Characterizing the body morphology of the first metacarpal in the Homininae using <scp>3D</scp> geometric morphometrics

Morley, Jonathan; Bucchi, Ana; Lorenzo, Carlos; Püschel, Thomas A.

doi:10.1002/ajpa.24473

Cited by 3 publications

(8 citation statements)

References 71 publications

(134 reference statements)

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“…Given the high external and muscular forces incurred by the modern H. sapiens Mc1 (Cooney & Chao, 1977; Rolian et al, 2011), it is surprising that H. sapiens do not also show a distal extension of trabeculae within the medullary cavity. However, the distinct absence of medullary trabeculae in humans may be due to the concentrated trabecular distribution in regions of habitual loading (D'Agostino et al, 2017; Dunmore, Bardo, et al, 2020; Figures 3–6), robust external shape and cortical structure (Bowland et al, 2021; Dunmore, Skinner, et al, 2020; Galletta et al, 2019; Marchi et al, 2017; Marzke et al, 2010; Morley et al, 2022; Wong et al, 2018; Figure S7), as well as other soft tissue adaptations for manipulation (Marzke, 2013; van Leeuwen et al, 2018). That is, other H. sapiens Mc1 morphology may make medullary trabeculae unnecessary for the efficient resistance of incurred loads.…”

Section: Discussionmentioning

confidence: 99%

“…As the present study is focused on internal bone structure within the volume of the Mc1, rather than the external morphology as in previous studies (Bowland et al, 2021; Galletta et al, 2019; Morley et al, 2022), boundaries between each of the three segments were defined on the canonical trabecular volume created by cHMA to ensure geometrically homologous volumes required for analysis (Bachmann et al, 2022). The boundary between the medullary cavity and the head was defined as a plane orthogonal to the proximo‐distal axis of the volume, where the edges of the trabecular volume are no longer convex in dorsal view and just beneath the most proximal aspect of the dorso‐radial epicondyle on the canonical trabecular volume.…”

Section: Methodsmentioning

confidence: 99%

“…The shape of the human Mc1 diaphysis has also been argued to aid in the dissipation of large forces incurred by the human thumb during manipulation or tool‐use, as it is more robust than in most other extant hominids (Hamrick & Inouye, 1995; Niewoehner, 2006; Rolian et al, 2011; Tocheri, Orr, Jacofsky, & Marzke, 2008b). The term robust, however, has been variously used to refer to the radio‐ulnar width of the Mc1, the development of the distal epicondyles, the development of the entheses, or some combination of these (Bowland et al, 2021; Hamrick & Inouye, 1995; Morley et al, 2022; Susman, 1994). Overlap in the radio‐ulnar width of the Mc1 between modern humans and gorillas, complicates our understanding of the potential manipulative or technological pressures that may have selected for it in human evolution (Bowland et al, 2021; Hamrick & Inouye, 1995; Morley et al, 2022; Susman, 1994).…”

Section: Introductionmentioning

confidence: 99%

“…The term robust, however, has been variously used to refer to the radio‐ulnar width of the Mc1, the development of the distal epicondyles, the development of the entheses, or some combination of these (Bowland et al, 2021; Hamrick & Inouye, 1995; Morley et al, 2022; Susman, 1994). Overlap in the radio‐ulnar width of the Mc1 between modern humans and gorillas, complicates our understanding of the potential manipulative or technological pressures that may have selected for it in human evolution (Bowland et al, 2021; Hamrick & Inouye, 1995; Morley et al, 2022; Susman, 1994). This radio‐ulnar width of the Mc1 diaphysis is also highly dependent on the disto‐radial flange (sometimes also referred to as a crest or ridge), which is a linear ridge of bone on the radial margin of the Mc1 diaphysis that is thought to provide greater surface area for the m. opponens pollicis (OP) insertion (Bowland et al, 2021;Karakostis et al, 2021; Maki & Trinkaus, 2011).…”

Section: Introductionmentioning

confidence: 99%

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The deep trabecular structure of first metacarpals in extant hominids

Dunmore

Bachmann

Synek

et al. 2023

American Journal of Biological Anthropology

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ObjectivesRecent studies have associated subarticular trabecular bone distribution in the extant hominid first metacarpal (Mc1) with observed thumb use, to infer fossil hominin thumb use. Here, we analyze the entire Mc1 to test for interspecific differences in: (1) the absolute volume of trabecular volume fraction, (2) the distribution of the deeper trabecular network, and (3) the distribution of trabeculae in the medullary cavity, especially beneath the Mc1 disto‐radial flange.Materials and MethodsTrabecular bone was imaged using micro‐computed tomography in a sample of Homo sapiens (n = 11), Pan paniscus (n = 10), Pan troglodytes (n = 11), Gorilla gorilla (n = 10) and Pongo sp., (n = 7). Using Canonical Holistic Morphometric Analysis (cHMA), we tested for interspecific differences in the trabecular bone volume fraction (BV/TV) and its relative distribution (rBV/TV) throughout the Mc1, including within the head, medullary cavity, and base.ResultsP. paniscus had the highest, and H. sapiens the lowest, BV/TV relative to other species. rBV/TV distribution statistically distinguished the radial concentrations and lack of medullary trabecular bone in the H. sapiens Mc1 from all other hominids. H. sapiens and, to a lesser extent, G. gorilla also had a significantly higher trabecular volume beneath the disto‐radial flange relative to other hominids.DiscussionThese results are consistent with differences in observed thumb use in these species and may also reflect systemic differences in bone volume fraction. The trabecular bone extension into the medullary cavity and concentrations beneath the disto‐radial flange may represent crucial biomechanical signals that will aid in the inference of fossil hominin thumb use.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The deep trabecular structure of first metacarpals in extant hominids

Dunmore

Bachmann

Synek

et al. 2023

American Journal of Biological Anthropology

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“…The concavo‐convex curvature of the TMc joint as well as the complexity of radiocarpal articulations, in which the trapezium articulates with the scaphoid (or os centrale), trapezoid, and capitate, makes this anatomical region challenging to quantify using traditional linear measurements. Three‐dimensional approaches have recently been applied to the TMc joint (Marzke et al, 2010; Tocheri, 2007), the radiocarpal articulations (Orr et al, 2010; Tocheri et al, 2003, 2005), the Mc1's trapezium surface alone (Marchi et al, 2017; Niewoehner, 2005), the non‐articular Mc1 body alone (Bowland et al, 2021; Morley et al, 2022), the distal (phalangeal) Mc1 surface alone (Galletta et al, 2019), and the overall shape of the Mc1 including a focus of its entheses (Kunze et al, 2022). For example, using mathematical modeling, Marzke et al (2010) quantified variation in the 3D curvature of both surfaces of the TMc saddle‐shaped joint, showing that the human joint surfaces are flatter, both dorsopalmarly and radioulnarly, than in other extant hominids.…”

Section: Introductionmentioning

confidence: 99%

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

Bardo

Dunmore

Cornette

et al. 2023

American Journal of Biological Anthropology

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ObjectivesThe 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 MethodsWe 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.ResultsSignificant 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.DiscussionOur 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.

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