M.N. Scholz scite author profile

SUMMARYBetter running economy (i.e. a lower rate of energy consumption at a given speed) is correlated with superior distance running performance. There is substantial variation in running economy, even among elite runners. This variation might be due to variation in the storage and reutilization of elastic energy in tendons. Using a simple musculoskeletal model, it was predicted that the amount of energy stored in a tendon during a given movement depends more critically on moment arm than on mechanical properties of the tendon, with the amount of stored energy increasing as the moment arm gets smaller. Assuming a link between elastic energy reutilization and overall metabolic cost of running, a smaller moment arm should therefore be associated with superior running economy. This prediction was confirmed experimentally in a group of 15 highly trained runners. The moment arm of the Achilles tendon was determined from standardized photographs of the ankle, using the position of anatomical landmarks. Running economy was measured as the rate of metabolic energy consumption during level treadmill running at a speed of 16 km h

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Vertical jumping performance of bonobo (Pan paniscus) suggests superior muscle properties

Scholz

D’Août

Bobbert

et al. 2006

Proc. R. Soc. B.

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Vertical jumping was used to assess muscle mechanical output in bonobos and comparisons were drawn to human jumping. Jump height, defined as the vertical displacement of the body centre of mass during the airborne phase, was determined for three bonobos of varying age and sex. All bonobos reached jump heights above 0.7 m, which greatly exceeds typical human maximal performance (0.3-0.4 m). Jumps by one male bonobo (34 kg) and one human male (61.5 kg) were analysed using an inverse dynamics approach. Despite the difference in size, the mechanical output delivered by the bonobo and the human jumper during the push-off was similar: about 450 J, with a peak power output close to 3000 W. In the bonobo, most of the mechanical output was generated at the hips. To account for the mechanical output, the muscles actuating the bonobo's hips (directly and indirectly) must deliver muscle-mass-specific power and work output of 615 W kg K1 and 92 J kg K1, respectively. This was twice the output expected on the basis of muscle mass specific work and power in other jumping animals but seems physiologically possible. We suggest that the difference is due to a higher specific force (force per unit of cross-sectional area) in the bonobo.

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Scaling and jumping: Gravity loses grip on small jumpers

Scholz

Bobbert

Soest

2006

Journal of Theoretical Biology

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Modeling vertical jumping in bonobo (pan paniscus)

Scholz¹

2006

Journal of Biomechanics

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M.N. Scholz

Running biomechanics: shorter heels, better economy

Vertical jumping performance of bonobo (Pan paniscus) suggests superior muscle properties

Scaling and jumping: Gravity loses grip on small jumpers

Modeling vertical jumping in bonobo (pan paniscus)

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