Trunk Restraint Therapy in Post-stroke Patients.

Not Applicable

Completed

• Conditions: Stroke
• Interventions: Other: Trunk unrestraint therapy; Other: Trunk restraint therapy

• Registration Number: NCT02364141
• Lead Sponsor: University of Campinas, Brazil

Brief Summary

The aim of this study was to evaluate the long-term effects of the task-specific training with trunk restraint comparing to the free one in post-stroke reaching movements. Twenty hemiparetic chronic stroke patients were selected and randomized into two training groups: Trunk restraint group - TRG (reaching training with trunk restraint) and Trunk free group - TFG (unrestraint reaching). Twenty sessions with forty-five minutes of training were accomplished. The subjects were evaluated in pre-treatment (PRE), post-treatment (POST) and three months after the completed training (RET). The measures administered were the Modified Ashworth Scale, Barthel Index, Fugl-Meyer Scale and kinematic analysis (movement trajectory, velocity, angles).

Detailed Description

Twenty stroke subjects were recruited from the Physiotherapy and Occupational Therapy Outpatient Unit of the University Hospital at Campinas - UNICAMP and all of them signed informed consent forms previously approved by the Research Ethics Committee of the University (#110/2004). Ten healthy subjects were also selected to obtain normal reference parameters of kinematic assessment. Patients had sustained a single and chronic (\>6 months post-event) unilateral stroke of non-traumatic origin, with hemiparetic sequel in the upper limb, could understand simple instructions, perform community gait, and had a good sitting balance. Those with shoulder pain or other neurological and orthopedic conditions affecting the reaching movement ability or trunk, hemispatial neglect or apraxia were excluded. The patients who met the inclusion criteria were stratified to one of two groups. A sealed opaque envelope containing a single cheat of paper marked with numbers 1 (group 1) or 2 (group 2), was used to allocate the patient. This procedure was made by an external assessor. The patients were not informed about the different treatment groups and therefore, they were blind for the type of intervention applied.

The muscle tone (shoulder and elbow flexors) was evaluated using the Modified Ashworth Scale (MAS)9; motor impairment was evaluated using the upper limb section of Fugl-Meyer Assessment Scale (FM) and activities of daily living was assessed by the Barthel Index (BI). Kinematic data were recorded by an infrared system of motion analysis (Qualisys Motion Capture System - 2.57 Sweden) with sample frequency of 240 Hz, during 8 seconds. The coordinated data was low-pass filtered using a 6 Hz, finite impulse response filter with order 26 using the Matlab software. Five infrared reflexive markers were used. For the kinematic capture, the subjects were seated in a chair and invited to fit a cone in a target placed within arm's length (measured on the non-affected arm from the medial border of axilla to the distal wrist crease). The target was placed so that only the arm movement was required to reach the target. The initial hand position of the affected arm was on the lateral trunk, with the shoulder in neutral position and the elbow close to the side of the body (90°). Three trials of 6 to 8 seconds' time were recorded and a media was used to calculate the evaluated data.From the collected dates, values concerning to sagittal (YZ), horizontal (XY) and 3-dimensional (XYZ) planes were computed.

Trunk displacement was verified in millimeters as sagittal movement of marker 3.

Index of curvature was measured from marker 5. This index shows the straightness of the wrist trajectory from the initial position to the goal, resulting in a ratio of actual end point path to a straight line (index = 1, whereas a semicircle has an index of 1.57).

Shoulder angles were calculated using 2 vectors formed from marker 1 to marker 2, and from marker 2 to marker 4; with flexion/extension movements in sagittal plane and adduction/abduction movement in horizontal plane. Full horizontal abduction and the anatomical position were considered at 0°. Flexion/extension elbow angles were measured using 2 vectors formed from marker 2 to 4 and from marker 4 to 5, using the sagittal and horizontal planes. The elbow full extension was considered at 180°.

Movement time was defined as differences between movement onsets and offsets which tangential velocity rose above and fell below at 5% of its peak value.

The maximum tangential velocity of the arm was computed from the velocity vector expressed by a numerical differentiation from wrist and sternum markers in the 3-dimensional plane. Numbers of peaks and the percentage of movement time at the maximum peak velocity (rate - %) were extracted from tangential velocity traces.

The evaluations were performed by a blind researcher, in admission time (PRE), after the end of the twenty treatment sessions (POST) and three months after the training was completed (retention test - RET).

The selected patients were randomized individually into two training groups:

Trunk restraint group - TRG (n = 10): reaching training with trunk restraint by a harness that limited the trunk movements.

Trunk free group - TFG (n = 10): unrestraint reaching training, only with verbal feedback to maintain the trunk right position.

Forty-five training minutes, twice a week, totaling twenty sessions, were performed (The participants will be trained for 10 weeks, and with 3 months of follow-up).

The training was based in the motor learning concepts including repetitive and task-specific practice. The training task consisted of grasping a cone (3.5 cm diameter base, 13 cm high) and fitting random targets as requested by the therapist in a training platform (54 cm length, 64 cm extent, 1.5 cm high) with 9 targets (6.5 cm diameter) placed 10-13 cm apart, along 3 lines. The targets that were ordered in a way that stimulated the complete range of motion of shoulder and elbow, had pictures, colors, letters and numbers on them yielding variability and feedback to the performing tasks.

Chi-squared, or Fisher's tests, was used to compare the categorical variables (i.e. gender) between the three groups (HS, TRG, TFG). Mann-Whitney (for two groups) and Kruskal-Wallis (for three groups) tests were used to compare the ratio dates (i.e. age, years since stroke) measured at a single instant. Repeated-measure analysis of variance (ANOVA) and appropriate post-hoc tests (Bonferroni) were applied to compare the numerical variables (i.e. kinematics dates) between groups and instants. The normality of the kinematic variables was detected by Shapiro-Francia test and for variables that were not normal was proposed Box-Cox transformation. The significance level adopted for the statistical tests was 5% (p\< 0.05).

Study Timeline

• Study Start: 2004-08
• Primary Completion: 2007-11
• Study Completion: 2008-07
• Status Verified: 2015-02
• Study First Submitted: 2015-02-05
• Study First Submitted QC: 2015-02-13
• Last Update Submitted: 2015-02-13
• Study First Posted: 2015-02-16
• Last Update Posted: 2015-02-16

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 40

Inclusion Criteria

• single and chronic (>6 months post-event) unilateral stroke of non-traumatic origin
• hemiparetic sequel in the upper limb
• could understand simple instructions
• perform community gait
• had a good sitting balance

Exclusion Criteria

• shoulder pain or other neurological and orthopedic conditions affecting the reaching movement ability or trunk
• hemispatial neglect
• apraxia

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
Trunk unrestraint therapy	Trunk unrestraint therapy	Unrestraint reaching training, only with verbal feedback to maintain the trunk right position.
Trunk restraint therapy	Trunk restraint therapy	Reaching training with trunk restraint by a harness that limited the trunk movements.

Primary Outcome Measures

Name	Time	Method
upper limb motor impairment	10 weeks	by Fugl-Meyer Assessment Scale (FM)
muscle tone (shoulder and elbow flexors)	10 weeks	by Modified Ashworth Scale (MAS)
activities of daily living level	10 weeks	by Barthel Index (BI)

Secondary Outcome Measures

Name	Time	Method
maximum peak velocity	10 weeks	Kinematic data
Trunk displacement in millimeters as sagittal movement	10 weeks	Kinematic data
Index of curvature of wrist trajectory	10 weeks	Kinematic data
Shoulder and elbow angles	10 weeks	Kinematic data
Movement time	10 weeks	Kinematic data
maximum tangential velocity	10 weeks	Kinematic data
Numbers of peaks	10 weeks	Kinematic data