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Arm cooling selectively impacts sensorimotor control.

Cecile R Scotto1, Florian Petitcollin1, Olivier Dupuy2,3

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Summary
This summary is machine-generated.

Cold exposure impacts sensorimotor control by slowing proprioceptive processing. This affects both feedback and feedforward control, altering action representations and movement execution.

Keywords:
Fitts’s taskcryotherapyimplicit motor imagerysensorimotor control

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Area of Science:

  • Neuroscience
  • Human Movement Science
  • Sports Medicine

Background:

  • Cold exposure is recognized for its benefits in sports and medicine.
  • However, the costs of cold, particularly on sensorimotor control, are less understood.
  • Proprioceptive cue processing may be affected by cold, impacting motor control.

Purpose of the Study:

  • To investigate how arm cooling affects sensorimotor representations and control.
  • To test the hypothesis that cold slows proprioceptive processing, impacting feedback and feedforward control.
  • To examine the effects of cold on action representations and motor imagery.

Main Methods:

  • Experiment 1: Participants performed a Fitts's pointing task after arm immersion in cold (14°C) or lukewarm (34°C) water, with kinematic analysis.
  • Experiment 2: Participants completed a hand laterality task (assessing mental hand representation) with a cooled or non-cooled hand, without physical movement.

Main Results:

  • Cold exposure altered early kinematic parameters in pointing, suggesting impacts on feedforward control or hand representation.
  • Cold exposure modified late kinematic parameters in pointing, indicating changes in proprioceptive feedback utilization.
  • Performance on the hand laterality task was impaired with a cooled hand, particularly at extreme orientations, supporting altered action representations.

Conclusions:

  • Arm cooling influences sensorimotor control by affecting both feedback and feedforward processes.
  • Cold exposure appears to modify the internal representation of the body, specifically the hand.
  • These findings highlight the complex effects of cold on the nervous system's control of movement and perception.