Fused and vaulted nasals of tyrannosaurid dinosaurs: Implications for cranial strength and feeding mechanics
Author
Eric Snively
Department of Biological Sciences, University of Calgary, 2500 University Drive NW, Calgary, Alberta T 2 N 1 N 4, Canada
esnively@ucalgary.ca
Author
Donald M. Henderson
Royal Tyrrell Museum of Palaeontology, Box 7500, Drumheller, Alberta T 0 J 0 Y 0, Canada
don.henderson@gov.ab.ca
Author
Doug S. Phillips
Department of Information Technologies, University of Calgary, 2500 Univer− sity Drive NW, Calgary, Alberta T 2 N 1 N 4, Canada
phillips@ucalgary.ca
text
Acta Palaeontologica Polonica
2006
2006-12-31
51
3
435
454
journal article
10.5281/zenodo.3739898
b59ceaea-b2b8-4c81-a78a-083ea9cfe615
3739898
Hypotheses and approach
The fusion and vaulting of tyrannosaurid nasals, and their position as the keystone (
Busbey 1995
) of a broad, strongly articulated nasal−maxillary arch, suggest that the nasals enhanced the strength of the snout against compressive, bending, shear, and torsional forces. The confluence of unusual mandible, tooth, and nasal morphologies in the Tyrannosauridae suggests a correlated progression (
Thomson 1966
;
Kemp 1999
) towards a reinforced head skeleton and high bite power.
Fig. 1. Comparison of cranial and nasal morphology of:
A
, the tyrannosaurid
Tyrannosaurus rex
(TMP 98.86.01; cast of BHI 2033) and
B
, the carnosaur
Allosaurus fragilis
(UUVP 1663/UMNH VP 9146; mirrored to depict a complete pair). Scale axes for crania are in meters. Nasals in their life positions are highlighted in lateral and dorsal cranial views, and rendered in oblique view (not to scale). The
T. rex
nasals are tall, vaulted, and fused, while the
A. fragilis
nasals are lower and unfused.
Fig. 2. Comparison of vertical bending strengths of adult theropod dentaries, graphed as mid−dentary section modulus versus mandible length (data from
Therrien et al. 2005
). Lines fitted by least squares regression, by log transformed values for the tyrannosaurid data. Carnosaur dentary strengths scale linearly with dentary length, while tyrannosaurid dentary strengths show an exponential increase. The tyrannosaurid dentaries are stronger than those of carnosaurs for a given mandible length, indicating a relatively stronger bite. See Appendix 1 for specimen labels; Gc,
Giganotosaurus carolinii
.
Using data derived from CT cross−sections of theropod nasals, analysis of cross−sectional geometry of theropod crania, and measurements of maxillary teeth, we tested several hypotheses related to possible correlated progression of the tyrannosaurid feeding apparatus:
(1) Tyrannosaurid maxillary teeth were stronger in bending those of other large carnivorous dinosaurs.
(2) Vaulting contributed significantly to tyrannosaurid nasal strength.
(3) Fusion of tyrannosaurid nasals imparted higher torsional and shear strengths than those of
Allosaurus
nasals.
(4) Tyrannosaurid crania were stronger in bending and torsion than carnosaur crania of similar length.
We approach these hypotheses inductively, proceeding from tooth to nasal to cranial strengths. The teeth were the elements that would first encounter resistance of prey tissues and would transmit food reaction forces to the cranium. Tyrannosaurid nasals were potentially adapted to resisting those forces, as dorsally positioned compressive members of the truss−like cranium (
Molnar 2000
;
Rayfield 2004
). We chose this order of investigation because each inductive stage can potentially falsify our overall hypothesis of correlated progression, and will build up to an integrated picture of the strengths of theropod feeding apparatus.
To compare these strengths, we used simple engineering principles and calculations. Simplified models of biological structures have a rich history in the palaeontological and neontological literature (
Alexander 1985
;
Farlow et al. 1995
;
Greaves 1978
,
1991
;
Henderson 2002
;
Holtz 1995
;
Molnar 2000
;
Slijper 1946
;
Thomason and Russell 1986
;
Thompson 1917
). Simple approximations are valuable for numerous reasons, especially in palaeontology.
Fig. 3. Comparisons of mediolateral (
A
,
B
) and anteroposterior (
C
,
D
) strengths of tyrannosaurid and non−tyrannosaurid theropod maxillary teeth, plotted against skull length. Regressions are by least squares, on log transformed data for the tyrannosaurids. Trend lines are allometric in the tyannosaurids but linear in non−tyrannosaurids. Tooth strengths of
Tyrannosaurus rex
are much higher than in any other examined taxon. Starting points of the small arrows indicate the position of the juvenile
T. rex
(TrJ). See Appendix 1 for other specimen labels.
First, reductionist models allow efficient tests of strength hypotheses by equations of beam theory and its elaborations (
Young and Budynas 2001
). These methods are applicable to cantilevered structures regardless of the proportions or shape of the beam (
Molnar 2000
;
Henderson 2002
) or truss (
Rayfield 2004
). Second, simple computational models can be constructed quickly, enabling assessment of variation across taxa. In contrast, 3D finite element modeling is time consuming and usually encompasses one taxon at a time (
Rayfield et al. 2001
;
Snively and Russell 2002
;
Mazzetta et al. 2004
;
Rayfield 2005
). Third, simple analyses, as of skull and metatarsal function (
Bakker 2000
;
Holtz 1994
;
Molnar 1973
,
2000
;
Snively and Russell 2003
;
Snively et al. 2004
), yield rapid generation of results and hypotheses that are testable by more sophisticated means (
Rayfield et al. 2001
;
Rayfield 2004
;
Snively and Russell 2002
). Conversely, elaborate tests (
Rayfield et al. 2001
) are subject to refinement of assumptions, whose effects are more easily testable with simplified methods (
Rayfield 2004
).
Using shell−like theropod cranial models to test relative strengths exemplifies this approach. Models incorporating the influence of intracranial joints, cranial fenestration, and the palate (
Rayfield 2005
) will be valuable for future studies, because these factors affected second moments of area and hence bending and torsional strengths. We did not construct them here for several reasons. Fenestration occurred in areas where stresses would otherwise be minimal (
Molnar 2000
;
Rayfield et al. 2001
), stress concentrations will be similar overall in shell−like and lattice models (
Gordon 1978
;
Greaves 1985
), and a shell−like model does not obscure relative strengths of theropod crania.
For our purposes, the main benefit of the shell−like models is that they isolate the effects of geometry from other factors contributing to cranial strength. Tyrannosaurid crania had proportionally more bone and smaller fenestrae than did carnosaurs (
Henderson 2002
), and larger and presumably stronger ligamentous joints for resisting tension along the ventral bor− der of the cranium (
Rayfield 2004
). The anterior secondary palate of tyrannosaurids (
Holtz 2002
) would greatly increase the torsional strength of the tyrannosaurid rostrum over that in some carnosaurs (contact of the palatal shelves in synapsids increased torsional strength immensely:
Thomason and Russell 1986
; Busby 1995). We gave the more open carnosaur specimens a relative advantage by approximating all crania as equally “closed” structures, effectively putting tyrannosaurid cranial geometry to a more stringent test.
Institutional abbreviations
.—AMNH, American Museum of Natural History, New York, New York, USA; BHI, Black Hills Institute of Geological Research, Hill City, South Dakota, USA; BMRP, Burpee Museum of Natural History, Rockford, Illinois, USA; FMNH, Field Museum of Natural History, Chicago, Illinois, USA; IVPP, Institute of Vertebrate Palaeontology and Palaeoanthropology, Bejing, China; LACM, Natural History Museum of Los Angeles County, Los Angeles, California, USA; ROM, Royal Ontario Museum, Toronto, Ontario, Canada; MACN, Museo Argentino de Ciencias Naturales, Buenos Aires, Argentina; MOR, Museum of the Rockies, Bozeman, Montana, USA; MWC, Museum of Western Colorado, Grand Junction, Colorado, USA; NCSM, North Carolina State Museum of Natural Sciences, Raleigh, North Carolina, USA; SGM, Ministere de l̓Energie et des Mines, Rabat, Morocco; TCMI, The Children̓s Museum of Indianapolis, Indianapolis, Indiana, USA; TMP, Royal Tyrrell Museum of Palaeontology, Drumheller, Alberta, Canada; UUVP, University of Utah Vertebrate Paleontology, Salt Lake City, Utah, USA.
Strengths of large theropod teeth
Materials and methods for testing tooth strength of large
theropods
.—We measured
in situ
maxillary teeth of large theropods (
Table 1
, Appendix 1) to determine if the tyrannosaurid teeth were stronger than those of non−tyrannosaurids, and to reveal any trends in tooth strength with increases in body size. Specimens included tyrannosaurids, carnosaurs, and neoceratosaurians. Maxillary tooth measurements of the carnosaur
Acrocanthosaurus atokensis
were obtained from the literature (
Harris 1998
;
Currie and Carpenter 2000
).
Table 1. Measured and computed properties of theropod maxillary teeth. N, number of teeth measured; CH, average crown height; FABL, average fore, aft basal length; MLBL, averge medolateral basal length; AP str., average anteroposterior bending strength indicator; ML str., mediolateral bending strength indicator; Skull l., skull length. Raw measurements of CH, FABL, and MLBL, not these averages, were used to calculate strength indicators.
| N |
CH (mm) |
FABL (mm) |
MLBL (mm) |
AP str. m3 |
ML str. m3 |
Skull l. cm |
|
Tyrannosauridae
|
|
Albertosaurus sarcophagus
(As)
|
7 |
70 |
29.9 |
17 |
0.214 |
0.122 |
86.0 |
|
Daspletosaurus torosus
(DtS)
|
9 |
37.9 |
16.8 |
11.1 |
0.086 |
0.055 |
57.3 |
|
Daspletosaurus torosus
(DtL)
|
6 |
72.5 |
27.3 |
19.7 |
0.202 |
0.144 |
97.0 |
|
Gorgosaurus libratus
(Gl)
|
13 |
54.8 |
22.90 |
12.90 |
0.12 |
0.213 |
75.0 |
|
Gorgosaurus libratus
(GlL)
|
11 |
57.1 |
23.13 |
22.6 |
0.127 |
0.088 |
76.0 |
|
Tyrannosaurus rex
(TrA)
|
10 |
101.6 |
37.0 |
28.20 |
0.471 |
0.630 |
119.0 |
|
Tyrannosaurus rex
(TrB)
|
11 |
98.4 |
45.0 |
33.50 |
0.864 |
1.154 |
140.0 |
|
Tyrannosaurus rex
(TrL)
|
9 |
78.6 |
41.4 |
25.70 |
0.659 |
1.042 |
122.0 |
|
Tyrannosaurus rex
juv. (TrJ)
|
11 |
45.5 |
22.6 |
11.20 |
0.131 |
0.065 |
74.0 |
| Non−tyrannosaurids |
|
Acrocanthosaurus atokensis
(Aa)
|
1 |
84.0 |
31.0 |
19.5 |
0.492 |
0.310 |
105.0 |
|
Allosaurus fragilis
(Af)
|
14 |
44.3 |
18.40 |
12.70 |
0.121 |
0.176 |
76.0 |
|
Carnotaurus sastrei
(Cs)
|
12 |
47.5 |
22.60 |
15.70 |
0.211 |
0.310 |
56.0 |
|
Ceratosaurus dentisulcatus
(Cd)
|
10 |
62.9 |
26.10 |
10.60 |
0.079 |
0.193 |
63.0 |
|
Monolophosaurus jiangi
(Mj)
|
13 |
39.8 |
19.80 |
11.00 |
0.103 |
0.187 |
83.0 |
|
Sinraptor dongi
(Sd)
|
12 |
47.5 |
22.60 |
15.70 |
0.211 |
0.310 |
84.0 |
Measurements (with Mitutoyo 505–634 calipers) were crown height, fore−aft basal length (FABL) and mediolateral basal length (MLBL),
sensu
Farlow et al. (1991)
. Because teeth of
Tyrannosaurus rex
BHI 2033
had taphonomically slipped out of the alveoli, their cross sectional measurements were taken from the proximal base of the enamel, and crown heights measured from this point as well. Strength indicators for maxillary teeth in mediolateral and anteroposterior bending were determined by calculating their section modulus after
Farlow et al. (1991
; assuming a rectangular cross−section), dividing by crown height, and assuming a unit force.
These tooth strength indicators were plotted against skull length. Skull lengths (from the anterior tip of the premaxilla to the posterior edge of the quadrates in lateral view) were measured with a tape measure, taken from the literature, or calculated from maxillary measurements and the log form of regression equations in
Currie (2003b)
. The predicted lengths of measured skulls were within 3% of their actual lengths. However, for disarticulated skulls whose lengths were calculated using the regression equations (TCMI 2001.89.01; TMP 1994.143.1, 2001.36.1, and 2004.03.03), future published lengths from reconstructed skulls will be more definitive than those calculated here.
Results for maxillary tooth bending strengths
.—
Table 1
enumerates average measurements and strength results for theropod maxillary teeth, and
Fig. 3
plots mean maxillary tooth strengths versus theropod skull lengths. Fitted trend lines (using least squares regression) are shown for tyrannosaurids and carnosaurs, with the neoceratosaurians plotted as well. Smaller tyrannosaurid teeth are generally weaker in anteroposterior and mediolateral bending than teeth of non−tyrannosaurids. Maxillary teeth of most large tyrannosaurids are as strong or slightly stronger in mediolateral bending and stronger in anteroposterior bending than teeth of non−tyrannosaurids, except for the large carnosaurs
Sinraptor dongi
and
Acrocanthosaurus atokensis
.
Tyrannosaurus rex
has much higher tooth strengths than these carnosaurs or other large tyrannosaurids. The average strengths of
T. rex
teeth are extraordinary high relative to skull length, despite marked discrepancies in tooth sizes along each specimen̓s maxillary row (evident in the lower average strength in
AMNH 5027
). The patterns of increasing tooth strength with skull length differ between tyrannosaurids and other large theropods. The line of best fit for the non−tyrannosaurids is linear, while that for the tyrannosaurids is best described by an exponential function.
Fig. 4. CT reconstructions of tyrannosaurid nasals in side and top views. Anterior is to the right.
A
.
Tyrannosaurus rex
(
TMP 98.86.01; cast of BHI 2033
).
B
.
Daspletosaurus torosus
(TMP 98.48.1).
C
.
Albertosaurus sarcophagus
(TMP 2000.12.1).
D
. Adult
Gorgosaurus libratus
(TMP 86.64.1).
E
. Juvenile
Gorgosaurus libratus
(TMP 86.144.1). Scale bars 15 cm.
Strengths of tyrannosaurid and
Allosaurus
nasals
Materials and methods for examining theropod nasal strength
Nasal specimens
.—Fossil nasal specimens included juvenile and adult specimens of
Gorgosaurus libratus
, and a larger adult specimen of
Gorgosaurus
̓s sister taxon
Albertosaurus sarcophagus
(
Fig. 4
). These specimens are a tentative proxy for a nasal growth series of these tyrannosaurids, since the nasals share general morphological features (
Currie 2003a
) and the animals reach identical adult sizes (
Currie 2003b
).
We also scanned fossilized nasals of a large adult
Daspletosaurus torosus
and a high−resolution cast of nasals from its close relative
Tyrannosaurus rex
(
Fig. 4
). Scanning a cast to obtain cross−sections was appropriate for three reasons. Examination of the original specimen confirmed the fidelity of the cast, no other isolated
T. rex
nasal specimens were available, and cross−sectional geometry would be informative about strengths independently of internal architecture. A previous scan of a fossil
T. rex
skull (FMNH PR2081;
Brochu 2003
) demonstrated internal fusion of the nasals similar to that of other tyrannosaurids. We expect that the fossil template of our cast is internally similar to nearly all other tyrannosaurid nasals, and predict that CT sections of the fossil specimen (
BHI 2033
) would validate our strength calculations based on the cast.
We examined three individual left or right nasal specimens of the carnosaur
Allosaurus fragilis
(reconstructed and mirrored to represent paired nasals:
Fig. 5
) from the collections of UUVP. These nasals represent a growth series of
A. fragilis
ranging in size from juvenile to adult, and overlap the size range of the smaller tyrannosaurids.
Fig. 5. CT cross sections and reconstructions of
Allosaurus fragilis
nasals:
A
, largest (UUVP 1663/UMNH VP 9146);
B
, midsize (UUVP 1913/ UMNH VP 9144); and
C
, smallest (UUVP 10854/UMNHVP 7784). Anterior is to the right. Cross sections are from the strongly pneumatized regions of the nasals, at positions indicated by the dashed lines. The slices are normalized to the same size to show the relative degree of pneumatic excavation, evident despite mineral infilling in some sections. Reconstructions are in lateral views and in dorsal views with single left or right specimens mirrored to replicate complete pairs. Specimen B is broken over the posterior part of the external nares. Scale bar 10 cm.
Fig. 6. Geometry used to compute the area, centroid, and second moments of area of a nasal cross−section (from middle region of fused
Tyrannosaurus rex
nasals:
TMP 98.86.01; cast of BHI 2033
).
A
. Decomposition of the cross−section to compute area by summing areas of triangles. Small “+”s are centroids of individual triangles. Large “+” is the centroid for the complete section.
B
. Cross−section partitioned into horizontal and vertical strips of known area and position, used to calculate second moments of area.
Fig. 7. CT−scanned cross−sections of fused tyrannosaurid nasals, showing greater vaulting and higher cross−sectional areas of bone in larger individuals.
A
.
Gorgosaurus libratus
(juvenile: TMP 86.144.1).
B
.
Gorgosaurus libratus
(subadult: TMP 86.64.1).
C
.
Daspletosaurus torosus
(adult: TMP 98.48.1). Numbers 1–4: cross−sections at topologically similar positions, from posterior to anterior.
The specimens were CT scanned on a General Electric QX/1 scanner at Foothills Hospital, Calgary, Alberta. Scan settings of 120 KVp and 200 mA, at 5 mm thickness, produced good results. Thickness was reduced to 2.5 mm for the smaller
Gorgosaurus libratus
specimen.
Specimen comparisons and CT data processing
.—CT slices were viewed to evaluate internal anatomy of the nasals in Madena X (http://radonc.usc.edu/USCRadOnc/Madena/ Madena.html; Apple Macintosh OS X 10.3). Three−dimensional renderings (
Figs. 1–3
) and volume slicing for examining internal structure in context (
Fig. 7
) were performed in OsiriX (http://homepage.mac.com/rossetantoine/osirix/Index2.htm; Apple Macintosh OS X 10.3). To test if our CT manipulations correctly visualized the internal structure of the bone, we examined naturally broken tyrannosaurid nasal specimens of varying size (TMP 81.23.1, 86.36.36, 92.36.81, 94.12.414, 94.154.2, 96.12.404).
The raw CT data were imported into ImageJ (http://rsb. info.nih.gov/ij/) where contrast enhancement, thresholding, particle analysis and other image processing commands (to fill holes, for example) were executed to produce filled regions corresponding to the nasal cross−sections. Subsequently, custom software was used to determine the (x,y) coordinates of the bone perimeters. The resolution of the finished contours is estimated to be 0.5 mm.
Area calculations
.—With their positions along the top of the muzzle, the nasals are well positioned to receive the compressive forces associated with biting (
Rayfield 2004
), and their resistance to these forces will be proportional to their cross−sectional areas. The areas of the irregular nasal crosssections were determined by the triangular decomposition method (
Fig. 6
) outlined in
Henderson (2002)
.
Strength calculations
.—Both nasals and skulls were represented in three−dimensional, Cartesian coordinate space, with posterior edges set at X = 0. The midsagittal axis was defined as the X−axis, and the dorsoventral axis was set to the Y−axis. The Z−axis defined the mediolateral axis, with negative and positive Z−coordinates correspond to left and right sides, respectively.
Determination of the horizontal and vertical neutral axes of bending of the nasal slices came from determining the Z− and Y−axis centroids (horizontal and vertical, respectively) of the contour bounded regions, and this was facilitated by the triangular decompositions used to determine areas (
Fig. 6A
) The centroid of the entire contour−bounded region (
z
,
y
)
slice
is given by:
(1)
where N is the number of triangles in a contour decomposition, and (
zn
,
yn
) and
An
are the centroid and area, respectively, of the
nth
sub−triangle (Appendix 2).
The second moments of area of a nasal cross−section with respect to the two axes were determined with the following expressions:
I
–1
J
I
–1
I nasal = Ʃ Ʃ y 2 · area (h _ strip) z i
(
i
,
j
)
i
= 0
j
= 0
(2)
J
–1
I
I
–1
I nasal = Ʃ Ʃ z 2 · area (v_ strip) y j
(
j
,
i
)
j
= 0
i
= 0
(3)
I
and
J
are the numbers of horizontal and vertical slices,
Ij
and
Ji
are the numbers of separate strips on
I
th
horizontal and
J
th
vertical slices,
y
i
and
z
i
are the vertical and horizontal distances of strips from the centroid, and
h_strip
and
v_strip
are the areas of sets of individual strips taken in the vertical and horizontal directions, respectively (
Fig. 6B
).
Fig. 8. Average strengths of nasal cross−sections in tyrannosaurids and
Allosaurus fragilis
, plotted against nasal length.
A
. Cross−sectional areas, proportional to compression strengths.
B
. Second moment of area, proportional to vertical bending strength.
C
. Second moment of area, proportional to lateral bending strength. Values for the
A. fragilis
nasals are uncorrected for the hollowness of the sections, which would reduce their strengths. Lines fitted to the tyrannosaurid values are derived from log transformed data. See Appendix 1 for labels.
Influence of vaulting on tyrannosaurid nasals strengths
.—
We investigated the influence of vaulting on vertical strength by normalizing
I
z
for cross−sectional area of every tyrannosaurid CT slice, using the expression
h
slice
=
I
z
slice
/
A
slice
. The term
h
slice
is the height of a rectangular cross−section, of area equal to that of the real slice (
A
slice
), which would have a vertical second moment of area equal to that of the real slice (
I
z
slice
). Dividing
h
slice
by the length of the nasals converts
h
slice
to a relative height, a dimensionless “vaulting index”, that allows comparison of the degree of vaulting between cross−sections of all taxa.
We also investigated the influence of allometry in nasal width on lateral strength by normalizing
Iy
for slice crosssectional area. By the expression
s
slice
=,
s
slice
is the span (width) of a rectangle of area equal to
Aslice
, that would have the same lateral second moment of area as the real slice. Dividing
s
slice
for every slice by the lengths of their respective nasals yields a dimensionless “span index” for the contribution of slice widths to
I
y
slice
.
Fig. 9. Comparison of theropod nasal strengths at multiple transverse sections. Horizontal (
Iy
) and vertical (
Iz
) second moments of area of nasal cross−sections of
Allosaurus fragilis
(upper two graphs) and tyrannosaurids (lower two graphs). Second moments of area are proportional to lateral (
Iy
) and vertical (
Iz
) bending strengths. X−axes of graphs show relative position of slices along the long axes of the bones: 0.0 is posterior and 1.0 anterior.
Results of nasal morphology and strength analyses
Fig. 7
depicts several CT cross−sections through selected tyrannosaurid nasals. All are minimally fused to unfused anteriorly, strongly fused and vaulted in the middle sections, and flatter posteriorly. Cortical bone was extensive, and the struts comprising the spongy bone in the nasals̓ interiors were so densely packed that they were only clearly visible under high contrast in the CT images. Observations of naturally broken specimens corroborate that the high density apparent in CT slices was not an artifact of inaccurate visualization. CT slices of larger specimens appear proportionally more highly vaulted, wider relative to the element̓s length, and consequently more robust than in the juvenile
Gorgosaurus libratus
specimen (
Fig. 7A
). The
Daspletosaurus torosus
specimen (
Fig. 7C
) appears especially massive and tall in cross section.
Table 2. Computed strength properties of theropod nasals
.
| Length (cm) |
Iz (m4×10–8) |
Iy (m4×10–9) |
Avg. Cross−Sectional Area (m2×10–4) |
|
Gorgosaurus libratus
(juvenile) (Gl)
|
31.0 |
2.935 |
3.515 |
2.335 |
|
Gorgosaurus libratus
(subadult) (Gl)
|
46.5 |
21.94 |
45.55 |
7.709 |
|
Albertosaurus sarcophagus
(As)
|
68.7 |
93.30 |
302.6 |
19.44 |
|
Daspletosaurus torosus
(Dt)
|
68.0 |
187.5 |
519.0 |
27.69 |
|
Tyrannosaurus rex
(Tr)
|
81.0 |
496.3 |
769.7 |
33.30 |
|
Allosaurus fragilis
(small) (Af)
|
24.1 |
3.881 |
17.01 |
4.376 |
|
Allosaurus fragilis
(medium) (Af)
|
28.0 |
7.186 |
45.53 |
6.725 |
|
Allosaurus fragilis
(large) (Af)
|
40.5 |
24.62 |
115.3 |
13.04 |
Nasal cross−sectional areas, which correlate positively with compressional strength (Gordon 1979), are much higher in the adult tyrannosaurids than in other specimens (
Table 2
,
Fig. 8
). Areas for
Daspletosaurus torosus
are higher than in the
Albertosaurus sarcophagus
nasals of the same length.
Table 2
reports average second moments of area
Iz
and
Iy
, which respectively indicate vertical and lateral bending strengths, and average cross−sectional area, for all examined tyrannosaurid and
Allosaurus
nasals. The average
Iz
for resistance to vertical bending increases faster than nasal length. While lateral strength indicators
Iy
are not as high as those for vertical bending, the discrepancies between small and large specimens are even more dramatic (
Table 2
).
The
Daspletosaurus
and
Tyrannosaurus
nasals had higher average indicators for vertical bending strength than in the adult
Gorgosaurus
and
Albertosaurus
.
Iy
of the
Daspletosaurus
nasals is almost twice that of the equivalently long adult
Albertosaurus
specimen (
Fig. 8
). The
Allosaurus
nasals had relatively high strength indicators
Iy
and
Iz
for bending when compared with tyrannosaurid nasals of a given length (
Fig. 8
), although their increases in nasal bending strength with increases in nasal length are less dramatic than in the tyrannosaurids.
Fig. 9
graphs the distribution of second moments of area for individual nasal cross−sections. For resistance to vertical bending
Allosaurus
and tyrannosaurid nasals have higher
Iz
anteriorly than posteriorly. At posterior sections in
Gorgosaurus
and
Albertosaurus
,
Iz
falls off more rapidly than in
Tyrannosaurus
and
Daspletosaurus
. Resistance to lateral bending
Iy
generally increases posteriorly in
Allosaurus
. The lateral strength indicators peak anteriorly in tyrannosaurids, and in general decrease posteriorly.
In all specimens the anterior− and posteriormost second moments of area are low. Other bones articulate with the nasals in these areas, however, and presumably compensate for low strengths here of the nasals themselves (
Figs. 5
,
7
,
8
).
Our “vaulting index” measures the effects of shape on nasal strength (
Fig. 10A
), and shows that the vertical second moment of area would be greater in the adult tyrannosaurids, even if corresponding slices in all tyrannosaurid specimens were scaled to the same cross sectional areas. Above the largest maxillary teeth, the adult
Albertosaurus
,
Daspletosaurus
, and
Tyrannosaurus
nasals are more highly vaulted than in the juvenile
Gorgosaurus
. The subadult
Gorgosaurus
specimen approaches the degree of vaulting seen in the adult
Albertosaurus
, possibly indicating that the nasals of these taxa increased little in vaulting after a certain stage of growth. Posteriorly the
Daspletosaurus
and
Tyrannosaurus
nasals are more vaulted than in the other taxa, and which may have contributed to greater relative bending strength of these elements.
The “span index” (
Fig. 10B
) indicates that allometric expansion in width had little effect on lateral second moment of area
Iy
for most of the tyrannosaurids, because their area−normalized scores for
Iy
overlap. However,
Iy
values of the anterior
Tyrannosaurus rex
cross−sections were much higher than in the other taxa, indicating that allometric lateral expansion increased the relative lateral bending strength of its nasals.
Cranium strengths of
tyrannosaurids and carnosaurs
Materials and methods for calculating theropod cranium strength
External geometry of theropod crania
.—We produced 3D numerical representations of theropod crania (
Fig. 11
) in or− der to examine the correspondence between cranium shape and strength. We chose tyrannosaurid and carnosaur specimens of similar skull lengths, approximately matching the tyrannosaurids
Gorgosaurus libratus
,
Daspletosaurus torosus
, and a medium sized
Tyrannosaurus rex
with the carnosaurs
Allosaurus fragilis
,
Sinraptor dongi
, and
Acrocanthosaurus atokensis
, respectively.
Fig. 10. Heights and widths of tyrannosaurid nasal slices normalized for slice area and bone length.
A
. Normalized heights (“vaulting index”) showing convergence of vaulting pattern at large size.
B
. Normalized widths (“span index”) showing isometric form in most specimens, but exaggerated relative width in
Tyrannosaurus rex
nasals. Points of maximum vaulting and span are indicated on nasals of
T. rex
(TMP 98.86.01; cast of BHI 2033). Symbols as per Fig. 9.
To encompass the upper end of the theropod size range, we reconstructed the cranium of a large
Tyrannosaurus rex
(1.4 m; FMNH PR2081) and the similarly huge
Carcharodontosaurus saharicus
(1.6 m; SGM−Din 1). The larger
Tyrannosaurus rex
cranium (FMNH PR2081) was crushed during fossilization, but we were able to reconstruct it based on measurements in its description (
Brochu 2003
) and comparisons with other
T. rex
crania. The
C. saharicus
cranium (SGM−Din 1) lacks the premaxilla but the specimen̓s width and height are known. Because bending and torsional strength scale linearly with length but with the square of width and height, a different length than restored for the
Carcharodontosaurus
cranium by
Sereno et al. (1996)
would have a relatively minor effect on the specimen̓s strength indices.
Data collection for cranium geometry
.—Isometric dorsal and lateral images of the crania from published illustrations were scanned on a flatbed scanner, and the dorsal and lateral profiles of the crania were traced in Canvas 7 (Deneba Software Inc.;
Fig. 11
). The bending and torsional strengths of a cranium depend on its transverse cross−sectional shapes, and on how these shapes vary along the cranium̓s length. All the crania were therefore represented in mathematical form as sets of horizontally stacked, transverse, two−dimensional plinges (flat−topped corbelled vaults: Gordon 1984;
Figs. 8
,
9
). Unlike the strong nasals, the crania of most dinosaurs are found in slightly to very distorted states (e.g., the American and Field Museum
Tyrannosaurus rex
specimens, respectively). This leads to uncertainty regarding the exact form of the original uncrushed cranium. With the nasals, their original geometry is well preserved and it was felt worthwhile to use precise CT methods to capture their shape. In contrast, the uncertainties of cranial preservation made a first order approximation adequate for our purposes.
Area calculations
.—Calculating areas of cranium plinge sections is fundamental, as all other mechanical properties of the cranium depend on the areas in some way. All theropod crania have a typical form that results in all transverse slices being laterally symmetrical quadrilaterals (“trapezoids”) with a ventral (lower) edge that is wider than the accompanying dorsal (upper) edge (
Fig. 9
). The areas of these trapezoidal cross−sections, and excised areas representing the interior of each plinge (see below), were computed using the method outlined in
Henderson (2002)
.
Strength calculations
.—Dorsoventral and mediolateral modes of bending are relevant to the study of the cranium mechanics of predatory dinosaurs. In each mode the side of the cranium where a force is being applied will experience tension, while the opposite side will be in compression. Somewhere between the compressed and tensed sides is an infinitesimally thin zone, the neutral axis, that does not experience any stress. For dorsoventral bending this neutral axis is equivalent to the horizontal, y−axis centroid,
y
. As the crania and their transverse slices are left−right symmetrical, the central Y−axis (Z = 0) is the neutral axis for mediolateral bending.
A cranium̓s bending strength at a particular point depends on two parameters—the second moment of area of the corresponding cross−section, and its distance from the point of force application. The first parameter is a measure of how the material comprising the slice is distributed about the neutral axis of the slice (
Gordon 1978
). For dorsoventral bending this quantity,
I
z
skull
, is computed relative to the horizontal Z−axis, and is expressed as:
yc
I z skull
= I
y
2
dA
(4)
yt
where
yc
and
yt
are the distances from
y
to the top and bottom edges of the cross−section that experience compression and tension, respectively, and
dA
is a horizontal strip of area that will vary with height (
Fig. 12A
). For a theropod biting prey, and with the impact force directed upwards, the dorsal side of the cranium will be under compression and the ventral side under tension.
Fig. 11. Top and side views of theropod crania used to reconstruct crosssectional shapes, and oblique views of reconstructed plinge cross−sections for each cranium. Second moments of area of the plinges were calculated as indices of bending and torsional cranium strengths.
A–D
, carnosaurs;
E–G
, tyrannosaurids.
For mediolateral bending the expression for second moment of area with respect to the vertical axis,
I
y
skull
, is given by:
zD
I y skull
= 2 · I
z
2 · (
y D – y V
)
dz
+
z
= 0
z V
+ 2 I
z
2[
m lateral
(
z – z D
) +
y D – y V
]
dz z
=
z
D
(5)
where the first term is for a rectangular region immediately adjacent to the central, vertical neutral axis, which is bounded vertically by
yD
, and
yV
, and laterally by z
D
(
Fig. 12B
). The second term is for a laterally positioned triangular region which is bounded along its top edge by the lateral side of the plinge, and extends along its lower edge to
zV
. To account for the left−right symmetry of the trapezoidal shape each term is multiplied by two.
The above expressions for second moments of area are for solids, but crania are not solid blocks of bone. To represent for the hollowness of the cranial vault, a second inner shell was defined. The mean thickness of bones comprising a cranium was estimated to be 5% of the cranium length. This thickness was subtracted from the dimensions defining the outer cranium contours, with the original and reduced trapezoids sharing the same bottom edge. Second moments of area were computed for the reduced internal cranium shapes, and the resulting values were subtracted from second moments of area of the original, external geometries following the methods of
Farlow et al. (1995)
. We used the mean of the second moments of area all the slices as a strength indicator for the cranium as a whole. This was appropriate for our present interest in correlations between nasal bone strengths and general cranium strengths.
Fig. 12. Schematic trapezoidal cross−sections of theropod crania, with geometry and expressions for computing second moments of area.
A
. Determining moments with respect to the horizontal (Z) axis. The width of a strip of area is a function of its vertical (Y) coordinate.
B
. Determining moments with respect to the vertical (Y) axis; the cross−section is partitioned into two central rectangular areas, and two lateral triangular regions.
In addition to the two modes of bending deformation, there is also the potential for the torsional deformation as the cranium twists about its long axis during feeding activities. The torsional strength of the cranium is proportional to the polar second moment of area (
J
). For each cranium slice,
J
was computed as the sum of the two orthogonal second moments of area,
Iz
and
Iy
(
Biewener 1992
). The mean value
J
for all the slices was then assigned to the cranium.
Cranial strength results
The results in
Fig. 13
and
Table 3
show that tyrannosaurid crania had generally higher second moments of area and higher torsional strength indicators than carnosaur crania of equivalent length. Tyrannosaurid cranium geometry there− fore conferred generally higher strength in torsion and in lateral and dorsoventral bending. The results for
Tyrannosaurus rex
amplify the trend towards higher strengths in tyrannosaurids than in carnosaurs. The smaller
T. rex
cranium (TrA) shows approximately twice the dorsoventral bending and torsional strengths, and three times the mediolateral bending strength, of the equally long cranium of
Acrocanthosaurus atokensis
(Aa)
. This
T. rex
cranium had higher torsional and lateral bending strength indicators than the much longer cranium of
Carcharodontosaurus saharicus
(Cs)
. The larger
T. rex
cranium TrF is 12.5% longer than the smaller TrA, but its substantially higher strength reflects the non−linear increase in second moment of area with increasing linear size (equations 4 and 5).
Fig. 13. Strength indicators computed for theropod crania under mediolateral (
A
), dorsoventral (
B
), and torsional (
C
) loadings. Tyrannosaurid crania are invariably stronger than those of carnosaurs for a given skull length. See Appendix 1 for labels.
Discussion
Table 3. Computed strength properties of theropod crania.
| Length (cm) |
Iz Iy (m4×10–5) (m4×10–6) |
|
Allosaurus fragilis
(Af)
|
79.1 |
1.411 |
2.975 |
|
Sinraptor dongi
(Sd)
|
84.2 |
5.083 |
12.93 |
|
Acrocanthrosaurus atokensis
(Aa)
|
124 |
16.68 |
36.26 |
|
Carcharodontosaurus saharicus
(Cs)
|
160 |
37.61 |
65.11 |
|
Gorgosaurus libratus
(Al)
|
75.0 |
2.304 |
8.296 |
|
Daspletosaurus torosus
(Dt)
|
104 |
9.911 |
28.85 |
|
Tyrannosaurus rex
(TrA)
|
125 |
34.02 |
122.5 |
|
Tyrannosaurus rex
(TrF)
|
140 |
53.53 |
192.8 |
Are hypotheses of tyrannosaurid tooth, nasal and cranial strength validated?
Tyrannosaurid maxillary teeth were stronger in bending
than those of other large carnivorous dinosaurs
.—This hypothesis is partly falsified in that the average maxillary tooth strengths of most tyrannosaurids are not substantially higher than those of carnosaurs at equivalent skull lengths. The teeth of the carnosaur
Sinraptor dongi
are notably robust; while not as thick at the base as most tyrannosaurid teeth they have lower crown heights and low bending moments arms. However, tyrannosaurid teeth vary more in size along the maxillary row than in other theropods, and the strengths of the largest maxillary tooth tend to be higher in tyrannosaurids relative to skull length. The average and maximum tooth strengths of
Tyrannosaurus rex
are much higher than those of non−tyrannosaurids when normalized for skull size. High mediolateral bending strength of
T. rex
teeth corresponds with Meers̓ (2003) observation that
T. rex
rostra were broader than the mediolateral span of the dentaries. If the animals bit into bone often and food was caught between the tooth rows, this jaw arrangement would impose lateral bending forces on the maxillary teeth and medial forces on the dentary teeth. A high mediolateral section modulus would reduce stress that these forces imposed on the teeth.
The trends of increase in tooth strength with skull length are markedly different between tyrannosaurids and other large theropods. The high strengths of
Tyrannosaurus rex
teeth contribute to the non−linear trend in the tyrannosaurids. The particularly strong maxillary teeth of
T. rex
are consistent with high bite forces (
Erickson et al. 1996
) and mandible strength (
Therrien et al. 2005
) found for this taxon, and indicate that its feeding apparatus was stronger than expected for a tyrannosaurid its size.
Vaulting contributed significantly to tyrannosaurid nasal
strength
.—The nasal “vaulting index” (
Fig. 10A
) indicates that the vertical second moments of area in large tyrannosaurids is higher than expected if they retained the same cross−sectional shapes of the smaller specimens. Thus vaulting of the nasals, more than increased cross−sectional area, increased their second moments of area and strengths of large tyrannosaurid nasals in bending and torsion. We predict that analysis including more juvenile specimens will uphold these findings. Our “span index” (
Fig. 10B
) shows that anterior broadening of the nasals in the
Tyrannosaurus rex
specimen increased its lateral bending strength in this region.
Fused tyrannosaurid nasals were stronger than unfused
carnosaur nasals
.—Our results for the geometric contributions to nasal strength artificially exaggerate the strengths of the
Allosaurus fragilis
nasals, and diminish those of
Gorgosaurus libratus
and
Albertosaurus sarcophagus
. The computed average strengths of
Allosaurus fragilis
nasals are
higher than those of the albertosaurine tyrannosaurids when plotted against nasal length (
Fig. 8
). However, averages for the albertosaurine tyrannosaurid nasals are reduced by strength properties of their flat caudal projection, where articulating bones would augment the nasal strengths. The anterior, vaulted portions of the albertosaurine nasals, where they would receive the brunt of forces from the maxillae, have higher strengths than the
A. fragilis
nasals (
Fig. 9
). Also, pneumaticity of the
A. fragilis
nasals (
Fig. 5
) would reduce their strengths somewhat. The average compressional strengths would decrease by approximately 30%, and second moments of area by approximately 6%
The extensive fusion seen in tyrannosaurid CT sections would increase their torsional and compressive strengths, with benefits for feeding function. Tooth marks show that large theropods applied powerful bites that cut bone (
Chure et al. 2000
). With unilateral biting, unfused nasals would experience vertical shear between left and right halves, causing dorsal displacement of one side of the snout relative to the other and straining ligaments that connected the nasals. In tyrannosaurids, fusion added bone to the midline of the nasals where the structures are notably tall in cross−section (
Fig. 6
). Because shear strength is proportional to the dimension of a structure parallel to shear forces, increased height of bone along the midline would resist dorsoventral shear.
The combination of fusion and high second moments of area gave the dorsal portion of tyrannosaurid nasals the properties of a torsion tube resistant to twisting forces (similar to the entire muzzles of crocodilians:
Busbey 1995
). With bone rather than ligaments resisting the tensile components of shear and torsion, and bone resisting compressive torsional components, the food would have experienced a greater proportion of the full bite force in tyrannosaurids than in carnosaurs.
High proportions of bone in cross−sections of tyrannosaurid nasals indicate higher compressional strength than the collective strength of
Allosaurus
nasals. CT sections (
Fig. 5
; Emily Rayfield, personal communication 2004) and openings into the bones (
Witmer 1997
) show that
Allosaurus
nasals were hollowed out through much of their length (
Fig. 5
) by pneumatizing tissues, reducing their cross−sectional area and compressive strength. In contrast, CT sections and broken fossilized specimens show that tyrannosaurid nasals had extensive cortical bone, high densities of trabecular bone, and small vascular canals (
Currie 2003a
) but no pneumatic cavities.
Tyrannosaurid crania were stronger overall than carnosaur
crania
.—The results confirm that tyrannosaurid crania were stronger than those of other theropods of similar skull length (
Table 3
). The
Gorgosaurus libratus
cranium was minimally 1.5 times stronger (in vertical bending) than a slightly longer cranium of
Allosaurus fragilis
. The
Tyrannosaurus rex
crania were much stronger than equivalently sized or larger carnosaur crania, except for a modestly higher vertical bending indicator for
Carcharodontosaurus saharicus
versus the smaller
T. rex
specimen.
Pattern of correlated progression of tyrannosaurid feeding mechanics
Thomson̓s (1966)
concept of correlated progression involves the evolutionary integration of adaptive features (
Fig. 14A
). Structural modifications of the tyrannosauroid feeding apparatus suggest integration of faculties towards reduction of large prey. We adopt the phrase “correlated progression” with the caveat that it does not imply universal adaptive improvement. Escalating performance in one area may lead to loss of capability in others, such as a reduced ability of the adults of larger predators to capture smaller prey.
Correlated progression is testable by examining correspondences between rates of performance increase for various structures. The nasals, teeth, dentaries, and crania of tyrannosaurids show consistent patterns of positive allometric increase in strength when plotted against cranium or dentary length (
Figs. 2
,
3
,
8
,
13
). In contrast, elements of other large theropods show linear increases in strength with increasing skull size (
Figs. 2
,
3
,
8
,
13
).
The tyrannosaurid trends reveal a more complex, mosaic pattern of correlated progression than lock−step increases in strength for all structures. With most comparable structures, adult tyrannosaurine taxa (
Daspletosaurus torosus
and
Tyrannosaurus rex
) have higher size−normalized strengths than the albertosaurine forms, and
T. rex
in turn has higher strengths than
D. torosus
. Because these taxa represent successively more derived forms (
Holtz 2004
), similar patterns of strength increase for all examined structures support the hypothesis of correlated progression of the tyrannosaurid feeding apparatus (
Fig. 14B
). However, the adult
D. torosus
maxillary teeth are no stronger than those of the
Albertosaurus
specimen, while
T. rex
maxillary teeth are much stronger than either. Rather than showing an insensibly continuous trend, the allometric increase for maxillary teeth probably reflects a quantum jump in strength from the condition in
Albertosaurus
and
Daspletosaurus
to that of
T. rex
. The more gradual increase in nasal and cranial strengths indicates that robustness of these structures preceded acquisition of particularly strong teeth in adult
T. rex
(
Fig. 14B
). If the giant
Tarbosaurus bataar
experienced a “growth spurt” similar to that of
T. rex
(
Erickson et al. 2004
), its narrower skull (
Hurum and Sabath 2003
) indicates that it may have continued the ontogenetic trajectory of strength increase seen in smaller tyrannosaurids.
T. rex
, in contrast, probably experienced greater hypermorphosis of tooth and cranial strengths during this growth period.
Tooth, nasal, and cranial strengths likely increased in parallel with jaw adductor forces. Bite forces were probably enhanced in tyrannosaurids through enlarged muscle origins from midsagittal and nuchal crests (m. adductor mandibulae externus medialis) and perhaps the expanded quadratojugalsquamosal contact (
Molnar 1973
), and increased size of the adductor chamber. These trends in feeding strengths are elucidated by consideration of how tyrannosaurid nasals contributed to cranium strength, and possible behavioural consequences of skull strengths in theropods.
Mechanical integration of theropod nasal and cranium strengths
Our results for nasal compressional strength support
Rayfield̓s (2004)
hypothesis that the nasals strengthened the cranium in vertical bending.
Rayfield (2004)
ran a finite element analysis of the skull of
Tyrannosaurus rex
(BHI 2033, the specimen that was cast for our
T. rex
nasals: TMP 98.86.01) as a plate−like lateral projection. With the joints between ventral cranium bones treated realistically as unfused, the model showed high compressional stress over the anterior maxillary teeth (as predicted by
Molnar 1973
,
2000
). This is precisely where
Tyrannosaurus rex
nasals, and those of other tyrannosaurids, show the highest cross−sectional areas. With a large cross−sectional area the nasals could withstand high compressional forces, such as those incurred during dorsal bending of the rostrum, without experiencing unusually high stress.
Adult specimens
Tyrannosaurus rex
, and similarly gigantic adults of the tyrannosaurid
Tarbosaurus bataar
, have staircase−style interdigitating sutures, with triangular pegs and sockets, between the nasals and maxillae (
Hurum and Sabath 2003
;
Rayfield 2004
;
Fig. 15
). This staircasing does not occur in a juvenile specimen of
Tarbosaurus bataar
(TMP 2000.50.5; cast), or in adults of other examined tyrannosaurids (including the large, robust
Daspletosaurus torosus
specimen). This additional reinforcement of the nasal−maxillary suture may be exclusive to adult
Tarbosaurus
and
Tyrannosaurus
, and related to increased feeding forces involved with engaging larger prey (see below).
Rayfield (2004)
noted that nasal−maxilla interlocking would brace the joint against high concentrations of shear stress in the region between the nasals and maxillae of
Tyrannosaurus rex
, and efficiently channel compressive biting stress from the maxillae to the nasals. The staircasing would also brace the joints against shear induced by lateral bending and torsion of the snout, and complement high nasal and rostrum strengths found for
T. rex
.
High second moments of area of the tyrannosaurid nasals relative to those of
Allosaurus fragilis
demonstrate higher strength of the dorsal part of the snout, and emphasize how the tyrannosaurids̓ nasals contributed to overall cranium strength. The breadth of the nasals (
Figs. 4
and
10
) gave them a high lateral second moment of area, and increased the width of the snout by laterally displacing the maxillae. The great width of the rostrum greatly increased its lateral second moment of area, and overall strength in torsion and lateral bending.
Fig. 14.
A
. Functional integration of strengths of the tyrannosaurid head skeleton when subjected to feeding forces. Dark arrows represent direct influences of forces on structures, and direct integration of structural strengths. Light arrows represent less direct influences of structures on one another.
B
. Correlated progression of tyrannosauroid feeding adaptations mapped onto a tyrannosauroid cladogram after
Xu et al. (2004)
and
Holtz (2004)
. Arrow at left represents phyletic increases that likely occurred at all ingroup nodes except
G. libratus
+
A. sarcophagus
.
In contrast, the nasals of
Allosaurus
and other carnosaurs are narrow between the articulations with the maxillae (
Madsen 1976
), the maxillae arch outward less, and the muzzle is consequently narrow (
Meers 2003
). The narrower rostra of carnosaurs conferred lower lateral bending and torsional strength relative to cranium length than in tyrannosaurids (
Fig. 11
,
Table 2
).
theropods. Combined with strong articulations between bones of the palate, strong nasals and wide muzzles suggest that adult tyrannosaurids engaged in different feeding behaviours than carnosaurs (
Holtz 2002
).
Behavioural implications of theropod skull strength
Fig. 15. Nasal articulations with maxillae in juvenile
Gorgosaurus libratus
(nasals at top; TMP 86.144.1) adult
Tyrannosaurus rex
(nasals in middle and maxilla below; TMP 98.86.01; cast of BHI 2033). The interlocking, staircase−style articulation in the adult
Tyrannosaurus rex
efficiently transmitted compressional forces and increased the shear strength of the articulation. Dashed lines show the extent of the staircased articulation, and the solid line indicates a projection on the nasals and the corresponding depression in the maxilla.
High torsional strengths of tyrannosaurid crania and nasals support Holtz̓s (2002) hypothesis that tyrannosaurids could subject their crania to greater torsional loads than could other The longer nasal specimens of the tyrannosaurids are stronger than expected than if they were geometrically similar to the nasals of smaller individuals (
Fig. 10
). The skulls of juvenile tyrannosaurids were proportionally lower than adult skulls (
Carr 1999
;
Currie 2003b
), and concomitantly much weaker in vertical bending. Much stronger nasals and allometrically taller skulls in adult tyrannosaurids than in juveniles (
Currie 2003b
) support hypotheses of dramatic shifts in dietary niche between juveniles and adults (
Molnar and Farlow 1990
;
Holtz 2002
).
This ecological partitioning would be similar to that seen in varanid lizards and crocodilians (
Bradshaw and Chabreck 1987
;
Hutton 1987
;
Losos and Greene 1988
), in which the young subsist upon small prey (including insects) and adults tackle much larger animals. Proportionally stronger nasals and crania of adult tyrannosaurids versus juveniles indicate that the adults could probably engage larger prey relative to their own body size.
In the adult cranial specimens examined for this study, the discrepancy in vertical bending strength between tyrannosaurid and carnosaur crania is less than that for lateral strength. With relatively tall, narrow crania, carnosaurs were well equipped to rake down and backwards into the flesh of prey with their upper teeth (
Bakker 2000
;
Rayfield et al. 2001
;
Antón et al. 2003
). Finite element analysis (
Rayfield et al. 2001
) and consideration of the moment arms of neck muscles (
Bakker 2000
) demonstrate the probable success of these activities in
Allosaurus fragilis
. High vertical bending strengths of the crania of
Acrocanthosaurus atokensis
,
Carcharodontosaurus saharicus
, and
Sinraptor dongi
suggest the suitability of this strategy for other carnosaurs.
Tyrannosaurid crania were nevertheless relatively stronger dorsoventrally than carnosaur crania, and much stronger in lateral bending and torsion (
Holtz 2002
). As discussed above, the cranium and nasals would experience high torsional forces from uneven bites, with higher food reaction forces on one side of the skull than the other. Ornithischian fossils damaged during apparently unilateral bites by tyrannosaurids (
Erickson and Olson 1996
;
Wegweiser et al. 2004
) indicate that these theropods imposed this loading regime on their crania (
Holtz 2002
). Adaptations for this biting behaviour would include the great width and height of tyrannosaurid nasals and rostra, a stronger palate than in other theropods (
Holtz 2002
), and the interdigitating, posteriorly declined mandibular symphysis (
Therrien et al. 2005
), which increased the torsional strength of the cranium and articulated lower jaws. Additional strength imparted by the staircase−like nasal−maxillary joint of adult
Tarbosaurus bataar
and
Tyrannosaurus rex
would benefit these 5–10 tonne giants (
Paul 1988
,
Henderson and Snively 2003
) when reducing larger prey animals beyond the capacity of other tyrannosaurids.
Potential tyrannosaurid prey (including ceratopsians and hadrosaurs:
Russell 1970
) were generally smaller than the giant, long−necked sauropods that
Allosaurus
and other carnosaurs more often encountered. It is therefore possible that tyrannosaurids bit into bone more often than would carnosaurs biting into the flesh of larger prey, although fragments in a coprolite (
Stone et al. 2000
) suggest that large carnosaurs splintered bones before ingestion.
High bending and torsional (
Holtz 2002
) strength of tyrannosaurid crania and nasals are consistent with biting into bone, but also with adeptness at tearing bone and flesh from large prey (
Farlow and Brinkman 1994
). High strength in lateral bending suggests the cranium was well equipped to withstand lateral movements of the head and neck while the teeth were embedded in the prey. The great posterior width of tyrannosaurid crania (especially in
Tyrannosaurus rex
) indicates high leverage for muscles that would turn the head (m. longissimus capitis superficialis) or turn and raise it at the same time (m. complexus) during unilateral contraction.
These results complement findings, from tooth marks and finite element analysis, that
Tyrannosaurus rex
was proficient at “puncture and pull” feeding by retraction of the head (
Erickson et al. 1996
;
Rayfield 2004
). The high lateral bending strength of tyrannosaurid crania indicates that the animals could have augmented linear retraction with vigorous sideways movements.
High strength of nasals and crania would augment a variety of feeding functions in tyrannosaurids, including the infliction of tissue damage without the need to secure food with their reduced forelimbs (
Holtz 2004
). Modern carnivorous animals employ forceful bites and lateral tearing of flesh whether killing or eating prey (
Auffenberg 1981
;
Erickson and Olson 1996
), and inference of these actions in tyrannosaurids is uninformative for debates over scavenging or predation frequency (
Holtz 2002
). However, high strength of tyrannosaurid crania indicates that they could afford indelicacy during attempted killing bites (
Carpenter 2000
;
Wegweiser et al. 2004
).