Energy cost and muscular activity required for propulsion during walking

doi:10.1152/japplphysiol.00670.2002

Energy cost and muscular activity required for propulsion during walking

Jinger S. Gottschall and Rodger Kram

Department of Kinesiology and Applied Physiology, University of Colorado, Boulder, Colorado 80309

We reasoned that with an optimal aiding horizontal force, the reduction in metabolic rate would reflect the cost of generatingpropulsive forces during normal walking. Furthermore, the reductionsin ankle extensor electromyographic (EMG) activity would indicatethe propulsive muscle actions. We applied horizontal forces atthe waist, ranging from 15% body weight aiding to 15% body weightimpeding, while subjects walked at 1.25 m/s. With an aiding horizontalforce of 10% body weight, 1) the net metabolic cost of walkingdecreased to a minimum of 53% of normal walking, 2) the mean EMGof the medial gastrocnemius (MG) during the propulsive phase decreasedto 59% of the normal walking magnitude, and yet 3) the mean EMGof the soleus (Sol) did not decrease significantly. Our data indicatethat generating horizontal propulsive forces constitutes nearlyhalf of the metabolic cost of normal walking. Additionally, itappears that the MG plays an important role in forward propulsion,whereas the Sol doesnot.

biomechanics; locomotion; energetic cost; electromyography

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