Your search keyword '"Pongo pygmaeus anatomy & histology"' showing total 119 results

1. Phylogenetic differences in the morphology and shape of the central sulcus in great apes and humans: implications for the evolution of motor functions.

Author

Foubet O, Mangin JF, Sun ZY, Sherwood CC, and Hopkins WD

Subjects

Animals, Humans, Male, Female, Adult, Hand physiology, Hand anatomy & histology, Young Adult, Pongo pygmaeus anatomy & histology, Pongo pygmaeus physiology, Species Specificity, Pongo abelii anatomy & histology, Pongo abelii physiology, Biological Evolution, Pan troglodytes anatomy & histology, Pan troglodytes physiology, Gorilla gorilla anatomy & histology, Gorilla gorilla physiology, Magnetic Resonance Imaging, Phylogeny, Motor Cortex anatomy & histology, Motor Cortex physiology, Motor Cortex diagnostic imaging, Hominidae anatomy & histology, Hominidae physiology

Abstract

The central sulcus divides the primary motor and somatosensory cortices in many anthropoid primate brains. Differences exist in the surface area and depth of the central sulcus along the dorso-ventral plane in great apes and humans compared to other primate species. Within hominid species, there are variations in the depth and aspect of their hand motor area, or knob, within the precentral gyrus. In this study, we used post-image analyses on magnetic resonance images to characterize the central sulcus shape of humans, chimpanzees (Pan troglodytes), gorillas (Gorilla gorilla), and orangutans (Pongo pygmaeus and Pongo abelii). Using these data, we examined the morphological variability of central sulcus in hominids, focusing on the hand region, a significant change in human evolution. We show that the central sulcus shape differs between great ape species, but all show similar variations in the location of their hand knob. However, the prevalence of the knob location along the dorso-ventral plane and lateralization differs between species and the presence of a second ventral motor knob seems to be unique to humans. Humans and orangutans exhibit the most similar and complex central sulcus shapes. However, their similarities may reflect divergent evolutionary processes related to selection for different positional and habitual locomotor functions., (© The Author(s) 2024. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2024

2. Cortical bone architecture of hominid intermediate phalanges reveals functional signals of locomotion and manipulation.

Author

Syeda SM, Tsegai ZJ, Cazenave M, Skinner MM, and Kivell TL

Subjects

Animals, Humans, Gorilla gorilla anatomy & histology, Locomotion, Pongo, Pongo pygmaeus anatomy & histology, Cortical Bone, Hominidae anatomy & histology

Abstract

Objectives: Reconstruction of fossil hominin manual behaviors often relies on comparative analyses of extant hominid hands to understand the relationship between hand use and skeletal morphology. In this context, the intermediate phalanges remain understudied. Thus, here we investigate cortical bone morphology of the intermediate phalanges of extant hominids and compare it to the cortical structure of the proximal phalanges, to investigate the relationship between cortical bone structure and inferred loading during manual behaviors., Materials and Methods: Using micro-CT data, we analyze cortical bone structure of the intermediate phalangeal shaft of digits 2-5 in Pongo pygmaeus (n = 6 individuals), Gorilla gorilla (n = 22), Pan spp. (n = 23), and Homo sapiens (n = 23). The R package morphomap is used to study cortical bone distribution, cortical thickness and cross-sectional properties within and across taxa., Results: Non-human great apes generally have thick cortical bone on the palmar shaft, with Pongo only having thick cortex on the peaks of the flexor sheath ridges, while African apes have thick cortex along the entire flexor sheath ridge and proximal to the trochlea. Humans are distinct in having thicker dorsal shaft cortex as well as thick cortex at the disto-palmar region of the shaft., Discussion: Variation in cortical bone distribution and properties of the intermediate phalanges is consistent with differences in locomotor and manipulative behaviors in extant great apes. Comparisons between the intermediate and proximal phalanges reveals similar patterns of cortical bone distribution within each taxon but with potentially greater load experienced by the proximal phalanges, even in knuckle-walking African apes. This study provides a comparative context for the reconstruction of habitual hand use in fossil hominins and hominids., (© 2024 The Authors. American Journal of Biological Anthropology published by Wiley Periodicals LLC.)

Published

2024

3. Morphological integration and shape covariation between the trapezium and first metacarpal among extant hominids.

Author

Bardo A, Dunmore CJ, Cornette R, and Kivell TL

Subjects

Animals, Humans, Thumb, Gorilla gorilla anatomy & histology, Pan troglodytes anatomy & histology, Pan paniscus, Pongo pygmaeus anatomy & histology, Hominidae anatomy & histology, Metacarpal Bones anatomy & histology, Pongo abelii

Abstract

Objectives: The shape of the trapezium and first metacarpal (Mc1) markedly influence thumb mobility, strength, and the manual abilities of extant hominids. Previous research has typically focused solely on trapezium-Mc1 joint shape. Here we investigate how morphological integration and shape covariation between the entire trapezium (articular and non-articular surfaces) and the entire Mc1 reflect known differences in thumb use in extant hominids., Materials and Methods: We analyzed shape covariation in associated trapezia and Mc1s across a large, diverse sample of Homo sapiens (n = 40 individuals) and other extant hominids (Pan troglodytes, n = 16; Pan paniscus, n = 13; Gorilla gorilla gorilla, n = 27; Gorilla beringei, n = 6; Pongo pygmaeus, n = 14; Pongo abelii, n = 9) using a 3D geometric morphometric approach. We tested for interspecific significant differences in degree of morphological integration and patterns of shape covariation between the entire trapezium and Mc1, as well as within the trapezium-Mc1 joint specifically., Results: Significant morphological integration was only found in the trapezium-Mc1 joint of H. sapiens and G. g. gorilla. Each genus showed a specific pattern of shape covariation between the entire trapezium and Mc1 that was consistent with different intercarpal and carpometacarpal joint postures., Discussion: Our results are consistent with known differences in habitual thumb use, including a more abducted thumb during forceful precision grips in H. sapiens and a more adducted thumb in other hominids used for diverse grips. These results will help to infer thumb use in fossil hominins., (© 2023 The Authors. American Journal of Biological Anthropology published by Wiley Periodicals LLC.)

Published

2024

4. Relationships between the hard and soft dimensions of the nose in Pan troglodytes and Homo sapiens reveal the positions of the nasal tips of Plio-Pleistocene hominids.

Author

Campbell RM, Vinas G, and Henneberg M

Subjects

Animals, Fossils history, Gorilla gorilla anatomy & histology, Gorilla gorilla classification, History, Ancient, Humans, Hylobatidae anatomy & histology, Hylobatidae classification, Male, Pan paniscus anatomy & histology, Pan paniscus classification, Papio hamadryas anatomy & histology, Papio hamadryas classification, Phylogeny, Pongo abelii anatomy & histology, Pongo abelii classification, Pongo pygmaeus anatomy & histology, Pongo pygmaeus classification, Regression Analysis, Biological Evolution, Face anatomy & histology, Nose anatomy & histology, Pan troglodytes anatomy & histology

Abstract

By identifying homogeneity in bone and soft tissue covariation patterns in living hominids, it is possible to produce facial approximation methods with interspecies compatibility. These methods may be useful for producing facial approximations of fossil hominids that are more realistic than currently possible. In this study, we conducted an interspecific comparison of the nasomaxillary region in chimpanzees and modern humans with the aim of producing a method for predicting the positions of the nasal tips of Plio-Pleistocene hominids. We addressed this aim by first collecting and performing regression analyses of linear and angular measurements of nasal cavity length and inclination in modern humans (Homo sapiens; n = 72) and chimpanzees (Pan troglodytes; n = 19), and then performing a set of out-of-group tests. The first test was performed on four subjects that belonged to the same genus as the training sample, i.e., Homo (n = 2) and Pan (n = 2), and the second test, which functioned as an interspecies compatibility test, was performed on Pan paniscus (n = 1), Gorilla gorilla (n = 3), Pongo pygmaeus (n = 1), Pongo abelli (n = 1), Symphalangus syndactylus (n = 3), and Papio hamadryas (n = 3). We identified statistically significant correlations in both humans and chimpanzees with slopes that displayed homogeneity of covariation. Prediction formulae combining these data were found to be compatible with humans and chimpanzees as well as all other African great apes, i.e., bonobos and gorillas. The main conclusion that can be drawn from this study is that our set of regression models for approximating the position of the nasal tip are homogenous among humans and African apes, and can thus be reasonably extended to ancestors leading to these clades., Competing Interests: The authors have declared that no competing interests exist.

Published

2022

5. Ontogenetic insights into the significance of mandibular corpus shape variation in hominoids: Developmental covariation between M 2 crypt formation and corpus shape.

Author

Pitirri MK and Begun D

Subjects

Animals, Mandible anatomy & histology, Molar anatomy & histology, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Species Specificity, Mandible growth & development, Molar growth & development, Pan paniscus growth & development, Pan troglodytes growth & development, Pongo pygmaeus growth & development

Abstract

Objectives: Here, we quantify and compare the cross-sectional shape of the mandibular corpus between M 1 and M 2 during growth in Pan paniscus, Pan troglodytes, and Pongo pygmaeus. The goal is to assess the hypothesis that the shape of the corpus is influenced by the development of permanent molars in their crypts, by examining ontogenetic changes in corpus shape and investigating covariation between corpus shape and M 2 and M 3 molar crypt forms., Materials and Methods: Ontogenetic changes in mandibular corpus shape were assessed using landmarks and semilandmarks, and measurements of length, width, and height were used to quantify molar crypts (M 2 and M 3 ). Ontogenetic changes in corpus growth from the eruption of M 1 to the eruption of M 3 were evaluated for each species through generalized Procrustes analysis and principal components analysis in shape-space and form-space. The relationship between corpus shape and molar crypt form was investigated at three different developmental stages using two-block partial least squares (2B-PLS) analysis., Results: The results show clear differences in growth patterns among all three species and provide evidence that species-level differences in mandibular corpus growth occur prior to the emergence of M 1 . The results of the 2B-PLS analysis reveal that significant covariance between corpus shape and molar crypt form is limited to the developmental stage marked by the emergence of M 1 , with covariance between corpus shape and M 2 crypt width. Corpora that are relatively narrower in the inferior portion of the cross section covary with relatively narrower M 2 crypts., Conclusions: These results have important implications for understanding the taxonomic and phylogenetic significance of mandibular corpus shape variation in the hominoid fossil record., (© 2019 Wiley Periodicals, Inc.)

Published

2020

6. Metacarpal trabecular bone varies with distinct hand-positions used in hominid locomotion.

Author

Dunmore CJ, Kivell TL, Bardo A, and Skinner MM

Subjects

Animals, Gorilla gorilla anatomy & histology, Hand anatomy & histology, Humans, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo abelii anatomy & histology, Pongo pygmaeus anatomy & histology, Posture physiology, Walking physiology, Hominidae anatomy & histology, Locomotion physiology, Metacarpal Bones anatomy & histology

Abstract

Trabecular bone remodels during life in response to loading and thus should, at least in part, reflect potential variation in the magnitude, frequency and direction of joint loading across different hominid species. Here we analyse the trabecular structure across all non-pollical metacarpal distal heads (Mc2-5) in extant great apes, expanding on previous volume of interest and whole-epiphysis analyses that have largely focused on only the first or third metacarpal. Specifically, we employ both a univariate statistical mapping and a multivariate approach to test for both inter-ray and interspecific differences in relative trabecular bone volume fraction (RBV/TV) and degree of anisotropy (DA) in Mc2-5 subchondral trabecular bone. Results demonstrate that whereas DA values only separate Pongo from African apes (Pan troglodytes, Pan paniscus, Gorilla gorilla), RBV/TV distribution varies with the predicted loading of the metacarpophalangeal (McP) joints during locomotor behaviours in each species. Gorilla exhibits a relatively dorsal distribution of RBV/TV consistent with habitual hyper-extension of the McP joints during knuckle-walking, whereas Pongo has a palmar distribution consistent with flexed McP joints used to grasp arboreal substrates. Both Pan species possess a disto-dorsal distribution of RBV/TV, compatible with multiple hand postures associated with a more varied locomotor regime. Further inter-ray comparisons reveal RBV/TV patterns consistent with varied knuckle-walking postures in Pan species in contrast to higher RBV/TV values toward the midline of the hand in Mc2 and Mc5 of Gorilla, consistent with habitual palm-back knuckle-walking. These patterns of trabecular bone distribution and structure reflect different behavioural signals that could be useful for determining the behaviours of fossil hominins., (© 2019 Anatomical Society.)

Published

2019

7. Applying standard perikymata profiles to Pongo pygmaeus canines to estimate perikymata counts between linear enamel hypoplasias.

Author

O'Hara M

Subjects

Animals, Anthropology, Physical, Female, Male, Models, Dental, Cuspid anatomy & histology, Cuspid pathology, Dental Enamel anatomy & histology, Dental Enamel pathology, Dental Enamel Hypoplasia pathology, Pongo pygmaeus anatomy & histology

Abstract

Objectives: Recently, studies have interpreted regular spacing and average number of perikymata between dental enamel defects in orangutans to reflect seasonal episodes of physiological stress. To estimate the amount of time between developmental defects (enamel hypoplasia), studies have relied on perikymata counts. Unfortunately, perikymata are frequently not continuously visible between defects, significantly reducing data sets. A method is presented here for estimating the number of perikymata between defects using standard perikymata profiles (SPP) that allow the number of perikymata between all pairs of defects across a tooth to be analyzed. The SPP method should allow the entire complement of defects to be analyzed within the context of an individual's crown formation time., Materials and Methods: The average number of perikymata were established per decile and charted to create male and female Pongo pygmaeus SPPs. The position of the beginning of each defect was recorded for lower canines from males (n = 6) and females (n = 17). The number of perikymata between defects estimated by the SPP was compared to the actual count (where perikymata were continuously visible)., Results: The number of perikymata between defects estimated by the SPPs was accurate within three perikymata and highly correlated with the actual counts, significantly increasing the number of analyzable defect pairs., Conclusion: SPPs allow all defect pairs to be included in studies of defect timing, not just those with continuously visible perikymata. Establishing an individual's entire complement of dental defects makes it possible to calculate the regularity (and potential seasonality) of defects., (© 2017 Wiley Periodicals, Inc.)

Published

2017

8. Morphometric analyses of hominoid crania, probabilities of conspecificity and an approximation of a biological species constant.

Author

Thackeray JF and Dykes S

Subjects

Animals, Cephalometry statistics & numerical data, Colobus anatomy & histology, Female, Gorilla gorilla anatomy & histology, Hominidae classification, Humans, Male, Paleontology, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Species Specificity, Cephalometry methods, Hominidae anatomy & histology, Skull anatomy & histology

Abstract

Thackeray has previously explored the possibility of using a morphometric approach to quantify the "amount" of variation within species and to assess probabilities of conspecificity when two fossil specimens are compared, instead of "pigeon-holing" them into discrete species. In an attempt to obtain a statistical (probabilistic) definition of a species, Thackeray has recognized an approximation of a biological species constant (T=-1.61) based on the log-transformed standard error of the coefficient m (log sem) in regression analysis of cranial and other data from pairs of specimens of conspecific extant species, associated with regression equations of the form y=mx+c where m is the slope and c is the intercept, using measurements of any specimen A (x axis), and any specimen B of the same species (y axis). The log-transformed standard error of the co-efficient m (log sem) is a measure of the degree of similarity between pairs of specimens, and in this study shows central tendency around a mean value of -1.61 and standard deviation 0.10 for modern conspecific specimens. In this paper we focus attention on the need to take into account the range of difference in log sem values (Δlog sem or "delta log sem") obtained from comparisons when specimen A (x axis) is compared to B (y axis), and secondly when specimen A (y axis) is compared to B (x axis). Thackeray's approach can be refined to focus on high probabilities of conspecificity for pairs of specimens for which log sem is less than -1.61 and for which Δlog sem is less than 0.03. We appeal for the adoption of a concept here called "sigma taxonomy" (as opposed to "alpha taxonomy"), recognizing that boundaries between species are not always well defined., (Copyright © 2015 Elsevier GmbH. All rights reserved.)

Published

2016

9. Forearm articular proportions and the antebrachial index in Homo sapiens, Australopithecus afarensis and the great apes.

Author

Williams FL, Cunningham DL, and Amaral LQ

Subjects

Animals, Biological Evolution, Biomechanical Phenomena, Cluster Analysis, Female, Forearm physiology, Fossils anatomy & histology, Gorilla gorilla anatomy & histology, Gorilla gorilla physiology, Hominidae physiology, Humans, Male, Pan troglodytes anatomy & histology, Pan troglodytes physiology, Pongo pygmaeus anatomy & histology, Pongo pygmaeus physiology, Radius anatomy & histology, Sex Characteristics, Species Specificity, Ulna anatomy & histology, Forearm anatomy & histology, Hominidae anatomy & histology

Abstract

When hominin bipedality evolved, the forearms were free to adopt nonlocomotor tasks which may have resulted in changes to the articular surfaces of the ulna and the relative lengths of the forearm bones. Similarly, sex differences in forearm proportions may be more likely to emerge in bipeds than in the great apes given the locomotor constraints in Gorilla, Pan and Pongo. To test these assumptions, ulnar articular proportions and the antebrachial index (radius length/ulna length) in Homo sapiens (n=51), Gorilla gorilla (n=88), Pan troglodytes (n=49), Pongo pygmaeus (n=36) and Australopithecus afarensis A.L. 288-1 and A.L. 438-1 are compared. Intercept-adjusted ratios are used to control for size and minimize the effects of allometry. Canonical scores axes show that the proximally broad and elongated trochlear notch with respect to size in H. sapiens and A. afarensis is largely distinct from G. gorilla, P. troglodytes and P. pygmaeus. A cluster analysis of scaled ulnar articular dimensions groups H. sapiens males with A.L. 438-1 ulna length estimates, while one A.L. 288-1 ulna length estimate groups with Pan and another clusters most closely with H. sapiens, G. gorilla and A.L. 438-1. The relatively low antebrachial index characterizing H. sapiens and non-outlier estimates of A.L. 288-1 and A.L. 438-1 differs from those of the great apes. Unique sex differences in H. sapiens suggest a link between bipedality and forearm functional morphology., (Copyright © 2015 Elsevier GmbH. All rights reserved.)

Published

2015

10. The foot of Homo naledi.

Author

Harcourt-Smith WE, Throckmorton Z, Congdon KA, Zipfel B, Deane AS, Drapeau MS, Churchill SE, Berger LR, and DeSilva JM

Subjects

Animals, Biological Evolution, Gorilla gorilla anatomy & histology, Humans, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Foot anatomy & histology, Foot Bones anatomy & histology, Fossils, Hominidae anatomy & histology

Abstract

Modern humans are characterized by a highly specialized foot that reflects our obligate bipedalism. Our understanding of hominin foot evolution is, although, hindered by a paucity of well-associated remains. Here we describe the foot of Homo naledi from Dinaledi Chamber, South Africa, using 107 pedal elements, including one nearly-complete adult foot. The H. naledi foot is predominantly modern human-like in morphology and inferred function, with an adducted hallux, an elongated tarsus, and derived ankle and calcaneocuboid joints. In combination, these features indicate a foot well adapted for striding bipedalism. However, the H. naledi foot differs from modern humans in having more curved proximal pedal phalanges, and features suggestive of a reduced medial longitudinal arch. Within the context of primitive features found elsewhere in the skeleton, these findings suggest a unique locomotor repertoire for H. naledi, thus providing further evidence of locomotor diversity within both the hominin clade and the genus Homo.

Published

2015

11. Neurocranium versus Face: A Morphometric Approach with Classical Anthropometric Variables for Characterizing Patterns of Cranial Integration in Extant Hominoids and Extinct Hominins.

Author

Pérez-Claros JA, Jiménez-Arenas JM, and Palmqvist P

Subjects

Animals, Anthropometry, Biological Evolution, Female, Fossils, Gorilla gorilla anatomy & histology, Humans, Male, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Face anatomy & histology, Skull anatomy & histology

Abstract

The relative importance of the two main cranial complexes, the neurocranium and the splanchnocranium, has been examined in the five species of extant hominoids and in a huge sample of extinct hominins using six standard craniometric variables that measure the length, width and height of each cranial module. Factor analysis and two-block partial least squares were used for establishing the major patterns of developmental and evolutionary integration between both cranial modules. The results obtained show that all extant hominoids (including the anatomically modern humans) share a conserved pattern of developmental integration, a result that agrees with previous studies. The pattern of evolutionary integration between both cranial modules in australopiths runs in parallel to developmental integration. In contrast, the pattern of evolutionary and developmental integration of the species of the genus Homo is the opposite, which is probably the consequence of distinctive selective regimes for both hominin groups.

Published

2015

12. Recent origin of low trabecular bone density in modern humans.

Author

Chirchir H, Kivell TL, Ruff CB, Hublin JJ, Carlson KJ, Zipfel B, and Richmond BG

Subjects

Adult, Animals, Body Size, Bone and Bones anatomy & histology, Bone and Bones diagnostic imaging, Extremities anatomy & histology, Female, Fossils, Humans, Imaging, Three-Dimensional, Male, Neanderthals anatomy & histology, Neanderthals physiology, Pan troglodytes anatomy & histology, Pan troglodytes physiology, Pongo pygmaeus anatomy & histology, Pongo pygmaeus physiology, Primates anatomy & histology, Primates physiology, X-Ray Microtomography, Biological Evolution, Bone Density physiology, Hominidae anatomy & histology, Hominidae physiology

Abstract

Humans are unique, compared with our closest living relatives (chimpanzees) and early fossil hominins, in having an enlarged body size and lower limb joint surfaces in combination with a relatively gracile skeleton (i.e., lower bone mass for our body size). Some analyses have observed that in at least a few anatomical regions modern humans today appear to have relatively low trabecular density, but little is known about how that density varies throughout the human skeleton and across species or how and when the present trabecular patterns emerged over the course of human evolution. Here, we test the hypotheses that (i) recent modern humans have low trabecular density throughout the upper and lower limbs compared with other primate taxa and (ii) the reduction in trabecular density first occurred in early Homo erectus, consistent with the shift toward a modern human locomotor anatomy, or more recently in concert with diaphyseal gracilization in Holocene humans. We used peripheral quantitative CT and microtomography to measure trabecular bone of limb epiphyses (long bone articular ends) in modern humans and chimpanzees and in fossil hominins attributed to Australopithecus africanus, Paranthropus robustus/early Homo from Swartkrans, Homo neanderthalensis, and early Homo sapiens. Results show that only recent modern humans have low trabecular density throughout the limb joints. Extinct hominins, including pre-Holocene Homo sapiens, retain the high levels seen in nonhuman primates. Thus, the low trabecular density of the recent modern human skeleton evolved late in our evolutionary history, potentially resulting from increased sedentism and reliance on technological and cultural innovations.

Published

2015

13. A comparison of proximal humeral cancellous bone of great apes and humans.

Author

Scherf H, Harvati K, and Hublin JJ

Subjects

Adult, Anatomy, Comparative, Animals, Anthropology, Physical, Female, Humans, Humerus diagnostic imaging, Male, Principal Component Analysis, Tomography, X-Ray Computed, Humerus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology

Abstract

The shoulder is the most mobile joint in the primate body, and is involved in both locomotor and manipulative activities. The presumed functional sensibility of trabecular bone can offer a way of decoding the activities to which the forelimbs of fossil primates were subjected. We examine the proximal humeral trabecular architecture in a relatively closely related group of similarly sized hominids (Pongo pygmaeus, Pan troglodytes, and Homo sapiens), in order to evaluate the effect of diverging habitual motion behaviors of the shoulder complex in a coherent phylogenetic group. In order to characterize and compare the humeral trabecular architectures of the three species, we imaged a large sample by high-resolution computed tomography (HrCT) and quantified their trabecular architectures by standard bone 3D morphometric parameters. Univariate statistical analysis was performed, showing significant differences among the species. However, univariate statistics could not highlight the structural particularity in the cancellous bone of each species. A principal component analysis also showed clear separation of the three taxa and enabled a structural characterization of the humeral trabecular bone of each species. We conclude that the differences in the architectural setup of the three hominids likely reflect multiple differences in their habitual activity patterns of their shoulder joint, although individual structural features are difficult to relate to specific loading conditions., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

14. 3D geometric morphometric analysis of the proximal epiphysis of the hominoid humerus.

Author

Arias-Martorell J, Potau JM, Bello-Hellegouarch G, Pastor JF, and Pérez-Pérez A

Subjects

Adaptation, Physiological, Animals, Biological Evolution, Female, Gorilla gorilla anatomy & histology, Humans, Imaging, Three-Dimensional, Male, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Species Specificity, Epiphyses anatomy & histology, Hominidae anatomy & histology, Humerus anatomy & histology

Abstract

In this study we perform a three-dimensional geometric morphometric (3D GM) analysis of the proximal epiphysis of the humerus in extant great apes, including humans, in order to accurately describe the functional anatomical differences between these taxa. In addition, a fossil hominin specimen of Australopithecus afarensis was included in a multivariate GM analysis in order to test the potential of this methodological approach for making locomotor inferences from fossil remains. The results obtained show significant differences in proximal humeral morphology among the taxa studied, which had thus far largely remained unnoticed. Based on morphofunctional considerations, these anatomical differences can be correlated to differences in the locomotor repertoires of the taxa, thus confirming that the proximal humerus is suitable for constructing paleobiological inferences about locomotion. Modern humans display markedly divergent features, which set them apart from both the extant great apes and the fossil hominin A. afarensis. The morphology of the proximal epiphysis of the humerus of the latter more closely resembles that of the orangutans, thus suggesting that despite hindlimb adaptations to bipedalism, the forelimb of this taxon was still functionally involved in arboreal behaviors, such as climbing or suspension., (© 2012 The Authors Journal of Anatomy © 2012 Anatomical Society.)

Published

2012

15. Enamel thickness in Bornean and Sumatran orangutan dentitions.

Author

Smith TM, Kupczik K, Machanda Z, Skinner MM, and Zermeno JP

Subjects

Animals, Biological Evolution, Borneo, Dentition, Female, Indonesia, Male, Statistics, Nonparametric, Tooth, Dental Enamel anatomy & histology, Diet, Pongo abelii anatomy & histology, Pongo pygmaeus anatomy & histology

Abstract

Dental enamel thickness has received considerable attention in ecological models of the adaptive significance of primate morphology. Several authors have theorized that the degree of enamel thickness may reflect selective pressures related to the consumption of fallback foods (dietary items that may require complex processing and/or have low nutritional value) during times of preferred food scarcity. Others have speculated that enamel thickness reflects selection during mastication of foods with particular material properties (i.e., toughness and hardness). Orangutans prefer ripe fruit when available, but show interspecific and sex differences in the consumption of fallback foods (bark, leaves, and figs) and other preferred foods (certain seeds). Bornean orangutans (Pongo pygmaeus) have also been reported to masticate more mechanically demanding foods than Sumatran orangutans (Pongo abelii). To test these ecological models, we assessed two-dimensional enamel thickness in orangutan full dentitions using established histological and virtual quantification methods. No significant differences in average enamel thickness (AET) were found between species. We found significant differences in the components of enamel thickness indices between sexes, with males showing greater enamel-dentine junction lengths and dentine core areas, and thus relatively thinner enamel than females. Comparisons of individuals of known sex and species revealed a dentition-wide trend for Bornean females to show greater AET than Sumatran females. Differences between small samples of males were less evident. These data provide only limited support for ecological explanations of enamel thickness patterns within great ape genera. Future studies of dietary ecology and enamel thickness should consider sex differences more systematically., (Copyright © 2012 Wiley Periodicals, Inc.)

Published

2012

16. Functional adaptations in the forelimb muscles of non-human great apes.

Author

Myatt JP, Crompton RH, Payne-Davis RC, Vereecke EE, Isler K, Savage R, D'Août K, Günther MM, and Thorpe SK

Subjects

Analysis of Variance, Animals, Female, Forelimb physiology, Gorilla gorilla anatomy & histology, Muscle, Skeletal physiology, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Adaptation, Physiological, Forelimb anatomy & histology, Hominidae anatomy & histology, Locomotion physiology, Muscle, Skeletal anatomy & histology

Abstract

The maximum capability of a muscle can be estimated from simple measurements of muscle architecture such as muscle belly mass, fascicle length and physiological cross-sectional area. While the hindlimb anatomy of the non-human apes has been studied in some detail, a comparative study of the forelimb architecture across a number of species has never been undertaken. Here we present data from chimpanzees, bonobos, gorillas and an orangutan to ascertain if, and where, there are functional differences relating to their different locomotor repertoires and habitat usage. We employed a combination of analyses including allometric scaling and ancovas to explore the data, as the sample size was relatively small and heterogeneous (specimens of different sizes, ages and sex). Overall, subject to possible unidentified, confounding factors such as age effects, it appears that the non-human great apes in this sample (the largest assembled to date) do not vary greatly across different muscle architecture parameters, even though they perform different locomotor behaviours at different frequencies. Therefore, it currently appears that the time spent performing a particular behaviour does not necessarily impose a dominating selective influence on the soft-tissue portion of the musculoskeletal system; rather, the overall consistency of muscle architectural properties both between and within the Asian and African apes strengthens the case for the hypothesis of a possible ancient shared evolutionary origin for orthogrady under compressive and/or suspensory loading in the great apes., (© 2011 The Authors. Journal of Anatomy © 2011 Anatomical Society of Great Britain and Ireland.)

Published

2012

17. Functional anatomy and adaptation of male gorillas (Gorilla gorilla gorilla) with comparison to male orangutans (Pongo pygmaeus).

Author

Zihlman AL, McFarland RK, and Underwood CE

Subjects

Adaptation, Physiological, Animals, Biological Evolution, Biomechanical Phenomena, Body Composition, Body Weight, Dissection, Gorilla gorilla physiology, Joints anatomy & histology, Joints physiology, Locomotion, Male, Muscle Strength, Muscle, Skeletal anatomy & histology, Muscle, Skeletal physiology, Pongo pygmaeus physiology, Range of Motion, Articular, Species Specificity, Weight-Bearing, Gorilla gorilla anatomy & histology, Pongo pygmaeus anatomy & histology

Abstract

Great apes diversified during the Miocene in Old World forests. Two lineages, gorillas in Africa and orangutans in Asia, have sexual dimorphisms of super-sized males, though they presumably diverged from a smaller common ancestor. We test the hypothesis that they increased in body mass independently and convergently, and that their many postcranial differences reflect locomotor differences. Whole body dissections of five adult male gorillas and four adult male orangutans allowed quantification of body mass distribution to limb segments, of body composition (muscle, bone, skin, and fat relative to total body mass), and of muscle distribution and proportions. Results demonstrate that gorilla forelimb anatomy accommodates shoulder joint mobility for vertical climbing and reaching while maintaining joint stability during quadrupedal locomotion. The heavily muscled hind limbs are equipped for propulsion and weight-bearing over relatively stable substrates on the forest floor. In contrast, orangutan forelimb length, muscle mass, and joint construction are modified for strength and mobility in climbing, bridging, and traveling over flexible supports through the forest canopy. Muscles of hip, knee, and ankle joints provide rotational and prehensile strength essential for moving on unstable and discontinuous branches. We conclude that anatomical similarities are due to common ancestry and that differences in postcranial anatomy reflect powerful selection for divergent locomotor adaptations. These data further support the evolutionary conclusion that gorillas fall with chimpanzees and humans as part of the African hominoid radiation; orangutans are a specialized outlier., (Copyright © 2011 Wiley-Liss, Inc.)

Published

2011

18. A comparative study on testicular microstructure and relative sperm production in gorillas, chimpanzees, and orangutans.

Author

Fujii-Hanamoto H, Matsubayashi K, Nakano M, Kusunoki H, and Enomoto T

Subjects

Animals, Gorilla gorilla physiology, Leydig Cells cytology, Male, Pan troglodytes physiology, Pongo pygmaeus physiology, Seminiferous Epithelium anatomy & histology, Gorilla gorilla anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Spermatogenesis, Testis anatomy & histology

Abstract

We performed histological analyses for comparing testicular microstructure between the gorilla, chimpanzee, and orangutan. Testicular samples were obtained by autopsy or biopsy from 10 gorillas, 11 chimpanzees, and 7 orangutans from several zoos and institutes. The seminiferous epithelia were thick in the chimpanzee and orangutan but thin in the gorilla. Leydig cells in the interstitial tissue were abundant in the gorilla. The acrosomic system was extremely well developed in the orangutans. Our study reveals that the cycle of seminiferous epithelium in orangutan testis can be divided into ten stages, whereas that in human, chimpanzee, and gorilla testes can be divided into only six stages. Phylogenetic analyses of the number of divisions may indicate that the seminiferous epithelium of our common ancestor has changed since the orangutan diverged from it. Furthermore, we performed comparative analyses of testicular microstructure to estimate relative sperm production among these three animals, and proposed a new indicator (namely the spermatogenic index, SI) closely related to sperm production. The SI indicated that a chimpanzee usually produces about 223 times more sperm than a gorilla and about 14 times more than an orangutan. Our data demonstrate the significance of the SI for estimating sperm production, thus aiding our understanding of the reproductive strategy as well as testis weight and relative testis size in investigated primates., (© 2011 Wiley-Liss, Inc.)

Published

2011

19. Three-dimensional orientations of talar articular surfaces in humans and great apes.

Author

Kanamoto S, Ogihara N, and Nakatsukasa M

Subjects

Anatomy, Comparative classification, Animals, Biological Evolution, Female, Gorilla gorilla genetics, Humans, Imaging, Three-Dimensional, Locomotion, Male, Pan troglodytes genetics, Pongo pygmaeus genetics, Species Specificity, Gorilla gorilla anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Talus anatomy & histology

Abstract

The morphology of the talus prescribes relative positions and movements of the calcaneus and navicular with respect to the tibia, hence determining the overall geometry, mobility and function of the foot that mechanically interacts with environments. Clarifying the variations of the articular surface orientations of the talus in humans and extant great apes is therefore of importance in understanding the evolution of bipedal locomotion in the human lineage. The aim of this study is to clarify the three-dimensional orientations of three articular surfaces of the talus (superior, posterior calcaneal and navicular articular surfaces) by means of the newly proposed surface approximation method. Thirty-two tali in humans, chimpanzees, gorillas and orangutans were scanned using a three-dimensional noncontact digitizer, and the articular surfaces were then approximated using a paraboloid or a plane to calculate the orientations of the surfaces with respect to the body of the talus. The results quantitatively demonstrated that the superior articular surfaces in humans were relatively more parallel with the horizontal plane of the talar body, while those in apes were more medially oriented. Furthermore, the cylindrical axis defined by the shape of the posterior calcaneal articular surface was directed less anteroposteriorly in humans than in apes, in contrast to the fact that the subtalar axis is more anteroposteriorly oriented in humans. It was also demonstrated that the navicular articular surface in humans was more plantarly oriented and axially twisted. These specialized features of the human talus seem to be functionally linked to obligate bipedal locomotion. The talar morphological differences among the great apes were prominent in the mediolateral and rotational orientations of the navicular articular surfaces, possibly reflecting the degree of arboreality among the great apes.

Published

2011

20. Arboreality, terrestriality and bipedalism.

Author

Crompton RH, Sellers WI, and Thorpe SK

Subjects

Animals, Biomechanical Phenomena physiology, Hominidae physiology, Humans, Pan troglodytes physiology, Pongo pygmaeus physiology, Gait physiology, Hominidae anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Trees

Abstract

The full publication of Ardipithecus ramidus has particular importance for the origins of hominin bipedality, and strengthens the growing case for an arboreal origin. Palaeontological techniques however inevitably concentrate on details of fragmentary postcranial bones and can benefit from a whole-animal perspective. This can be provided by field studies of locomotor behaviour, which provide a real-world perspective of adaptive context, against which conclusions drawn from palaeontology and comparative osteology may be assessed and honed. Increasingly sophisticated dynamic modelling techniques, validated against experimental data for living animals, offer a different perspective where evolutionary and virtual ablation experiments, impossible for living mammals, may be run in silico, and these can analyse not only the interactions and behaviour of rigid segments but increasingly the effects of compliance, which are of crucial importance in guiding the evolution of an arboreally derived lineage.

Published

2010

21. Quantifying mental foramen position in extant hominoids and Australopithecus: implications for its use in studies of human evolution.

Author

Robinson CA and Williams FL

Subjects

Adult, Animals, Female, Gorilla gorilla anatomy & histology, Gorilla gorilla classification, Hominidae classification, Humans, Male, Multivariate Analysis, Pan paniscus anatomy & histology, Pan paniscus classification, Pan troglodytes classification, Pongo pygmaeus anatomy & histology, Pongo pygmaeus classification, Sex Characteristics, Species Specificity, Biological Evolution, Fossils, Hominidae anatomy & histology, Mandible anatomy & histology

Abstract

The location of the mental foramen on the mandibular corpus has figured prominently in debates concerning the taxonomy of fossil hominins and Gorilla gorilla. In this study we quantify the antero/posterior (A/P) position of the mental foramen across great apes, modern humans and Australopithecus. Contrary to most qualitative assessments, we find significant differences between some extant hominoid species in mental foramen A/P position supporting its potential usefulness as a character for taxonomic and phylogenetic analyses of fossil hominoids. Gorilla gorilla, particularly the eastern subspecies, with a comparatively longer dental arcade and fossil and extant hominins with reduced canines and incisors tend to exhibit more anteriorly positioned mental foramina. Conversely, Pan troglodytes exhibits more posteriorly positioned mental foramina. Variation in this character among Gorilla gorilla subspecies supports recent taxonomic assessments that separate eastern and western populations. In all taxa other than Pan troglodytes the A/P position of the mental foramen is positively allometric with respect to dental arcade length. Thus, within each of these species, specimens with longer dental arcades tend to have more posteriorly positioned mental foramina. Those species with greater sexual dimorphism in canine size and dental arcade length (i.e., Gorilla gorilla and Pongo pygmaeus) exhibit more extreme differences between smaller and larger individuals. Moreover, among great apes those individuals with greater anterior convergence of the dental arcade tend to exhibit more posteriorly positioned mental foramina. Dental arcade length, canine crown area and anterior convergence are all significantly associated with mental foramen A/P position, suggesting that these traits may influence taxonomic variation in the A/P position of the mental foramen., ((c) 2010 Wiley-Liss, Inc.)

Published

2010

22. Hominoid visual brain structure volumes and the position of the lunate sulcus.

Author

de Sousa AA, Sherwood CC, Mohlberg H, Amunts K, Schleicher A, MacLeod CE, Hof PR, Frahm H, and Zilles K

Subjects

Animals, Biological Evolution, Fossils, Geniculate Bodies anatomy & histology, Humans, Magnetic Resonance Imaging, Organ Size, Hominidae anatomy & histology, Hylobates anatomy & histology, Macaca fascicularis anatomy & histology, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Visual Cortex anatomy & histology

Abstract

It has been argued that changes in the relative sizes of visual system structures predated an increase in brain size and provide evidence of brain reorganization in hominins. However, data about the volume and anatomical limits of visual brain structures in the extant taxa phylogenetically closest to humans-the apes-remain scarce, thus complicating tests of hypotheses about evolutionary changes. Here, we analyze new volumetric data for the primary visual cortex and the lateral geniculate nucleus to determine whether or not the human brain departs from allometrically-expected patterns of brain organization. Primary visual cortex volumes were compared to lunate sulcus position in apes to investigate whether or not inferences about brain reorganization made from fossil hominin endocasts are reliable in this context. In contrast to previous studies, in which all species were relatively poorly sampled, the current study attempted to evaluate the degree of intraspecific variability by including numerous hominoid individuals (particularly Pan troglodytes and Homo sapiens). In addition, we present and compare volumetric data from three new hominoid species-Pan paniscus, Pongo pygmaeus, and Symphalangus syndactylus. These new data demonstrate that hominoid visual brain structure volumes vary more than previously appreciated. In addition, humans have relatively reduced primary visual cortex and lateral geniculate nucleus volumes as compared to allometric predictions from other hominoids. These results suggest that inferences about the position of the lunate sulcus on fossil endocasts may provide information about brain organization., (Copyright 2010 Elsevier Ltd. All rights reserved.)

Published

2010

23. Joint orientation and function in great ape and human proximal pedal phalanges.

Author

Griffin NL and Richmond BG

Subjects

Animals, Female, Gorilla gorilla physiology, Humans, Locomotion physiology, Male, Pan troglodytes physiology, Pongo pygmaeus physiology, Sex Characteristics, Toe Phalanges physiology, Gorilla gorilla anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Toe Phalanges anatomy & histology

Abstract

Previous studies have referred to the degree of dorsal canting of the base of the proximal phalanx as an indicator of human-like metatarsophalangeal joint function and thus a diagnostic trait of habitual bipedality in the fossil record. Here, we used a simple method to investigate differences in forefoot function on a finer scale. Building on Duncan et al.'s (Am J Phys Anthropol 93 [1994] 67-81) research, we tested whether dorsal canting reflects differences between sexes in locomotor behavior, whether habitual shoe wear influences dorsal canting in humans, and whether proximal joint morphology differs between rays in Pan and humans. Our results corroborate previous research in showing that humans have proximal phalanges with joint orientations that are significantly more dorsal than, but overlap with, those of great apes. We also found that male gorillas have significantly more dorsally canted second proximal phalanges than their female counterparts, while the opposite pattern between the sexes was found in Pan troglodytes. Inter-ray comparisons indicate that Pan have more dorsally canted first proximal phalanges than second proximal phalanges, while the opposite pattern was found in humans. Minimally shod humans have slightly but significantly more dorsally canted second proximal phalanges than those of habitually shod humans, indicating that phalanges of unshod humans provide the most appropriate comparative samples for analyses of early hominins. Overall, our analysis suggests that though the measurement of dorsal canting is limited in its sensitivity to certain intraspecific differences in function, phalangeal joint orientation reflects interspecific differences in joint function, with the caveat that different patterns of forefoot function during gait can involve similar articular sets of metatarsophalangeal joints.

Published

2010

24. Foraging and ranging behavior during a fallback episode: Hylobates albibarbis and Pongo pygmaeus wurmbii compared.

Author

Vogel ER, Haag L, Mitra-Setia T, van Schaik CP, and Dominy NJ

Subjects

Analysis of Variance, Animals, Cuspid anatomy & histology, Fruit anatomy & histology, Hylobates anatomy & histology, Indonesia, Molar anatomy & histology, Pongo pygmaeus anatomy & histology, Species Specificity, Appetitive Behavior physiology, Diet, Feeding Behavior, Hylobates physiology, Motor Activity physiology, Pongo pygmaeus physiology

Abstract

Periodic episodes of food scarcity may highlight the adaptive value of certain anatomical traits, particularly those that facilitate the acquisition and digestion of exigent fallback foods. To better understand the selective pressures that favored the distinctive dental and locomotor morphologies of gibbons and orangutans, we examined the foraging and ranging behavior of sympatric Hylobates albibarbis and Pongo pygmaeus wurmbii during an episode of low fruit availability at Tuanan, Kalimantan Tengah, Indonesia. We found that Hylobates ranged 0.5 km day(-1) or 33% farther than did Pongo, but the overall daily ranging of both species did not vary as fruit availability decreased by as much as 50%. Among gibbons, we observed dietary switching to fallback foods; in particular, there was a progressively greater reliance on figs, liana products, and unripe fruit. Orangutans relied heavily on unripe fruit and fracture-resistant bark and pith tissues. Despite these divergent fallback patterns, the stiffness of fruit mesocarp consumed by Hylobates and Pongo did not differ. We discuss canine and molar functional morphology with respect to dietary mechanics. Next, to contextualize these results, we discuss our findings with respect to forest structure. The rain forests of Southeast Asia have been described as having open, discontinuous canopies. Such a structure may inform our understanding of the ranging behavior and distinctive locomotion of apes in the region, namely richochetal brachiation and quadrumanous clambering. Our approach of integrating behavioral ecology with physical measures of food may be a powerful tool for understanding the functional adaptations of primates.

Published

2009

25. Beyond Gorilla and Pongo: alternative models for evaluating variation and sexual dimorphism in fossil hominoid samples.

Author

Scott JE, Schrein CM, and Kelley J

Subjects

Animals, Cuspid anatomy & histology, Dentition, Female, Male, Molar anatomy & histology, Species Specificity, Cercopithecinae anatomy & histology, Fossils, Gorilla gorilla anatomy & histology, Hominidae anatomy & histology, Pongo pygmaeus anatomy & histology, Sex Characteristics

Abstract

Sexual size dimorphism in the postcanine dentition of the late Miocene hominoid Lufengpithecus lufengensis exceeds that in Pongo pygmaeus, demonstrating that the maximum degree of molar size dimorphism in apes is not represented among the extant Hominoidea. It has not been established, however, that the molars of Pongo are more dimorphic than those of any other living primate. In this study, we used resampling-based methods to compare molar dimorphism in Gorilla, Pongo, and Lufengpithecus to that in the papionin Mandrillus leucophaeus to test two hypotheses: (1) Pongo possesses the most size-dimorphic molars among living primates and (2) molar size dimorphism in Lufengpithecus is greater than that in the most dimorphic living primates. Our results show that M. leucophaeus exceeds great apes in its overall level of dimorphism and that L. lufengensis is more dimorphic than the extant species. Using these samples, we also evaluated molar dimorphism and taxonomic composition in two other Miocene ape samples--Ouranopithecus macedoniensis from Greece, specimens of which can be sexed based on associated canines and P(3)s, and the Sivapithecus sample from Haritalyangar, India. Ouranopithecus is more dimorphic than the extant taxa but is similar to Lufengpithecus, demonstrating that the level of molar dimorphism required for the Greek fossil sample under the single-species taxonomy is not unprecedented when the comparative framework is expanded to include extinct primates. In contrast, the Haritalyangar Sivapithecus sample, if itrepresents a single species, exhibits substantially greater molar dimorphism than does Lufengpithecus. Given these results, the taxonomic status of this sample remains equivocal.

Published

2009

26. Temporal squama shape in fossil hominins: relationships to cranial shape and a determination of character polarity.

Author

Terhune CE and Deane AS

Subjects

Animals, Asian People, Black People, China, Geography, Pongo pygmaeus anatomy & histology, Humans, Character, Fossils, Hominidae anatomy & histology, Skull anatomy & histology

Abstract

In 1943, Weidenreich described the squamosal suture of Homo erectus as long, low, and simian in character and suggested that this morphology was dependent upon the correlation between the size of the calvarium and the face. Many researchers now consider this character to be diagnostic of H. erectus. The relationship between cranial size and shape and temporal squama morphology, however, is unclear, and several authors have called for detailed measurements of squamosal variation to be collected before any conclusions are drawn regarding the nature of the morphology observed in H. erectus. Thirteen fossil and extant taxa were examined to address two questions: 1) Are size and shape of the temporal squama correlated with cranial vault morphology? and 2) Is the H. erectus condition plesiomorphic? To answer these questions, measurements were collected and indices were calculated for squamosal suture height, length, and area in relation to metric variables describing cranial size and shape. A two-dimensional morphometric study was also completed using High Resolution-Polynomial Curve Fitting (HR-PCF) to investigate correlations between curvature of the squamosal suture and curvature of the cranial vault. Results of both analyses indicate that squamosal suture form is related to cranial size and shape. Furthermore, the plesiomorphic condition of the squamosal suture for hominins was identified as high and moderately arched; this condition is retained in H. erectus and is distinct from the great ape condition. It is suggested that this similarity is the result of increased cranial length without a corresponding increase in cranial height., ((c) 2008 Wiley-Liss, Inc.)

Published

2008

27. Development of the ethmoid sinus and extramural migration: the anatomical basis of this paranasal sinus.

Author

Márquez S, Tessema B, Clement PA, and Schaefer SD

Subjects

Anatomy history, Animals, Ethmoid Bone diagnostic imaging, Frontal Sinus anatomy & histology, History, 19th Century, History, 20th Century, Humans, Mammals anatomy & histology, Maxillary Sinus anatomy & histology, Nasal Cavity diagnostic imaging, Paranasal Sinus Diseases diagnostic imaging, Paranasal Sinus Diseases surgery, Pongo pygmaeus anatomy & histology, Radiography, Skull anatomy & histology, Skull diagnostic imaging, Sphenoid Sinus anatomy & histology, Ethmoid Sinus anatomy & histology, Paranasal Sinuses anatomy & histology

Abstract

Frontal and/or maxillary sinusitis frequently originates with pathologic processes of the ethmoid sinuses. This clinical association is explained by the close anatomical relationship between the frontal and maxillary sinuses and the ethmoid sinus, since developmental trajectories place the ethmoid in a strategic central position within the nasal complex. The advent of optical endoscopes has permitted improved visualization of these spaces, leading to a renaissance in intranasal sinus surgery. Advancing patient care has consequently driven the need for the proper and accurate anatomical description of the paranasal sinuses, regrettably the continuing subject of persistent confusion and ambiguity in nomenclature and terminology. Developmental tracking of the pneumatization of the ethmoid and adjacent bones, and particularly of the extramural cells of the ethmoid, helps to explain the highly variable adult morphology of the ethmoid air sinus system. To fully understand the nature and underlying biology of this sinus system, multiple approaches were employed here. These include CT imaging of living humans (n = 100), examination of dry cranial material (n = 220), fresh tissue and cadaveric anatomical dissections (n = 168), and three-dimensional volume rendering methods that allow digitizing of the spaces of the ethmoid sinus for graphical examination. Results show the ethmoid sinus to be highly variable in form and structure as well as in the quantity of air cells. The endochondral bony origin of the ethmoid sinuses leads to remarkably thin bony contours of their irregular and morphologically unique borders, making them substantially different from the other paranasal sinuses. These investigations allow development of a detailed anatomical template of this region based on observed patterns of morphological diversity, which can initially mask the underlying anatomy. For example, the frontal recess, ethmoid infundibulum, and hiatus semilunaris are key anatomical components of the ethmoid structural complex that are fully documented and explained here on the basis of the template we have developed, as well as being comprehensively illustrated. In addition, an exhaustive 2000-year literature search identified original sources of nomenclature, in order to help clarify the persistent confusions found in the literature. Modified anatomical terms are suggested to permit proper description of the ethmoid region. This clarification of nomenclature will permit better communication in addition to eliminating redundant terminology. The combination of anatomical, evolutionary, and clinical perspectives provides an important strategy for gaining insight into the complexity of these sinuses., (Copyright 2008 Wiley-Liss, Inc.)

Published

2008

28. A comparative quantitative analysis of cytoarchitecture and minicolumnar organization in Broca's area in humans and great apes.

Author

Schenker NM, Buxhoeveden DP, Blackmon WL, Amunts K, Zilles K, and Semendeferi K

Subjects

Adult, Aged, Aged, 80 and over, Animals, Female, Frontal Lobe cytology, Gorilla gorilla anatomy & histology, Humans, Male, Middle Aged, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Frontal Lobe anatomy & histology, Hominidae anatomy & histology

Abstract

Broca's area was identified in the inferior frontal gyrus of chimpanzee, bonobo, gorilla, and orangutan brains through direct cytoarchitectonic comparison with human brains. Across species, Broca's area comprises Brodmann's areas 44 and 45. We found that these areas exhibited similar cytoarchitectonic characteristics in all species examined. We analyzed the minicolumnar organization of cells in layer III of Broca's area in 11 human and 9 great ape specimens. A semiautomated method was used to analyze digitized images of histological sections stained for Nissl substance. Horizontal spacing distance and gray level index (GLI; or the area fraction occupied by cells) were quantified in all images. In contrast to area Tpt, the only cortical area for which comparative minicolumnar data have been published previously for humans and one of the great apes, we found no population-level asymmetry, for either horizontal spacing distance or GLI. Only human females exhibited a leftward asymmetry in GLI. GLI was lower in humans than in great apes (P < 0.001), allowing more space for connectivity in layer III. In humans, horizontal spacing distance was greater than in great apes but smaller relative to brain size., ((c) 2008 Wiley-Liss, Inc.)

Published

2008

29. Muscle architecture of the upper limb in the orangutan.

Author

Oishi M, Ogihara N, Endo H, and Asari M

Subjects

Animals, Elbow anatomy & histology, Wrist Joint anatomy & histology, Arm anatomy & histology, Muscle, Skeletal anatomy & histology, Pongo pygmaeus anatomy & histology

Abstract

We dissected the left upper limb of a female orangutan and systematically recorded muscle mass, fascicle length, and physiological cross-sectional area (PCSA), in order to quantitatively clarify the unique muscle architecture of the upper limb of the orangutan. Comparisons of the musculature of the dissected orangutan with corresponding published chimpanzee data demonstrated that in the orangutan, the elbow flexors, notably M. brachioradialis, tend to exhibit greater PCSAs. Moreover, the digital II-V flexors in the forearm, such as M. flexor digitorum superficialis and M. flexor digitorum profundus, tend to have smaller PCSA as a result of their relatively longer fascicles. Thus, in the orangutan, the elbow flexors demonstrate a higher potential for force production, whereas the forearm muscles allow a greater range of wrist joint mobility. The differences in the force-generating capacity in the upper limb muscles of the two species might reflect functional specialization of muscle architecture in the upper limb of the orangutan for living in arboreal environments.

Published

2008

30. Functional ecology and evolution of hominoid molar enamel thickness: Pan troglodytes schweinfurthii and Pongo pygmaeus wurmbii.

Author

Vogel ER, van Woerden JT, Lucas PW, Utami Atmoko SS, van Schaik CP, and Dominy NJ

Subjects

Anatomy, Comparative, Animals, Dental Enamel anatomy & histology, Feeding Behavior, Fruit chemistry, Hardness, Hominidae, Humans, Molar anatomy & histology, Pan troglodytes anatomy & histology, Plants chemistry, Pongo pygmaeus anatomy & histology, Biological Evolution, Dental Enamel chemistry, Ecology, Molar chemistry, Pan troglodytes physiology, Pongo pygmaeus physiology

Abstract

The divergent molar characteristics of Pan troglodytes and Pongo pygmaeus provide an instructive paradigm for examining the adaptive form-function relationship between molar enamel thickness and food hardness. Although both species exhibit a categorical preference for ripe fruit over other food objects, the thick enamel and crenulated occlusal surface of Pongo molar teeth predict a diet that is more resistant to deformation (hard) and fracture (tough) than the diet of Pan. We confirm these predictions with behavioral observations of Pan troglodytes schweinfurthii and Pongo pygmaeus wurmbii in the wild and describe the mechanical properties of foods utilized during periods when preferred foods are scarce. Such fallback foods may have exerted a selective pressure on tooth evolution, particularly molar enamel thinness, which is interpreted as a functional adaptation to seasonal folivory and a derived character trait within the hominoid clade. The thick enamel and crenulated occlusal surface of Pongo molars is interpreted as a functional adaptation to the routine consumption of relatively tough and hard foods. We discuss the implications of these interpretations for inferring the diet of hominin species, which possessed varying degrees of thick molar enamel. These data, which are among the first reported for hominoid primates, fill an important empirical void for evaluating the mechanical plausibility of putative hominin food objects.

Published

2008

31. Orrorin tugenensis femoral morphology and the evolution of hominin bipedalism.

Author

Richmond BG and Jungers WL

Subjects

Animals, Biomechanical Phenomena, Gorilla gorilla anatomy & histology, Hip anatomy & histology, Hip physiology, Humans, Kenya, Pan paniscus anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Posture, Biological Evolution, Femur anatomy & histology, Fossils, Gait, Hominidae anatomy & histology, Hominidae classification, Hominidae physiology, Walking

Abstract

Bipedalism is a key human adaptation and a defining feature of the hominin clade. Fossil femora discovered in Kenya and attributed to Orrorin tugenensis, at 6 million years ago, purportedly provide the earliest postcranial evidence of hominin bipedalism, but their functional and phylogenetic affinities are controversial. We show that the O. tugenensis femur differs from those of apes and Homo and most strongly resembles those of Australopithecus and Paranthropus, indicating that O. tugenensis was bipedal but is not more closely related to Homo than to Australopithecus. Femoral morphology indicates that O. tugenensis shared distinctive hip biomechanics with australopiths, suggesting that this complex evolved early in human evolution and persisted for almost 4 million years until modifications of the hip appeared in the late Pliocene in early Homo.

Published

2008

32. A macroscopic examination of M. biceps femoris and M. gluteus maximus in the orangutan.

Author

Kaseda M, Nakamura M, Ichihara N, Hayakawa T, and Asari M

Subjects

Animals, Hip innervation, Muscle, Skeletal innervation, Pan troglodytes anatomy & histology, Species Specificity, Thigh innervation, Hip anatomy & histology, Muscle, Skeletal anatomy & histology, Pongo pygmaeus anatomy & histology, Thigh anatomy & histology

Abstract

The musculature of the hip and thigh in the orangutan has been described previously. Anatomically, there are various descriptions among primates in those structures, in particular, the relationship between M. biceps femoris and M. gluteus maximus, their derivatives, and the muscle segment. However, a detailed innervation system to this ischiofemoral part has not been described, thus there is still uncertainty as to with which muscle it is associated. In this analysis, we examined the gross anatomy of the hip and thigh muscles of the orangutan and chimpanzee, including their innervation. Also, a comparison was made with documented data of other primates. As a result of these observations, it was found that the ischiofemoral part in the orangutan is innervated by the same sciatic nerve branch (the common peroneal nerve) as the long head of M. biceps femoris, but not by the same nerve as M. gluteus maximus. Therefore, the ischiofemoral part is appropriately considered as a part of the long head of M. biceps femoris. It appears that this morphologic feature is an adjustment to the arboreal life of the orangutan. The development of the flexor complex of the thigh is necessary for this arboreal adaptation, resulting in a unique musculature of M. biceps femoris in the orangutan.

Published

2008

33. Strong postcranial size dimorphism in Australopithecus afarensis: results from two new resampling methods for multivariate data sets with missing data.

Author

Gordon AD, Green DJ, and Richmond BG

Subjects

Animals, Anthropology, Physical, Biological Evolution, Female, Fossils, Gorilla gorilla anatomy & histology, Humans, Male, Multivariate Analysis, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Bone and Bones pathology, Hominidae anatomy & histology, Sex Characteristics, Social Behavior

Abstract

There is considerable debate over the level of size dimorphism and inferred social behavior of Australopithecus afarensis. Most previous studies have analyzed size variation in single variables or multiple variables drawn from single elements. These approaches suffer from small sample sizes, underscoring the need for new techniques that incorporate measurements from multiple unassociated elements, reducing the influence of random sampling on size variation in fossil samples. One such technique, the template method, has recently been proposed but is limited to samples with a template specimen and is sensitive to a number of assumptions. Here we present two new resampling methods that do not require a template specimen, allow measurements from multiple unassociated elements to be included in a single analysis, and allow for significance tests between comparative and fossil multivariate data sets with missing data. Using these new methods, multivariate postcranial size dimorphism is measured using eight measurements of the femur, tibia, humerus, and radius in samples of A. afarensis, modern humans, chimpanzees, gorillas, and orangutans. Postcranial dimorphism in A. afarensis is similar to that of gorillas and orangutans, and significantly greater than in modern humans and chimpanzees. Because studies in living primates have examined the association of behavior with dimorphism in body mass and craniodental measurements, not postcrania, relationships between postcranial dimorphism and social behavior must be established to make robust behavioral inferences for A. afarensis. However, the results of this and past studies strongly suggest behavioral and mating strategies differed between A. afarensis and modern humans., (2007 Wiley-Liss, Inc.)

Published

2008

34. Anthropology. Walking on trees.

Author

O'Higgins P and Elton S

Subjects

Adaptation, Biological, Animals, Biomechanical Phenomena, Ecosystem, Fossils, Hand anatomy & histology, Hand physiology, Hindlimb anatomy & histology, Hindlimb physiology, Hominidae anatomy & histology, Humans, Posture, Biological Evolution, Hominidae physiology, Locomotion, Pongo pygmaeus anatomy & histology, Pongo pygmaeus physiology, Trees, Walking

Published

2007

35. Origin of human bipedalism as an adaptation for locomotion on flexible branches.

Author

Thorpe SK, Holder RL, and Crompton RH

Subjects

Adaptation, Biological, Animals, Biomechanical Phenomena, Ecosystem, Hand anatomy & histology, Hand physiology, Hindlimb anatomy & histology, Hindlimb physiology, Humans, Pongo pygmaeus anatomy & histology, Posture, Biological Evolution, Hominidae anatomy & histology, Hominidae physiology, Locomotion, Pongo pygmaeus physiology, Trees, Walking

Abstract

Human bipedalism is commonly thought to have evolved from a quadrupedal terrestrial precursor, yet some recent paleontological evidence suggests that adaptations for bipedalism arose in an arboreal context. However, the adaptive benefit of arboreal bipedalism has been unknown. Here we show that it allows the most arboreal great ape, the orangutan, to access supports too flexible to be negotiated otherwise. Orangutans react to branch flexibility like humans running on springy tracks, by increasing knee and hip extension, whereas all other primatesdothe reverse. Human bipedalism is thus less an innovation than an exploitation of a locomotor behavior retained from the common great ape ancestor.

Published

2007

36. Gorilla-like anatomy on Australopithecus afarensis mandibles suggests Au. afarensis link to robust australopiths.

Author

Rak Y, Ginzburg A, and Geffen E

Subjects

Animals, Gorilla gorilla anatomy & histology, Humans, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Biological Evolution, Fossils, Hominidae anatomy & histology, Mandible anatomy & histology

Abstract

Mandibular ramus morphology on a recently discovered specimen of Australopithecus afarensis closely matches that of gorillas. This finding was unexpected given that chimpanzees are the closest living relatives of humans. Because modern humans, chimpanzees, orangutans, and many other primates share a ramal morphology that differs from that of gorillas, the gorilla anatomy must represent a unique condition, and its appearance in fossil hominins must represent an independently derived morphology. This particular morphology appears also in Australopithecus robustus. The presence of the morphology in both the latter and Au. afarensis and its absence in modern humans cast doubt on the role of Au. afarensis as a modern human ancestor. The ramal anatomy of the earlier Ardipithecus ramidus is virtually that of a chimpanzee, corroborating the proposed phylogenetic scenario.

Published

2007

37. The orang-utan mating system and the unflanged male: A product of increased food stress during the late Miocene and Pliocene?

Author

Harrison ME and Chivers DJ

Subjects

Animals, Asia, Southeastern, Climate, Diet, Female, Male, Pongo pygmaeus physiology, Sex Characteristics, Social Dominance, Starvation, Biological Evolution, Cheek anatomy & histology, Pongo pygmaeus anatomy & histology, Sexual Behavior, Animal physiology

Abstract

The orang-utan is unique among apes in having an unusually long male developmental period and two distinct adult male morphs (flanged and unflanged), which generally, but not exclusively, employ different reproductive strategies (call-and-wait vs. sneak-and-rape). Both morphs have recently been shown to have roughly similar levels of reproductive success in the one site where such a study has been conducted. This is in stark contrast to the unimale polygynous gorilla, in which dominant males sire almost all infants. Despite this, evidence on sexual dimorphism, life history, diet, and socioecology of extant and extinct apes, as well as the ontogeny, reproductive morphology, and physiology of extant apes, all indicate that the orang-utan's present-day mating system most likely evolved from a gorilla-like base, with one dominant male guarding a harem of females. The available evidence indicates that, due chiefly to the likely onset of the El Niño Southern Oscillation (generally regarded as the trigger for mast fruiting in dipterocarps) approximately 3-5Ma, southeast Asian forests would have begun to experience longer and more severe periods of low food availability. This change in food availability would have meant that full-time gregariousness was no longer energetically tolerable and, as a result, females dispersed more widely in search of food and adult/flanged males were no longer able to effectively guard a harem of females. A niche for a quiet, quick, opportunistic "sexual predator" (i.e., the unflanged male) then became available. This finding implies that, despite being anatomically quite chimpanzee-like, the ancestral hominoid probably had a social and mating system more similar to the gorilla than any other living ape.

Published

2007

38. Mona Lisa smile: the morphological enigma of human and great ape evolution.

Author

Grehan JR

Subjects

Animals, Female, Humans, Male, Sequence Analysis, DNA, Species Specificity, Tooth anatomy & histology, Biological Evolution, Fossils, Hominidae anatomy & histology, Hominidae classification, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology

Abstract

The science of human evolution is confronted with the popular chimpanzee theory and the earlier but largely ignored orangutan theory. The quality and scope of published documentation and verification of morphological features suggests there is very little in morphology to support a unique common ancestor for humans and chimpanzees. A close relationship between humans and African apes is currently supported by only eight unproblematic characters. The orangutan relationship is supported by about 28 well-supported characters, and it is also corroborated by the presence of orangutan-related features in early hominids. The uniquely shared morphology of humans and orangutans raises doubts about the almost universal belief that DNA sequence similarities necessarily demonstrate a closer evolutionary relationship between humans and chimpanzees. A new evolutionary reconstruction is proposed for the soft tissue anatomy, physiology, and behavioral biology of the first hominids that includes concealed ovulation, male beard and mustache, prolonged mating, extended pair-bonding, "house" construction, mechanical "genius," and artistic expression.

Published

2006

39. Morphological analysis of the hindlimb in apes and humans. II. Moment arms.

Author

Payne RC, Crompton RH, Isler K, Savage R, Vereecke EE, Günther MM, Thorpe SK, and D'Août K

Subjects

Animals, Biomechanical Phenomena, Gorilla gorilla anatomy & histology, Gorilla gorilla physiology, Humans, Hylobates anatomy & histology, Hylobates physiology, Muscle, Skeletal anatomy & histology, Muscle, Skeletal physiology, Pan paniscus anatomy & histology, Pan paniscus physiology, Pongo pygmaeus anatomy & histology, Pongo pygmaeus physiology, Posture, Hindlimb anatomy & histology, Hindlimb physiology, Locomotion physiology, Primates physiology

Abstract

Flexion/extension moment arms were obtained for the major muscles crossing the hip, knee and ankle joints in the orang-utan, gibbon, gorilla (Eastern and Western lowland) and bonobo. Moment arms varied with joint motion and were generally longer in proximal limb muscles than distal limb muscles. The shape of the moment arm curves (i.e. the plots of moment arm against joint angle) differed in different hindlimb muscles and in the same muscle in different subjects (both in the same and in different ape species). Most moment arms increased with increasing joint flexion, a finding which may be understood in the context of the employment of flexed postures by most non-human apes (except orang-utans) during both terrestrial and arboreal locomotion. When compared with humans, non-human great apes tended to have muscles better designed for moving the joints through large ranges. This was particularly true of the pedal digital flexors in orang-utans. In gibbons, the only lesser ape studied here, many of the moment arms measured were relatively short compared with those of great apes. This study was performed on a small sample of apes and thus differences noted here warrant further investigation in larger populations.

Published

2006

40. Interpretation of bootstrap values in phylogenetic analysis.

Author

Wiesemüller B and Rothe H

Subjects

Animals, Gorilla gorilla anatomy & histology, Gorilla gorilla classification, Gorilla gorilla genetics, Hominidae genetics, Humans, Male, Pan troglodytes anatomy & histology, Pan troglodytes classification, Pan troglodytes genetics, Pongo pygmaeus anatomy & histology, Pongo pygmaeus classification, Pongo pygmaeus genetics, Signal Processing, Computer-Assisted, Biological Evolution, Hominidae anatomy & histology, Hominidae classification, Phylogeny, Radiographic Image Interpretation, Computer-Assisted methods, Skull anatomy & histology, Skull diagnostic imaging

Abstract

Bootstrap Analysis is a common tool in cladistics, and consequently many authors tend to believe that it could be close to a test of monophyly. In fact, it is only a procedure to calculate the redundancy of a certain character pattern among taxa. To demonstrate this, we set up a study with questionable data: Four skulls of great apes and humans were digitally photographed, and the pixels' brightness values were simply transformed to a one-zero-matrix, which was then used to calculate a Wagner tree with PHYLIP. As a rule, the higher the resolution of the photos is, the higher are the bootstrap values of supported taxa (and the lower are the bootstrap values of non-supported data). Redundancy of intertaxic information might indeed be an indicator of phylogenetic relationship, but can also be due to other reasons, like functional-adaptive needs in morphology, or semantic needs in a DNA-code. As a result, we tend to believe that high bootstrap values are actually less important than low ones. It is safer, based on a low bootstrap value, to claim that a certain taxon is not well supported by certain data. Therefore, we recommend discussions of low bootstrap values in future publications.

Published

2006

41. Morphological analysis of the hindlimb in apes and humans. I. Muscle architecture.

Author

Payne RC, Crompton RH, Isler K, Savage R, Vereecke EE, Günther MM, Thorpe SK, and D'Août K

Subjects

Animals, Female, Gorilla gorilla anatomy & histology, Humans, Hylobates anatomy & histology, Male, Pan paniscus anatomy & histology, Pongo pygmaeus anatomy & histology, Tendons anatomy & histology, Hindlimb anatomy & histology, Locomotion physiology, Muscle, Skeletal anatomy & histology

Abstract

We present quantitative data on the hindlimb musculature of Pan paniscus, Gorilla gorilla gorilla, Gorilla gorilla graueri, Pongo pygmaeus abelii and Hylobates lar and discuss the findings in relation to the locomotor habits of each. Muscle mass and fascicle length data were obtained for all major hindlimb muscles. Physiological cross-sectional area (PCSA) was estimated. Data were normalized assuming geometric similarity to allow for comparison of animals of different size/species. Muscle mass scaled closely to (body mass)(1.0) and fascicle length scaled closely to (body mass)(0.3) in most species. However, human hindlimb muscles were heavy and had short fascicles per unit body mass when compared with non-human apes. Gibbon hindlimb anatomy shared some features with human hindlimbs that were not observed in the non-human great apes: limb circumferences tapered from proximal-to-distal, fascicle lengths were short per unit body mass and tendons were relatively long. Non-human great ape hindlimb muscles were, by contrast, characterized by long fascicles arranged in parallel, with little/no tendon of insertion. Such an arrangement of muscle architecture would be useful for locomotion in a three dimensionally complex arboreal environment.

Published

2006

42. Feeding behavior, diet, and the functional consequences of jaw form in orangutans, with implications for the evolution of Pongo.

Author

Taylor AB

Subjects

Animals, Female, Fossils, Jaw physiology, Male, Mandible anatomy & histology, Plants, Edible, Biological Evolution, Diet, Feeding Behavior physiology, Jaw anatomy & histology, Pongo pygmaeus anatomy & histology, Pongo pygmaeus physiology

Abstract

Orangutans are amongst the most craniometrically variable of the extant great apes, yet there has been no attempt to explicitly link this morphological variation with observed differences in behavioral ecology. This study explores the relationship between feeding behavior, diet, and mandibular morphology in orangutans. All orangutans prefer ripe, pulpy fruit when available. However, some populations of Bornean orangutans (Pongo pygmaeus morio and P. p. wurmbii) rely more heavily on bark and relatively tough vegetation during periods of low fruit yield than do Sumatran orangutans (Pongo abelii). I tested the hypothesis that Bornean orangutans exhibit structural features of the mandible that provide greater load resistance abilities to masticatory and incisal forces. Compared to P. abelii, P. p. morio exhibits greater load resistance abilities as reflected in a relatively deeper mandibular corpus, deeper and wider mandibular symphysis, and relatively greater condylar area. P. p. wurmbii exhibits most of these same morphologies, and in all comparisons is either comparable in jaw proportions to P. p. morio, or intermediate between P. p. morio and P. abelii. These data indicate that P. p. morio and P. p. wurmbii are better suited to resisting large and/or frequent jaw loads than P. abelii. Using these results, I evaluated mandibular morphology in P. p. pygmaeus, a Bornean orangutan population whose behavioral ecology is poorly known. Pongo p. pygmaeus generally exhibits relatively greater load resistance capabilities than P. abelii, but less than P. p. morio. These results suggest that P. p. pygmaeus may consume greater amounts of tougher and/or more obdurate foods than P. abelii, and that consumption of such foods may intensify amongst Bornean orangutan populations. Finally, data from this study are used to evaluate variation in craniomandibular morphology in Khoratpithecus piriyai, possibly the earliest relative of Pongo from the late Miocene of Thailand, and the late Pleistocene Hoa Binh subfossil orangutan recovered from Vietnam. With the exception of a relatively thicker M(3) mandibular corpus, K. piriyai has jaw proportions that would be expected for an extant orangutan of comparable jaw size. Likewise, the Hoa Binh subfossil does not differ in skull proportions from extant Pongo, independent of the effects of increase in jaw size. These results indicate that differences in skull and mandibular proportions between these fossil and subfossil orangutans and extant Pongo are allometric. Furthermore, the ability of K. piriyai to resist jaw loads appears to have been comparable to that of extant orangutans. However, the similarity in jaw proportions between P. abelii and K. piriyai suggest the latter may have been dietarily more similar to Sumatran orangutans.

Published

2006

43. Size and shape dimorphism in great ape mandibles and implications for fossil species recognition.

Author

Taylor AB

Subjects

Animals, Female, Gorilla gorilla classification, Male, Pan troglodytes classification, Phylogeny, Pongo pygmaeus classification, Skull anatomy & histology, Species Specificity, Fossils, Gorilla gorilla anatomy & histology, Mandible anatomy & histology, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Sex Characteristics

Abstract

Sexual dimorphism is an important source of morphological variation, and species differences in dimorphism may be reflected in magnitude, pattern, or both. While the extant great apes are commonly used as a reference sample for distinguishing between sexual dimorphism and intertaxic variation in the fossil record, few studies have evaluated mandibular dimorphism in these taxa. In this study, percentage, degree, and pattern of mandibular dimorphism are evaluated in Pongo, Gorilla, and Pan. Mandibular dimorphism patterns are explored to determine the extent to which such patterns accurately track great ape phylogeny. Pattern stability is assessed to determine whether there are stable patterns of mandibular size and shape dimorphism that may be usefully applied to hominoid or hominid fossil species recognition studies. Finally, the established patterns of dimorphism are used to address recent debates surrounding great ape taxonomy. Results demonstrate that mandibular dimorphism is universally expressed in size, but only Pongo and Gorilla exhibit shape dimorphism. Pattern similarity tends to be greater between subspecies of the same species than between higher-order taxa, suggesting that within the great apes, there is a relationship between dimorphism pattern and phylogeny. However, this relationship is not exact, given that dimorphism patterns are weakly correlated between some closely related taxa, while great ape subspecies may be highly correlated with taxa belonging to other species or genera. Furthermore, dimorphism patterns are not significantly correlated between great ape genera, even between Gorilla and Pan. Dimorphism patterns are more stable in Gorilla and Pongo as compared to Pan, but there is little pattern stability between species or genera. Importantly, few variables differ significantly between taxa that simultaneously show consistently relatively low levels of dimorphism and low levels of variation within taxa. Combined, these findings indicate that mandibular dimorphism patterns can and do vary considerably, even among closely related species, and suggest that it would be difficult to employ great ape mandibular dimorphism patterns for purposes of distinguishing between intra- and interspecies variation in fossil samples. Finally, the degree of pattern similarity in mandibular dimorphism is lower than previously observed by others for craniofacial dimorphism. Thus, the possibility cannot be ruled out that patterns of craniofacial dimorphism in great apes may be associated with a stronger phylogenetic signal than are patterns of mandibular dimorphism.

Published

2006

44. A 3D quantitative comparison of trapezium and trapezoid relative articular and nonarticular surface areas in modern humans and great apes.

Author

Tocheri MW, Razdan A, Williams RC, and Marzke MW

Subjects

Anatomy, Comparative methods, Animals, Body Weights and Measures methods, Gorilla gorilla anatomy & histology, Humans, Image Processing, Computer-Assisted methods, Imaging, Three-Dimensional methods, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Species Specificity, Hominidae anatomy & histology, Trapezium Bone anatomy & histology, Trapezoid Bone anatomy & histology

Abstract

The structure and functions of the modern human hand are critical components of what distinguishes Homo sapiens from the great apes (Gorilla, Pan, and Pongo). In this study, attention is focused on the trapezium and trapezoid, the two most lateral bones of the distal carpal row, in the four extant hominid genera, representing the first time they have been quantified and analyzed together as a morphological-functional complex. Our objective is to quantify the relative articular and nonarticular surface areas of these two bones and to test whether modern humans exhibit significant shape differences from the great apes, as predicted by previous qualitative analyses and the functional demands of differing manipulative and locomotor strategies. Modern humans were predicted to show larger relative first metacarpal and scaphoid surfaces on the trapezium because of the regular recruitment of the thumb during manipulative behaviors; alternatively, great apes were predicted to show larger relative second metacarpal and scaphoid surfaces on the trapezoid because of the functional demands on the hands during locomotor behaviors. Modern humans were also expected to exhibit larger relative mutual joint surfaces between the trapezoid and adjacent carpals than do the great apes because of assumed transverse loads generated by the functional demands of the modern human power grip. Using 3D bone models acquired through laser digitizing, the relative articular and nonarticular areas on each bone are quantified and compared. Multivariate analyses of these data clearly distinguish modern humans from the great apes. In total, the observed differences between modern humans and the great apes support morphological predictions based on the fact that this region of the human wrist is no longer involved in weight-bearing during locomotor behavior and is instead recruited solely for manipulative behaviors. The results provide the beginnings of a 3D comparative standard against which further extant and fossil primate wrist bones can be compared within the contexts of manipulative and locomotor behaviors.

Published

2005

45. Planum parietale of chimpanzees and orangutans: a comparative resonance of human-like planum temporale asymmetry.

Author

Gannon PJ, Kheck NM, Braun AR, and Holloway RL

Subjects

Animals, Hominidae physiology, Image Interpretation, Computer-Assisted methods, Male, Parietal Lobe physiology, Temporal Lobe physiology, Brain Mapping, Magnetic Resonance Imaging, Pan troglodytes anatomy & histology, Parietal Lobe anatomy & histology, Pongo pygmaeus anatomy & histology, Temporal Lobe anatomy & histology

Abstract

We have previously demonstrated that leftward asymmetry of the planum temporale (PT), a brain language area, was not unique to humans since a similar condition is present in great apes. Here we report on a related area in great apes, the planum parietale (PP). PP in humans has a rightward asymmetry with no correlation to the L>R PT, which indicates functional independence. The roles of the PT in human language are well known while PP is implicated in dyslexia and communication disorders. Since posterior bifurcation of the sylvian fissure (SF) is unique to humans and great apes, we used it to determine characteristics of its posterior ascending ramus, an indicator of the PP, in chimpanzee and orangutan brains. Results showed a human-like pattern of R>L PP (P = 0.04) in chimpanzees with a nonsignificant negative correlation of L>R PT vs. R>L PP (CC = -0.3; P = 0.39). In orangutans, SF anatomy is more variable, although PP was nonsignificantly R>L in three of four brains (P = 0.17). We have now demonstrated human-like hemispheric asymmetry of a second language-related brain area in great apes. Our findings persuasively support an argument for addition of a new component to the comparative neuroanatomic complex that defines brain language or polymodal communication areas. PP strengthens the evolutionary links that living great apes may offer to better understand the origins of these progressive parts of the brain. Evidence mounts for the stable expression of a neural foundation for language in species that we recently shared a common ancestor with., ((c) 2005 Wiley-Liss, Inc.)

Published

2005

46. Neural connectivity and cortical substrates of cognition in hominoids.

Author

Schenker NM, Desgouttes AM, and Semendeferi K

Subjects

Anatomy, Comparative methods, Animals, Biological Evolution, Female, Gorilla gorilla anatomy & histology, Humans, Hylobates anatomy & histology, Magnetic Resonance Imaging, Male, Organ Size, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Sex Factors, Species Specificity, Cerebral Cortex anatomy & histology, Cognition physiology, Hominidae anatomy & histology, Hominidae physiology

Abstract

Cognitive functions and information processing recruit discrete neural systems in the cortex and white matter. We tested the idea that specific regions in the cerebrum are differentially enlarged in humans and that some of the neural reorganizational events that took place during hominoid evolution were species-specific and independent of changes in absolute brain size. We used magnetic resonance images of the living brains of 10 human and 17 ape subjects to obtain volumetric estimates of regions of interest. We parcellated the white matter in the frontal and temporal lobes into two sectors, including the white matter immediately underlying the cortex (gyral white matter) and the rest of white matter (core). We outlined the dorsal, mesial, and orbital subdivisions of the frontal lobe and analyzed the relationship between cortex and gyral white matter within each subdivision. For all regions analyzed, the observed human values are as large as expected, with the exception of the gyral white matter, which is larger than expected in humans. We found that orangutans had a relatively smaller orbital sector than any other great ape species, with no overlap in individual values. We found that the relative size of the dorsal subdivision is larger in chimpanzees than in bonobos, and that the ratio of gyral white matter to cortex stands out in Pan in comparison to Gorilla and Pongo. Individual variability, possible sex differences, and hemispheric asymmetries were present not only in humans, but in apes as well. Differences in the distribution of neural connectivity and cortical sectors were identified among great ape species that share similar absolute brain sizes. Given that these regions are part of neural systems with distinct functional attributes, we suggest that the observed differences may reflect different evolutionary pressures on regulatory mechanisms of complex cognitive functions, including social cognition.

Published

2005

47. Variation in hominoid molar enamel thickness.

Author

Smith TM, Olejniczak AJ, Martin LB, and Reid DJ

Subjects

Animals, Gorilla gorilla anatomy & histology, Humans, Odontometry, Pan troglodytes anatomy & histology, Pongo pygmaeus anatomy & histology, Dental Enamel anatomy & histology, Hominidae anatomy & histology, Molar anatomy & histology

Abstract

Enamel thickness has figured prominently in discussions of hominid origins for nearly a century, although little is known about its intra-taxon variation. It has been suggested that enamel thickness increases from first to third molars, perhaps due to varying functional demands or developmental constraints, but this has not been tested with appropriate statistical methods. We quantified enamel cap area (c), dentine area (b), and enamel-dentine junction length (e) in coronal planes of sections through the mesial and distal cusps in 57 permanent molars of Pan and 59 of Pongo, and calculated average (c/e) and relative enamel thickness (([c/e]/ radicalb) * 100). Posteriorly increasing or decreasing trends in each variable and average (AET) and relative enamel thickness (RET) were tested among molars in the same row. Differences between maxillary and mandibular analogues and between mesial and distal sections of the same tooth were also examined. In mesial sections of both genera, enamel cap area significantly increased posteriorly, except in Pan maxillary sections. In distal sections of maxillary teeth, trends of decreasing dentine area were significant in both taxa, possibly due to hypocone reduction. Significant increases in AET and RET posteriorly were found in all comparisons, except for AET in Pongo distal maxillary sections. Several significant differences were found between maxillary and mandibular analogues in both taxa. Relative to their mesial counterparts, distal sections showed increased enamel cap area and/or decreased dentine area, and thus increased AET and RET. This study indicates that when AET and RET are calculated from samples of mixed molars, variability is exaggerated due to the lumping of tooth types. To maximize taxonomic discrimination using enamel thickness, tooth type and section plane should be taken into account. Nonetheless, previous findings that African apes have relatively thinner enamel than Pongo is supported for certain molar positions.

Published

2005

48. Developmental changes in the facial morphology of the Borneo orangutan (Pongo pygmaeus): possible signals in visual communication.

Author

Kuze N, Malim TP, and Kohshima S

Subjects

Age Factors, Animals, Hair anatomy & histology, Hair growth & development, Hair physiology, Malaysia, Photography, Sex Factors, Skin Physiological Phenomena, Statistics, Nonparametric, Face anatomy & histology, Pigmentation physiology, Pongo pygmaeus anatomy & histology, Pongo pygmaeus growth & development

Abstract

Orangutans display remarkable developmental changes and sexual differences in facial morphology, such as the flanges or cheek-pads that develop only on the face of dominant adult males. These changes suggest that facial morphology is an important factor in visual communication. However, developmental changes in facial morphology have not been examined in detail. We studied developmental changes in the facial morphology of the Borneo orangutan (Pongo pygmaeus) by observing 79 individuals of various ages living in the Sepilok Orangutan Rehabilitation Centre (SORC) in Malaysia and in Japanese zoos. We also analyzed photographs of one captive male that were taken over a period of more than 16 years. There were clear morphological changes that occurred with growth, and we identified previously unreported sexual and developmental differences in facial morphology. Light-colored skin around the eyes and mouth is most prominent in animals younger than 3 years, and rapidly decreases in area through the age of approximately 7 years. At the same time, the scattered, erect hairs on the head (infant hair) become thick, dense hairs lying on the head (adult hair) in both sexes. The results suggest that these features are infant signals, and that adult signals may include darkened face color, adult hair, whiskers, and a beard, which begin to develop after the age of approximately 7 years in both sexes. In females, the eyelids remain white even after 10 years, and turn black at around the age of 20; in males, the eyelids turn black before the age of 10. The whiskers and beards of adults are thicker in males than in females, and are fully developed before the age of 10 in males, while they begin to develop in females only after approximately 20 years. White eyelids and undeveloped whiskers and beards may be visual signals that are indicative of young adult females. Our results also show that the facial morphology of the unflanged male is similar to that of the adult female, although it has also been pointed out that unflanged males resemble younger individuals., (Copyright 2005 Wiley-Liss, Inc)

Published

2005

49. Ontogeny of craniofacial sexual dimorphism in the orangutan (Pongo pygmaeus). I: face and palate.

Author

Hens SM

Subjects

Animals, Face physiology, Female, Male, Palate growth & development, Pongo pygmaeus growth & development, Face anatomy & histology, Palate anatomy & histology, Pongo pygmaeus anatomy & histology, Sex Characteristics

Abstract

The orangutan is widely recognized as a highly dimorphic species. An ontogenetic approach to the study of sexual dimorphism can assist researchers in understanding both where and when these differences develop. In this study, 357 orangutans from Borneo were divided into five developmental stages representing infancy to mature adulthood. Three-dimensional (3D) coordinate data from 16 landmarks representing the face and palate were analyzed by means of a Euclidean distance matrix analysis (EDMA), a quantitative method for the comparison of forms. Three separate analyses (an age-specific static comparison of forms, a sex-specific analysis of growth trajectories, and an intersex comparison of patterns of relative growth) were carried out with the intent to describe the rate, timing, magnitude, and pattern of growth in the orangutan face and palate. The results indicate that generally males and females share a similar, but not identical, pattern of growth or local form change, but differ in growth rate, timing, and magnitude of difference. Dimorphism in the face and palate can be localized in infancy and traced throughout all age intervals. Orangutan females grow slightly faster than males from infancy to adolescence, at which time male growth exceeds female growth. Female growth ceases with the advent of adulthood, while male growth continues (i.e., both the number and magnitude of the dimorphic dimensions increase). Males and females are similar in facial dimensions and growth related to the orbits, upper face, and palate width. They maintain these similarities throughout development. However, they differ in facial and nasal height, palate length, snout projection, depth of the nasopharynx, and hafting of the face onto the skull. The face broadens and the zygomatic bone flares dramatically in adult males, corresponding to the development of cheek pads. While growth patterns are similar between the two sexes, they differ in the lateral orbit, snout projection, and hafting of the face onto the cranium. Adult dimorphism is the result of growth patterns experienced throughout life, and it is not equally expressed across the cranium. An understanding of patterns of dimorphism, along with the magnitude of difference, may be helpful for interpreting dimorphism in the fossil record., (Copyright 2005 Wiley-Liss, Inc.)

Published

2005

50. State-of-the-Art computed tomography of primate skulls--comparison of different scan-protocols.

Author

Wallner CP, Roehrer-Ertl O, and Schneider K

Subjects

Animals, Pongo pygmaeus anatomy & histology, Reproducibility of Results, Skull diagnostic imaging, Tomography, X-Ray Computed methods, Primates anatomy & histology, Skull anatomy & histology

Abstract

To evaluate the image quality of different scan-protocols on 3 different CT-scanners for data acquisition of skulls of apes and monkeys with special respect on imaging the paranasal sinuses, we compared CT image quality in 452 skulls on either the Philips "Mx8000" Multi-Slice CT, the "Aura" Spiral CT or the "T omoscanM" CT scanner. Therefore, we used sequential and volume scanning as well as different slice thickness, table feed, voltage and X-ray current intensity. Representative axial scans of the anonymized studies as well as three-dimensional reconstructions were independently analyzed by an experienced radiologist and an anthropologist, using a study protocol covering relevant anatomical findings. Low-Dose protocols at 40 mAs demonstrated an equal diagnostic value with better CT-performance due to lower overheatening of the X-ray tube in all studies. Resolution, especially in small anatomical structures, was best with multi-slice CT. On both single-slice scanners resolution was significantly better with sequential-protocols (slice 2-5 mm; feed 1:1) than with volume-protocols. Volume scans are required for 3D-reconstruction. Best 3D results were achieved with "M x8000" due to its better spatial resolution, followed by the "Aura" scanner. Multi-slice CT (MSCT) was found to be the superior method for the radiographic evaluation of small anatomical structures. However, there is no significant loss of information with thin sequential scans in LD technique on a single-slice spiral CT scanner. Volume-data aquisition is required for 3D reconstruction.

Published

2004