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Raptor talon shape and biomechanical performance are controlled by relative prey size but not by allometry


Most birds of prey (raptors), rely heavily on their talons for capturing prey. However, the relationship between talon shape and the ability to take prey is poorly understood. In this study we investigate whether raptor talons have evolved primarily in response to adaptive pressures exerted by different dietary demands, or if talon morphology is largely constrained by allometric or phylogenetic factors. We focus on the hallux talon and include 21 species in total varying greatly in body mass and feeding ecology, ranging from active predation on relatively large prey to obligate scavenging. To quantify the variation in talon shape and biomechanical performance within a phylogenetic framework, we combined three dimensional (3D) geometric morphometrics, finite element modelling and phylogenetic comparative methods. Our results indicate that relative prey size plays a key role in shaping the raptorial talon. Species that hunt larger prey are characterised by both distinct talon shape and mechanical performance when compared to species that predate smaller prey, even when accounting for phylogeny. In contrast to previous results of skull-based analysis, allometry had no significant effect. In conclusion, we found that raptor talon evolution has been strongly influenced by relative prey size, but not allometry and, that talon shape and mechanical performance are good indicators of feeding ecology.


Identifying the factors that drive morphological evolution is a central topic in evolutionary biology1,2. Birds use their talons (claws) to perform a wide variety of tasks and their talon morphology has often been associated with a particular behaviour and/or ecology3,4,5. For example, birds claws can show clear adaptations to perching (Passeriformes), climbing (Piciformes), manipulating objects (Psittaciformes), foraging on the ground (Galliformes) and killing/restraining prey (birds of prey, i.e., raptors)3,4. The talons of raptors are of particular interest because of their importance in predatory success4. Typically raptors possess tapered and markedly curved talons compared to those of other birds3,5. However, talon morphology has received little attention, with most studies focused mainly on analysing curvature and using this proxy to quantify behaviour and ecology3,4,5,6,7,8. Some authors have adopted different methods and metrics in order to determine possible associations between claw function and claw geometry4,5,9,10. For example, Csermely and Rossi3 considered different linear measurements to separate raptorial from non-raptorial species, whereas Fowler and colleagues4 considered interdigit size variation to make similar distinctions. A few in vivo studies have considered some proxy of mechanical performance to test whether a relationship exists between predatory behaviour and grip forces9,10.

However, the analysis of single phenotypic features (e.g., talon curvature, grip strength) might not be able to reveal one-to-one relationships between form and function2, because different forms may produce similar performance outputs, as suggested by the “many-to-one” model11. In other words, divergent forms may produce similar functional capabilities, thus precluding a single, straightforward relationship between form and function, even if phenotypes have evolved adaptively in response to similar selective pressures2,12. Furthermore, other factors that could potentially impact talon morphology, such as evolutionary allometry and phylogenetic history, have remained largely untested. Recently, Bright and colleagues13 showed that the raptor beak and skull are highly integrated and controlled by allometric factors more than by dietary ones. This suggests that strong developmental constraints may channel raptor beak and skull shape along specific evolutionary trajectories, challenging the common view of the birds’ beak as a highly adaptable structure13. Further, the pervasive presence of evolutionary allometry in the avian lineage was confirmed by Felice and Goswami14, who also included non-raptorial taxa in their work.

In the present study, we combined 3D geometric morphometrics (GMM), Finite Elements Analysis (FEA) and Phylogenetic Comparative Methods (PCM) to provide a deeper understanding of raptor talon evolution. These methods can be integrated within the framework of evolutionary biology and their combined application has yielded significant advancements in the understanding of evolutionary dynamics among different clades15,16,17. Here we sampled representatives of each raptorial clade (Accipitridae, Falconidae, Strigiformes and Pandionidae), as well as non-raptorial species (Passeriform, Psittaciform) to determine whether, in a phylogenetic context, the evolution of raptor talon shape and biomechanical performance has been driven by feeding ecology, or whether, as with the avian skull, it has been heavily constrained by allometric factors.


Dietary categories

The species included in this study have been classified into the following three broad categories according to the ratio between their average body mass (to account for sexual dimorphism) and maximum prey body mass: relatively small to medium sized prey (SM), assigned to species that are able to capture prey that weighs up to half of their body mass; medium to large sized prey (ML), assigned to species that are able to capture prey weighing from half to more than half of their body mass; non-predatory (NP), assigned to species that don’t use their feet for prey capture. The dietary categories have been defined based on existing literature, summarised in Table 1. Maximum prey body mass values are taken for largest prey items that are regularly taken (total number of captures), as opposed to larger prey that might be taken irregularly or recorded in very low numbers (<5 records).

Table 1 Sampling effort and dietary category species assignment.

GMM talon shape analysis

Principal Component Analysis (PCA) plots show a clear separation between the three considered dietary categories (see Table 1), i.e., non-predators (NP), and predators on relatively small prey or large prey (SM and ML, respectively) (Fig. 1 and Supplementary Fig. S1). In particular, along the PC1 axis (51.1% of the total variance) the non-predators (NP, vultures, Corvus and Eolophus) cluster at negative values and are characterized by a less curved, and, overall, shorter talon with a less robust ungual articulation (see Fig. 1). At positive values of PC1 the talon morphology is characterized by a more curved and pointed ungual shaft and by a more robust ungual articulation, representative of species preying on small to medium sized prey (SM). PC2 (24.06% of the total variance) (Fig. 1) separates, from positive to negative values, taxa belonging to medium to large (ML) and small to medium (SM) dietary categories. At positive values of PC2 the talon is characterized by a highly curved morphology and concave articular facet, whereas at negative values the talon is shorter, less curved and characterized by a flatter articular facet. In particular, the ML taxa (positive values), including osprey, the two large eagles (Aquila, Haliaeetus), and the Grey and Brown Goshawks, occupy a restricted area of the PC1-PC2 morphospace and are characterized by a longer and more curved talon, whereas the whistling kite (Haliastur sphenurus) and the swamp harrier (Circus approximans) overlap with the SM taxa and are characterized by a less curved talon, a flatter articular facet and a smaller flexor tubercle. It must be noted that within the SM group there are clear separations between family groups, with Falconidae sharing positive values for both PC1 and PC2, in contrast to the crepuscular Accipitrids (Elanus) and the nocturnal owls (Tyto and Ninox), sharing negative values along PC2.

Figure 1
figure 1

PC1/PC2 scatterplot of the PCA on talon shape variables. Warped meshes refer to positive and negative extremes of the axes. Warped meshes colors refer to the intensity of the shape changes: cooler colours (blue) indicate less change, warmer colours (orange-red) indicate major changes.

The Procrustes ANOVA performed on the shape variables confirmed the groups clustering observed in the PCA and returned highly significant results (F2,21 = 8.725; r2 = 0.478; p-value = 0.001). Moreover, pairwise comparisons evidenced that all the dietary categories were significantly different in shape from each other (Table 2).

Table 2 Pairwise comparison of shape differences between dietary groups.

Finite element analysis

When we applied FEA simulation to the talon models (see Materials and Methods for detail on protocols and boundary conditions), we found different stress magnitudes and distributions between the three dietary categories (NP, SM and ML; Fig. 2 shows three representative models and Supplementary Fig. S2 summarizes the FEA results). Non-predatory species (NP), e.g., Aegypius monachus display, on average, higher von Mises (VM) stress values that are concentrated on the flexor tubercle, the ventral region of the inner curvature, along the outer curvature, and on the medial edge of the talon. In contrast, species that feed on larger prey items (ML, e.g. Haliaeetus leucogaster, Aquila audax) showed, on average, the lowest VM stress values in correspondence with those regions previously described (Fig. 2 and Supplementary Fig. S2). In particular, results showed reduced VM stress values on the outer and inner curvature, the medial edge and the flexor tubercle, whereas the ventral region of the inner curvature showed high stress values. Species belonging to the SM category (e.g., Falco peregrinus) displayed, on average, intermediate VM stress values. The ventral region of the inner curvature, the flexor tubercle and the outer curvature were markedly more stressed when compared to the taxa belonging to the ML category (Fig. 2 and Supplementary Fig. 2). The ANOVA test performed on the mean VM stress values confirmed the inter-group differences (Fig. 2) returning highly significant results (F2,21 = 7.322; r2 = 0.568; p-value = 0.001). Pairwise comparisons confirmed that each of the dietary categories were significantly different in mean VM stress values from each other (Table 3).

Figure 2
figure 2

Boxplot of mean VM stress values detected at the 26 homologous landmarks and representative FEMs for the three dietary categories. Bottom and top of the boxes are the first and third quartiles, the horizontal black lines represent the mean and whiskers represent the minimum and maximum values. Animal silhouettes were available under Public Domain license at phylopic ( Specifically, starting from the left, Accipitrinae (, This image is available for reuse under the Public Domain Dedication 1.0 license; Falconidae (, available for reuse and under the Creative Commons Attribution 3.0 Unported ( image by Liftarn; Cathartiformes (, available for reuse and under the Creative Commons Attribution 3.0 Unported ( image by Mark P. Witton & Darren Naish.

Table 3 Pairwise comparison of VM stress differences between dietary groups.

Evolutionary allometry

Our tests revealed that shape and size (CS) variables were not significantly correlated for each multivariate regression model considered (Table 4). Similarly, all regressions between the averaged VM stress values and size (CS) were non-significant (Table 4).

Table 4 The different multivariate regression models of shape and Von Mises stress on size (CS) tested in the present work.

Phylogenetic comparative methods

Phylogenetic signal analyses revealed a significant degree of phylogenetic structure in the shape variables (Kmult = 0.804, p-value = 0.001), and for the averaged VM stress variables (Kmult = 1.227, p-value = 0.004; see Fig. 3). PGLS analyses revealed that talon shape was not significantly correlated with size (CS) even when excluding the NP taxa (F1,21 = 1.321, r2 = 0.06; p-value = 0.422; F1,17 = 1.147, r2 = 0.046; p-value = 0.632), while shape was significantly different between dietary categories (F2,21 = 7.148, r2 = 0.429, p-value = 0.038). Talon averaged VM stress values were not correlated with size even when excluding the NP taxa (F1,21 = 1.741; r2 = 0.083; p-value = 0.298; F1,17 = 1.628; r2 = 0.071; p-value = 0.343, respectively), whereas they were significantly different between dietary categories (F2,21 = 7.174; r2 = 0.44; p-value = 0.027).

Figure 3
figure 3

Measured averaged VM stress values for each species mapped on the phylogeny. Values at nodes and branches were reconstructed using a maximum-likelihood ancestral character estimation method based on a Brownian motion model of evolution.


Our results indicate how talon shape and biomechanical performance evolved in response to the selective pressures exerted by different feeding ecologies, even when phylogeny is taken into account. The maximum prey size relative to body mass proved to be an important factor in shaping the raptor talon. Non-predatory species (NP category) possess shorter, blunter and less curved talons, with flatter articular facets and reduced flexor tubercles, consistent with their unspecialized feeding behaviour. This suggests that the talons of NP species are not constrained by the same biomechanical and morphological influences as predatory species. In fact, NP species are characterized by markedly higher VM stress values (Figs 1 and 2). Vultures are specialized carrion feeders, known to have shorter talons unsuitable for prey seizing18,19.

The recurved talon of the galah (Eolophus roseicapilla), despite its superficial resemblance to those of raptors20, displayed extremely high VM stress values, evidencing that it is poorly adapted to sustain the relatively heavy loads applied during prey capture.

Conversely, predatory species hunting larger prey (accipitrids, ML category) show highly curved talons, suggesting an adaptation to immobilise and subdue relatively larger and heavier prey4,18. Species belonging to the ML category also possessed an enlarged flexor tubercule, suggesting the presence of relatively larger and more powerful digit flexor muscles responsible for transmitting and maintaining grip forces9,21. Consistent with these observations, we found that taxa preying on relatively larger species (ML) showed markedly lower VM stress values along the talon curvature and in correspondence with the flexor tubercle, thus suggesting adaptation to sustain a stronger and extended (in time) restraining action4,9,10.

Our results showed that the talons of species preying on relatively smaller prey (SM category) were morphologically distinct from those of predators on relatively large prey (ML), being characterized by a slender, less curved talon with a reduced flexor tubercle (Fig. 1). Along PC2 we observed an overlap between the SM species and the whistling kite and the swamp harrier (H. sphenurus and C. approximans, see Fig. 1 and Supplementary Fig. S1). Despite being able to hunt relatively large prey, these species display more generalised behaviours than the other ML species. H. sphenurus also relies on carrion during the breeding season. This is in line with the biomechanical analysis, which showed that the whistling kite and the swamp harrier display higher stresses along the talon curvature and on the flexor tubercle.

However, the osprey (Pandion cristatus) overlapped with species belonging to the ML category along the first two PC scores (Fig. 1), although it was clearly separated on the third (Supplementary Fig. S1). This result is in line with other studies which have showed the osprey to have a distinctive morphology, thought to be a consequence of its highly specialized piscivorous diet4,5,13. Indeed, the osprey showed a slender, highly curved talon with a much reduced, elongated flexor tubercle characterized by significantly higher VM stress values, comparable to those of the other species belonging to the SM category (Figs 1 and 2).

Despite having highly distinctive talon morphology, the barn owl (Tyto alba) showed low VM stress values (Supplementary Table S1 and Fig. S2) comparable with the members of the ML category. This finding may reflect that predicted by the ‘many-to-one’ hypothesis, i.e., that very different forms may have similar functional outputs11,22. However, it must be noted that this species possesses a large flexor tubercle (Supplementary Fig. S2) and that, in general, Strigiformes show a highly specialized tendon locking mechanism, short tarsometatarsus and sesamoid bones which contribute to enhance the grip force4,21,23. By contrast, the boobook (Ninox boobook) displayed average VM stress values in line with the other taxa belonging to the SM category (Supplementary Table S1). The boobook has a more insectivorous diet, possesses a reduced flexor tubercle and a flatter talon, suggesting a lesser degree of specialization toward improved grip force24. Furthermore, true owls (Strigidae) are reported to be more specialized toward aerial prey capture, having a tendon locking mechanism more similar to that of falcons than to the closely related barn owls (Tytonidae)24.

Among the species included in the SM category, falconids occupied a distinct region of the talon morphospace (Fig. 1). This is in line with previous studies, which have found that falcons rely more on their beak to kill their prey and, therefore, display higher bite forces but weaker grip forces compared to accipitrids4,5,10,18,25. In fact, falcons showed higher stress values along the talon curvature, on the medial edge and on the flexor tubercle (Fig. 2). The shape and biomechanical analyses depict a scenario of morpho-functional convergence driven by relative prey size, more than prey type. In fact, species belonging to the same dietary category occupied a similar morphospace and experienced similar VM stress distribution patterns on the talon (Fig. 2). This result is also supported by the absence of correlation between both talon shape and biomechanical performance with size.

Despite a great range of body sizes, the talons of raptors showed similar adaptive features which grouped according to relative prey size, not the absolute size of the predator itself. In other words, the raptor talon is more likely shaped by adaptive factors than developmental constraints, such as allometry. Accipitrids, falconids, Strigiformes and cathartids were separated on the morphospace plot and showed different VM stress values (Figs 1 and 2), which suggests that phylogenetic history may influence talon phenotypes. Further, we found a strong phylogenetic signal in both shape and VM stress variables (Fig. 3). However, the absence of an allometric relationship, when accounting for phylogenetic effect, suggests that the observed variation in both shape and performance cannot be reduced to shared ancestry alone, or the tendency of related species to display similar phenotypes. Therefore, it is likely that raptor talon morphology and performance vary in response to functional selective pressures, since raptor talons are critical for prey capture, killing and/or restraining4,9,26.

Our results appear to contrast with those obtained for raptor skulls13, where allometry and phenotypic integration were found to have a major impact in shaping the cranial variability of raptors. Although, it must be noted that allometric and heterochronic changes are important factors in the evolution of the vertebrate skull27,28,29. These processes are thought to act as paths of least resistance in the skull’s evolutionary history and may facilitate morphological evolution along particular trajectories27,30. However, traits constrained along narrow evolutionary trajectories are also less responsive to changes in selective pressures31,32,33,34. In this context, the allometry-free evolution of the talon could have allowed raptors to exploit different resources and to expand their ecological niches. Poor correlation between claw curvature and body mass has been evidenced for Aves, Squamata and Mesozoic dinosaur5, suggesting that the lack of allometric constraint on claws may also be common to these taxa. Therefore, the evolutionary plasticity of the talon could have had an important role in providing the opportunity for raptors to exploit resources and adaptive pathways that could not have been accessed through changing skull shape, because of the high levels of constraint on this structure1,13,35. Our study supports the hypothesis that evolutionary mosaicism has played a key role in the successful adaptive radiation of birds14, and that the raptorial talon evolved under different adaptive constraints.

Materials and Methods

Specimen collection

In this study, we compared the talon shape and biomechanical performance of 12 species of accipitrid raptors, three species from Falconiformes, and two species of Strigiformes. We also include non-predatory species, comprising a representative of passeriform (raven), parrot (cockatoo), and two vultures (Table 1 and Supplementary Table ST1). Although the keratin sheath reflects actual claw curvature36, we chose to focus on the ungual cortical bone as this is the underlying supporting structure of the keratin and the site of attachment for tendons of the major flexor muscles (e.g. M. flexor hallucis longus). Most FEA of biological structures treat bone as a simplified, non-porous material, however, our Finite Element Models incorporate geometry of the trabecular networks, which can provide added insight into mechanical performance37,38. Ungual bones were sourced from both prepared, disarticulated skeletal material from the Australian Museum; and whole, thawed, unprocessed digits (dissected limbs) at the University of New England, Australia.

CT-scanning, image processing and finite element model assembly

Micro-computed tomography (µ-CT) scans of ungual bones were taken using a Phoenix GE micro-CT scanner. Specimens were scanned using energy settings set at 110 kV voltage and 140 µA current. Each scan comprised 1000 slices. Images were stacked and processed using GE Phoenix proprietary software. Three-dimensional surface and volume meshes were constructed from each CT scanned talon using Mimics (v.16.0) and 3-Matic (v.8.0) (Materialise N. V.), using previously described protocols37,39.

All volume models comprised of between 2 million to 2.1 million tetrahedral elements and between 419,033 to 441,598 nodes (i.e., tetrahedral vertices). The volume models were imported into Strand7 (v.2.4.6) and finite element models were created for each specimen. We note that, as with most similar interspecies comparisons, FEA is used here in a wholly comparative fashion. In this study we aim to compare FE models in the context of their phylogenetic relationships and we applied the same approximations for all the models. Material properties were assigned for cortical bone (Young’s Modulus of 21,100 MPa)7. We applied the same properties used by Manning et al.7 in their study on theropod claw biomechanics and all materials were treated as isotropic, using a Poisson’s Ratio value of 0.32 for bone. To remove the size information, as recommended for comparative and biomechanical shape analyses15,40,41, all simulations were performed under a scale-free framework by scaling all the models to the same surface area. The models were scaled using the following relationship: \(=\frac{\sqrt{SA}}{SB}\); where K is the scaling factor, SA is the surface area of the target model and SB is the surface area of the reference model.


An elastic solid mesh consisting of beam elements (Structural Steel AS 4100–1998, Young’s Modulus of 200,000 MPa)39 was placed on the surface of the model around the selected restraint areas to minimize the incidence of artefacts that can occur where single beam nodes are loaded42.

All the models were restrained at the tip of the ungual bones for each degree of freedom in translation and rotation. Two restraints were placed respectively at nodes on the apex of the rim of the medial and lateral cotylae (that comprise the articular facet at the proximal end of the ungual bone). These were fixed in translation for each degree of freedom (x, y, z), but left free in rotation along the x axis following previous protocols43 (see Fig. 4a,b).

Figure 4
figure 4

(a) 3D model of Aquila audax talon showing the anatomical terminology used in the present study. (b) Finite element model (FEM) of Aquila audax talon, showing location of tessellated beams (red), rotation points (curved yellow arrow), node force location and direction (red arrow) and fixed talon tip (yellow circle). (c) The landmarks (red) and semi-landmarks on curves (black) digitized on the ungual bone (Accipiter cirrhocephalus). Landmarks and curves definition: S1-S2: Tip of the talon. S3: talon midpoint height. S4: Ventral end of the inner curvature. S5: Tip of the flexor tubercle. S6: Tip of the extensor tubercle. S7-8: Ventral foramina. C1: Distal outer curvature. C2: Inner curvature. C3: proximal outer curvature. C4: Ventral curvature. C5-6: Talon maximum width. C7-8: Lateral borders of the articular facet. (d) The selected landmarks (green) used to collect the VM stress values.

The grid boundary of the previously described mesh applied on the distal tip of the ungual bone was identified by visually following the dorsal aspect of the bone, with the grid applied at the distal-most point of the bone tip, then moving around the circumference of the model surface until a conical shaped grid covered the bone tip.

Digit force estimations and loadings

To assess the biomechanical performance of the ungual bone during flexion, relative forces need to be applied to simulate gripping action for each Finite Element Model (FEM). Forces were applied in the negative direction along the z axis.

We used the brown goshawk (Accipiter fasciatus) as reference model for scaling the Finite Elements models, using the relationship described in the “CT-scanning, image processing and finite element model assembly” section. This choice is motivated by the similarity in shape and size between the brown goshawk and the Cooper’s hawk (Accipiter cooperi) for which the grip force has been measured in vivo (9.77 N)10. Therefore, the maximum grip force of 9.77 N, estimated for the Cooper’s hawk10, was used as the force that was applied to all of the models. As this study focuses on a single talon (hence digit), we calculated the theoretical force equally distributed across all four digits. Although this approach provides a conservative estimate of force applicable to the hallux, the analysis can still be functionally informative from a predatory ecology perspective, since the action of constriction of the feet and toes via muscle flexion produces force output across all toes and talons, which enables a bird to grasp an object. The loads were applied on two nodes placed on the beams composing the elastic mesh embedded respectively on the medial and lateral side of the flexor tubercle. Both nodes were restrained for each degree of freedom (global x, y, z restraint for translation and rotation) and forces applied along the z axes. The site of attachment of M. flexor hallucis longus, the primary muscle that activates the associated tendon resulting in flexion of the hallux44 was, again, covered with an elastic mesh composed by beam elements (Structural Steel AS 4100–1998, Young’s Modulus of 200,000 MPa)39, on both the medial and lateral sides of the flexor tubercule, and placed caudo-ventral to the ventral foramina (see Fig. 4a,b), in order to minimize the incidence of artefacts that can occur where single nodes are loaded42. To simulate talon flexion (hence piercing action), we applied negative force values at each node on the flexor tubercule, in the negative direction to the ungual tip.

Von mises stress analysis

To allow a direct comparison of results between talon FEMs, and to further integrate stress and shape outputs from FEA with GMM, we followed the method used in45. At the location of 26 selected landmarks (green landmarks on Fig. 4d) sampled from the GMM dataset (see below), we computed the mean von Mises stress values from the four nearest tetrahedral elements (each tetrahedral element has four nodes). After this process was completed, we averaged the landmark VM stress values and the significance of the observed stress variation between SM, ML and NP categories was evaluated by performing an ANOVA on the stress values using the function procD.lm(). Pairwise comparisons between ML, SM and NP categories were performed using the function advanced.procD.lm(). VM stress differences between dietary categories were visualized using a boxplot (Fig. 2).

Geometric morphometric (GMM) shape analysis

On each talon (Fig. 4a), we digitized 8 anatomical landmarks and 65 semi-landmarks placed equidistantly along the outer and inner curve of the ungual bone to capture its shape in three dimensions (Fig. 4c) using IDAV Landmark software46. We manually digitized the homologous landmarks on all the specimens included in this this study, then we manually digitized the semi-landmarks on curves on the Accipiter fasciatus talon and used it as the template individual. The points on the template were projected onto all the other specimens following the automatic procedure described in47 (the protocol is fully described in Supplementary Methods). Once all the semi-landmarks were automatically placed we imported the landmarks into R version 3.4.4 for further analyses. We performed Generalized Procrustes Analysis48,49 (GPA) on all landmarks, implemented in the ProcSym() function from the R package “Morpho”50, to rotate, translate, and scale landmark configurations to unit centroid size51 (CS, square root of squared differences between landmark coordinates and Centroid coordinates). To visualize the multivariate ordination of the aligned Procrustes coordinates, we performed a principal component analysis (PCA). The significance of the observed shape changes between the three dietary categories was evaluated by performing a Procrustes ANOVA49 on aligned Procrustes coordinates using the function procD.lm() from the R package “geomorph”52. Pairwise comparisons between ML, SM and NP categories were performed using the function advanced.procD.lm()52.

Evolutionary allometry

We tested the relationship between talon size (independent variable) and Procrustes shape coordinates (dependent variable) by performing a multivariate regression of shape on size (CS). This analysis was performed, and visualized, using the function procD.allometry() from the R package “geomorph”52. This analysis was repeated removing the species belonging to the NP category since these taxa could represent potential outliers due to their different ecology and behaviour. These analyses were then repeated using the averaged VM stress values as dependent variables.

Phylogeny and comparative methods

A maximum clade credibility tree of the species in the analysis was constructed from a set of 1,000 molecular trees53 ( using the function MaxCredTree() from the R package “phangorn”54.

Phylogenetic signal was calculated for the shape data using the Kmult statistic, a method that measures the similarity of trait values in relation to a Brownian motion model of evolution, and that is specifically designed for the challenges of working with high-dimensional landmark configurations55. We used a phylogenetic generalized least squares (PGLS) linear model to account for the non-independence among observations due to shared phylogenetic history56,57. PGLS linear model and Kmult statistic were also computed for the averaged VM-stress values and, then, mapped on the phylogeny using the contMap() function from the R package “phytools”58 (Fig. 3).

Data Availability

The datasets used in the current study are available in the e-publications@UNE repository at Data can be accessed pending a reasonable request to the corresponding author at the following e-mail address:


  1. Losos, J. B. Adaptive radiation, ecological opportunity, and evolutionary determinism: American Society of Naturalists EO Wilson Award address. Am. Nat. 175, 623–639 (2010).

    Article  PubMed  Google Scholar 

  2. Losos, J. B. Convergence, adaptation, and constraint. Evolution 65, 1827–1840 (2011).

    Article  PubMed  Google Scholar 

  3. Csermely, D. & Rossi, O. Bird claws and bird of prey talons: Where is the difference? It. J. Zool. 73, 43–53 (2006).

    Google Scholar 

  4. Fowler, D. W., Freedman, E. A. & Scannella, J. B. Predatory functional morphology in raptors: interdigital variation in talon size is related to prey restraint and immobilisation technique. PLoS One 4, e7999 (2009).

    ADS  Article  PubMed  PubMed Central  Google Scholar 

  5. Birn-Jeffery, A. V., Miller, C. E., Naish, D., Rayfield, E. J. & Hone, D. W. Pedal claw curvature in birds, lizards and Mesozoic dinosaurs–complicated categories and compensating for mass-specific and phylogenetic control. PLoS One 7, e50555 (2012).

    ADS  CAS  Article  PubMed  PubMed Central  Google Scholar 

  6. Feduccia, A. Evidence from claw geometry indicating arboreal habits of Archaeopteryx. Science 259, 790–793 (1993).

    ADS  CAS  Article  PubMed  Google Scholar 

  7. Manning, P. L. et al. Biomechanics of dromaeosaurid dinosaur claws: application of X‐ray microtomography, nanoindentation, and finite element analysis. Anat. Record 292, 1397–1405 (2009).

    Article  Google Scholar 

  8. Dececchi, T. A. & Larsson, H. C. Assessing arboreal adaptations of bird antecedents: testing the ecological setting of the origin of the avian flight stroke. PLoS One 6, e22292 (2011).

    ADS  Article  PubMed  PubMed Central  Google Scholar 

  9. Sustaita, D. Musculoskeletal underpinnings to differences in killing behavior between North American accipiters (Falconiformes: Accipitridae) and falcons (Falconidae). J. Morphol. 269, 283–301 (2008).

    Article  PubMed  Google Scholar 

  10. Sustaita, D. & Hertel, F. In vivo bite and grip forces, morphology and prey-killing behavior of North American accipiters (Accipitridae) and falcons (Falconidae). J. Exper. Biol. 213, 2617–2628 (2010).

    Article  Google Scholar 

  11. Wainwright, P. C., Alfaro, M. E., Bolnick, D. I. & Hulsey, C. D. Many-to-one mapping of form to function: a general principle in organismal design? Int. Comp. Biol. 45, 256–262 (2005).

    Article  Google Scholar 

  12. Alfaro, M. E., Bolnick, D. I. & Wainwright, P. C. Evolutionary consequences of many-to-one mapping of jaw morphology to mechanics in labrid fishes. Am. Nat. 165, 140–154 (2005).

    Article  Google Scholar 

  13. Bright, J. A., Marugán-Lobón, J., Cobb, S. N. & Rayfield, E. J. The shapes of bird beaks are highly controlled by nondietary factors. PNAS 113, 5352–5357 (2016).

    ADS  CAS  Article  PubMed  Google Scholar 

  14. Felice, R. N. & Goswami, A. Developmental origins of mosaic evolution in the avian cranium. PNAS 201716437 (2017).

  15. Piras, P. et al. Digging adaptation in insectivorous subterranean eutherians. The enigma of Mesoscalops montanensis unveiled by geometric morphometrics and finite element analysis. J. Morphol. 276, 1157–1171 (2015).

    Article  PubMed  Google Scholar 

  16. Polly, P. D. et al. Combining geometric morphometrics and finite element analysis with evolutionary modeling: towards a synthesis. J. Vert. Paleontol. 36, e1111225 (2016).

    Article  Google Scholar 

  17. Tseng, Z. J. & Flynn, J. J. Structure-function covariation with nonfeeding ecological variables influences evolution of feeding specialization in Carnivora. Sci. Advanc. 4, eaao5441 (2018).

    Article  Google Scholar 

  18. Backus, S. B., Sustaita, D., Odhner, L. U. & Dollar, A. M. Mechanical analysis of avian feet: multiarticular muscles in grasping and perching. Royal Soc. open sci. 2, 140350 (2015).

    ADS  Article  Google Scholar 

  19. Hertel, F., Maldonado, J. E. & Sustaita, D. Wing and hindlimb myology of vultures and raptors (Accipitriformes) in relation to locomotion and foraging. Acta Zoologica 96, 283–295 (2015).

    Article  Google Scholar 

  20. Brown, C. & Magat, M. Cerebral lateralization determines hand preferences in Australian parrots. Biol. Lett. 7, 496–498 (2011).

    Article  PubMed  PubMed Central  Google Scholar 

  21. Ward, A. B., Weigl, P. D. & Conroy, R. M. Functional morphology of raptor hindlimbs: implications for resource partitioning. The Auk 119, 1052–1063 (2002).

    Article  Google Scholar 

  22. Anderson, P. S., Friedman, M., Brazeau, M. D. & Rayfield, E. J. Initial radiation of jaws demonstrated stability despite faunal and environmental change. Nature 476, 206–209 (2011).

    ADS  CAS  Article  PubMed  Google Scholar 

  23. Einoder, L. D. & Richardson, A. M. Aspects of the hindlimb morphology of some Australian birds of prey: a comparative and quantitative study. The Auk 124, 773–788 (2007).

    Article  Google Scholar 

  24. Einoder, L. D. & Richardson, A. The digital tendon locking mechanism of owls: variation in the structure and arrangement of the mechanism and functional implications. Emu 107, 223–230 (2007).

    Article  Google Scholar 

  25. Csermely, D., Rossi, O. & Nasi, F. Comparison of claw geometrical characteristics among birds of prey and non-raptorial birds. Ital. J. Zool. 79, 410–433 (2012).

    Article  Google Scholar 

  26. Einoder, L. D. & Richardson, A. An ecomorphological study of the raptorial digital tendon locking mechanism. Ibis 148, 515–525 (2006).

    Article  Google Scholar 

  27. Marroig, G., Shirai, L. T., Porto, A., de Oliveira, F. B. & De Conto, V. The evolution of modularity in the mammalian skull II: evolutionary consequences. Evol. Biol. 36, 136–148 (2009).

    Article  Google Scholar 

  28. Bhullar, B. A. S. et al. Birds have paedomorphic dinosaur skulls. Nature 487, 223 (2012).

    ADS  CAS  Article  PubMed  Google Scholar 

  29. Cardini, A. & Polly, P. D. Larger mammals have longer faces because of size-related constraints on skull form. Nature Comm. 4, 2458 (2013).

    ADS  Article  Google Scholar 

  30. Marroig, G. & Cheverud, J. M. Size as a line of least evolutionary resistance: diet and adaptive morphological radiation in New World monkeys. Evolution 59, 1128–1142 (2005).

    Article  PubMed  Google Scholar 

  31. Villmoare, B. Morphological integration, evolutionary constraints, and extinction: a computer simulation-based study. Evol. Biol. 40, 76–83 (2013).

    Article  Google Scholar 

  32. Pélabon, C. et al. Evolution of morphological allometry. Ann. N. Y. Acad. Sci. 1320, 58–75 (2014).

    ADS  Article  PubMed  Google Scholar 

  33. Voje, K. L., Hansen, T. F., Egset, C. K., Bolstad, G. H. & Pelabon, C. Allometric constraints and the evolution of allometry. Evolution 68, 866–885 (2014).

    Article  PubMed  Google Scholar 

  34. Sansalone, G. et al. Influence of evolutionary allometry on rates of morphological evolution and disparity in strictly subterranean moles (Talpinae, Talpidae, Lipotyphla, Mammalia). Journal of Mammalian Evolution 25, 1–14 (2018).

    Article  Google Scholar 

  35. Schluter, D. Ecological character displacement in adaptive radiation. Am. Nat. 156, S4–S16 (2000).

    Article  Google Scholar 

  36. Manning, P. L., Payne, D., Pennicott, J., Barrett, P. M. & Ennos, R. A. Dinosaur killer claws or climbing crampons? Biol. Lett. 2, 110–112 (2006).

    Article  PubMed  Google Scholar 

  37. Parr, W. C. H., Chamoli, U., Jones, A., Walsh, W. R. & Wroe, S. Finite element micro-modelling of a human ankle bone reveals the importance of the trabecular network to mechanical performance: New methods for the generation and comparison of 3D models. J Biomech 46, 200–205 (2013).

    CAS  Article  PubMed  Google Scholar 

  38. Evans, S. P., Parr, W. C. H., Clausen, P. D., Jones, A. & Wroe, S. Finite element analysis of a micromechanical model of bone and a new 3D approach to validation. J. Biomech. 45, 2702–2705 (2012).

    CAS  Article  PubMed  Google Scholar 

  39. Attard, M. R. et al. Moa diet fits the bill: virtual reconstruction incorporating mummified remains and prediction of biomechanical performance in avian giants. Proc. R. Soc. B 283, 20152043 (2016).

    Article  PubMed  Google Scholar 

  40. Dumont, E. R., Grosse, I. R. & Slater, G. J. Requirements for comparing the performance of finite element models of biological structures. J. Theor. Biol. 256, 96–103 (2009).

    MathSciNet  CAS  Article  PubMed  Google Scholar 

  41. Stayton, C. T. Application of thin‐plate spline transformations to finite element models, or, how to turn a bog turtle into a spotted turtle to analyze both. Evolution 63, 1348–1355 (2009).

    Article  PubMed  Google Scholar 

  42. McHenry, C., Wroe, S., Clausen, P. D., Moreno, K. & Cunningham, E. Supermodeled sabercat, predatory behavior in Smilodon fatalis revealed by high-resolution 3D computer simulation. PNAS 104, 16010–16015 (2007).

    ADS  CAS  Article  PubMed  Google Scholar 

  43. Wroe, S. et al. Computer simulations show that Neanderthal facial morphology represents adaptation to cold and high energy demands, but not heavy biting. Proc. R. Soc. B 285, 20180085 (2018).

    Article  PubMed  Google Scholar 

  44. George, J. C. & Berger, A. J. Avian Myology. (Academic Press, 1966)

  45. Parr, W. C. H. et al. Toward integration of geometric morphometrics and computational biomechanics: new methods for 3D virtual reconstruction and quantitative analysis of Finite Element Models. J. Theor. Biol. 301, 1–14 (2012).

    CAS  Article  PubMed  Google Scholar 

  46. Wiley, D. F. et al. Evolutionary morphing. Proceedings of the IEEE Visualization 2005 (VIS’05), 431–438 (2005).

  47. Dumont, M. et al. Do functional demands associated with locomotor habitat, diet, and activity pattern drive skull shape evolution in musteloid carnivorans? Biol. J. Linn. Soc. 117, 858–878 (2016).

    Article  Google Scholar 

  48. Rohlf, F. J. & Slice, D. Extensions of the Procrustes Method for the Optimal Superimposition of Landmarks. Syst. Biol. 39, 40–59 (1990).

    Google Scholar 

  49. Goodall, C. Procrustes methods in the statistical analysis of shape. J. R. Stat. Soc. 53, 285–339 (1991).

    MathSciNet  MATH  Google Scholar 

  50. Schlager, S. Morpho: Calculations and visualisations related to Geometric Morphometrics. R-package version 2.0. 3–1 (2014).

  51. Bookstein, F. L. Morphometric Tools for Landmark Data. (Cambridge University Press, 1991).

  52. Adams, D. C. & Otárola‐Castillo, E. geomorph: an R package for the collection and analysis of geometric morphometric shape data. Meth. Ecol. Evol. 4, 393–399 (2013).

    Article  Google Scholar 

  53. Jetz, W., Thomas, G. H., Joy, J. B., Hartmann, K. & Mooers, A. O. The global diversity of birds in space and time. Nature 491, 444 (2012).

    ADS  CAS  Article  Google Scholar 

  54. Schliep, K. & Paradis, E. Package ‘phangorn’. The comprehensive R archive network. Available at (2015).

  55. Adams, D. C. A generalized K statistic for estimating phylogenetic signal from shape and other high-dimensional multivariate data. Syst. Biol. 63, 685–697 (2014).

    Article  PubMed  Google Scholar 

  56. Zelditch, M. L., Swiderski, D. L. & Sheets, H. D. Geometric Morphometrics for Biologists. (Academic Press, 2012).

  57. Adams, D. C. & Collyer, M. L. Permutation tests for phylogenetic comparative analyses of high‐dimensional shape data: What you shuffle matters. Evolution 69, 823–829 (2015).

    Article  PubMed  Google Scholar 

  58. Revell, L. J. phytools: an R package for phylogenetic comparative biology (and other things). Meth. Ecol. Evol. 3, 217–223 (2012).

    Article  Google Scholar 

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The authors are grateful to the Australian Museum (previously Ross Sadlier, Jaynia Sladek) for providing access to skeletal specimens and study skins for use in this project. Special thanks to Leo Joseph and Alex Drew at the Australian National Wildlife Collection (ANWC, CSIRO) for provision of additional skeletal material. We thank Michael Curry for assistance with additional CT scanning and statistical analyses, and Samuel Evans from the University of Newcastle (Australia) for assistance with landmark data processing. We thank Stephen Debus for discussions and input on raptor feeding behaviour and ecology, and Walter Boles for provision of early raptor literature. We are grateful to Phil Clausen for the extensive discussion on the generation of the FEA models. We are grateful to an anonymous reviewer for their comments which greatly improved the quality of the manuscript. We are grateful to Anneke van Heteren for providing us the CT scan of the Aegypius monachus talon.

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L.R.T., M.A., S.W. and G.S. conceived the study. L.R.T., M.A. and J.L. completed the CT scanning of material. L.R.T. and G.S. prepared the FEMs. G.S. and L.A.B.W. performed the geometric morphometric analyses. G.S. interpreted the results. L.R.T. and G.S. wrote the manuscript. All of the authors have significantly contributed in producing and analysing the data, and in preparing the manuscript and related material.

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Correspondence to Gabriele Sansalone.

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Tsang, L.R., Wilson, L.A.B., Ledogar, J. et al. Raptor talon shape and biomechanical performance are controlled by relative prey size but not by allometry. Sci Rep 9, 7076 (2019).

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