Modern three-dimensional digital methods for studying locomotor biomechanics in tetrapods

Demuth, Oliver E.; Herbst, Eva C.; Polet, Delyle T.; Wiseman, Ashleigh L. A.; Hutchinson, John R.

doi:10.1242/jeb.245132

Cited by 13 publications

(7 citation statements)

References 163 publications

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“…As mobility and functional centre account for differences in axial mobility across the joint globe, they are more suitable for comparing joint ROM and distinguishing function across locomotor groups. This highlights the need for a 3D approach in characterizing primate GH function [ 51 ].…”

Section: Discussionmentioning

confidence: 99%

A comparative approach for characterizing the relationship among morphology, range-of-motion and locomotor behaviour in the primate shoulder

Lee,

Young,

Rainbow

2023

Proc. R. Soc. B.

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Shoulder shape directly impacts forelimb function by contributing to glenohumeral (GH) range-of-motion (ROM). However, identifying traits that contribute most to ROM and visualizing how they do so remains challenging, ultimately limiting our ability to reconstruct function and behaviour in fossil species. To address these limitations, we developed an in silico proximity-driven model to simulate and visualize three-dimensional (3D) GH rotations in living primate species with diverse locomotor profiles, identify those shapes that are most predictive of ROM using geometric morphometrics, and apply subsequent insights to interpret function and behaviour in the fossil hominin Australopithecus sediba . We found that ROM metrics that incorporated 3D rotations best discriminated locomotor groups, and the magnitude of ROM (mobility) was decoupled from the anatomical location of ROM (e.g. high abduction versus low abduction). Morphological traits that enhanced mobility were decoupled from those that enabled overhead positions, and all non-human apes possessed the latter but not necessarily the former. Model simulation in A. sediba predicted high mobility and a ROM centred at lower abduction levels than in living apes but higher than in modern humans. Together these results identify novel form-to-function relationships in the shoulder and enhance visualization tools to reconstruct past function and behaviour.

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Section: Discussionmentioning

confidence: 99%

A comparative approach for characterizing the relationship among morphology, range-of-motion and locomotor behaviour in the primate shoulder

Lee,

Young,

Rainbow

2023

Proc. R. Soc. B.

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“…One would think that our toolbox to study terrestrial locomotion is well-developed and sophisticated (Demuth et al, 2023;McHenry and Hedrick, 2023). After all, locomotion has been intriguing people for hundreds, thousands, maybe tens of thousands of years.…”

Section: Which Analytical Tools Do We Have?mentioning

confidence: 99%

Methodological Advances in Studying Postnatal Locomotor Development

Mielke¹

2023

Preprint

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We study piglet locomotion, attempting to falsify a difference that is due to birth weight category.This requires a methodological foundation on topics unfamiliar to most Biologists (Fourier Analysis, probabilistic models), which I introduce in dedicated chapters._Part I: Kinematic Analysis_+ I will introduce Fourier Methods with a practical guide and review its occurrence specifically in the field of locomotor biomechanics (Ch. 2).+ The power of Fourier tools is then unleashed onto a large cross-species study that covers most of the ungulate clade (Ch. 3, Mielke et al., 2019)._Part II: Probabilistic Modeling_+ Processing complex kinematic data, I will introduce the basics of probabilistic modeling (Ch. 4) in a "tiny textbook of statistics"...+ ... before turning around the conventional modeling strategy and applying it to piglets (Ch. 5, Mielke et al., 2023)._Part III: Dynamics_+ Kinematics are just half of locomotor research: the study of forces and moments is reviewed and summarized in another overview chapter (Ch. 6).+ To calculate joint moments, one needs to measure inertial properties, yet it turns out that these are not trivial to retrieve from x-ray tomographic images (Ch. 7).The thesis closes with a general discussion to round up and project the presented work to potential future applications (Ch. 8).

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“…Such simulations have even been used to predict optimal muscle behaviour in novel conditions, without performing any experiment (DeMers et al, 2017;Dorn et al, 2015;Ong et al, 2016). Similar models and simulations have also been made and analysed for a variety of other land vertebrates (Bishop, Michel, et al, 2021;Heers et al, 2018;Lerner et al, 2015;Schaffelhofer et al, 2015; see Demuth et al, 2023). In horses, biomechanical models have been used to estimate forces at the joints, muscles, tendons and ligaments during walking, trotting, galloping and jumping, at speeds up to 18 m s −1 (65 km h −1 ), and the results of these simulations overall are relatively consistent with experimental data (e.g.…”

Section: Introductionmentioning

confidence: 99%

Estimation of the forces exerted on the limb long bones of a white rhinoceros (Ceratotherium simum) using musculoskeletal modelling and simulation

Etienne,

Houssaye,

Fagan

et al. 2024

Journal of Anatomy

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Heavy animals incur large forces on their limb bones, due to the transmission of body weight and ground reaction forces, and the contractions of the various muscles of the limbs. This is particularly true for rhinoceroses, the heaviest extant animals capable of galloping. Several studies have examined their musculoskeletal system and the forces their bones incur, but no detailed quantification has ever been attempted. Such quantification could help understand better the link between form and function in giant land animals. Here we constructed three‐dimensional musculoskeletal models of the forelimb and hindlimb of Ceratotherium simum, the heaviest extant rhino species, and used static optimisation (inverse) simulations to estimate the forces applied on the bones when standing at rest, including magnitudes and directions. Overall, unsurprisingly, the most active muscles were antigravity muscles, which generate moments opposing body weight (thereby incurring the ground reaction force), and thus keep the joints extended, avoiding joint collapse via flexion. Some muscles have an antigravity action around several joints, and thus were found to be highly active, likely specialised in body weight support (ulnaris lateralis; digital flexors). The humerus was subjected to the greatest amount of forces in terms of total magnitude; forces on the humerus furthermore came from a great variety of directions. The radius was mainly subject to high‐magnitude compressive joint reaction forces, but to little muscular tension, whereas the opposite pattern was observed for the ulna. The femur had a pattern similar to that of the humerus, and the tibia's pattern was intermediate, being subject to great compression in its caudal side but to great tension in its cranial side (i.e. bending). The fibula was subject to by far the lowest force magnitude. Overall, the forces estimated were consistent with the documented morphofunctional adaptations of C. simum's long bones, which have larger insertion areas for several muscles and a greater robusticity overall than those of lighter rhinos, likely reflecting the intense forces we estimated here. Our estimates of muscle and bone (joint) loading regimes for this giant tetrapod improve the understanding of the links between form and function in supportive tissues and could be extended to other aspects of bone morphology, such as microanatomy.

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Modern three-dimensional digital methods for studying locomotor biomechanics in tetrapods

Cited by 13 publications

References 163 publications

A comparative approach for characterizing the relationship among morphology, range-of-motion and locomotor behaviour in the primate shoulder

A comparative approach for characterizing the relationship among morphology, range-of-motion and locomotor behaviour in the primate shoulder

Methodological Advances in Studying Postnatal Locomotor Development

Estimation of the forces exerted on the limb long bones of a white rhinoceros (Ceratotherium simum) using musculoskeletal modelling and simulation

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