The integration of haptically acquired size information in the programming of precision grip

Recent evidence for the use of visual cues in the programming of the precision grip has been given by Gordon et al. (1991). Visually invoked size-related information influenced the physical forces used to produce a lift, even when it was not consistent with other sensory information. In the present...

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Veröffentlicht in:	Experimental brain research 1991-02, Vol.83 (3), p.483-488
Hauptverfasser:	GORDON, A. M, FORSSBERG, H, JOHANSSON, R. S, WESTLING, G
Format:	Artikel
Sprache:	eng
Schlagworte:	Adult Biological and medical sciences Female Fundamental and applied biological sciences. Psychology Hand - physiology Humans Isometric Contraction Male Middle Aged Movement Muscles - innervation Perception Psychology. Psychoanalysis. Psychiatry Psychology. Psychophysiology Space life sciences Vision Vision, Ocular Visual Perception
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container_title	Experimental brain research
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creator	GORDON, A. M FORSSBERG, H JOHANSSON, R. S WESTLING, G
description	Recent evidence for the use of visual cues in the programming of the precision grip has been given by Gordon et al. (1991). Visually invoked size-related information influenced the physical forces used to produce a lift, even when it was not consistent with other sensory information. In the present study, blind-folded subjects were required to feel the size of an object by haptic exploration prior to lifting it. Two boxes of equal weight and unequal size were used for the lift objects and were attached to an instrumented (grip) handle. Grip force and load force, their rates, and the vertical movement of the object were measured. Most subjects reported that the small box was heavier, which is consistent with size-weight illusion predictions. However, peak grip force, grip force rate, peak load force, and load force rate were greater for the large box when the boxes were randomly presented, but not when the same boxes were lifted consecutively. If subjects did not feel the box prior to a lift, these parameters were scaled in between those normally employed for the large and small box. Most subjects apparently programmed the parallel increase of the grip and load force during the loading phase as one force rate pulse. This represented a "target strategy" in which an internal neural representation of the objects weight determined the actual target parameter (i.e. just enough force required to overcome gravity). The other subjects exhibited a slower stepwise increase in grip and load force rate. The subjects choosing this "probing strategy" did not scale the force parameters differently for the two boxes.
doi_str_mv	10.1007/bf00229825
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However, peak grip force, grip force rate, peak load force, and load force rate were greater for the large box when the boxes were randomly presented, but not when the same boxes were lifted consecutively. If subjects did not feel the box prior to a lift, these parameters were scaled in between those normally employed for the large and small box. Most subjects apparently programmed the parallel increase of the grip and load force during the loading phase as one force rate pulse. This represented a "target strategy" in which an internal neural representation of the objects weight determined the actual target parameter (i.e. just enough force required to overcome gravity). The other subjects exhibited a slower stepwise increase in grip and load force rate. 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Most subjects reported that the small box was heavier, which is consistent with size-weight illusion predictions. However, peak grip force, grip force rate, peak load force, and load force rate were greater for the large box when the boxes were randomly presented, but not when the same boxes were lifted consecutively. If subjects did not feel the box prior to a lift, these parameters were scaled in between those normally employed for the large and small box. Most subjects apparently programmed the parallel increase of the grip and load force during the loading phase as one force rate pulse. This represented a "target strategy" in which an internal neural representation of the objects weight determined the actual target parameter (i.e. just enough force required to overcome gravity). The other subjects exhibited a slower stepwise increase in grip and load force rate. 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S</au><au>WESTLING, G</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>The integration of haptically acquired size information in the programming of precision grip</atitle><jtitle>Experimental brain research</jtitle><addtitle>Exp Brain Res</addtitle><date>1991-02</date><risdate>1991</risdate><volume>83</volume><issue>3</issue><spage>483</spage><epage>488</epage><pages>483-488</pages><issn>0014-4819</issn><eissn>1432-1106</eissn><coden>EXBRAP</coden><abstract>Recent evidence for the use of visual cues in the programming of the precision grip has been given by Gordon et al. (1991). Visually invoked size-related information influenced the physical forces used to produce a lift, even when it was not consistent with other sensory information. In the present study, blind-folded subjects were required to feel the size of an object by haptic exploration prior to lifting it. Two boxes of equal weight and unequal size were used for the lift objects and were attached to an instrumented (grip) handle. Grip force and load force, their rates, and the vertical movement of the object were measured. Most subjects reported that the small box was heavier, which is consistent with size-weight illusion predictions. However, peak grip force, grip force rate, peak load force, and load force rate were greater for the large box when the boxes were randomly presented, but not when the same boxes were lifted consecutively. If subjects did not feel the box prior to a lift, these parameters were scaled in between those normally employed for the large and small box. Most subjects apparently programmed the parallel increase of the grip and load force during the loading phase as one force rate pulse. 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source	MEDLINE; SpringerLink Journals - AutoHoldings
subjects	Adult Biological and medical sciences Female Fundamental and applied biological sciences. Psychology Hand - physiology Humans Isometric Contraction Male Middle Aged Movement Muscles - innervation Perception Psychology. Psychoanalysis. Psychiatry Psychology. Psychophysiology Space life sciences Vision Vision, Ocular Visual Perception
title	The integration of haptically acquired size information in the programming of precision grip
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