Probing the limits to muscle-powered accelerations: lessons from jumping bullfrogs

doi:10.1242/jeb.00452

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The Journal of Experimental Biology 206, 2567-2580 (2003)
doi: 10.1242/jeb.00452

Probing the limits to muscle-powered accelerations: lessons from jumping bullfrogs

Thomas J. Roberts^* and Richard L. Marsh

Biology Department, Northeastern University, 414 Mugar, 360 Huntington Ave, Boston, MA 02115, USA

^* Author for correspondence at present address: Oregon State University, Zoology Department, 3029 Cordley Hall, Corvallis, OR 97331, USA (e-mail: robertst{at}bcc.orst.edu)

Accepted 10 April 2003

The function of many muscles during natural movements is toaccelerate a mass. We used a simple model containing the essentialelements of this functional system to investigate which musculoskeletalfeatures are important for increasing the mechanical work donein a muscle-powered acceleration. The muscle model consistedof a muscle-like actuator with frog hindlimb muscle properties,operating across a lever to accelerate a load. We tested this modelin configurations with and without a series elastic elementand with and without a variable mechanical advantage. When totalmuscle shortening was held constant at 30%, the model producedthe most work when the muscle operated with a series elasticelement and an effective mechanical advantage that increasedthroughout the contraction (31 J kg^-1 muscle vs 26.6 J kg^-1muscle for the non-compliant, constant mechanical advantageconfiguration). We also compared the model output with the dynamics ofjumping bullfrogs, measured by high-speed video analysis, andthe length changes of the plantaris muscle, measured by sonomicrometry.This comparison revealed that the length, force and power trajectoryof the body of jumping frogs could be accurately replicatedby a model of a fully active muscle operating against an inertialload, but only if the model muscle included a series elasticelement. Sonomicrometer measurements of the plantaris muscle revealedan unusual, biphasic pattern of shortening, with high muscle velocitiesearly and late in the contraction, separated by a period ofslow contraction. The model muscle produced this pattern ofshortening only when an elastic element was included.

These results demonstrate that an elastic element can increasethe work output in a muscle-powered acceleration. Elastic elementsuncouple muscle fiber shortening velocity from body movementto allow the muscle fibers to operate at slower shortening velocitiesand higher force outputs. A variable muscle mechanical advantageimproves the effectiveness of elastic energy storage and recoveryby providing an inertial catch mechanism. These results canexplain the high power outputs observed in jumping frogs. Moregenerally, our model suggests how the function of non-muscularelements of the musculoskeletal system enhances performancein muscle-powered accelerations.

Key words: locomotion, muscle work, muscle power, jumping, frog, Rana catesbeiana, elastic, tendon, acceleration

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