal

REFERENCES

DE Beer, G. R.

1937. The development of the vertebrate skull. Oxford. 522 pp.

DE BURLET, H. M.

1934. Vergleichende Anatomie des stato-akustischen Organs. Handb. d. vergl.
Anat. Wirbeltiere, Bolk, L. et al, 2, Part II, pp. 1293-1432.

Goodrich, E. H.

1916. On the classification of the Reptilia. Proc. Roy. Soc. London. B 89,
pp. 261-267.

OLSON: RELATIONSHIPS OF DIADECTES 227

HoTTON, Nicholas, III

1959. The pelvcosaur tympanum and early evolution of the middle ear. Evo-
lution, 13, pp. 99-121.

Nick, L.

1912. Das Kopfskelet von Dermochelys coricacea L. Zool. Jahrb., Anat., 33,
pp. 1-238.

Olson, E. C.

1944. The origin of mammals based upon the cranial morphology of therapsid
suborders. Geol. Soc. Amer. Special Papers, no. 55, pp. 1-136.

1947. The family Diadectidae and its bearing on the classification of reptiles.
Fieldiana, Geol., 7, pp. 2-53.

1962. Les problemes de I'origine des reptiles. Problemes Actuels de Pal^onto-
logie (Evolution des Vertebres), Colloques Internat. C.N.R.S., 104, pp. 157-
174.

1965. Relationships of Seymouria, Diadectes, and Chelonia. Amer. Zool., 5,
pp. 295-307.

Parrington, F. R.

1958. The problem of classification of reptiles. Jour. Linn. Soc. London, Zool.,
44, pp. 99-115.

1962. Les relations des Cotylosaures Diadectomorphes. Problemes Actuels de
Paleontologie (Evolution des Vertebres) Colloques Internat. C.N.R.S., 104,
pp. 175-185.

ROMER, A. S. and L. I. Price

1940. Review of the Pelyeosauria. Geol. Soc. Amer., Special Papers, no. 28,
pp. 1-538.

1964. Diadectes an amphibian? Copeia, 4, pp. 718-719.

Vaughn, P. P.

1955. The Permian reptile Araeoscelis restudied. Bull. Mus. Comp. Zool., 113,
pp. 305-467.

1964. Vertebrates from the Organ Rock shale of the Cutler Group, Permian of
Monument Valley and vicinity, Utah and Arizona. Jour. Paleo., 38, pp. 567-
583.

Watson, D. M. S.

1954. On Bolosaurus and the origin and classification of reptiles. Bull. Mus.
Comp. Zool., Ill, pp. 297-449.

1957. On Millerosaurus and the early history of the sauropsid reptiles. Philos.
Trans. Roy. Soc. London, B 240, pp. 325-400.

Wever, E. G. and J. A. Vernon

1956. Sound transmission in the turtle's ear. Proc. Nat. Acad. Sci., 42, pp. 292-
299.

White, T. E.

1939. Osteology of Seymouria baylorensis Broili. Bull. Mus. Comp. Zool., 85,
pp. 325-409.