Abstract
Proprioception—the sense of body segment’s position and movement—plays a crucial role in human motor control, integrating the sensory information necessary for the correct execution of daily life activities. Despite scientific evidence recognizes that several neurological diseases hamper proprioceptive encoding with consequent inability to correctly perform movements, proprioceptive assessment in clinical settings is still limited to standard scales. Literature on physiology of upper limb’s proprioception is mainly focused on experimental approaches involving planar setups, while the present work provides a novel paradigm for assessing proprioception during single—and multi-joint matching tasks in a three-dimensional workspace. To such extent, a six-degrees of freedom exoskeleton, ALEx-RS (Arm Light Exoskeleton Rehab Station), was used to evaluate 18 healthy subjects’ abilities in matching proprioceptive targets during combined single and multi-joint arm’s movements: shoulder abduction/adduction, shoulder flexion/extension, and elbow flexion/extension. Results provided evidence that proprioceptive abilities depend on the number of joints simultaneously involved in the task and on their anatomical location, since muscle spindles work along their preferred direction, modulating the streaming of sensory information accordingly. These findings suggest solutions for clinical sensorimotor evaluation after neurological disease, where assessing proprioceptive deficits can improve the recovery path and complement the rehabilitation outcomes.
Highlights
Proprioception can be defined as the awareness of body segment positions and movements in the surrounding space [1]
We developed a protocol to compare “single”- versus “multi-joint” position matching in order to assess how perception of a proprioceptive target changes when multiple sensory information is encoded from the different sources or joints involved in the task
This study proposes a new paradigm using a robotic device for quantitively assessing upper limb proprioception during a three-dimensional Joint Position Matching task
Summary
Proprioception can be defined as the awareness of body segment positions and movements in the surrounding space [1]. Any change regarding a body district’s configuration activates mechanoreceptors located in joints, muscles, and tendons [2]. A key role in providing proprioceptive signals is played by the muscle spindles, the Golgi tendon organs, and the stretch receptors [3]. All the proprioceptive processes that promote awareness of body segment’s position are critical for the control of complex movement as well as posture [4]. Neurological injuries can significantly alter or deprive the central nervous system of peripheral sensory information [5], leading to a deterioration of the body awareness [6] and of the capacity to perform even a simple movement [7]. Despite gross motor functions are preserved [8], yet considerable sensorimotor deficits can persist [9]
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