The ability to move the fingers relatively independently of one another enables human and non-human primates to manipulate diverse objects in the environment and to execute an immense variety of movements and gestures. Lesions of the motor cortex, such as those associated with stroke, give rise to debilitating and persistent deficits in the ability to move fingers individually even though the capacity to flex and extend the fingers together recovers. Accordingly, much scientific attention has been directed toward understanding how motor centers of the brain impart the ability to separately control the fingers. The function of the peripheral motor apparatus, however, has been largely ignored in the interpretation of findings related to the organization of the motor cortex. In particular, the actuators primarily responsible for moving the fingers are single-bellied muscles that give rise distally to multiple tendons that insert onto all the fingers. While the current view is that these multiendoned muscles consist of distinct functional compartments that govern the motion of different digits, the investigators have recently shown that motor unit force in these muscles is not concentrated on a single tendon but is broadly distributed across many tendons. This observation promotes a number of questions about the neural and muscular control of the fingers that are addressed in the specific aims of this proposal. First, what specific factors contribute to the dispersal of motor unit force across multiple tendons in muscles that control the fingers? Second, to what extent is it actually possible to move the fingers independently. And third, what strategies are employed by the nervous system when attempting to move a single finger given the apparent absence of independent actuators of the digits? These questions will be addressed in human subjects using a variety of electrophysiological and biomechanical techniques, including intraneural and intramuscular microstimulation, cross-correlation analysis of spike trains recorded from concurrently active motor units, kinematic analysis, and electromyographic recordings from multiple muscles during the execution of individuated finger movements. The results from these studies will add to our comprehension of how the spinal and muscular systems are coordinated in the elaboration of finger movements and will provide an important framework for understanding how the motor cortex specifies voluntary motion of the hand.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS039489-04
Application #
6629325
Study Section
Geriatrics and Rehabilitation Medicine (GRM)
Program Officer
Chen, Daofen
Project Start
2000-02-25
Project End
2004-05-14
Budget Start
2003-02-01
Budget End
2004-05-14
Support Year
4
Fiscal Year
2003
Total Cost
$109,572
Indirect Cost
Name
University of Arizona
Department
Physiology
Type
Schools of Medicine
DUNS #
806345617
City
Tucson
State
AZ
Country
United States
Zip Code
85721
Keen, Douglas A; Chou, Li-Wei; Nordstrom, Michael A et al. (2012) Short-term synchrony in diverse motor nuclei presumed to receive different extents of direct cortical input. J Neurophysiol 108:3264-75
Fuglevand, Andrew J (2011) Mechanical properties and neural control of human hand motor units. J Physiol 589:5595-602
Johns, Richard K; Fuglevand, Andrew J (2011) Number of motor units in human abductor hallucis. Muscle Nerve 43:895-6
Marcus, Patrick L; Fuglevand, Andrew J (2009) Perception of electrical and mechanical stimulation of the skin: implications for electrotactile feedback. J Neural Eng 6:066008
Waller, B M; Parr, L A; Gothard, K M et al. (2008) Mapping the contribution of single muscles to facial movements in the rhesus macaque. Physiol Behav 95:93-100
McIsaac, Tara L; Fuglevand, Andrew J (2008) Common synaptic input across motor nuclei supplying intrinsic muscles involved in the precision grip. Exp Brain Res 188:159-64
Anderson, Chad V; Fuglevand, Andrew J (2008) Probability-based prediction of activity in multiple arm muscles: implications for functional electrical stimulation. J Neurophysiol 100:482-94
McIsaac, Tara L; Fuglevand, Andrew J (2007) Motor-unit synchrony within and across compartments of the human flexor digitorum superficialis. J Neurophysiol 97:550-6
Bailey, E Fiona; Rice, Amber D; Fuglevand, Andrew J (2007) Firing patterns of human genioglossus motor units during voluntary tongue movement. J Neurophysiol 97:933-6
Fuglevand, Andrew J; Dutoit, Andrea P; Johns, Richard K et al. (2006) Evaluation of plateau-potential-mediated 'warm up' in human motor units. J Physiol 571:683-93

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