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María Hernández, Fabrício Zambom-Ferraresi, Pilar Cebollero, Javier Hueto, José Antonio Cascante, and María M. Antón

 al., 2011 ). However, it is not entirely clear whether muscle strength and muscle power are involved in the physical activity levels of older men with COPD. The peripheral muscle dysfunction of the lower limbs observed in older men with COPD is characterized by a reduction in the maximum muscle strength and

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Konstantina Katsoulis, Liza Stathokostas, and Catherine E. Amara

After age 65 years, muscle power (the product of force and velocity or force per unit time) declines faster than muscle strength (the ability to produce maximal force), with the rate of power loss reported to be 3.5–6% per year compared with strength losses of 0–1.5% per year ( Clark et al., 2013

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José Machado Filho, Carlos Leonardo Figueiredo Machado, Hirofumi Tanaka, and Rodrigo Ferrari

adults are faced with the loss of functional independence. Among the neuromuscular parameters associated with functional independence, the development of muscular power is a strong predictor of functional status in the older population ( Foldvari et al., 2000 ; Reid & Fielding, 2012 ). Muscle power

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Rheanna Bulten, Sara King-Dowling, and John Cairney

field tests to assess MF in children, there is still a lack of evidence on their validity. A recent study by King-Dowling et al ( 18 ) assessed the validity of SLJ for predicting peak muscle power as measured by a Wingate test in preschool-aged children (aged 3–5 y). Results of the study showed that SLJ

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Elaine Trudelle-Jackson, Emerenciana Hines, Ann Medley, and Mary Thompson

rather than muscle power as an outcome when rehabilitating patients with TKA. 6 With persistent residual deficits in muscle strength and functional performance 6 months or more after TKA, a more intensive approach may be necessary. Muscle strength and power both decrease with age, but muscle power

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Yassine Negra, Helmi Chaabene, Senda Sammoud, Olaf Prieske, Jason Moran, Rodrigo Ramirez-Campillo, Ali Nejmaoui, and Urs Granacher

, speed, and derivatives thereof (ie, acceleration, sprinting, jumping, and CoD), when compared with subelite soccer players. 2 , 3 Accordingly, the development of muscle power, speed, and CoD through well-designed strength and conditioning programs is vital to optimize the development of the elite

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Michael L. Madigan

The purpose of this study was to investigate agerelated differences in muscle power during a surrogate task of trip recovery. Participants included 10 healthy young men (19–23 years old) and 10 healthy older men (65–83). The task involved releasing participants from a forward-leaning posture. After release, participants attempted to recover their balance using a single step of the right foot. Muscle power at the hip, knee, and ankle of the stepping limb were determined from the product of joint angular velocity and joint torque. Muscle powers during balance recovery followed a relatively consistent pattern in both young and older men, and showed effects of both lean and age. Interestingly, the effects of age did not always involve smaller peak power values in the older men as expected from the well-documented loss of muscle power with aging. Older men exhibited smaller peak muscle power at the knee and larger peak muscle power at the ankle and hip compared to young men. The increases in muscle power at the ankle and hip may result from a neuromuscular adaptation aimed at improving balance recovery ability by compensating for the age-related loss of muscle function.

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Jocelyn F. Hafer, Mark S. Miller, Jane A. Kent, and Katherine A. Boyer

-related changes in gait and muscle function compared with males but that high levels of PA would mitigate this effect, and thus, fewer differences would be present between highly active males and females. In agreement with this hypothesis, our results suggest age-related changes in gait mechanics, muscle power

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Eric Maylia, John A. Fairclough, Leonard D.M. Nokes, and Michael D. Jones

The purpose of this study was to assess whether measurements of thigh bulk taken with a tape measure would give an indication of muscle power. Eleven male patients, all undergoing unilateral menisectomies, performed exercises of the quadriceps and hamstring muscles during concentric loading at 60°/s. The patients were tested three times over a 12-week period: one day before the operation and 2 and 12 weeks after the operation. Thigh girth was recorded, using a conventional plastic tape measure, 10 cm from the top of the patella in each of the three test sessions. The results of this study demonstrated that muscle power cannot be predicted from thigh girth measurements.

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Neil A. Doldo, Matthew J. Delmonico, Jason A. Bailey, Brian D. Hand, Matthew C. Kostek, Karma M. Rabon-Stith, Kalapurakkal S. Menon, Joan M. Conway, Craig R. Carignan, and Ben F. Hurley

To determine sex and race differences in muscle power per unit of muscle contraction, knee-extensor muscle power normalized for knee-extensor muscle volume was measured in 79 middle-aged and older adults (30 men and 49 women, age range 50–85 years). Results revealed that women displayed a 38% faster peak movement velocity than men and African Americans had a 14% lower peak movement velocity than Whites of a similar age when expressed per unit of involved muscle (p < .001). As expected, men exhibited greater knee-extensor strength and peak power per unit of muscle than women, but women had a faster knee-extension movement velocity per unit of muscle than men at the same relative strength level. Moreover, African Americans had greater knee-extensor muscle volume than Whites but exhibited lower knee-extensor strength and lower movement velocity per unit of muscle when tested at the same relative strength levels.