Force enhancement following muscle stretch of electrically stimulated and voluntarily activated human adductor pollicis

Lee, Hae Dong; Herzog, Walter

doi:10.1113/jphysiol.2002.018010

Cited by 149 publications

(234 citation statements)

References 37 publications

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“…For the stimulation condition T ecc /T 0 ranged between 1.4 − 1.8. The lower end of this range is similar to values reported in previous in vivo stimulation studies for the quadriceps (Dudley et al, 1990;Westing et al, 1991) soleus (Pinniger et al, 2000) and adductor pollicis (De Ruiter et al, 2000;Lee and Herzog, 2002). While the upper end is similar to values found in previous in vivo stimulation studies for the first dorsal interosseus (Cook and McDonagh, 1995) and in vitro studies for mouse and frog muscle fibres (Katz, 1939;Délèze, 1961;Edmann, 1988;Lombardi and Piazzesi, 1990;Krylow and Sandercock, 1997).…”

Section: Discussionsupporting

confidence: 77%

The torque–velocity relationship in large human muscles: Maximum voluntary versus electrically stimulated behaviour

Pain

Young

Kim

et al. 2013

Journal of Biomechanics

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Section: Discussionsupporting

confidence: 77%

The torque–velocity relationship in large human muscles: Maximum voluntary versus electrically stimulated behaviour

Pain

Young

Kim

et al. 2013

Journal of Biomechanics

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“…Recent evidence shows that the PEVK segments of titin bind Ca 2C with high affinity (Tatsumi et al 2001), and that increasing Ca 2C concentration enhances force produced by titin at a given sarcomere length (Labeit et al 2003), suggesting a link between Ca 2C -induced activation and force produced by titin. In studies conducted in our laboratory with singlemuscle fibres (Rassier et al 2003;Rassier & Herzog 2004a,b), whole muscles (Herzog & Leonard 2002;Herzog et al 2003) and human muscles (Lee & Herzog 2002), we observed that passive force is increased when activated muscles are stretched along the descending limb of the force-length relationship, when compared with the passive forces following passive stretches or isometric contractions at the corresponding lengths. We refer to this phenomenon as passive force enhancement (Herzog & Leonard 2002;Herzog et al 2003;Rassier et al 2003;Rassier & Herzog 2004a,b).…”

Section: Introductionmentioning

confidence: 99%

Modulation of passive force in single skeletal muscle fibres

2005

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In this study, we investigated the effects of activation and stretch on the passive forcesarcomere length relationship in skeletal muscle. Single fibres from the lumbrical muscle of frogs were placed at varying sarcomere lengths on the descending limb of the forcesarcomere length relationship, and tetanic contractions, active stretches and passive stretches (amplitudes of ca 10% of fibre length at a speed of 40% fibre length/s) were performed. The passive forces following stretch of an activated fibre were higher than the forces measured after isometric contractions or after stretches of a passive fibre at the corresponding sarcomere length. This effect was more pronounced at increased sarcomere lengths, and the passive force-sarcomere length relationship following active stretch was shifted upwards on the force axis compared with the corresponding relationship obtained following isometric contractions or passive stretches. These results provide strong evidence for an increase in passive force that is mediated by a length-dependent combination of stretch and activation, while activation or stretch alone does not produce this effect. Based on these results and recently published findings of the effects of Ca 2C on titin stiffness, we propose that the observed increase in passive force is caused by the molecular spring titin.

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“…As in FD, the occurrence of FE initially was linked only to the lower limb and the peak of the LTC (22,23,24). However, new findings indicate that FE is also observed with reasonable stability in the ascending limb of the LCT (39,80,81,82).…”

Section: Theory Of Non-uniformity and Instability Of Sarcomerementioning

confidence: 90%

“…This association is independent of the coupling of new cross bridges actin -myosin that remains after ceased the stimulus (7,17,22,28,33,97).…”

Section: Elastic Components In Parallel Recruitment Theorymentioning

confidence: 92%

See 1 more Smart Citation

Variation in isometric force after active shortening and lengthening and their mechanisms: a review

Lima

Farinatti²,

Monteiro

et al. 2014

Fisioter. mov.

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Introduction:The isometric force history dependence of skeletal muscle has been studied along the last one hundred years. Several theories have been formulated to explain and establish the causes of the phenomenon, but not successfully, as they have not been fully accepted and demonstrated, and much controversy on such a subject still remains. Objective: To present a systematic literature review on the dynamics of the mechanisms of force depression and force enhancement after active shortening and lengthening, respectively, identifying the key variables involved in the phenomenon, and to date to present the main theories and hypothesis developed trying to explaining it. Method: The procedure of literature searching complied the major databases, including articles either, those which directly investigated the phenomena of force depression and force enhancement or those which presented possible causes and mechanisms associated with their respective events, from the earliest studies published until the year of 2010. Results: 97

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Force enhancement following muscle stretch of electrically stimulated and voluntarily activated human adductor pollicis

Cited by 149 publications

References 37 publications

The torque–velocity relationship in large human muscles: Maximum voluntary versus electrically stimulated behaviour

The torque–velocity relationship in large human muscles: Maximum voluntary versus electrically stimulated behaviour

Modulation of passive force in single skeletal muscle fibres

Variation in isometric force after active shortening and lengthening and their mechanisms: a review

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