Compliant Substrates Disrupt Elastic Energy Storage in Jumping Tree Frogs

Author:

Reynaga Crystal M12ORCID,Eaton Caitrin E23,Strong Galatea A2,Azizi Emanuel2

Affiliation:

1. Department of Biology, Duke University, Durham, NC, USA

2. Department of Ecology and Evolutionary Biology, University of California, Irvine, 321 Steinhaus Hall, Irvine, CA, USA

3. Department of Computer Science, Colby College, 5852 Mayflower Hill, Waterville, ME, USA

Abstract

Abstract Arboreal frogs navigate complex environments and face diverse mechanical properties within their physical environment. Such frogs may encounter substrates that are damped and absorb energy or are elastic and can store and release energy as the animal pushes off during take-off. When dealing with a compliant substrate, a well-coordinated jump would allow for the recovery of elastic energy stored in the substrate to amplify mechanical power, effectively adding an in-series spring to the hindlimbs. We tested the hypothesis that effective use of compliant substrates requires active changes to muscle activation and limb kinematics to recover energy from the substrate. We designed an actuated force platform, modulated with a real-time feedback controller to vary the stiffness of the substrate. We quantified the kinetics and kinematics of Cuban tree frogs (Osteopilus septentrionalis) jumping off platforms at four different stiffness conditions. In addition, we used electromyography to examine the relationship between muscle activation patterns and substrate compliance during take-off in a knee extensor (m. cruralis) and an ankle extensor (m. plantaris). We find O. septentrionalis do not modulate motor patterns in response to substrate compliance. Although not actively modulated, changes in the rate of limb extension suggest a trade-off between power amplification and energy recovery from the substrate. Our results suggest that compliant substrates disrupt the inertial catch mechanism that allows tree frogs to store elastic energy in the tendon, thereby slowing the rate of limb extension and increasing the duration of take-off. However, the slower rate of limb extension does provide additional time to recover more energy from the substrate. This work serves to broaden our understanding of how the intrinsic mechanical properties of a system may broaden an organism’s capacity to maintain performance when facing environmental perturbations.

Funder

US Army Research Laboratory

US Army Research Office

National Science Foundation

Department of Education

Department of Ecology and Evolutionary Biology

School of Biological Sciences

Graduate Division

Chancellor’s Club at UCI

Publisher

Oxford University Press (OUP)

Subject

Plant Science,Animal Science and Zoology

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