Your search keyword '"Antoine Mudakikwa"' showing total 2 results

1. Body mass estimation in hominoids: Age and locomotor effects

Author

Antoine Mudakikwa, Christopher B. Ruff, Shannon C. McFarlin, Michael R. Cranfield, and M. Loring Burgess

Subjects

0106 biological sciences, Male, Gorilla, Hylobatidae, Body weight, 010603 evolutionary biology, 01 natural sciences, Distal femur, biology.animal, medicine, Animals, 0601 history and archaeology, Humerus, Femur, Ecology, Evolution, Behavior and Systematics, Estimation, 060101 anthropology, biology, Tibia, Body Weight, Age Factors, Hominidae, 06 humanities and the arts, Anatomy, Regression, medicine.anatomical_structure, Reference sample, Anthropology, Female, Allometry, Locomotion

Abstract

While there are a number of methods available for estimation of body mass in adult nonhuman primates, very few are available for juveniles, despite the potential utility of such estimations in both analyses of fossils and in museum collection based research. Furthermore, because of possible scaling differences, adult based body mass estimation equations may not be appropriate for non-adults. In this study, we present new body mass estimation equations for both adult and immature nonhuman hominoids based on joint and metaphyseal dimensions. Articular breadths of the proximal and distal femur, distal humerus and tibial plateau, and metaphyseal breadths of the distal femur and humerus were collected on a reference sample of 159 wild Pan , Gorilla , Pongo , Hylobates , and Symphalangus specimens of known body mass from museum and research collections. Scaling of dimensions with body weight was assessed in both the adult and the ontogenetic sample at several taxonomic levels using reduced major axis regression, followed by regression of each dimension against body mass to generate body mass estimation equations. Joint dimensions were found to be good predictors of body mass in both adult and immature hominoids, with percent prediction errors of 10–20%. However, subtle scaling differences between taxa impacted body mass estimation, suggesting that phylogeny and locomotor effects should be considered when selecting reference samples. Unlike patterns of joint growth in humans, there was little conclusive evidence for consistently larger joints relative to body mass in the non-adult sample. Metaphyseal breadths were strong predictors of body mass and, with some exceptions, gave more precise body mass estimates for non-adults than epiphyseal breadths.

Published

2016

2. Ontogenetic changes in limb bone structural proportions in mountain gorillas (Gorilla beringei beringei)

Author

Antoine Mudakikwa, Shannon C. McFarlin, Christopher B. Ruff, Timothy G. Bromage, and M. Loring Burgess

Subjects

Male, Arboreal locomotion, animal structures, Mountain gorilla, Zoology, Gorilla, Motor Activity, Arm Bones, Western lowland gorilla, Quadrupedalism, biology.animal, medicine, Juvenile, Animals, Leg Bones, Ecology, Evolution, Behavior and Systematics, Gorilla gorilla, biology, Ecology, Rwanda, fictional_universe, fictional_universe.character_species, biology.organism_classification, Biological Evolution, medicine.anatomical_structure, Anthropology, Climbing, Female, Diaphyses, Forelimb

Abstract

Behavioral studies indicate that adult mountain gorillas (Gorilla beringei) are the most terrestrial of all nonhuman hominoids, but that infant mountain gorillas are much more arboreal. Here we examine ontogenetic changes in diaphyseal strength and length of the femur, tibia, humerus, radius, and ulna in 30 Virunga mountain gorillas, including 18 immature specimens and 12 adults. Comparisons are also made with 14 adult western lowland gorillas (Gorilla gorilla gorilla), which are known to be more arboreal than adult mountain gorillas. Infant mountain gorillas have significantly stronger forelimbs relative to hind limbs than older juveniles and adults, but are nonsignificantly different from western lowland gorilla adults. The change in inter-limb strength proportions is abrupt at about two years of age, corresponding to the documented transition to committed terrestrial quadrupedalism in mountain gorillas. The one exception is the ulna, which shows a gradual increase in strength relative to the radius and other long bones during development, possibly corresponding to the gradual adoption of stereotypical fully pronated knuckle-walking in older juvenile gorillas. Inter-limb bone length proportions show a contrasting developmental pattern, with hind limb/forelimb length declining rapidly from birth to five months of age, and then showing no consistent change through adulthood. The very early change in length proportions, prior to significant independent locomotion, may be related to the need for relatively long forelimbs for climbing in a large-bodied hominoid. Virunga mountain gorilla older juveniles and adults have equal or longer forelimb relative to hind limb bones than western lowland adults. These findings indicate that both ontogenetically and among closely related species of Gorilla, long bone strength proportions better reflect actual locomotor behavior than bone length proportions.

Published

2013