Red muscle activity in bluegill sunfish Lepomis macrochirus during forward accelerations

BioRxiv : the Preprint Server for Biology
Margot A B SchwalbeEric D Tytell

Abstract

Fishes generate force to swim by activating muscles on either side of their flexible bodies. To accelerate, they must produce higher muscle forces, which leads to higher reaction forces back on their bodies from the environment. If their bodies are too flexible, the forces during acceleration could not be transmitted effectively to the environment. Here, we investigate whether fish can use their red muscle to stiffen their body during acceleration. We used high-speed video, electromyographic recordings, and a new digital inertial measurement unit to quantify body kinematics, red muscle activity, and 3D orientation and centre of mass acceleration during forward accelerations and steady swimming over several speeds. During acceleration, fish co-activated anterior muscle on the left and right side, and activated all muscle sooner and kept it active for a larger fraction of the tail beat cycle. These activity patterns are consistent with our hypothesis that fish use their red muscle to stiffen their bodies during acceleration. We suggest that during impulsive movements, flexible organisms like fishes can use their these muscles not only to generate propulsive power but to tune the effective mechanical properties of their bodies, in...Continue Reading

Related Concepts

Bluegill
Electromyography
Environment
Muscle
Zebrafish
Right
Left
Muscle Fibers, Red
Heart Beat
Kinematics

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