Brevity of haptic force perturbations induces heightened adaptive sensitivity
Identifieur interne : 000262 ( PascalFrancis/Corpus ); précédent : 000261; suivant : 000263Brevity of haptic force perturbations induces heightened adaptive sensitivity
Auteurs : Paul A. Wanda ; Michael S. Fine ; Heidi M. Weeks ; Andrew M. Gross ; Jenny L. Macy ; Kurt A. ThoroughmanSource :
- Experimental brain research [ 0014-4819 ] ; 2013.
Descripteurs français
- Pascal (Inist)
English descriptors
- KwdEn :
Abstract
We have exposed human participants to both full-movement and pulsatile viscous force perturbations to study the effect of force duration on the incremental transformation of sensation into adaptation. Traditional views of movement biomechanics could suggest that pulsatile forces would largely be attenuated as stiffness and viscosity act as a natural low-pass filter. Sensory transduction, however, tends to react to changes in stimuli and therefore could underlie heightened sensitivity to briefer, pulsatile forces. Here, participants adapted within perturbation duration conditions in a manner proportionate to sensed force and positional errors. Across perturbation conditions, we found participants had greater adaptive sensitivity when experiencing pulsatile forces rather than full-movement forces. In a follow-up experiment, we employed error-clamped, force channel trials to determine changes in predictive force generation. We found that while participants learned to closely compensate for the amplitude and breadth of full-movement forces, they exhibited a persistent mismatch in amplitude and breadth between adapted motor output and experienced pulsatile forces. This mismatch could generate higher salience of error signals that contribute to heightened sensitivity to pulsatile forces.
Notice en format standard (ISO 2709)
Pour connaître la documentation sur le format Inist Standard.
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Format Inist (serveur)
NO : | FRANCIS 13-0185153 INIST |
---|---|
ET : | Brevity of haptic force perturbations induces heightened adaptive sensitivity |
AU : | WANDA (Paul A.); FINE (Michael S.); WEEKS (Heidi M.); GROSS (Andrew M.); MACY (Jenny L.); THOROUGHMAN (Kurt A.) |
AF : | Department of Biomedical Engineering, Washington University in St. Louis, One Brookings Drive, Campus Box 1097/St. Louis, MO 63130/Etats-Unis (1 aut., 2 aut., 3 aut., 4 aut., 5 aut., 6 aut.) |
DT : | Publication en série; Niveau analytique |
SO : | Experimental brain research; ISSN 0014-4819; Coden EXBRAP; Allemagne; Da. 2013; Vol. 226; No. 3; Pp. 407-420; Bibl. 3/4 p. |
LA : | Anglais |
EA : | We have exposed human participants to both full-movement and pulsatile viscous force perturbations to study the effect of force duration on the incremental transformation of sensation into adaptation. Traditional views of movement biomechanics could suggest that pulsatile forces would largely be attenuated as stiffness and viscosity act as a natural low-pass filter. Sensory transduction, however, tends to react to changes in stimuli and therefore could underlie heightened sensitivity to briefer, pulsatile forces. Here, participants adapted within perturbation duration conditions in a manner proportionate to sensed force and positional errors. Across perturbation conditions, we found participants had greater adaptive sensitivity when experiencing pulsatile forces rather than full-movement forces. In a follow-up experiment, we employed error-clamped, force channel trials to determine changes in predictive force generation. We found that while participants learned to closely compensate for the amplitude and breadth of full-movement forces, they exhibited a persistent mismatch in amplitude and breadth between adapted motor output and experienced pulsatile forces. This mismatch could generate higher salience of error signals that contribute to heightened sensitivity to pulsatile forces. |
CC : | 770B06D01 |
FD : | Force; Perturbation; Sensation; Biomécanique; Rigidité; Viscosité; Apprentissage; Contrôle moteur; Homme; Perception haptique |
FG : | Processus acquisition |
ED : | Force; Perturbation; Sensation; Biomechanics; Stiffness; Viscosity; Learning; Motor control; Human; Haptic perception |
EG : | Acquisition process |
SD : | Fuerza; Perturbación; Sensación; Biomecánica; Rigidez; Viscosidad; Aprendizaje; Control motor; Hombre |
LO : | INIST-12535.354000173386670100 |
ID : | 13-0185153 |
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Francis:13-0185153Le document en format XML
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<front><div type="abstract" xml:lang="en">We have exposed human participants to both full-movement and pulsatile viscous force perturbations to study the effect of force duration on the incremental transformation of sensation into adaptation. Traditional views of movement biomechanics could suggest that pulsatile forces would largely be attenuated as stiffness and viscosity act as a natural low-pass filter. Sensory transduction, however, tends to react to changes in stimuli and therefore could underlie heightened sensitivity to briefer, pulsatile forces. Here, participants adapted within perturbation duration conditions in a manner proportionate to sensed force and positional errors. Across perturbation conditions, we found participants had greater adaptive sensitivity when experiencing pulsatile forces rather than full-movement forces. In a follow-up experiment, we employed error-clamped, force channel trials to determine changes in predictive force generation. We found that while participants learned to closely compensate for the amplitude and breadth of full-movement forces, they exhibited a persistent mismatch in amplitude and breadth between adapted motor output and experienced pulsatile forces. This mismatch could generate higher salience of error signals that contribute to heightened sensitivity to pulsatile forces.</div>
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<ET>Brevity of haptic force perturbations induces heightened adaptive sensitivity</ET>
<AU>WANDA (Paul A.); FINE (Michael S.); WEEKS (Heidi M.); GROSS (Andrew M.); MACY (Jenny L.); THOROUGHMAN (Kurt A.)</AU>
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