Neural Control of Motion-to-force Transitions with the Fingertip

Overview

Journal J Neurosci

Specialty Neurology

Date 2008 Feb 8

PMID 18256256

Citations 42

Authors

Madhusudhan Venkadesan

Francisco J Valero-Cuevas

Affiliations

Soon will be listed here.

Abstract

The neural control of tasks such as rapid acquisition of precision pinch remains unknown. Therefore, we investigated the neural control of finger musculature when the index fingertip abruptly transitions from motion to static force production. Nine subjects produced a downward tapping motion followed by vertical fingertip force against a rigid surface. We simultaneously recorded three-dimensional fingertip force, plus the complete muscle coordination pattern using intramuscular electromyograms from all seven index finger muscles. We found that the muscle coordination pattern clearly switched from that for motion to that for isometric force approximately 65 ms before contact (p = 0.0004). Mathematical modeling and analysis revealed that the underlying neural control also switched between mutually incompatible strategies in a time-critical manner. Importantly, this abrupt switch in underlying neural control polluted fingertip force vector direction beyond what is explained by muscle activation-contraction dynamics and neuromuscular noise (p < or = 0.003). We further ruled out an impedance control strategy in a separate test showing no systematic change in initial force magnitude for catch trials where the tapping surface was surreptitiously lowered and raised (p = 0.93). We conclude that the nervous system predictively switches between mutually incompatible neural control strategies to bridge the abrupt transition in mechanical constraints between motion and static force. Moreover because the nervous system cannot switch between control strategies instantaneously or exactly, there arise physical limits to the accuracy of force production on contact. The need for such a neurally demanding and time-critical strategy for routine motion-to-force transitions with the fingertip may explain the existence of specialized neural circuits for the human hand.

Citing Articles

A computational study of how an α- to γ-motoneurone collateral can mitigate velocity-dependent stretch reflexes during voluntary movement.

Niyo G, Almofeez L, Erwin A, Valero-Cuevas F Proc Natl Acad Sci U S A. 2024; 121(34):e2321659121.

PMID: 39116178 PMC: 11348295. DOI: 10.1073/pnas.2321659121.

Effects of noninvasive neuromodulation targeting the spinal cord on early learning of force control by the digits.

Urbin M, Lafe C, Bautista M, Wittenberg G, Simpson T CNS Neurosci Ther. 2024; 30(2):e14561.

PMID: 38421127 PMC: 10851178. DOI: 10.1111/cns.14561.

Evolution, biomechanics, and neurobiology converge to explain selective finger motor control.

Xu J, Mawase F, Schieber M Physiol Rev. 2024; 104(3):983-1020.

PMID: 38385888 PMC: 11380997. DOI: 10.1152/physrev.00030.2023.

An alpha- to gamma-motoneurone collateral can mitigate velocity-dependent stretch reflexes during voluntary movement: A computational study.

Niyo G, Almofeez L, Erwin A, Valero-Cuevas F bioRxiv. 2023; .

PMID: 38106121 PMC: 10723443. DOI: 10.1101/2023.12.08.570843.

Muscle redundancy is greatly reduced by the spatiotemporal nature of neuromuscular control.

Cohn B, Valero-Cuevas F Front Rehabil Sci. 2023; 4:1248269.

PMID: 38028155 PMC: 10663283. DOI: 10.3389/fresc.2023.1248269.

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