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Hindlimb motion during steady flight of the lesser dog-faced fruit bat, Cynopterus brachyotis

Hindlimb motion during steady flight of the lesser dog-faced fruit bat, Cynopterus brachyotis
Hindlimb motion during steady flight of the lesser dog-faced fruit bat, Cynopterus brachyotis
In bats, the wing membrane is anchored not only to the body and forelimb, but also to the hindlimb. This attachment configuration gives bats the potential to modulate wing shape by moving the hindlimb, such as by joint movement at the hip or knee. Such movements could modulate lift, drag, or the pitching moment. In this study we address: 1) how the ankle translates through space during the wingbeat cycle; 2) whether amplitude of ankle motion is dependent upon flight speed; 3) how tension in the wing membrane pulls the ankle; and 4) whether wing membrane tension is responsible for driving ankle motion. We flew five individuals of the lesser dog-faced fruit bat, Cynopterus brachyotis (Family: Pteropodidae), in a wind tunnel and documented kinematics of the forelimb, hip, ankle, and trailing edge of the wing membrane. Based on kinematic analysis of hindlimb and forelimb movements, we found that: 1) during downstroke, the ankle moved ventrally and during upstroke the ankle moved dorsally; 2) there was considerable variation in amplitude of ankle motion, but amplitude did not correlate significantly with flight speed; 3) during downstroke, tension generated by the wing membrane acted to pull the ankle dorsally, and during upstroke, the wing membrane pulled laterally when taut and dorsally when relatively slack; and 4) wing membrane tension generally opposed dorsoventral ankle motion. We conclude that during forward flight in C. brachyotis, wing membrane tension does not power hindlimb motion; instead, we propose that hindlimb movements arise from muscle activity and/or inertial effects.
1932-6203
Cheney, Jorn A.
3cf74c48-4eba-4622-9f29-518653d79d93
Ton, Daniel
97a67e77-79c2-445d-b42d-39b4ee60d0e2
Konow, Nicolai
5007b728-a5cb-426b-8eca-6470c5a2d8d7
Riskin, Daniel K.
6658ef1e-f1fd-4785-8033-e4d4c4f76b7f
Breuer, Kenneth S.
4135a9b1-05d3-4b83-b25e-b7b9e7f30b46
Swartz, Sharon M.
8112b896-ef39-413e-abed-8d21e9e58cfc
Cheney, Jorn A.
3cf74c48-4eba-4622-9f29-518653d79d93
Ton, Daniel
97a67e77-79c2-445d-b42d-39b4ee60d0e2
Konow, Nicolai
5007b728-a5cb-426b-8eca-6470c5a2d8d7
Riskin, Daniel K.
6658ef1e-f1fd-4785-8033-e4d4c4f76b7f
Breuer, Kenneth S.
4135a9b1-05d3-4b83-b25e-b7b9e7f30b46
Swartz, Sharon M.
8112b896-ef39-413e-abed-8d21e9e58cfc

Cheney, Jorn A., Ton, Daniel, Konow, Nicolai, Riskin, Daniel K., Breuer, Kenneth S. and Swartz, Sharon M. (2014) Hindlimb motion during steady flight of the lesser dog-faced fruit bat, Cynopterus brachyotis. PLoS ONE, 9 (5). (doi:10.1371/journal.pone.0098093).

Record type: Article

Abstract

In bats, the wing membrane is anchored not only to the body and forelimb, but also to the hindlimb. This attachment configuration gives bats the potential to modulate wing shape by moving the hindlimb, such as by joint movement at the hip or knee. Such movements could modulate lift, drag, or the pitching moment. In this study we address: 1) how the ankle translates through space during the wingbeat cycle; 2) whether amplitude of ankle motion is dependent upon flight speed; 3) how tension in the wing membrane pulls the ankle; and 4) whether wing membrane tension is responsible for driving ankle motion. We flew five individuals of the lesser dog-faced fruit bat, Cynopterus brachyotis (Family: Pteropodidae), in a wind tunnel and documented kinematics of the forelimb, hip, ankle, and trailing edge of the wing membrane. Based on kinematic analysis of hindlimb and forelimb movements, we found that: 1) during downstroke, the ankle moved ventrally and during upstroke the ankle moved dorsally; 2) there was considerable variation in amplitude of ankle motion, but amplitude did not correlate significantly with flight speed; 3) during downstroke, tension generated by the wing membrane acted to pull the ankle dorsally, and during upstroke, the wing membrane pulled laterally when taut and dorsally when relatively slack; and 4) wing membrane tension generally opposed dorsoventral ankle motion. We conclude that during forward flight in C. brachyotis, wing membrane tension does not power hindlimb motion; instead, we propose that hindlimb movements arise from muscle activity and/or inertial effects.

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Published date: 23 May 2014
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Identifiers

Local EPrints ID: 471825
URI: http://eprints.soton.ac.uk/id/eprint/471825
DOI: doi:10.1371/journal.pone.0098093
ISSN: 1932-6203
PURE UUID: bec225d0-ce92-4bdd-95b0-904793b37cd9
ORCID for Jorn A. Cheney: ORCID iD orcid.org/0000-0002-9952-2612

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Date deposited: 21 Nov 2022 17:46
Last modified: 17 Mar 2024 04:16

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Author: Jorn A. Cheney ORCID iD
Author: Daniel Ton
Author: Nicolai Konow
Author: Daniel K. Riskin
Author: Kenneth S. Breuer
Author: Sharon M. Swartz

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