Error-enhancement for Arm Rehabilitation Post Stroke

The overall aim of this study is to gain knowledge into the potential of error-enhancement robot training in patients with upper limb impairments in the chronic phase after stroke. Error-enhancement is characterized as unexpected external perturbation forces acting upon the upper limb during a reaching movement, causing the upper limb to deflect from the reaching pathway, and this results in errors. If one allows for repetitive reaching performance with the same systematic perturbation forces, then a decrease in errors and improvement in movement performance is expected. The robot used for the training, the DeXtreme, is a CE marked rehabilitation device that offers this error-enhancement approach during three-dimensional movements.

The pilot study has a pre-post intervention design, recruiting 20 patients in the chronic phase after stroke. Error-enhancement treatment will be provided on day 2 to 6, i.e., for 5 consecutive days and will consist of facilitation of accuracy, range of movement, stability, and smoothness. Algorithms provide progression in terms of accuracy, range of movement, stability and smoothness, depending upon the performance of the patient.

The treatment will start with the installation of the patient and a warming up, followed by a first block of DeXtreme training. Then a short break is given followed by a short conventional therapy session. The content of the conventional therapy will involve active relaxation, focusing on stretching and (auto-)mobilisation. Afterwards, a second block of training with the DeXtreme follows, and it finishes with a cooling down. A therapist trained by the company will provide all assessment and training sessions. Training with the DeXtreme is additional to the conventional therapy the patient receives. Therefore, a diary of their conventional therapy sessions will be kept, and the content will be reviewed with the patient.

Advancements in upper limb motor function and activity will be evaluated through a triad of measurements including clinical and patient-reported outcomes, error-enhancement variables, and objective quantification of uni- and bimanual sensorimotor function by making use of the KINARM robotic manipulandum. These tests and questionnaires are administered on day 1 and day 7.

The aim of the study is to investigate whether patients with upper limb impairments in a chronic phase after stroke clinical and meaningful benefits from 5 hours DeXtreme training. In addition, it is examined whether improvements in the upper limb outcome is the result of restitution or compensation in the upper limb function.

In order to evaluate whether a randomized controlled trial is useful, the investigators will analyse the outcomes of our study twofold. (1) At group level, the investigators will calculate mean and standard deviation or median and interquartile range (based on whether data is normally distributed or not) and evaluate whether pre- to post-intervention scores for clinical, deXtreme and objective outcomes are significantly improved by means of Wilcoxon signed rank test (nonparametric), at a 0,05 significance level. Each p-value will be interpreted in a descriptive manner.

(2) At patient level, the investigators will evaluate how many patients (%) achieve a clinically significant improvement based on the therapy provided.

To see if the improvement might be explained by restitution or compensation, the association between the scores of the MAL-14 and the visually guided reaching task of the KINARM will be explored by Spearman correlations.