Quantifying the effect of intervertebral cartilage on neutral posture in the necks of sauropod dinosaurs

View article
PeerJ
Note that a Preprint of this article also exists, first published November 5, 2014.

Introduction

The habitual posture of the necks of sauropod dinosaurs has been controversial ever since their body shape has been understood. Both elevated and more horizontal postures have been depicted, sometimes even in the same images—for example, Knight’s classic 1897 painting of Apatosaurus and Diplodocus (Fig. 1). See the introduction to Taylor & Wedel (2013) for a more comprehensive historical overview.

Charles R. Knight’s famous 1897 painting of sauropods, which were then considered amphibious.

Figure 1: Charles R. Knight’s famous 1897 painting of sauropods, which were then considered amphibious.

In the foreground, Apatosaurus (“Brontosaurus” of his usage) wades in a lake, its neck erect. In the background, Diplodocus wanders on the shore, its neck held low and horizontal. These differences in posture may not represent different perceptions of the habitual behaviour of these different taxa, merely the postures these individuals happened to adopt at a particular moment.

Stevens & Parrish (1999) used DinoMorph, a computer program of their own devising, to model the intervertebral articulations in the necks of two well-known sauropods, Apatosaurus and Diplodocus. They found that when the vertebrae were best aligned—with the centra in articulation and the zygapophyseal facets maximally overlapped—the necks were held in roughly horizontal positions; Stevens & Parrish (1999) concluded without further discussion that this was the habitual posture in life—an assumption which they subsequently asserted was supported by observation of extant tetrapods (Stevens & Parrish, 2005). In fact, as discussed below, tetrapods do not habitually hold their necks in neutral pose; nevertheless, determining neutral pose is an important step towards understanding habitual pose.

The study of Stevens & Parrish (1999) has been influential but can and should be further refined. Taylor & Wedel (2013) demonstrated the important role of a neglected element, the intervertebral cartilage that separates the centra of adjacent vertebrae. We noted in that paper that including the cartilage in models affects the neutral posture recovered, causing the neck to be raised more than when only bone is taken into account, but we failed to quantify the additional extension of the neck. The present paper remedies this deficiency.

The neutral pose determined by Stevens and Parrish from bones alone is termed osteological neutral pose (ONP). I use the term cartilaginous neutral pose (CNP) for the pose found when intervertebral cartilage is included. Each specimen has a true CNP, determined by the actual arrangement of cartilage on its vertebrae. Because we are dealing with extinct animals known only from fossils, we must make assumptions about the cartilage that existed in life, and so can derive only provisional CNPs.

Note that zygapophyseal cartilage has no or negligible effect on the angle of extension between vertebrae. This is partly because this cartilage is so thin compared with that between consecutive centra, but primarily because of the orientation of the zygapophyseal facets. If they faced anteriorly and posteriorly, then inserting cartilage between them would push the dorsal part of the vertebral articulation apart and deflect the neutral pose downwards. But because the facets face dorsomedially and ventrolaterally, the addition of cartilage between them does not affect their relative anteroposterior position.

Methods

Formula for additional extension

Figure 2A shows two adjacent vertebrae in osteological neutral pose (ONP): the condyle (anterior ball) of one vertebra is nestled in the cotyle (posterior cup) of the other, and its prezygapophyseal facets are maximally overlapped with the postzygapophyseal facets of the other.

Increased angle of elevation at an intervertebral joint when cartilage is included. Posterior cervical vertebrae 13 and 14 of Diplodocus carnegii holotype CM 84, from Hatcher (1901: plate III), in right lateral view.

Figure 2: Increased angle of elevation at an intervertebral joint when cartilage is included. Posterior cervical vertebrae 13 and 14 of Diplodocus carnegii holotype CM 84, from Hatcher (1901: plate III), in right lateral view.

(A) C13 (yellow) in osteological neutral posture, with the condyle of C14 embedded in its cotyle and with zygapophyseal facets maximally overlapped. (B) Intervertebral cartilage (black) added, and C13 (blue) rotated upwards to accommodate it. (For simplicity, the cartilage is depicted as though all attached to the condyle of the posterior vertebra in the present figure and in Fig. 3; in fact it would have been roughly half and half on this condyle and on the cotyle of the more anterior vertebra.) Since the zygapophyses remain maximally overlapped, the centre of their facets forms the axis of rotation (white dot); red lines join the centre of rotation to the most anterior point of the bony condyle and of the intervertebral cartilage. By similarity, the angle between the yellow and blue vertebrae is equal to that between the red lines.

Figure 2B shows the effect of including intervertebral cartilage of thickness t (here depicted as being one tenth as thick as the length of the bony centrum). The cartilage itself is shown in black. For simplicity, it is depicted as though all are attached to the condyle of the more posterior (grey) vertebra; in fact it would have been roughly half and half on this condyle and on the cotyle of the more anterior (blue) vertebra.

In order to accommodate the intervertebral cartilage, the cotyle of the anterior vertebra has to be shifted forward by a distance equal to the thickness of the cartilage, as shown in Fig. 2B. But in this new “neutral pose”, the zygapophyseal facets remain maximally overlapped, so the effect is to rotate the anterior vertebra anti-clockwise about the centre of the zygapophyses, which is at height h above the midline of the condyle. The red lines are drawn between the centre of rotation and the anteriormost point of the bony condyle and the cartilage extension (or, equivalently, the deepest part of the cotyles of both the yellow and blue vertebrae). The rotation between the blue and yellow vertebrae is equal to the angle θ between the red lines.

Because the thickness of cartilage is a small proportion of centrum length, this angle is small. Therefore a line drawn from the anteriormost point of the bony centrum to that of the cartilage (short line of length t in Fig. 3) forms a triangle with the red lines that is close to a right-angled triangle. Consider the angle θ: its opposite is the short line of length t and its hypotenuse is one of the long lines of length h. Therefore sin(θ) = t/h. But for small angles, sin(θ) ≈ θ (measured in radians).

Close-up of area of rotation in Fig. 2.

Figure 3: Close-up of area of rotation in Fig. 2.

The two long lines, each of length h, connect the middle of the zygapophyseal facets to the anteriormost point of the condyle of the posterior vertebra and the cotyle of the anterior one. The short line of length t is projected at a right angle to the left line, and more or less connects the points on the condyle and cotyle. The angle between the two long lines is θ.

Therefore, the angle of extension due to cartilage at an intervertebral joint, in radians, is approximately equal to the thickness of the cartilage divided by the height of the zygapophyses above half height of the joint between centra. θ=t/h. This formula is independent of the unit of linear measurement: inches, millimetres or pixels in a digitised photograph are all equally valid so long as the same unit is used for cartilage thickness and zygapophyseal height.

Since π radians is equal to 180° (half a circle), an angle in radians can be converted to degrees by multiplying by 180/π. Therefore, the angle of extension in degrees is t/h × 180/π.

This calculation is only approximate: the triangle is not a true right-triangle, and sin(θ) is only approximately equal to θ. However, these minor sources of inaccuracy are dwarfed by other sources of error when working with sauropods: distortions in the measured vertebrae, estimations in measurement where the vertebrae are incomplete, and uncertainty about cartilage thickness. In this context, the θ = t/h approximation is quite precise enough.

Cartilage thickness assumptions

Taylor & Wedel (2013: 7–8) recently estimated the thickness of intervertebral cartilage from vertebral spacing between adjacent vertebrae in two sauropod genera. We found that cartilage thickness between cervical vertebrae of an adult Sauroposeidon individual was about 4.5% of centrum length; that between anterior dorsal vertebrae of a subadult Apatosaurus individual CM 3390 it was about 20% of centrum length; and that between mid-to-posterior dorsal vertebrae of a second, juvenile, Apatosaurus individual CM 11339 it was about 15% of centrum length. Assuming similar absolute thickness of cartilage in the neck of adult Apatosaurus as in Sauroposeidon (about 52 mm), we estimated that cartilage thickness would be about 9.8% the length of the shorter Apatosaurus vertebrae. Similarly, assuming similar absolute thickness of cartilage in adult Apatosaurus necks as in subadult anterior torsos, we estimated cartilage thickness in adult Apatosaurus might have been about 11%, a value fairly consistent with that derived from Sauroposeidon measurements.

These cartilage thickness proportions are provisional—we are very aware that our sample is tiny, and encourage other sauropod workers to CT-scan articulated sequences of vertebrae when possible. However, since they are the only existing estimates, I calculated the effect of inserting intervertebral cartilage into the neck of Apatosaurus using three possible thicknesses: the 4.5% of the adult Sauroposeidon neck; the 10% that was estimated in two ways as most likely for the adult Apatosaurus neck; and 18%, the average of the 20% and 15% found for the two non-adult Apatosaurus torso sequences. Since Diplodocus is closely related to Apatosaurus and was also discussed by Stevens & Parrish (1999), I also calculated the effect of adding cartilage to its neck in the same proportions as for Apatosaurus.

Sauropod specimens

I used the same well-known specimens as Stevens & Parrish (1999): CM 3018, the holotype of Apatosaurus louisae; and CM 84, the holotype of Diplodocus carnegii. Both specimens reside in the Carnegie Museum of Natural History, Pittsburgh, Pennsylvania, USA. They are well-preserved for sauropods, having nearly complete cervical sequences, although the more posterior vertebrae of CM 3018 are badly damaged and all the vertebrae suffer from some distortion. All calculations are based only on centrum length, zygapophyseal height (measured from published illustrations) and hypothetical cartilage thicknesses.

Results

For Apatosaurus CM 3018, the results are as shown in Table 1: additional extension across all 13 analysed intervertebral joints sums to 70°, 155° and 279° for 4.5%, 10% and 18% cartilage thickness. Figure 4 shows the effect of the additional extension caused by 10% cartilage compared to a horizontal neck: if osteological neutral pose were horizontal, then the neutral pose when taking into account intervertebral cartilage whose thickness is 10% of centrum length would be as depicted. I term this the 10% cartilaginous neutral pose or 10% CNP. (In fact, Stevens & Parrish (1999) found ONP in both Apatosaurus and Diplodocus to be somewhat below horizontal, but since their exact angles of flexion were not published, it is not possible to determine how their favoured pose would appear when modified by the addition of cartilage.)

Effect of adding cartilage to the neutral pose of the neck of Apatosaurus louisae CM 3018.

Figure 4: Effect of adding cartilage to the neutral pose of the neck of Apatosaurus louisae CM 3018.

Images of vertebrae from Gilmore (1936: plate XXIV). At the bottom, the vertebrae are composed in a horizontal posture. Superimposed, the same vertebrae are shown inclined by the additional extension angles indicated in Table 1. If the slightly sub-horizontal osteological neutral pose of Stevens & Parrish (1999) is correct, then the cartilaginous neutral pose would be correspondingly slightly lower than depicted here, but still much closer to the elevated posture than to horizontal. (Note that the posture shown here would not have been the habitual posture in life: see discussion).
Table 1:
Centrum length, zygapophyseal height, possible cartilage thicknesses and corresponding additional angles of extension in the neck of the Apatosaurus louisae holotype CM 3018.
Centrum lengths are taken from Gilmore (1936: 196) except for C5, C14 and C15, which are omitted from Gilmore’s table and were instead measured from his illustration (Gilmore, 1936: plate XXIV). Zygapophyseal height was measured from the midline of the centrum to the midpoint of the postzygapophysis on plate XXIV. Cartilage thicknesses were calculated as percentages of the centrum lengths, using three different percentages as described in the text. Additional angles of extension were calculated using the formula in the Methods section. Cumulative angles measure the total additional extension from ONP, beginning with small extensions at the shoulder and increasing anteriorly. The full spreadsheet from which this table was exported, including formulae, is Supplemental Information 1.
Cv# Centrum
length (mm)
Zygapophysis
height (mm)
Cartilage
(mm)
Angle
(degrees)
Cumulative angle
(degrees)
4.5% 10% 18% 4.5% 10% 18% 4.5% 10% 18%
1 45 2 5 8
2 190 9 19 34
3 280 130 13 28 50 6 12 22 70 155 279
4 370 150 17 37 67 6 14 25 64 143 257
5 443 160 20 44 80 7 16 29 58 129 231
6 440 171 20 44 79 7 15 26 51 113 203
7 450 155 20 45 81 8 17 30 44 98 176
8 485 206 22 49 87 6 13 24 37 81 146
9 510 285 23 51 92 5 10 18 30 68 122
10 530 273 24 53 95 5 11 20 26 57 103
11 550 308 25 55 99 5 10 18 21 46 83
12 490 261 22 49 88 5 11 19 16 36 65
13 480 290 22 48 86 4 9 17 11 25 46
14 411 274 19 41 74 4 9 15 7 16 29
15 372 292 17 37 67 3 7 13 3 7 13
Average 18.3 40.3 72.5 5.5 11.8 21.2
DOI: 10.7717/peerj.712/table-1

For Diplodocus CM 84, the results are as shown in Table 2: additional extension across all 13 analysed intervertebral joints sums to 108°, 241° and 434° for 4.5%, 10% and 18% cartilage thickness. Figure 5 shows the effect of the additional extension caused by 10% cartilage compared to a horizontal Diplodocus neck, as Fig. 4 does for Apatosaurus; the same caveats apply.

Effect of adding cartilage to the neutral pose of the neck of Diplodocus carnegii CM 84.

Figure 5: Effect of adding cartilage to the neutral pose of the neck of Diplodocus carnegii CM 84.

Images of vertebrae from Hatcher (1901: plate III). At the bottom, the vertebrae are composed in a horizontal posture. Superimposed, the same vertebrae are shown inclined by the additional extension angles indicated in Table 2.
Table 2:
Centrum length, zygapophyseal height, possible cartilage thicknesses and corresponding additional angles of extension in the neck of the Diplodocus carnegii holotype CM 84.
Centrum lengths are taken from Hatcher (1901: 38). Zygapophyseal height was measured from the midline of the centrum to the midpoint of the postzygapophysis on Hatcher (1901: plate III). Cartilage thicknesses, angles and cumulative angles are as for Table 1. The full spreadsheet from which this table was exported, including formulae, is Supplemental Information 2.
Cv# Centrum
length (mm)
Zygapophysis
height (mm)
Cartilage
(mm)
Angle
(degrees)
Cumulative
angle (degrees)
4.5% 10% 18% 4.5% 10% 18% 4.5% 10% 18%
1
2 165 7 17 30
3 243 64 11 24 44 10 22 39 108 241 434
4 289 59 13 29 52 13 28 50 99 219 395
5 372 108 17 37 67 9 20 35 86 192 345
6 442 132 20 44 80 9 19 34 77 172 309
7 485 108 22 49 87 12 26 46 69 153 275
8 512 161 23 51 92 8 18 33 57 127 229
9 525 161 24 53 95 8 19 34 49 109 196
10 595 209 27 60 107 7 16 29 41 90 162
11 605 202 27 61 109 8 17 31 33 74 133
12 627 233 28 63 113 7 15 28 25 57 102
13 688 239 31 69 124 7 17 30 18 41 74
14 642 271 29 64 116 6 14 24 11 25 44
15 595 309 27 60 107 5 11 20 5 11 20
Average 21.9 48.6 87.4 8.4 18.6 33.3
DOI: 10.7717/peerj.712/table-2

Discussion

The additional angles of extension calculated here are greater for Diplodocus than for Apatosaurus—on average, about 55% greater. This is for two reasons. First, the additional angle of extension is directly proportional to cartilage thickness, which I calculated as proportional to centrum length, and the centra are longer in Diplodocus; and second, the angle is also inversely proportional to the height of the zygapophyseal facets above the centre of rotation between adjacent centra, and this is lower in Diplodocus.

There is no denying that the cartilaginous neutral poses (CNPs) described here for Apatosaurus and Diplodocus appear outlandish. Using the largest of the candidate cartilage thicknesses, 18% of centrum length, the neutral pose for Diplodocus has C3 oriented at 434° to the horizontal (Table 2, last column)—that is, the neck would be extended all the way around through 360° and a further 74°. This alone seems to be enough to discount the possibility that the 18% estimate of cartilage thickness is correct—not unreasonably, since this was measured from the dorsal sequences of sub-adult and juvenile specimens. However, the 10% cartilage thickness that seems the best estimate also yields surprising neutral postures (Figs. 4 and 5). It is tempting for this reason to prefer the 4.5% cartilage thickness, which results in C3 of Diplodocus extending only 108°—although note that even this is well past vertical. However, it seems unlikely (based on our small sample of CT scans) that half-meter-long Apatosaurus cervicals can have been separated by as little as 23 mm of cartilage. At present, 10% of centrum length is our best estimate of cartilage thickness.

The CNP for other dinosaurs may be even more extreme than for sauropods. Samman (2013) articulated the cervical series of Tyrannosaurus (using a composite of two specimens, FMNH PR 2081 and TCMI 2001.90.1). She found that the centra alone articulate naturally into an ‘S’-curve, due to their keystoned shapes in lateral view, but that when the zygapophyses are also articulated, the ONP was strongly extended into a posture that would surely not have been adopted in life. Inserting articular cartilage between the centra would raise this posture yet further.

Although the 10% CNP calculated and illustrated in this paper is a more defensible neutral pose than the ONP of Stevens & Parrish (1999), I must emphasised that I do not suggest this was the habitual pose in life. As noted by Vidal, Graf & Berthoz (1986) and Taylor, Wedel & Naish (2009), live tetrapods do not habitually hold their necks in neutral pose. Instead, when awake and alert, they extend (raise) the base of the neck and flex (lower) the anterior part. The result is that the middle part of the cervical column is habitually held much more vertically in most tetrapods that would be apparent from the fleshy envelope (Wedel & Taylor, 2014). Indeed, in many mammals that we hardly even think of as having a neck, the vertebral column bends backwards beyond the vertical: this is seen for example in rabbits, mice and guinea pigs as well as cats and chickens (Vidal, Graf & Berthoz, 1986: figs. 2–5, 7, 8). Accordingly, we would expect that the life poses of sauropods had the base of the neck extended yet further than the angles here shown as neutral; but that the anterior part of their necks would have been curved forwards and downwards. It seems possible that in both diplodocids analysed here, part of the neck habitually curved backwards beyond the vertical in an “S” shape, as in many extant birds.

Similarly, Tyrannosaurus must have habitually held its neck in a pose differing greatly from its neutral posture. In particular, much of its neck must have been flexed downwards most of the time, perhaps extending only when tearing meat from a carcass.

The effect of intervertebral cartilage on neck flexibility, as opposed to its effect on neutral posture, remains to be determined. Taylor & Wedel (2013: 15) showed that in turkeys, zygapophyseal surfaces are extended by cartilage, and it is likely that this is true of all tetrapods. Larger zygapophyseal facets translate to more flexibility, as a greater displacement from the neutral pose can occur before the facets become disarticulated. But this is only a relatively small effect (increasing flexibility by about 11% in our turkey specimen) and relates to zygapophyseal rather than intervertebral cartilage.

As noted by Taylor & Wedel (2013: 15), Cobley, Rayfield & Barrett (2013) found that ostrich necks with their soft tissue in place are less flexible than bones alone indicate. However, we know that human necks are much more flexible in life than the bones alone would suggest, since the flat articular surfaces of human cervical centra taken alone would indicate an almost entirely inflexible neck. The different effect on neck flexibility of intervertebral cartilage across different taxa would be a fruitful area for further study.

Supplemental Information

S1: Data on neck Apatosaurus lousiae CM 3018

DOI: 10.7717/peerj.712/supp-1

S2: Data on neck Diplodocus carnegii CM 82

DOI: 10.7717/peerj.712/supp-2
10 Citations   Views   Downloads