Estimating upper-extremity function from kinematics in stroke patients following goal-oriented computer-based training

Belén Rubio Ballester; Fabrizio Antenucci; Martina Maier; Anthony C C Coolen; Paul F M J Verschure

doi:10.1186/s12984-021-00971-8

Estimating upper-extremity function from kinematics in stroke patients following goal-oriented computer-based training

J Neuroeng Rehabil. 2021 Dec 31;18(1):186. doi: 10.1186/s12984-021-00971-8.

Authors

Belén Rubio Ballester¹, Fabrizio Antenucci², Martina Maier¹, Anthony C C Coolen³, Paul F M J Verschure^{1

4}

Affiliations

¹ Laboratory of Synthetic, Perceptive, Emotive and Cognitive Systems (SPECS), Institute for Bioengineering of Catalonia (IBEC), The Barcelona Institute of Science and Technology (BIST), Baldiri Reixac 10-12, 08028, Barcelona, Spain.
² Saddle Point Science Ltd, 10 Lincoln Street, York, UK. fabrizio.antenucci@saddlepointscience.com.
³ Saddle Point Science Ltd, 10 Lincoln Street, York, UK.
⁴ Institució Catalana de Recerca, Estudis Avançats (ICREA), Barcelona, Spain.

Abstract

Introduction: After a stroke, a wide range of deficits can occur with varying onset latencies. As a result, assessing impairment and recovery are enormous challenges in neurorehabilitation. Although several clinical scales are generally accepted, they are time-consuming, show high inter-rater variability, have low ecological validity, and are vulnerable to biases introduced by compensatory movements and action modifications. Alternative methods need to be developed for efficient and objective assessment. In this study, we explore the potential of computer-based body tracking systems and classification tools to estimate the motor impairment of the more affected arm in stroke patients.

Methods: We present a method for estimating clinical scores from movement parameters that are extracted from kinematic data recorded during unsupervised computer-based rehabilitation sessions. We identify a number of kinematic descriptors that characterise the patients' hemiparesis (e.g., movement smoothness, work area), we implement a double-noise model and perform a multivariate regression using clinical data from 98 stroke patients who completed a total of 191 sessions with RGS.

Results: Our results reveal a new digital biomarker of arm function, the Total Goal-Directed Movement (TGDM), which relates to the patients work area during the execution of goal-oriented reaching movements. The model's performance to estimate FM-UE scores reaches an accuracy of [Formula: see text]: 0.38 with an error ([Formula: see text]: 12.8). Next, we evaluate its reliability ([Formula: see text] for test-retest), longitudinal external validity ([Formula: see text] true positive rate), sensitivity, and generalisation to other tasks that involve planar reaching movements ([Formula: see text]: 0.39). The model achieves comparable accuracy also for the Chedoke Arm and Hand Activity Inventory ([Formula: see text]: 0.40) and Barthel Index ([Formula: see text]: 0.35).

Conclusions: Our results highlight the clinical value of kinematic data collected during unsupervised goal-oriented motor training with the RGS combined with data science techniques, and provide new insight into factors underlying recovery and its biomarkers.

Keywords: Interactive feedback; Motion classification; Motion sensing; Multivariate regression; Posture monitoring; Rehabilitation; Stroke; Upper extremities.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Biomechanical Phenomena
Goals
Humans
Recovery of Function
Reproducibility of Results
Stroke Rehabilitation* / methods
Stroke*
Upper Extremity