In mice, the muscle weakness due to age is absent during stretching.

Phillips, S. K.; Bruce, Stuart; Woledge, Roger C.

doi:10.1113/jphysiol.1991.sp018583

Cited by 69 publications

(69 citation statements)

References 12 publications

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“…For instance, Phillips et al measured specific force, defined as isometric tension (T 0 ) normalized to muscle cross sectional area (CSA), in isolated soleus muscles of young and old mice during eccentric and concentric muscle contractions. The results of this study confirm that agerelated deficits in specific force during stretching of the muscle are minimal (Phillips et al, 1991). In other words, muscle weakness due to age is manifested only in concentric contractions, while tension during stretching is preserved in old muscles.…”

Section: Cellular Mechanismssupporting

confidence: 80%

“…It has been suggested that the stretch produced during eccentric contractions might shift myosin heads into a strongly bound state (Lombardi and Piazzesi, 1990). This, in turn, would reduce during eccentric contractions the age-related force deficits commonly observed during either isometric or concentric contractions (Phillips et al, 1991). It is still unclear though, why this stretch-induced phenomenon does not bring about additional tension in young muscle fibers (Fig.…”

Section: Cellular Mechanismsmentioning

confidence: 97%

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Preservation of eccentric strength in older adults: Evidence, mechanisms and implications for training and rehabilitation

Roig

MacIntyre

Eng

et al. 2010

Experimental Gerontology

118

125

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Overall reductions in muscle strength typically accompany the aging process. However, older adults show a relatively preserved capacity of producing eccentric strength. The preservation of eccentric strength in older adults is a well-established phenomenon, occurring indiscriminately across different muscle groups, independent of age-related architectural changes in muscle structure and velocity of movement.The mechanisms for the preservation of eccentric strength appear to be mechanical and cellular in origin and include both passive and active elements regulating muscle stiffness. The age-related accumulation of non-contractile material in the muscle-tendon unit increases passive stiffness, which might offer mechanical advantage during eccentric contractions. In addition, the preserved muscle tension and increased instantaneous stiffness of old muscle fibers during stretch increase active stiffness, which might enhance eccentric strength.The fact that the preservation of eccentric strength is present in people with chronic conditions when compared to age-matched healthy controls indicates that the aging process per se does not exclusively mediate the preservation of eccentric strength. Physical inactivity, which is common in elderly and people with chronic conditions, is a potential factor regulating the preservation of eccentric strength.When compared to concentric strength, the magnitude of the preservation of eccentric strength in older adults ranges from 2% to 48% with a mean value from all studies of 21.6%. This functional reserve of eccentric strength might be clinically relevant, especially to initiate resistance training and rehabilitation programs in individuals with low levels of strength.

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Section: Cellular Mechanismssupporting

confidence: 80%

Section: Cellular Mechanismsmentioning

confidence: 97%

Preservation of eccentric strength in older adults: Evidence, mechanisms and implications for training and rehabilitation

Roig

MacIntyre

Eng

et al. 2010

Experimental Gerontology

118

125

View full text Add to dashboard Cite

show abstract

“…As mentioned above, a large R int,down requires a large force to be exerted during the following negative work phase (stretching), whereas a large R int,up requires a large force to be exerted during the preceding positive work phase (shortening). The finding that R int,down is less affected by age than R int,up suggests that the deficit in force during stretching is less than the deficit in force during shortening, which, as mentioned above, is a characteristics of aged muscle [80][81][82][83][84][85].…”

Section: The Landing-takeoff Asymmetry In Old Humansmentioning

confidence: 74%

“…In old age, muscular force is reduced, but the deficit in force is less during stretching than during shortening. This has been shown in experiments on isolated muscle specimens [80,81] and in vivo on humans [82][83][84][85]. The effect of this change of muscle contractile properties with age on the mechanics of locomotion is unknown.…”

Section: The Landing-takeoff Asymmetry In Old Humansmentioning

confidence: 96%

Symmetry and Asymmetry in Bouncing Gaits

Cavagna

2010

Symmetry

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Abstract:In running, hopping and trotting gaits, the center of mass of the body oscillates each step below and above an equilibrium position where the vertical force on the ground equals body weight. In trotting and low speed human running, the average vertical acceleration of the center of mass during the lower part of the oscillation equals that of the upper part, the duration of the lower part equals that of the upper part and the step frequency equals the resonant frequency of the bouncing system: we define this as on-offground symmetric rebound. In hopping and high speed human running, the average vertical acceleration of the center of mass during the lower part of the oscillation exceeds that of the upper part, the duration of the upper part exceeds that of the lower part and the step frequency is lower than the resonant frequency of the bouncing system: we define this as on-off-ground asymmetric rebound. Here we examine the physical and physiological constraints resulting in this on-off-ground symmetry and asymmetry of the rebound. Furthermore, the average force exerted during the brake when the body decelerates downwards and forwards is greater than that exerted during the push when the body is reaccelerated upwards and forwards. This landing-takeoff asymmetry, which would be nil in the elastic rebound of the symmetric spring-mass model for running and hopping, suggests a less efficient elastic energy storage and recovery during the bouncing step. During hopping, running and trotting the landing-takeoff asymmetry and the mass-specific vertical stiffness are smaller in larger animals than in the smaller animals suggesting a more efficient rebound in larger animals.

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“…The latter includes fiber loss and atrophy (Larsson et al 1979;Sato et al 1984;Lexell et al 1988), impairments in the excitation-contraction process (Delbono et al 1995;Wang et al 2002), and perturbations to actomyosin cross-bridge function (Larsson et al 1997; Thompson and Brown 1999;Lowe et al 2001;Frontera et al 2000;Hook et al 2001;Krivickas et al 2001). These factors are specific to the mode of muscle contraction, impacting force during isometric and shortening contractions but having much less effect on force during lengthening or eccentric, muscular activity (Porter et al 1997;Poulin et al 1992;Phillips et al 1991;Ochala et al 2006;Hortobagyi et al 1995).…”

Section: Introductionmentioning

confidence: 99%

Eccentric contraction-induced injury to type I, IIa, and IIa/IIx muscle fibers of elderly adults

Choi

Lim

Nibaldi

et al. 2011

AGE

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Muscles of old laboratory rodents experience exaggerated force losses after eccentric contractile activity. We extended this line of inquiry to humans and investigated the influence of fiber myosin heavy chain (MHC) isoform content on the injury process. Skinned muscle fiber segments, prepared from vastus lateralis biopsies of elderly men and women (78± 2 years, N=8), were subjected to a standardized eccentric contraction (strain, 0.25 fiber length; velocity, 0.50 unloaded shortening velocity). Injury was assessed by evaluating pre-and post-eccentric peak Ca 2+ -activated force per fiber cross-sectional area (F max ). Over 90% of the variability in post-eccentric F max could be explained by a multiple linear regression model consisting of an MHC-independent slope, where injury was directly related to pre-eccentric F max , and MHC-dependent y-intercepts, where the susceptibility to injury could be described as type IIa/IIx fibers>type IIa fibers>type I fibers. We previously reported that fiber type susceptibility to the same standardized eccentric protocol was type IIa/IIx>type IIa=type I for vastus lateralis fibers of 25-year-old adults (Choi and Widrick, Am J Physiol Cell Physiol 299:C1409-C1417, 2010). Modeling combined data sets revealed significant age by fiber type interactions, with posteccentric F max deficits greater for type IIa and type IIa/ IIx fibers from elderly vs. young subjects at constant pre-eccentric F max . We conclude that the resistance of the myofilament lattice to mechanical strain has deteriorated for type IIa and type IIa/IIx, but not for type I, vastus lateralis fibers of elderly adults.

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In mice, the muscle weakness due to age is absent during stretching.

Cited by 69 publications

References 12 publications

Preservation of eccentric strength in older adults: Evidence, mechanisms and implications for training and rehabilitation

Preservation of eccentric strength in older adults: Evidence, mechanisms and implications for training and rehabilitation

Symmetry and Asymmetry in Bouncing Gaits

Eccentric contraction-induced injury to type I, IIa, and IIa/IIx muscle fibers of elderly adults

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