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Related Experiment Video

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Study Motor Skill Learning by Single-pellet Reaching Tasks in Mice
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Interaction between model-based and model-free mechanisms in motor learning.

Adith Deva Kumar1, Adarsh Kumar2, Neeraj Kumar1

  • 1Department of Liberal Arts, Indian Institute of Technology Hyderabad, Hyderabad, India.

Journal of Neurophysiology
|October 13, 2025
PubMed
Summary
This summary is machine-generated.

Prior motor learning biases future adaptations. Initial exposure to small errors promotes model-free learning, while large errors favor model-based learning, impacting subsequent skill acquisition.

Keywords:
model-basedmodel-freemotor adaptationmotor learningperformance error

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Area of Science:

  • Motor neuroscience
  • Cognitive psychology
  • Human motor control

Background:

  • Motor learning utilizes distinct mechanisms: habitual, model-free (implicit) and strategic, model-based (explicit).
  • The influence of prior engagement of one mechanism on subsequent learning, particularly when task demands shift, is not well understood.

Purpose of the Study:

  • To investigate how prior exposure to specific motor learning mechanisms (model-free vs. model-based) influences subsequent motor adaptations.
  • To determine if these biases persist even when task conditions typically favor the alternative strategy.

Main Methods:

  • Participants (n=82) performed reaching movements with varying error magnitudes (small: 15°, large: 30°-60°) in three experiments.
  • The study manipulated error size to initially engage either model-free or model-based learning processes.
  • Washout phases were included to assess the persistence of learned biases.

Main Results:

  • Prior exposure to small errors led to persistent model-free aftereffects and stable reaction times, even with larger errors later.
  • Initial large errors induced model-based strategies (flexible reaction times, minimal aftereffects), which persisted with subsequent small errors.
  • These mechanistic biases remained even after washout phases, indicating durable imprints.

Conclusions:

  • Motor learning is hierarchically shaped by cumulative experiences, with early learning establishing frameworks that constrain future adaptations.
  • Prior engagement of either model-free or model-based processes significantly biases subsequent motor learning, prioritizing efficiency over flexibility.
  • Findings suggest initiating motor rehabilitation or training with model-based strategies may enhance long-term adaptability.