Dragons of the Air

<h2><SPAN name="CHAPTER_IX" id="CHAPTER_IX"></SPAN><small>CHAPTER IX</small><br/><br/> THE BACKBONE, OR VERTEBRAL COLUMN</h2> <p>The backbone is a more deep-seated part of the skeleton than the head. It is more protected by its position, and has less varied functions to perform. Therefore it varies less in distinctive character within the limits of each of the classes of vertebrate animals than either the head or limbs. It is divided into neck bones, the cervical vertebr&aelig;; back bones, the dorsal vertebr&aelig;; loin bones, the lumbar vertebr&aelig;; the sacrum, or sacral vertebr&aelig;, which support the hind limbs; and the tail. Of these parts the tail is the least important, though it reaches a length in existing reptiles which sometimes exceeds the whole of the remainder of the body, and includes hundreds of vertebr&aelig;. It attains its maximum among serpents and lizards. In frogs it is practically absent. In some of the higher mammals it is a rudiment, which does not extend beyond the soft parts of the body.</p> <h4>THE NECK</h4> <p>The neck is more liable to vary than the back, with the habit of life of the animal. And although mammals almost always preserve the same number <span class="pagenum"><SPAN name="Page_79" id="Page_79">[Pg 79]</SPAN></span> of seven bones in the neck, the bones vary in length between the short condition of the porpoise, in which the neck is almost lost, and the long bones which form the neck of the Llama, though even these may be exceeded by some fossil reptiles like Tanystroph&#339;us. In many mammals the neck bones do not differ in length or size from those of the back. In others, like the Horse and Ox, they are much broader and larger.</p> <p>There is the same sort of variation in the bones of the neck among birds, some being slender like the Heron, others broad like the Swan. But there is also a singular variation in number of vertebral bones in a bird's neck. At fewest there are nine, which equals the exceptionally large number found among mammals in the neck of one of the Sloths. Usually birds have ten to fifteen cervical vertebr&aelig;, and in the Swan there are twenty-three. Most of the neck bones of birds are relatively long, and the length of the neck is often greater than the remainder of the vertebral column.</p> <p>Reptiles usually have short necks. The common Turtle has eight bones in the neck, ten in the back. The two regions are sharply defined by the dorsal shield. Their articular ends are sometimes cupped in front, in the neck, sometimes cupped behind, or convex at both ends, or even flattened, or the articulation may be made exceptionally by the neural arch alone. Nine is the largest number of neck bones in existing Lizards, and there are usually nine in Crocodiles; so that reptiles closely approach mammals in number of the neck bones. It is remarkable that the maximum number in a mammal and in living reptiles should coincide with the minimum number in birds. Therefore <span class="pagenum"><SPAN name="Page_80" id="Page_80">[Pg 80]</SPAN></span> the number of cervical vertebr&aelig; as an attribute of Mammal, Bird, or Reptile, can only be important from its constancy.</p> <p>German naturalists affirm on clear evidence that the Solenhofen Pterodactyles have seven cervical vertebr&aelig;. In many specimens there can be no doubt about the number, because the neck bones are easily distinguished from those of the back by their size; but the number is not always easy to count.</p> <p>As in Birds, the first vertebra, or atlas, in Pterodactyles is extremely short, and is generally&mdash;if not always&mdash;blended with the much longer second vertebra, named the axis. The front of the atlas forms a small rounded cup to articulate with the rounded ball of the basioccipital bone at the back of the skull. The third and fourth vertebr&aelig; are longer, but the length visibly shortens in the sixth and seventh.</p> <p>Sometimes the vertebr&aelig; are slender and devoid of strong spinous processes. This is the condition in the little <i>Pterodactylus longirostris</i> and in the comparatively large <i>Cycnorhamphus Fraasii</i>, in which there is a slight median ridge along the upper surface of the arch of the vertebra. This condition is paralleled in birds with long necks, especially wading birds such as the Heron. Other Ornithosaurs, such as Ornithocheirus from the Cretaceous rocks, have the neck much more massive. The vertebr&aelig; are flattened on the under side. The arch above the nervous matter of the spinal cord has a more or less considerable transverse expansion, and may even be as wide as long. These vertebr&aelig; have proportions and form such as may be seen in Vultures or in the Swan. In either case the form of the neck bones is more or less bird-like, and the neural spine may <span class="pagenum"><SPAN name="Page_81" id="Page_81">[Pg 81]</SPAN></span> be elevated, especially in Pterodactyles with long tails.</p> <p>One of the most distinctive features of the neck bones of a bird is the way in which the cervical ribs are blended with the vertebr&aelig;. They are small, and each is often prolonged in a needle-like rod at the side of the neck bone.</p> <p>In Ornithocheirus the cervical rib similarly blends with the vertebra by two articulations, as in mammals, so that it might escape notice but for the channel of a blood vessel which is thus inclosed. In several of the older Pterodactyles from Solenhofen the ribs of the neck vertebr&aelig; remain separated, as in a Crocodile, though still bird-like in their form, anterior position, and mode of attachment. In Terrapins and Tortoises the long neck vertebr&aelig; have no cervical ribs.</p> <div class="figcenter"> <SPAN name="Fig_24" id="Fig_24"></SPAN> <span class="caption">FIG. 24 &nbsp; UNITED ATLAS AND AXIS OF ORNITHOCHEIRUS</span> <p class="center">(Cambridge Greensand)</p> <ANTIMG src="images/i_098.jpg" width-obs="640" height-obs="337" alt="FIG. 24" title="FIG. 24" /></div> <p>The articular surfaces between the bodies of the vertebr&aelig;, in the neck, are transversely oval. The middle part of this articular joint is made by the body of the vertebra; its outer parts are in the neural arch. In front this surface is a hollow channel, often more depressed than in any other animals. The corresponding surface behind is convex, with a process on <span class="pagenum"><SPAN name="Page_82" id="Page_82">[Pg 82]</SPAN></span> each side at its lower outer angles (<SPAN href="#Fig_25">Fig. 25</SPAN>). It is a modification of the cup-and-ball form of vertebral articulation, which at the present day is eminently reptilian. Serpents and Crocodiles have the articulations similarly vertical, but in both the form of the articulation is a circle. In Lizards the articular cup is usually rather wider than deep, when the cup and ball are developed in the vertebr&aelig;; it differs from the vertical condition in pterodactyles in being oblique and much narrower from side to side. Only among Crocodiles and Hatteria is there a double articulation for the cervical rib, though in neither order have rib or vertebra in the neck the bird-like proportions which are usual in these animals. Pterodactyles show no resemblance to birds in this vertebral articulation. A Bird has the corresponding surface concave from side to side in front, but it is also convex from above downward, producing what is known as the saddle-shaped form which is peculiarly avian, being found in existing birds except in part of the back in Penguins. It is faintly approximated to in one or two neck vertebr&aelig; in man. Professor Williston remarks that in the toothless Pterodactyles of Kansas the hinder ball of the vertebral articulation is continued downward and outward as a concave articulation upon the processes at its outer corners. There are no mammals with a cup-and-ball articulation between the vertebr&aelig;, so that for what it is worth the character now described in Ornithosaurs is reptilian, when judged by comparison with existing animals.</p> <p>Low down on each side of the vertebra, at the junction of its body with the neural arch, is a large ovate foramen, transversely elongated, and often a little impressed at the border, which is the entrance <span class="pagenum"><SPAN name="Page_83" id="Page_83">[Pg 83]</SPAN></span> of the air cell into the bone. These foramina are often one-third of the length of the neck vertebr&aelig; in specimens from the Cambridge Greensand, where the neck bones vary from three-quarters of an inch to about two and a half inches in length, and in extreme forms are as wide as long. The width of the interspace between the foramina is one-half the width of the vertebr&aelig;, though this character varies with different genera and species. Several species from the Solenhofen Slate have the neck long and slender, on the type of the Flamingo. In others the neck is thick and short&mdash;in the <i>Scaphognathus crassirostris</i> and <i>Pterodactylus spectabilis</i>. Some genera with slender necks have the bones preserved with a curved contour, such as might suggest a neck carried like that of a Llama or a Camel. The neck is occasionally preserved in a curve like a capital <b>S</b>, as though about to be darted forward like that of a bird in the act of striking its prey. The genera of Pterodactyles with short necks may have had as great mobility of neck as is found among birds named Ducks and Divers; but those Pterodactyles with stout necks, such as Dimorphodon and Ornithocheirus, in which the vertebr&aelig; are large, appear to <span class="pagenum"><SPAN name="Page_84" id="Page_84">[Pg 84]</SPAN></span> have been built more for strength than activity, and the neck bones have been chiefly concerned in the muscular effort to use the fighting power of the jaws in the best way.</p> <div class="figcenter"> <SPAN name="Fig_25" id="Fig_25"></SPAN> <span class="caption">FIG. 25. &nbsp; CERVICAL VERTEBRA OF ORNITHOCHEIRUS</span> <p class="center">From the Cambridge Greensand</p> <ANTIMG src="images/i_100.jpg" width-obs="640" height-obs="276" alt="FIG. 25." title="FIG. 25." /></div> <h4>THE BACK</h4> <p>The region of the back in a Pterodactyle is short as compared with the neck, and relatively is never longer than the corresponding region in a bird. The shortness results partly from the short length of the vertebr&aelig;, each of which is about as long as wide. There is also a moderate number of bones in the back. In most skeletons from Solenhofen these vertebr&aelig; between the neck and girdle of hip bones number from twelve to sixteen. They have a general resemblance in form to the dorsal vertebr&aelig; in birds. The greatest number of such vertebr&aelig; in birds is eleven. The number is small because some of the later vertebr&aelig; in birds are overlapped by the bones of the hip girdle, which extend forward and cover them at the sides, so that they become blended with the sacrum. This region of the skeleton in the Dimorphodon from the Lias is remarkable for the length of the median process, named the neural spine, which is prolonged upward like the spines of the early dorsal vertebr&aelig; of Horses, Deer, and other mammals. In this character they differ from living reptiles, and parallel some Dinosaurs from the Weald. The bones of the back in Ornithocheirus from the Cambridge Greensand show the under side to be well rounded, so that the articular surfaces between the vertebr&aelig;, though still rather wider than deep, are much less depressed than in the region of the neck. The neural canal for the spinal cord has become <span class="pagenum"><SPAN name="Page_85" id="Page_85">[Pg 85]</SPAN></span> larger and higher, and the sides of the bone are somewhat compressed. Strong transverse processes for the support of the ribs are elevated above the level of the neural canal, at the sides of vertebr&aelig; compressed on the under sides, and directed outward. Between these lateral horizontal platforms is the compressed median neural spine, which varies in vertical height. The articulation of the ribs is not seen clearly. Isolated ribs from the Stonesfield Slate have double-headed dorsal ribs, like those of birds. In some specimens from the Solenhofen Slate like the Scaphognathus, in the University Museum at Bonn, dorsal ribs appear to be attached by a notch in the transverse process of the dorsal vertebra, which resembles the condition in Crocodiles. Variations in the mode of attachment of ribs among mammals may show that character to be of subordinate importance. Von Meyer has described the first pair of ribs as frequently larger than the others, and there appear in Rhamphorhynchus to be examples preserved of the sternal ribs, which connect the dorsal ribs with the sternum. Six pairs have been counted. A more interesting feature in the ribs consists in the presence behind the sternum, which is shorter than the corresponding bone in most birds, of median sternal ribs. They are slender <b>V</b>-shaped bones in the middle line of the abdomen, which overlapped the ends of the dorsal ribs like the similar sternal bones of reptiles. Such structures are unknown among Birds and Mammals. There is no trace in the dorsal ribs of the claw-like process, which extends laterally from rib to rib as a marked feature in many birds. Its presence or absence may not be important, because it is represented by fibro-cartilage <span class="pagenum"><SPAN name="Page_86" id="Page_86">[Pg 86]</SPAN></span> in the ribs of crocodiles, and may be a small cartilage near the head of the rib in serpents, and is only ossified in some ribs of the New Zealand reptile Hatteria. So that it might have been present in a fossil animal without being ossified and preserved. Although the structure is associated with birds, it is possibly also represented by the great bony plates which cover the ribs in Chelonians, and combine to form the shield which covers the turtle's back. The structure is as characteristic of reptiles as of birds, but is not necessarily associated with either.</p> <div class="figcenter"> <SPAN name="Fig_26" id="Fig_26"></SPAN> <span class="caption">FIG. 26</span> <ANTIMG src="images/i_103.jpg" width-obs="640" height-obs="441" alt="FIG. 26" title="FIG. 26" /> <p class="center">The upper figures show the side and back of a dorsal vertebra of Ornithocheirus compared with corresponding views of the side and back of a dorsal vertebra of a Crocodile</p> </div> <p>There are two remarkable modifications of the early dorsal vertebr&aelig; in some of the Cretaceous Pterodactyles. First, in the genus Ornithodesmus from the Weald the early dorsal vertebr&aelig; are blended together into a continuous mass, like that which is found in the corresponding region of the living Frigate-bird, only more consolidated, and similar to <span class="pagenum"><SPAN name="Page_87" id="Page_87">[Pg 87]</SPAN></span> that consolidated structure found behind the dorsal vertebr&aelig;, known as the sacrum, made by the blending of the vertebr&aelig; into a solid mass which supports the hip bones. Secondly, in some of the Cretaceous genera of Pterodactyles of Europe and America the vertebr&aelig; in the front part of the back are similarly blended, but their union is less complete; and in genera Ornithocheirus and Ornithostoma&mdash;the former chiefly English, the latter chiefly American&mdash;the sides of the neural spines are flattened to form an oval articular surface on each side, which gives attachment to the flattened ends of their shoulder-blade bones named the scapul&aelig;. This condition is found in no other animals. Three vertebr&aelig; appear to have their neural arches thus united together. The structure so formed may be named the notarium to distinguish it from the sacrum.</p> <h4>SACRUM</h4> <p>For some mysterious reason the part of the backbone which lies between the bones of the hips and supports them is termed the sacrum. Among living reptiles the number of vertebr&aelig; in this region is usually two, as in lizards and crocodiles. There are other groups of fossil reptiles in which the number of sacral vertebr&aelig; is in some cases less and in other cases more. There is, perhaps, no group in which the sacrum makes a nearer approach to that of birds than is found among these Pterodactyles, although there are more sacral vertebr&aelig; in some Dinosaurs. In birds the sacral vertebr&aelig; number from five to twenty-two. In bats the number is from five to six. In some Solenhofen species, such as <i>Pterodactylus dubius</i> and <i>P. Kochi</i> and <i>P. grandipelvis</i>, the number <span class="pagenum"><SPAN name="Page_88" id="Page_88">[Pg 88]</SPAN></span> is usually five or six. The vertebr&aelig; are completely blended. The pneumatic foramina in the sacrum, so far as they have been observed, are on the under sides of the transverse processes; while in the corresponding notarial structure in the shoulder girdle the foramina are in front of the transverse processes. Almost any placental mammal in which the vertebr&aelig; of the sacral region are anchylosed together has a similar sacrum, which differs from that of birds in the more complete individuality of the constituent bones remaining evident. The transverse processes in front of the sacrum are wider than in its hinder part; so that the pelvic bones which are attached to it converge as they extend backward, as among mammals. The bodies of the vertebr&aelig; forming the sacrum are similar in length to those of the back. Each transverse process is given off opposite the body of its own vertebra, but from a lower lateral position than in the region of the back, in which the vertebr&aelig; are free.</p> <div class="figcenter"> <SPAN name="Fig_27" id="Fig_27"></SPAN> <span class="caption">FIG. 27. &nbsp; SACRUM OF RHAMPHORHYNCHUS</span> <ANTIMG src="images/i_105.jpg" width-obs="406" height-obs="640" alt="FIG. 27." title="FIG. 27." /> <p class="center">Showing the complete blending of the vertebr&aelig; and ribs as in a bird, with the well-defined Iliac bones, produced chiefly in front of the acetabulum for the head of the femur.</p> </div> <p>The hip bones are closely united with the sacrum by bony union, and rarely appear to come away from the sacral vertebr&aelig;, as among mammals and reptiles, though this happens with the Lias Pterodactyles. In the Stonesfield Slate and Solenhofen Slate the slender transverse processes from the vertebr&aelig; blend with the ilium of the hip girdle, and form a series of transverse <span class="pagenum"><SPAN name="Page_89" id="Page_89">[Pg 89]</SPAN></span> foramina on each side of the bodies of the vertebr&aelig;. In the Cambridge Greensand genera the part of the ilium above the acetabulum for the articular head of the femur appears to be always broken away, so that the relation of the sacrum to the pelvis has not been observed. This character is no mark of affinity, but only shows that ossification obliterated sutures among these animals in the same way as among birds.</p> <p>The great difference between the sacrum of a Pterodactyle and that of a bird has been rendered intelligible by the excellent discussion of the sacral region in birds made by Professor Huxley. He showed that it is only the middle part of the sacrum of a chicken which corresponds to the true sacrum of a reptile, and comprises the five shortest of the vertebr&aelig;; while the four in front correspond to those of the lower part of the back, which either bear no ribs or very short ribs, and are known as the lumbar region in mammals, so that the lower part of the back becomes blended with the sacrum, and thus reduces the number of dorsal vertebr&aelig;. Similarly the five vertebr&aelig; which follow the true sacral vertebr&aelig; are originally part of the tail, and have been blended with the other vertebr&aelig; in front, in consequence of the extension along them of the bird's hip bones. This interpretation helps to account for the great length of the sacrum in many birds, and also explains in part the singular shortness of the tail in existing birds. The Ornithosaur sacrum has neither the lumbar nor the caudal portions of the sacrum of a bird.</p> <p><span class="pagenum"><SPAN name="Page_90" id="Page_90">[Pg 90]</SPAN></span></p> <h4>THE TAIL</h4> <p>The tail is perhaps the least important part of the skeleton, since it varies in character and length in different genera. The short tails seen in typical pterodactyles include as few as ten vertebr&aelig; in <i>Pterodactylus grandipelvis</i> and <i>P. Kochi</i>, and as many as fifteen vertebr&aelig; in <i>Pterodactylus longirostris</i>. The tails are more like those of mammals than existing birds, in which there are usually from six to ten vertebr&aelig; terminating in the ploughshare bone. But just as some fossil birds, like the Arch&aelig;opteryx, have about twenty long and slender vertebr&aelig; in the tail, so in the pterodactyle Rhamphorhynchus this region becomes greatly extended, and includes from thirty-eight to forty vertebr&aelig;. In Dimorphodon the tail vertebr&aelig; are slightly fewer. The earliest are very short, and then they become elongated to two or three times the length of the early tail vertebr&aelig;, and finally shorten again towards the extremity of the tail, where the bones are very slender. In all long-tailed Ornithosaurians the vertebr&aelig; are supported and bordered by slender ossified ligaments, which extend like threads down the tail, just as they do in Rats and many other mammals and in some lizards.</p> <p>Professor Marsh was able to show that the extremity of the tail in Rhamphorhynchus sometimes expands into a strong terminal caudal membrane of four-sided somewhat rhomboidal shape. He regards this membrane as having been placed vertically. It is supported by delicate processes which represent the neural spines of the vertebr&aelig; prolonged upward. They are about fifteen in number. A corresponding <span class="pagenum"><SPAN name="Page_91" id="Page_91">[Pg 91]</SPAN></span> series of spines on the lower border, termed chevron bones, equally long, were given off from the junctions of the vertebr&aelig; on their under sides, and produced downward. This vertical appendage is of some interest because its expansion is like the tail of a fish. It suggests the possibility of having been used in a similar way to the caudal fin as an organ for locomotion in water, though it is possible that it may have also formed an organ used in flight for steering in the air.</p> <div class="figcenter"> <SPAN name="Fig_28" id="Fig_28"></SPAN> <span class="caption">FIG. 28. &nbsp; EXTREMITY OF THE TAIL OF <i>RHAMPHORHYNCHUS PHYLLURUS</i> (<span class="smcap">Marsh</span>)</span> <ANTIMG src="images/i_108.jpg" width-obs="640" height-obs="249" alt="FIG. 28." title="FIG. 28." /> <p class="center">Showing the processes on the upper and under sides of the vertebr&aelig; which make the terminal leaf-like expansion</p> </div> <p>The tail vertebr&aelig; from the Cambridge Greensand are mostly found isolated or with not more than four joints in association. They are very like the slender type of neck vertebr&aelig; seen in long-necked pterodactyles, but are depressed, and though somewhat wider are not unlike the tail vertebr&aelig; of the Rhamphorhynchus. The pneumatic foramen in them is a mere puncture. They have no transverse processes or neural spines, nor indications of ribs, or chevron bones.</p> <p>The hindermost specimens of tail vertebr&aelig; observed have the neural arch preserved to the end, as among reptiles; whereas in mammals this arch becomes lost towards the end of the tail. The processes by which the vertebr&aelig; are yoked together are <span class="pagenum"><SPAN name="Page_92" id="Page_92">[Pg 92]</SPAN></span> small. There is nothing to suggest that the tail was long, except the circumstance that the slender caudal vertebr&aelig; are almost as long as the stout cervical vertebr&aelig; in the same animal. No small caudal vertebr&aelig; have ever been found in the Cambridge Greensand. The tail is very short, according to Professor Williston, in the toothless Ornithostoma in the Chalk of Kansas.</p> <hr style="width: 65%;" /> <p><span class="pagenum"><SPAN name="Page_93" id="Page_93">[Pg 93]</SPAN></span></p> <div style="break-after:column;"></div><br />