Learning Realistic Joint Space Boundaries for Range of Motion
Analysis of Healthy and Impaired Human Arms

Shafagh Keyvanian, Michelle J. Johnson, PhD, Nadia Figueroa, PhD

University of Pennsylvania | Rehabilitation Robotics Lab | Figueroa Robotics Lab | GRASP Laboratory | Perelmen School of Medicine

Paper

Code

Poster

Shafagh Keyvanian

Michelle Johnson, PhD

Nadia Figueroa, PhD

Abstract

A realistic human kinematic model that satisfies anatomical constraints is essential for human-robot interaction, biomechanics and robot-assisted rehabilitation. Modeling realistic joint constraints, however, is challenging as human arm motion is constrained by joint limits, inter- and intra-joint dependencies, self-collisions, individual capabilities and muscular or neurological constraints which are difficult to represent. Hence, physicians and researchers have relied on simple box-constraints, ignoring important anatomical factors. In this paper, we propose a data-driven method to learn realistic anatomically constrained upper-limb range of motion (RoM) boundaries from motion capture data. This is achieved by fitting a one-class support vector machine to a dataset of upper-limb joint space exploration motions with an efficient hyper-parameter tuning scheme. Our approach outperforms similar works focused on valid RoM learning. Further, we propose an impairment index (II) metric that offers a quantitative assessment of capability/impairment when comparing healthy and impaired arms. We validate the metric on healthy subjects physically constrained to emulate hemiplegia and different disability levels as stroke patients.

Motivation

Human-capability aware Robotic Rehabilitation

Stroke survivors population growing to exceed 70 million by 2030.
A significant shortage of therapists is anticipated, creating a gap between required and provided rehabilitation services. Rehabilitation robots can fill in the gap.
To enable autonomous robotic rehabilitation, the therapeutic strategy should be tailored based on each patient’s capabilities.

Challenges

Realistic Range-of-Motion

Modeling realistic RoM is challenging as human motion limits depends on:

1. 1. Inter- and intra-joint dependencies, self-collisions, neuromuscular capabilities, motor synergistic movements.
  2. human's flexibility/capability level, demographics, and background

RoM in stroke: Impaired vs. intact arm

hemiplegia or hemiparesis: paralysis or weakness on one side of the body, and the most common physical consequence of stroke

RoM depends on

- Patient’s impairment severity
- Patient’s demographics
- Patient’s life-style and background
- Stroke synergistic movements

Inter-joint dependancy:
different shoulder abduction limit with elbow flexion

Hemiplegic stroke:different capability (RoM) in impaired and intact arm

Methods

Experiments & Data Construction

No stroke patients and therapists are recruited for this phase of the project.
The impairment is emulated by using extra weights and resistance band on the right arm of participants
Wights and bands are chosen to simulate different levels of impairment