Is skeletal muscle oxidative capacity decreased in old age?

In humans, decreases in cardiac output play an important role in the age-related decrease in whole-body oxidative capacity. What remains less clear is whether a decline in skeletal muscle oxidative capacity is also an inevitable consequence of aging, as a number of other factors that could affect ox...

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Published inSports medicine (Auckland) Vol. 34; no. 4; pp. 221 - 229
Main Authors RUSS, David W, KENT-BRAUN, Jane A
Format Journal Article
LanguageEnglish
Published Chester Adis International 01.01.2004
Hong Kong Wolters Kluwer Health, Inc
Auckland
Subjects
Adult
Aged
Aged, 80 and over
Aging - metabolism
Biological and medical sciences
Exercise
Female
Fundamental and applied biological sciences. Psychology
Health aspects
Humans
Male
Middle Aged
Muscle, Skeletal - blood supply
Muscle, Skeletal - metabolism
Muscle, Skeletal - physiology
Muscles
Oxidative stress
Oxygen - metabolism
Physiological aspects
Risk factors
Striated muscle. Tendons
Vertebrates: osteoarticular system, musculoskeletal system
United States
Human
Senescence
Oxidation
Striated muscle
Age
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Abstract In humans, decreases in cardiac output play an important role in the age-related decrease in whole-body oxidative capacity. What remains less clear is whether a decline in skeletal muscle oxidative capacity is also an inevitable consequence of aging, as a number of other factors that could affect oxidative capacity also change with age, including: physical activity, health status, fibre-type composition, rates of protein synthesis and muscle blood supply. Both in vitro studies using muscle biopsy tissue and in vivo studies using 31P-magnetic resonance spectroscopy are used to study muscular oxidative capacity. Using these methodologies, researchers have found age-associated reductions in the oxidative capacities of specific muscles. In most cases, however, the influence of physical activity has not been adequately controlled, making it difficult to evaluate the effects of age itself from those of lifestyle changes associated with aging. Upon critical evaluation of the existing literature, the following picture regarding the effect of age on muscle oxidative capacity appears: although the maximum level of muscular oxidative capacity attainable through training may decline with age, much of the age-associated decline in oxidative function is related to the reductions in fitness and/or habitual physical activity that typically occur in this population. Future studies in this area must account for the health and activity status of their study participants.
AbstractList In humans, decreases in cardiac output play an important role in the age-related decrease in whole-body oxidative capacity. What remains less clear is whether a decline in skeletal muscle oxidative capacity is also an inevitable consequence of aging, as a number of other factors that could affect oxidative capacity also change with age, including: physical activity, health status, fibre-type composition, rates of protein synthesis and muscle blood supply. Both in vitro studies using muscle biopsy tissue and in vivo studies using [sup.31]P-magnetic resonance spectroscopy are used to study muscular oxidative capacity. Using these methodologies, researchers have found age-associated reductions in the oxidative capacities of specific muscles. In most cases, however, the influence of physical activity has not been adequately controlled, making it difficult to evaluate the effects of age itself from those of lifestyle changes associated with aging. Upon critical evaluation of the existing literature, the following picture regarding the effect of age on muscle oxidative capacity appears: although the maximum level of muscular oxidative capacity attainable through training may decline with age, much of the age-associated decline in oxidative function is related to the reductions in fitness and/or habitual physical activity that typically occur in this population. Future studies in this area must account for the health and activity status of their study participants.
In humans, decreases in cardiac output play an important role in the age-related decrease in whole-body oxidative capacity. What remains less clear is whether a decline in skeletal muscle oxidative capacity is also an inevitable consequence of aging, as a number of other factors that could affect oxidative capacity also change with age, including: physical activity, health status, fibre-type composition, rates of protein synthesis and muscle blood supply. Both in vitro studies using muscle biopsy tissue and in vivo studies using [sup.31]P-magnetic resonance spectroscopy are used to study muscular oxidative capacity. Using these methodologies, researchers have found age-associated reductions in the oxidative capacities of specific muscles. In most cases, however, the influence of physical activity has not been adequately controlled, making it difficult to evaluate the effects of age itself from those of lifestyle changes associated with aging.
In humans, decreases in cardiac output play an important role in the age-related decrease in whole-body oxidative capacity. What remains less clear is whether a decline in skeletal muscle oxidative capacity is also an inevitable consequence of aging, as a number of other factors that could affect oxidative capacity also change with age, including: physical activity, health status, fibre-type composition, rates of protein synthesis and muscle blood supply. Both in vitro studies using muscle biopsy tissue and in vivo studies using 31P-magnetic resonance spectroscopy are used to study muscular oxidative capacity. Using these methodologies, researchers have found age-associated reductions in the oxidative capacities of specific muscles. In most cases, however, the influence of physical activity has not been adequately controlled, making it difficult to evaluate the effects of age itself from those of lifestyle changes associated with aging. Upon critical evaluation of the existing literature, the following picture regarding the effect of age on muscle oxidative capacity appears: although the maximum level of muscular oxidative capacity attainable through training may decline with age, much of the age-associated decline in oxidative function is related to the reductions in fitness and/or habitual physical activity that typically occur in this population. Future studies in this area must account for the health and activity status of their study participants.
In humans, decreases in cardiac output play an important role in the age-related decrease in whole-body oxidative capacity. What remains less clear is whether a decline in skeletal muscle oxidative capacity is also an inevitable consequence of aging, as a number of other factors that could affect oxidative capacity also change with age, including: physical activity, health status, fibre-type composition, rates of protein synthesis and muscle blood supply. Both in vitro studies using muscle biopsy tissue and in vivo studies using super(31)P-magnetic resonance spectroscopy are used to study muscular oxidative capacity. Using these methodologies, researchers have found age-associated reductions in the oxidative capacities of specific muscles. In most cases, however, the influence of physical activity has not been adequately controlled, making it difficult to evaluate the effects of age itself from those of lifestyle changes associated with aging. Upon critical evaluation of the existing literature, the following picture regarding the effect of age on muscle oxidative capacity appears: although the maximum level of muscular oxidative capacity attainable through training may decline with age, much of the age-associated decline in oxidative function is related to the reductions in fitness and/or habitual physical activity that typically occur in this population. Future studies in this area must account for the health and activity status of their study participants.
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Academic
Author RUSS, David W
KENT-BRAUN, Jane A
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Keywords Human
Senescence
Oxidation
Striated muscle
Age
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Snippet In humans, decreases in cardiac output play an important role in the age-related decrease in whole-body oxidative capacity. What remains less clear is whether...
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SubjectTerms Adult
Aged
Aged, 80 and over
Aging - metabolism
Biological and medical sciences
Exercise
Female
Fundamental and applied biological sciences. Psychology
Health aspects
Humans
Male
Middle Aged
Muscle, Skeletal - blood supply
Muscle, Skeletal - metabolism
Muscle, Skeletal - physiology
Muscles
Oxidative stress
Oxygen - metabolism
Physiological aspects
Risk factors
Striated muscle. Tendons
Vertebrates: osteoarticular system, musculoskeletal system
Title Is skeletal muscle oxidative capacity decreased in old age?
URI https://www.ncbi.nlm.nih.gov/pubmed/15049714
https://search.proquest.com/docview/17971308
https://search.proquest.com/docview/71786412
Volume 34
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