Stretching the skin immediately enhances perceived stiffness and gradually enhances the predictive control of grip force.

Mor Farajian,Tomer Zaidenberg,Ferdinando A Mussa-Ivaldi,Raz Leib,Hanna Kossowsky,Ilana Nisky

doi:10.7554/elife.52653

Mor Farajian, Tomer Zaidenberg + Show 4 more

Open Access

https://doi.org/10.7554/elife.52653

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Journal: eLife	Publication Date: Apr 15, 2020
Citations: 25	License type: CC BY 4.0

Affiliation: Ben-Gurion University of the Negev, Northwestern University

Abstract

When manipulating objects, we use kinesthetic and tactile information to form an internal representation of their mechanical properties for cognitive perception and for preventing their slippage using predictive control of grip force. A major challenge in understanding the dissociable contributions of tactile and kinesthetic information to perception and action is the natural coupling between them. Unlike previous studies that addressed this question either by focusing on impaired sensory processing in patients or using local anesthesia, we used a behavioral study with a programmable mechatronic device that stretches the skin of the fingertips to address this issue in the intact sensorimotor system. We found that artificial skin-stretch increases the predictive grip force modulation in anticipation of the load force. Moreover, the stretch causes an immediate illusion of touching a harder object that does not depend on the gradual development of the predictive modulation of grip force.

Highlights

During everyday interactions with objects, we control and sense the position of these objects and the forces they exert on us
We examined the effect of adding artificial skin-stretch to kinesthetic load force on the predictive control of grip force
We can conclude that the perceptual illusion was formed immediately, after a single probing movement into the force field, and before the increase in the predictive modulation of grip force in anticipation of load force that we identified in Experiment 1 was formed

Summary

Introduction

During everyday interactions with objects, we control and sense the position of these objects and the forces they exert on us. This occurs in perceptual tasks, such as when assessing the stiffness of an object using a tool (LaMotte, 2000), and in actions, such as when manipulating the same tool during probing of the object while adjusting the grip force – the perpendicular force between the digits and the object. Since we do not possess sensors for mechanical impedance, the perception of the impedance of objects, such as their stiffness, damping, and inertia, is based on the integration of motion and force signals, which are sensed during contact with the environment (Jones and Hunter, 1993; Nisky et al, 2008; Kuschel et al, 2010; Nisky et al, 2010; Gurari et al, 2012)

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