Metacarpal torsion in apes, humans, and early Australopithecus: implications for manipulatory abilities

Metacarpal torsion in apes, humans, and early Australopithecus: implications for manipulatory abilities

Human hands, when compared to that of apes, have a series of adaptations to facilitate manipulation. Numerous studies have shown that Australopithecus afarensis and Au. africanus display some of these adaptations, such as a longer thumb relative to the other fingers, asymmetric heads on the second a...

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Bibliographic Details
Published in:PeerJ (San Francisco, CA) Vol. 3; p. e1311
Main Author: Drapeau, Michelle S M
Format: Journal Article
Language:English
Published: United States PeerJ. Ltd 06-10-2015
PeerJ, Inc
PeerJ Inc
Subjects:
Adaptation
Anthropology
Australopithecus
Australopithecus afarensis
Australopithecus anamensis
Dimensional analysis
Evolution
Evolutionary Studies
Fingers & toes
Fossil hominids
Fossils
Hominids
Hominoid
Human
Manipulation
Metacarpal
Morphology
Paleontology
Physical anthropology
Torsion
Human
Swartkrans
A. afarensis
A. africanus
Manipulation
Australopithecus
Hominin
Metacarpal
Hominoid
Torsion
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Summary:Human hands, when compared to that of apes, have a series of adaptations to facilitate manipulation. Numerous studies have shown that Australopithecus afarensis and Au. africanus display some of these adaptations, such as a longer thumb relative to the other fingers, asymmetric heads on the second and fifth metacarpals, and orientation of the second metacarpal joints with the trapezium and capitate away from the sagittal plane, while lacking others such as a very mobile fifth metacarpal, a styloid process on the third, and a flatter metacarpo-trapezium articulation, suggesting some adaptation to manipulation but more limited than in humans. This paper explores variation in metacarpal torsion, a trait said to enhance manipulation, in humans, apes, early australopithecines and specimens from Swartkrans. This study shows that humans are different from large apes in torsion of the third and fourth metacarpals. Humans are also characterized by wedge-shaped bases of the third and fourth metacarpals, making the metacarpal-base row very arched mediolaterally and placing the ulnar-most metacarpals in a position that facilitate opposition to the thumb in power or cradle grips. The third and fourth metacarpals of Au. afarensis are very human-like, suggesting that the medial palm was already well adapted for these kinds of grips in that taxon. Au. africanus present a less clear human-like morphology, suggesting, perhaps, that the medial palm was less suited to human-like manipulation in that taxa than in Au. afarensis. Overall, this study supports previous studies on Au. afarensis and Au. africanus that these taxa had derived hand morphology with some adaptation to human-like power and precision grips and support the hypothesis that dexterous hands largely predated Homo.
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ISSN:2167-8359
2167-8359
DOI:10.7717/peerj.1311