This study investigated how torso and shoulder positioning can help restore coordinated hand movements in stroke patients.
Stroke patients and healthy subjects were randomly divided into two different groups and tested in different positions. In study group 1, the exercise test consisted of two motor tasks carried out in two different starting positions: sitting and supine. During the first examination, the subject sat on the therapeutic table (without back support), feet resting on the floor (active stabilization of the trunk and shoulder). The upper limb was examined in adduction, with the elbow bent in the intermediate position between pronation and supination of the forearm. In the supine position, the upper limb was held beside the subject's body (adduction in the humeral joint, elbow flexion in the intermediate position; passive stabilization of the trunk and shoulder). In study group 2, the exercise test again consisted of two motor tasks carried out in two different starting positions: supine with the upper extremity positioned perpendicularly to the trunk (passive stabilization of the trunk, active stabilization of the shoulder), and supine with the upper limb held beside the subject's body (adduction in the humeral joint, elbow flexion in the intermediate position; passive stabilization of the trunk and shoulder). A manual electronic dynamometer (EH 101) was used for grip strength measurement (error of measurement, 0.5 kg/lb). A Hand Tutor device (composed of a safe and comfortable glove equipped with position and motion sensors, and the Medi Tutor(TM) software) was used to measure the range of passive and active movement (error of measurement, 5 - 10 mm), as well as the speed/frequency of movement (error of measurement, 0,5 cycle/sec.). First, the range of passive movement in the radial-carpal joint (flexion and extension) and fingers (global flexion and extension) was measured in each position using the Hand Tutor Device. Then the subject made active movements in the same order. Finally, the subject was asked to make moves as quickly and in as full a range as possible. The measurement of grip strength with a dynamometer was performed in each position after the range of motion and speed/frequency tests.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
TREATMENT
Masking
NONE
Enrollment
277
The subject sat on the therapeutic table (without back support), feet resting on the floor. The upper limb was examined in adduction, with the elbow bent in the intermediate position between pronation and supination of the forearm. Wrist and a hand free from stabilization.
motor tasks carried out in starting positions: supine with the upper extremity positioned perpendicularly to the trunk; the upper limb in adduction and flexion in the humeral joint, elbow extension, forearm in the intermediate position; elbow, wrist, hand free from stabilization.
Military Institute of Medicine
Warsaw, Masovian District, Poland
Range of passive movement of the wrist
The Hand Tutor allows measurements of the range of passive movement of the wrist (in mm).
Time frame: up to 10 weeks
Range of active movement of the wrist
The Hand Tutor allows measurements of the range of active movement of the wrist (in mm)
Time frame: up to 10 week
Wrist extension deficit (mm). The extension deficit refers to the difference between passive and active ROM.
The Hand Tutor allows measurements of the extension deficit (in mm)
Time frame: up to 10 weeks
Wrist flexion deficit mm
The Hand Tutor allows measurements of the flexion deficit (in mm). The flexion deficit refers to the difference between passive and active ROM.
Time frame: up to 10 weeks
Wrist maximum range of motion (ROM), mm
The Hand Tutor allows measurements of the maximum range of motion (ROM) (in mm), from flexion to extension.
Time frame: up to 10 weeks
Frequency of wrist movement (flexion to extension), cycles#/sec
The Hand Tutor allows measurements of the speed or frequency (i.e., the number of cycles per sec).
Time frame: up to 10 weeks
Range of passive movement of the fingers
The Hand Tutor allows measurements of the passive movement of the fingers (in mm)
Time frame: up to 10 weeks
Range of active movement of the fingers
The Hand Tutor allows measurements of the active movement of the fingers (in mm)
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In the supine position, the upper limb was held beside the subject's body (adduction in the humeral joint, elbow flexion in the intermediate position between pronation and supination of the forearm. Wrist and a hand free from stabilization.
Time frame: up to 10 weeks
Fingers extension deficit mm
The Hand Tutor allows measurements of the extension deficit (in mm). The extension deficit refers to the difference between passive and active ROM.
Time frame: up to 10 weeks
Fingers flexion deficit mm
The Hand Tutor allows measurements of the flexion deficit (in mm). The flexion deficit refers to the difference between passive and active ROM.
Time frame: up to 10 weeks
Fingers maximum range of motion (ROM), mm
The Hand Tutor allows measurements of the maximum range of motion (ROM) (in mm), from flexion to extension of each finger.
Time frame: up to 10 weeks
Frequency of fingers movement (flexion to extension), cycles#/sec
The Hand Tutor allows measurements of the speed or frequency (i.e., the number of cycles per sec)
Time frame: up to 10 weeks
Assessment of the grip strength
Grip strength, kg (a manusl electronic dynamometr (EH 101) was used for grip strength
Time frame: up to 10 weeks