Abstract

The improvement of voluntary muscle strength can be accomplished by an enlargement of muscle mass or by changes that occur in the nervous system. The neural mechanism underlying the increase in strength are poorly understood. A recent study has demonstrated that the voluntary strength of a hand muscle can be increased by training with imagined maximal contractions. This finding indicates that the nervous system is able to increase strength in the absence of muscle exercise and the origin of the neural change associated with strength training appears to be in the brain. The current application proposes to explore this phenomenon by studying two specific aims.
Aim 1 will determine the effect of imagined-muscle-contraction training on the strength of the elbow flexor and abductor digiti minimi muscles. The basis for Aim 1 is that the control scheme for a hand muscle differs in several ways from a proximal muscle.
Aim 2 will identify the underlying neural mechanisms for the improved muscle performance due to the imagined-muscle-contraction training. Preliminary results demonstrated that: (1) the strength of the elbow flexor muscles can be increased (40%, an average of 3 subjects) by the imagined-contraction training; (2) there was a strong activation in the prefrontal association cortex during the imagined contraction and this activation was stronger in trained subjects; and (3) the activation pattern of the brain during an imagined contraction was similar to that during a forceful muscle contraction. The hypotheses of this application are that the imagined-contraction training will cause a similar increase in strength in the fifth finger abductor and elbow flexor muscles and that this increase in muscle force will be caused by a greater descending command from the prefrontal cortex. Three groups (one control and two training groups) of young, healthy human subjects will be recruited for the study. The training groups will be trained for 40 sessions with the imagined-maximal contractions. Voluntary strength of the two muscle groups will be evaluated before, during, and after training. Functional magnetic resonance imaging will be used to identify the activated brain regions during the imagined and actual maximal contractions and to quantify the magnitude of the brain and muscle activation before and after training. The project will provide information on the mechanisms of human voluntary muscle strengthening and on the understanding of how willed actions occur. The training method may lead to a rehabilitation regimen for maintaining and/or restoring motor functions in patients who cannot perform forceful muscle contractions.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS035130-02
Application #
2655536
Study Section
Special Emphasis Panel (ZRG4-GRM (01))
Program Officer
Heetderks, William J
Project Start
1997-02-01
Project End
2000-01-31
Budget Start
1998-02-01
Budget End
1999-01-31
Support Year
2
Fiscal Year
1998
Total Cost
Indirect Cost

  Institution

Name
Cleveland Clinic Lerner
Department
Type
DUNS #
017730458
City
Cleveland
State
OH
Country
United States
Zip Code
44195

  Publications

Jiang, Chang-Hao; Ranganathan, Vinoth K; Siemionow, Vlodek et al. (2017) The level of effort, rather than muscle exercise intensity determines strength gain following a six-week training. Life Sci 178:30-34
Cunningham, David A; Janini, Daniel; Wyant, Alexandria et al. (2016) Post-exercise depression following submaximal and maximal isometric voluntary contraction. Neuroscience 326:95-104
Jiang, Changhao; Ranganathan, Vinoth K; Zhang, Junmei et al. (2016) Motor effort training with low exercise intensity improves muscle strength and descending command in aging. Medicine (Baltimore) 95:e3291
Jiang, Zhiguo; Wang, Xiao-Feng; Yue, Guang H (2016) Strengthened Corticosubcortical Functional Connectivity during Muscle Fatigue. Neural Plast 2016:1726848
Bayram, Mehmed Bugrahan; Siemionow, Vlodek; Yue, Guang H (2015) Weakening of Corticomuscular Signal Coupling During Voluntary Motor Action in Aging. J Gerontol A Biol Sci Med Sci 70:1037-43
Sankarasubramanian, Vishwanath; Roelle, Sarah M; Bonnett, Corin E et al. (2015) Reproducibility of transcranial magnetic stimulation metrics in the study of proximal upper limb muscles. J Electromyogr Kinesiol 25:754-64
Plow, Ela B; Varnerin, Nicole; Cunningham, David A et al. (2014) Age-related weakness of proximal muscle studied with motor cortical mapping: a TMS study. PLoS One 9:e89371
Plow, Ela B; Cunningham, David A; Bonnett, Corin et al. (2013) Neurophysiological correlates of aging-related muscle weakness. J Neurophysiol 110:2563-73
Cunningham, David A; Machado, Andre; Yue, Guang H et al. (2013) Functional somatotopy revealed across multiple cortical regions using a model of complex motor task. Brain Res 1531:25-36
Yao, Wan X; Ranganathan, Vinoth K; Allexandre, Didier et al. (2013) Kinesthetic imagery training of forceful muscle contractions increases brain signal and muscle strength. Front Hum Neurosci 7:561

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