Study confirms differences in dominant- versus non-dominant-leg power output during exercise

Study confirms differences in dominant- versus non-dominant-leg power output during exercise

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Reviewed by James Ives, M.Psych. (Editor)Oct 24 2019

A new study confirms important differences in dominant- versus non-dominant-leg oxygen usage and power output during single-leg exercise. The study is published ahead of print in the American Journal of Physiology- Regulatory, Integrative and Comparative Physiology.

Single-leg exercise, such as cycling, may be a component of scientific studies that examine exercise capacity and other physiological changes that take place in the muscles during physical activity. Single-leg cycling may also play a role in physical, cardiac or respiratory rehabilitation in people who are recovering from injuries. In addition, "single-leg training might be a very useful tool in patients with conditions that prevent them from exercising at higher intensities during whole-body exercise, but who can still benefit from strong signals for adaptation within the active muscles," explained corresponding author Juan Murias, PhD, of the University of Calgary in Canada.

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Previous research has shown that the dominant leg- the preferred side of the body for motor skills-;often generates more power than the non-dominant leg during double-leg exercise, such as riding a standard bicycle. However, even with this knowledge, there has been an assumption in the field of exercise physiology that both legs have a similar capacity for exercise before fatiguing. Murias' research team examined the physiological responses of both the dominant and non-dominant legs during sessions of single- and double-leg cycling.

A small group of healthy men performed single- and double-leg cycling incremental tests-;exercise intensity progressively increases until exhaustion-;and 30-minute constant-intensity trials. The single-leg trials were aided with a 15-pound counterweight attached to the opposite pedal. In single-leg cycling, the participant must actively flex and lift the exercised leg with each revolution. Counterweighting balances the exercised leg so it does not move in a different pattern than in double-leg cycling, reducing discomfort and fatigue. The research team then measured the power generated, oxygen usage and exercise capacity in both dominant and non-dominant legs.

During the single-leg incremental tests, the volunteers' dominant legs consistently worked at a higher level of VO2max, the ability to use oxygen during exercise and a marker of aerobic fitness. The dominant leg was also able to generate and sustain more power than the non-dominant leg during the constant-intensity trials. These findings could affect rehabilitation and training intervention programs that include single-leg exercise and "have important implications for the design of future studies using counterweighted single-leg cycling," the researchers wrote.

Source:

American Physiological Society (APS)

Journal reference:

Iannetta, D., et al. (2019) Inter-limb differences in parameters of aerobic function and local profiles of deoxygenation during double-leg and counterweighted single-leg cycling. American Journal of Physiology- Regulatory, Integrative and Comparative Physiology. doi.org/10.1152/ajpregu.00164.2019.