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Clinical Trial Summary

In general, men and women experience differing degrees of age-related decreases in physical function, with women having a greater prevalence of functional limitations and disability. A key predictor of this decrease in functional capacity is the reduction in leg muscle maximal power (product of force and velocity), which can be improved with exercise training. However, the development of exercise interventions to optimally improve skeletal muscle function in older adults has been difficult, in part because we now know that men and women respond differently to the same exercise training stimulus. In fact, the fundamental mechanisms by which habitual exercise improves physical function in older adults are still not well understood. The proposed studies are designed to address these knowledge gaps by examining the molecular and cellular mechanisms underlying the response to two distinct exercise training paradigms, and determining how these responses differ between older men and women. The investigators hypothesize that molecular, cellular and whole muscle contractile performance will be most improved in men by traditional low-velocity, high-load resistance training, and in women by high-velocity, low-load power training. Moreover, sex-specific structural responses in myofilament remodeling, protein expression and post-translational modifications will explain these sex-specific performance adaptations to each modality. To test these hypotheses, data will be gathered from 50 healthy, sedentary older men and women (65-75 years) prior to and following a 16-week unilateral exercise training program in which one leg undergoes resistance training and the other power training. The Specific Aims of this project are to identify the sex-specific effects of low-velocity resistance training versus high-velocity power training on: Aim 1) skeletal muscle function at the molecular, cellular and whole muscle levels, and Aim 2) protein expression and modification as well as size at the molecular and cellular levels. The within subject, unilateral intervention design provides a powerful model to minimize the effects of between-subject variability, and the translational approach will take advantage of our unique expertise with state-of-the-art measures from the molecular to whole body levels.


Clinical Trial Description

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Study Design


Related Conditions & MeSH terms


NCT number NCT03440099
Study type Interventional
Source University of Massachusetts, Amherst
Contact Mark S Miller, PhD
Phone 4135774701
Email markmiller@kin.umass.edu
Status Recruiting
Phase N/A
Start date January 1, 2018
Completion date March 31, 2024

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