Linear spring-damper model of the hypertonic elbow: reliability and validity

Hypertonia of the elbow joint complex is common in individuals with stroke and is related to the magnitude of the torque response (described by position dependent parameters) during constant velocity extensions. The objective of this study was to model position and velocity dependent characteristics...

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Veröffentlicht in:	Journal of neuroscience methods 2003-09, Vol.128 (1), p.121-128
Hauptverfasser:	McCrea, Patrick H., Eng, Janice J., Hodgson, Antony J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aged Biomechanics Elbow Joint - physiology Female Humans Linear Models Male Middle Aged Muscle Hypertonia - diagnosis Muscle Hypertonia - etiology Muscle Hypertonia - physiopathology Reliability Spasticity Stroke Stroke - complications Stroke - physiopathology Torque Validity
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creator	McCrea, Patrick H. Eng, Janice J. Hodgson, Antony J.
description	Hypertonia of the elbow joint complex is common in individuals with stroke and is related to the magnitude of the torque response (described by position dependent parameters) during constant velocity extensions. The objective of this study was to model position and velocity dependent characteristics of hypertonia. For both the more and less affected arms in 17 persons with chronic stroke, we measured the torque response to constant velocity stretches (30–180°/s). The responses were combined in position–velocity space and parameters of stiffness, damping, and offset angle were determined from a linear spring-damper model of the torque profile. The model was assessed at three levels: (1) ability to describe the combined torque profile variance, (2) reliability of parameters, and (3) validity of parameters (i.e. clinical correlation). Model parameters fit the torque profiles of both arm groups well and exhibited day-to-day reliability. Stiffness (r=0.820), damping (r=0.816), and ‘viscoelasticity’ (r=0.909), a composite parameter index developed posthoc, were highly correlated to a manual assessment of hypertonia (Modified Ashworth Scale). Mechanically determined parameters of hypertonia graded along a continuum may have better discriminatory power than manual assessments and thus, may be better at tracking recovery and evaluating interventions.
doi_str_mv	10.1016/S0165-0270(03)00169-9
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The objective of this study was to model position and velocity dependent characteristics of hypertonia. For both the more and less affected arms in 17 persons with chronic stroke, we measured the torque response to constant velocity stretches (30–180°/s). The responses were combined in position–velocity space and parameters of stiffness, damping, and offset angle were determined from a linear spring-damper model of the torque profile. The model was assessed at three levels: (1) ability to describe the combined torque profile variance, (2) reliability of parameters, and (3) validity of parameters (i.e. clinical correlation). Model parameters fit the torque profiles of both arm groups well and exhibited day-to-day reliability. Stiffness (r=0.820), damping (r=0.816), and ‘viscoelasticity’ (r=0.909), a composite parameter index developed posthoc, were highly correlated to a manual assessment of hypertonia (Modified Ashworth Scale). 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source	MEDLINE; Elsevier ScienceDirect Journals
subjects	Aged Biomechanics Elbow Joint - physiology Female Humans Linear Models Male Middle Aged Muscle Hypertonia - diagnosis Muscle Hypertonia - etiology Muscle Hypertonia - physiopathology Reliability Spasticity Stroke Stroke - complications Stroke - physiopathology Torque Validity
title	Linear spring-damper model of the hypertonic elbow: reliability and validity
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