Abstract
Humans closely coordinate the grip force exerted on a hand-held object with changes in the load arising from the object’s dynamics. Recent work suggests the grip force is responsive to the predictability of the load forces as well. The well-known grip-force–load-force coupling is intermittent when the load arising from volitional movements fluctuates predictably, whereas grip force increases when loads are unpredictable. Here, we studied the influence of expected but uncertain volitional movements on the digit forces during a static grasp. Young, healthy participants used a pinch grasp to hold an instrumented object and track visual targets by moving the object. We quantified the mean grip force, the temporal decline in grip force (slacking), and the coupling between the pressing digit forces that yield the grip force during static prehension with no expectation of movement, and during the static phase of a choice reaction time task, when the participant expected to move the object after a variable duration. Simply expecting to move the object led to sustained (for at least 5 s) higher magnitude and lower slacking in the grip force, and weaker coupling between the pressing digit forces. These effects were modulated by the direction of the expected movement and the object’s mass. The changes helped to maintain the safety margin for the current grasp and likely facilitated the transition from static to dynamic object manipulation. Influence of expected actions on the current grasp may have implications for manual dexterity and its well-known loss with age.
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Data availability statement
The data sets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.
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Naik, A., Ambike, S. Expectation of volitional arm movement has prolonged effects on the grip force exerted on a pinched object. Exp Brain Res 240, 2607–2621 (2022). https://doi.org/10.1007/s00221-022-06438-z
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DOI: https://doi.org/10.1007/s00221-022-06438-z