Investigating Motor Preparation in Synchronous Hand and Foot Movements Under Reactive Vs. Predictive Control

Overview

Journal Exp Brain Res

Specialty Neurology

Date 2023 Mar 4

PMID 36869897

Authors

Allison Bui

Dana Maslovat

Yves Lajoie

Anthony N Carlsen

Affiliations

Soon will be listed here.

Abstract

Synchronizing hand and foot movements under reactive versus predictive control results in differential timing structures between the responses. Under reactive control, where the movement is externally triggered, the electromyographic (EMG) responses are synchronized, resulting in the hand displacement preceding the foot. Under predictive control, where the movement is self-paced, the motor commands are organized such that the displacement onset occurs relatively synchronously, requiring the EMG onset of the foot to precede that of the hand. The current study used a startling acoustic stimulus (SAS), which can involuntarily trigger a prepared response, to investigate whether these results are due to differences in a pre-programmed timing structure of the responses. Participants performed synchronous movements of the right heel and right hand under both reactive and predictive modes of control. The reactive condition involved a simple reaction time (RT) task, whereas the predictive condition involved an anticipation-timing task. On selected trials, a SAS (114 dB) was presented 150 ms prior to the imperative stimulus. Results from the SAS trials revealed that while the differential timing structures between the responses was maintained under both reactive and predictive control, the EMG onset asynchrony under predictive control was significantly smaller following the SAS. These results suggest that the timing between the responses, which differs between the two control modes, is pre-programmed; however, under predictive control, the SAS may accelerate the internal timekeeper, resulting in a shortened between-limb delay.

Citing Articles

An intense electrical stimulus can elicit a StartReact effect but with decreased incidence and later onset of the startle reflex.

Daher E, Maslovat D, Carlsen A Exp Brain Res. 2024; 242(10):2405-2417.

PMID: 39136724 DOI: 10.1007/s00221-024-06899-4.

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