Basicranial flexion, relative brain size, and facial kyphosis in nonhuman primates

Ross, Callum F.; Ravosa, Matthew J.

doi:10.1002/ajpa.1330910306

Cited by 253 publications

(391 citation statements)

References 38 publications

(38 reference statements)

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“…the chondrocranium plays a key integrative role in craniofacial development and evolution in genus Homo (Moss and Young, 1960;Enlow, 1990;Ross and Ravosa, 1993;Lieberman et al, 2000;McCarthy and Lieberman, 2001;Spoor, 2002, 2004;Bastir et al, , 2010Lieberman et al, 2008), the influence of the nasal septum, as one component of the chondrocranium, has not been as widely considered. There is, nevertheless, fossil evidence to suggest that an integrated nasal septal/premaxillary complex may account for variation in facial size between archaic and recent modern humans as Neandertal and recent human subadults exhibit taxonomic variation in the timing of premaxillary suture fusion.…”

Section: Discussionmentioning

confidence: 99%

“…A variety of ultimate causal mechanisms have been proposed to account for this evolutionary dynamic (see Lieberman, 2008); however, our ability to test hypotheses regarding morphological change in Homo relies on our understanding of the proximate causal mechanisms that underlie phenotypic variation in fossil forms. To this end, the development and integration of the chondrocranium has been a primary focus in detailing developmental (i.e., proximate) changes upon which evolutionary (i.e., ultimate) mechanisms operate (Moss and Young, 1960;Enlow, 1990;Ross and Ravosa, 1993;Lieberman et al, 2000;McCarthy and Lieberman, 2001;Spoor, 2002, 2004;Lieberman et al, 2008).…”

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confidence: 99%

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Nasal Septal and Premaxillary Developmental Integration: Implications for Facial Reduction in Homo

Holton

Franciscus

Marshall

et al. 2010

The Anatomical Record

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The influence of the chondrocranium in craniofacial development and its role in the reduction of facial size and projection in the genus Homo is incompletely understood. As one component of the chondrocranium, the nasal septum has been argued to play a significant role in human midfacial growth, particularly with respect to its interaction with the premaxilla during prenatal and early postnatal development. Thus, understanding the precise role of nasal septal growth on the facial skeleton is potentially informative with respect to the evolutionary change in craniofacial form. In this study, we assessed the integrative effects of the nasal septum and premaxilla by experimentally reducing facial length in Sus scrofa via circummaxillary suture fixation. Following from the nasal septal-traction model, we tested the following hypotheses: (1) facial growth restriction produces no change in nasal septum length; and (2) restriction of facial length produces compensatory premaxillary growth due to continued nasal septal growth. With respect to hypothesis 1, we found no significant differences in septum length (using the vomer as a proxy) in our experimental (n ¼ 10), control (n ¼ 9) and surgical sham (n ¼ 9) trial groups. With respect to hypothesis 2, the experimental group exhibited a significant increase in premaxilla length. Our hypotheses were further supported by multivariate geometric morphometric analysis and support an integrative relationship between the nasal septum and premaxilla. Thus, continued assessment of the growth and integration of the nasal septum and premaxilla is potentially informative regarding the complex developmental mechanisms that underlie facial reduction in genus Homo evolution. Anat Rec, 294:68-78, 2011. V V C 2010 Wiley-Liss, Inc.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Nasal Septal and Premaxillary Developmental Integration: Implications for Facial Reduction in Homo

Holton

Franciscus

Marshall

et al. 2010

The Anatomical Record

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“…The hypothesis suggests that the apparently derived modern human basicranium resulted from an overall geometric rearrangement of the skull to house successive phylogenetic increases in brain size given the same, or a relatively shorter length of cranial base. This suggestion has been substantiated by numerous studies of cranial base flexion and relative brain size across extant adult primates, and consequently spatial-packing has now become an established concept (Ross and Ravosa, 1993;Ross and Henneberg, 1995;Spoor, 1997;Lieberman et al, 2000;McCarthy, 2001). Nevertheless, despite all these corroborating interspecific findings, we still know little about the structural interplay between the primate brain and skull during ontogeny.…”

Section: Introductionmentioning

confidence: 99%

“…The above idea derives from hypotheses used to explain evolutionary changes and interspecific differences in the primate cranial base, typically with regard to the varied mechanical demands imposed by differences of posture, mastication, vocalization and brain size (see extensive reviews in Ross and Ravosa, 1993;Ross and Henneberg, 1995;Spoor, 1997;Lieberman and McCarthy, 1999;Strait and Ross, 1999;Lieberman et al, 2000;McCarthy and Lieberman, 2001;Jeffery and Spoor, 2002). These works have given useful insights into the evolutionary mechanisms responsible for the emergence of cranial features unique to Homo sapiens.…”

Section: Introductionmentioning

confidence: 99%

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Brain expansion and comparative prenatal ontogeny of the non-hominoid primate cranial base

Jeffery

2003

Journal of Human Evolution

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The basicranium is the keystone of the primate skull, and understanding its morphological interdependence on surrounding soft-tissue structures, such as the brain, can reveal important mechanisms of skull development and evolution. In particular, several extensive investigations have shown that, across extant adult primates, the degree of basicranial flexion and petrous orientation are closely linked to increases in brain size relative to cranial base length. The aim of this study was to determine if an equivalent link exists during prenatal life. Specific hypotheses tested included the idea that increases in relative endocranial size (IRE5), relative infratentorial size (RIE), and differential encephalization (IDE) determine the degree of basicranial flexion and coronal petrous reorientation during nonhominoid primate fetal development. Cross-sectional fetal samples of Alouatta caraya (n=17) and Macaca nemestrina (n=24) were imaged using high-resolution magnetic resonance imaging (hrMRI). Cranial base angles (CBA), petrous orientations (IPA), base lengths, and endocranial volumes were measured from the images. Findings for both samples showed retroflexion, or flattening, of the cranial base and coronal petrous reorientation as well as considerable increases in absolute and relative brain sizes. Although significant correlations of both IRE5 and RIE were observed against CBA and IPA, the correlation with CBA was in the opposite direction to that predicted by the hypotheses. Variations of IDE were not significantly correlated with either angle. Correlations of IPA with IRE5 and RIE appeared to support the hypotheses. However, partial coefficients computed for all significant correlations indicated that changes to the fetal non-hominoid primate cranial base were more closely related to increases in body size than the hypothesized influence of relative brain enlargement. These findings were discussed together with those from a previous study of modern human fetuses.

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Comparative review of the human bony labyrinth

Spoor¹,

Zonneveld²

1998

Am. J. Phys. Anthropol.

178

150

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The bony labyrinth inside the petrous part of the temporal bone houses the organs of hearing and balance. Being functionally linked with sensory control of body movements and located in a part of the basicranium that is closely associated with the brain, this structure is of great interest in the study of human evolutionary history. However, few aspects of its morphology have been studied in nonhuman primates. This review compares the bony labyrinth of humans with that of the great apes and 37 other primate species based on data newly acquired with computed tomography combined with previous descriptions. With body mass taken into account, consistent differences are found between the size of the semicircular canals in humans, the great apes, and other primates. In particular, the arcs of the anterior and posterior canals are larger in humans than in the African apes. The functional implications of semicircular canal dimensions for registering angular head motion are evaluated in relation to locomotor behavior. Biophysical models, comparative studies, and some neurophysiological experiments all support a link between semicircular canal size and agility, or more specifically the frequency contents of natural head movements, but the evidence on the exact nature of this link is ambiguous. It is concluded that any link between the characteristic dimensions of the human canals and locomotion will be more complex than a simple association with the broad categories of quadrupedal vs. bipedal behavior. The functionally important planar orientations of the semicircular canals are similar in humans and the African apes as well as in many other species. In contrast, other aspects of the human labyrinth differ markedly in shape, following a pattern that seems to reflect the characteristic architecture of the human basicranium. Indeed, it is found that labyrinthine and basicranial shape are interspecifically correlated in the sample, and in most respects the human morphology is consistent with the general trend among primate species. Differences in brain growth and development are proposed as the predominant factor underlying both the unique shape of the human labyrinth as well as the interspecific labyrintho-basicranial correlations.

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Basicranial flexion, relative brain size, and facial kyphosis in nonhuman primates

Cited by 253 publications

References 38 publications

Nasal Septal and Premaxillary Developmental Integration: Implications for Facial Reduction in Homo

Nasal Septal and Premaxillary Developmental Integration: Implications for Facial Reduction in Homo

Brain expansion and comparative prenatal ontogeny of the non-hominoid primate cranial base

Comparative review of the human bony labyrinth

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