Factors affecting the compliance and sway properties of tree branches used by the Sumatran orangutan (Pongo abelii)

• Published in: PloS one Vol. 8; no. 7; p. e67877
• Main Authors: van Casteren, Adam, Sellers, William I, Thorpe, Susannah K S, Coward, Sam, Crompton, Robin H, Ennos, A Roland
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 02.07.2013; Public Library of Science (PLoS)
• Subjects: Adaptation, Physiological - physiology; Algorithms; Animal behavior; Animal locomotion; Animals; Biology; Biomechanics; Body Weight - physiology; Branches; Ecology; Ecosystem; Evolution; Female; Inhabitants; Life sciences; Male; Mechanical properties; Models, Biological; Monkeys & apes; Multivariate analysis; Orangutans; Physical anthropology; Pongo abelii; Pongo abelii - physiology; Pongo pygmaeus; Rain forests; Rainforests; Social and Behavioral Sciences; Stability; Stress, Mechanical; Time Factors; Trees; Trees - anatomy & histology; Trees - physiology; Tropical Climate
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0067877

The tropical arboreal environment is a mechanically complex and varied habitat. Arboreal inhabitants must adapt to changes in the compliance and stability of supports when moving around trees. Because the orangutan is the largest habitual arboreal inhabitant, it is unusually susceptible to branch compliance and stability and therefore represents a unique animal model to help investigate how animals cope with the mechanical heterogeneity of the tropical canopy. The aim of this study was to investigate how changes in compliance and time of oscillation of branches are related to easily observable traits of arboreal supports. This should help predict how supports react mechanically to the weight and mass of a moving orangutan, and suggest how orangutans themselves predict branch properties. We measured the compliance and time of oscillation of branches from 11 tree species frequented by orangutans in the rainforest of Sumatra. Branches were pulled at several points along their length using a force balance at the end of a stiff rope, and the local diameter of the branch and the distance to its base and tip were measured. Compliance was negatively associated with both local diameter and length to the tip of the branch, and positively, if weakly, associated with length from the trunk. However, branch diameter not only predicted compliance best, but would also be easiest for an orangutan to observe. In contrast, oscillation times of branches were largely unaffected by local diameter, and only significantly increased at diameters below 2 cm. The results of this study validate previous field research, which related locomotory modes to local branch diameter, while suggesting how arboreal animals themselves sense their mechanical environment.