Dimetrodon was a
quadrupedal, sail-backed synapsid that most likely had a semi-sprawling posture between that of a mammal and a lizard and also could walk in a more upright stance with its body and the majority or all of its tail off the ground. Most
Dimetrodon species ranged in length from , The larger species of
Dimetrodon were among the largest predators of the Early Permian, with
D. grandis measuring and weighing some ; the closely related
Tappenosaurus, known from skeletal fragments in slightly younger rocks, may have been even larger at an estimated long.
Skull The skull of
Dimetrodon is tall and compressed
laterally, or side-to-side. The eye sockets are positioned high and far back in the skull. Behind each eye socket on each side is a single hole called an
infratemporal fenestra. An additional hole in the skull, the
pineal foramen (or "third eye") along the midline between the
parietal bones, can be seen when viewed from above. The back of the skull (the
occiput) is oriented at a slight upward angle, a feature that it shares with all other early
synapsids. The upper margin of the skull slopes downward in a convex arc to the tip of the snout. The tip of the upper jaw, formed by the
premaxilla bone, is raised above the part of the jaw formed by the
maxilla bone to form a maxillary "step". Within this step is a
diastema, a gap in the tooth row. Another transitional feature of
Dimetrodon is a ridge in the back of the jaw called the reflected lamina, which is found on the
articular bone, which connects to the
quadrate bone of the skull to form the jaw joint. In later mammal ancestors, the articular and quadrate separated from the jaw joint, while the articular developed into the
malleus bone of the
middle ear. The reflected lamina became part of a ring called the tympanic annulus that supports the
ear drum in all living mammals.
Teeth The size of the teeth varies greatly along the length of the jaws, lending
Dimetrodon its name, which means "two measures of tooth" in reference to sets of small and large teeth. One or two pairs of caniniforms (large, pointed,
canine-like teeth) extend from the maxilla. Large incisor teeth are also present at the tips of the upper and lower jaws, rooted in the premaxillae and
dentary bones. Small teeth are present around the maxillary "step" and behind the caniforms, becoming smaller further back in the jaw. On the roof of the mouth, towards the back, the
pterygoid bones each bear a large flange which supports a row of
palatal teeth. Many teeth are widest at their midsections and narrow closer to the jaws, giving them the appearance of a teardrop. Teardrop-shaped teeth are unique to
Dimetrodon and other closely related
sphenacodontids, which helps to distinguish them from other early synapsids. The dinosaur
Albertosaurus had similarly crack-like serrations, but, at the base of each serration was a round
void, which would have functioned to distribute force over a larger
surface area and prevent the stresses of feeding from causing the crack to spread through the tooth. Unlike
Albertosaurus,
Dimetrodon teeth lacked adaptations that would stop cracks from forming at their serrations. The smaller species,
D. milleri, had no tooth serrations because it ate small prey. As prey grew larger, several
Dimetrodon species started developing serrations on their teeth and increasing in size. For instance,
D. limbatus had enamel serrations that helped it cut through flesh (which were similar to the serrations that can be found on
Secodontosaurus). The second-largest species,
D. grandis, has denticle serrations similar to those of sharks and
theropod dinosaurs, making its teeth even more specialized for slicing through flesh. As
Dimetrodon's prey grew larger, the various species responded by growing to larger sizes and developing ever-sharper teeth. The thickness and mass of the teeth of
Dimetrodon may also have been an adaptation for increasing dental longevity.
Sail The sail of
Dimetrodon is formed by elongated
neural spines projecting from the vertebrae. Each spine varies in cross-sectional shape from its base to its tip in what is known as "dimetrodont" differentiation. Near the vertebra body, the spine cross section is laterally compressed into a rectangular shape and, closer to the tip, it takes on a figure-eight shape as a groove runs along either side of the spine. The figure-eight shape is thought to reinforce the spine, preventing bending and fractures. A cross-section of the spine of one specimen of
Dimetrodon giganhomogenes is rectangular in shape but preserves figure-eight shaped rings close to its center, indicating that the shape of spines may change as individuals age. The microscopic anatomy of each spine varies from base to tip, indicating where it was embedded in the muscles of the back and where it was exposed as part of a sail. The lower or
proximal portion of the spine has a rough surface that would have served as an anchoring point for the
epaxial muscles of the back and also has a network of connective tissues called
Sharpey's fibers that indicate it was embedded within the body. Higher up on the
distal (outer) portion of the spine, the bone surface is smoother. The
periosteum, a layer of tissue surrounding the bone, is covered in small grooves that presumably supported the blood vessels that vascularized the sail. The large groove that runs the length of the spine was once thought to be a channel for blood vessels, but since the bone does not contain vascular canals, the sail is not thought to have been as highly vascularized as once thought. Some specimens of
Dimetrodon preserve deformed areas of the neural spines that appear to be healed-over fractures. The
cortical bone that grew over these breaks is highly vascularized, suggesting that soft tissue must have been present on the sail to supply the site with
blood vessels. In many specimens of
D. gigashomogenes, the distal portions of spines bend sharply, indicating that the sail would have had an irregular profile in life. Their crookedness suggests that soft tissue may not have extended all the way to the tips of the spines, meaning that the sail's webbing may not have been as extensive as it is commonly imagined. One specimen of
D. limbatus, AM 4636, preserves more than 40 caudal vertebrae, and even that is incomplete. Some synapsid groups later developed bare, glandular skin, as indicated by the fossils of the dinocephalian therapsid
Estemmenosuchus from the middle Permian of Russia, which show its skin would have been smooth and well-provided with glands.
Estemmenosuchus also had osteoderms embedded in its skin. Later synapsids evolved hair and whiskers that became characteristics of
mammals.
Ascendonanus from the Early Permian of Germany was found with preserved soft tissues showing squamate-like scales and was initially classified as a
varanopid synapsid. However, the taxonomic placement of varanopids has been debated between synapsids or closer to
diapsid reptiles. A recent study removed
Ascendonanus from the varanopids (considered synapsids by the researchers) as a member of a separate clade in the Neoreptilia. == Classification ==