Litcius/Paper detail

Learning to stand with unexpected sensorimotor delays

Brandon G. Rasman, Patrick A. Forbes, Ryan M. Peters, Oscar Ortiz, Ian M. Franks, J. Timothy Inglis, Romeo Chua, Jean‐Sébastien Blouin

2021eLife29 citationsDOIOpen Access PDF

Abstract

Human standing balance relies on self-motion estimates that are used by the nervous system to detect unexpected movements and enable corrective responses and adaptations in control. These estimates must accommodate for inherent delays in sensory and motor pathways. Here, we used a robotic system to simulate human standing about the ankles in the anteroposterior direction and impose sensorimotor delays into the control of balance. Imposed delays destabilized standing, but through training, participants adapted and re-learned to balance with the delays. Before training, imposed delays attenuated vestibular contributions to balance and triggered perceptions of unexpected standing motion, suggesting increased uncertainty in the internal self-motion estimates. After training, vestibular contributions partially returned to baseline levels and larger delays were needed to evoke perceptions of unexpected standing motion. Through learning, the nervous system accommodates balance sensorimotor delays by causally linking whole-body sensory feedback (initially interpreted as imposed motion) to self-generated balance motor commands.

Topics & Concepts

Balance (ability)Vestibular systemSensory systemMotion (physics)Physical medicine and rehabilitationMotor learningPerceptionMotor controlPsychologyComputer scienceControl (management)Control theory (sociology)NeuroscienceArtificial intelligenceMedicineMotor Control and AdaptationBalance, Gait, and Falls PreventionVestibular and auditory disorders
Learning to stand with unexpected sensorimotor delays | Litcius