Abstract
The morphology of trabecular bone has proven sensitive to loading patterns in the long bones and metacarpal heads of primates. It is expected that we should also see differences in the manual digits of primates that practice different methods of locomotion. Primate proximal and middle phalanges are load-bearing elements that are held in different postures and experience different mechanical strains during suspension, quadrupedalism, and knuckle walking. Micro CT scans of the middle phalanx, proximal phalanx and the metacarpal head of the third ray were used to examine the pattern of trabecular orientation in Pan, Gorilla, Pongo, Hylobates and Macaca. Several zones, i.e., the proximal ends of both phalanges and the metacarpal heads, were capable of distinguishing between knuckle-walking, quadrupedal, and suspensory primates. Orientation and shape seem to be the primary distinguishing factors but differences in bone volume, isotropy index, and degree of anisotropy were seen across included taxa. Suspensory primates show primarily proximodistal alignment in all zones, and quadrupeds more palmar-dorsal orientation in several zones. Knuckle walkers are characterized by having proximodistal alignment in the proximal ends of the phalanges and a palmar-dorsal alignment in the distal ends and metacarpal heads. These structural differences may be used to infer locmotor propensities of extinct primate taxa.
Highlights
Living bone is a dynamic tissue that functionally adapts in response to mechanical loading
This paper examines the trabecular structure of the proximal and distal ends of manual middle and proximal phalanges and the metacarpal heads
Orangutans are characterized by more proximodistal alignment in all locations
Summary
Living bone is a dynamic tissue that functionally adapts in response to mechanical loading. The initial mathematical tenants of Wolff’s law have been discredited, the ability of trabecular bone to align along a functional axis has been revealed in several empirical studies [1,2,3,4,5,6,7,8]. The majority of these studies seek to explore possible trabecular bone alignment differences in animals that use different locomotor and/or positional behaviors. Trabecular bone is more porous than cortical bone; a feature that allows for greater surface area and increased cellular components [3] This increase in cells enables trabecular bone to be more
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