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A model for self-organization of sensorimotor function: the spinal monosynaptic loop.

Jonas M D Enander1, Adam M Jones2, Matthieu Kirkland2

  • 1Department of Experimental Medical Science, Faculty of Medicine, Lund University, Lund, Sweden.

Journal of Neurophysiology
|March 10, 2022
PubMed
Summary

Spinal cord circuits can self-organize through learning and muscle activity, not just genetic preprogramming. Modeling beta motoneurons and reduced muscle contractility during development is key for correct Ia to motoneuron connectivity.

Keywords:
extrafusal muscleintrafusal musclemuscle spindleneuron modelspinal development

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Area of Science:

  • Neuroscience
  • Developmental Biology
  • Computational Biology

Background:

  • Spinal cord circuit formation is often attributed to genetic preprogramming.
  • The precise mechanisms underlying the selective formation of monosynaptic Ia afferent to motoneuron projections remain incompletely understood.

Purpose of the Study:

  • To investigate the role of learning and self-organization in the formation of spinal circuitry.
  • To determine if activity-dependent mechanisms, rather than solely genetic preprogramming, can explain the development of Ia afferent-motor neuron connections.

Main Methods:

  • A computational neural network model was developed, incorporating Hebbian plasticity.
  • The model simulated spontaneous muscle activity patterns observed during early fetal development.
  • Key biological features, including beta motoneurons and reduced extrafusal muscle contractility, were modeled.

Main Results:

  • Normal Ia afferent to motoneuron connectivity patterns emerged when beta motoneurons and reduced muscle contractility were included in the model.
  • The model demonstrated that Hebbian plasticity and simulated early muscle activity could drive circuit self-organization.
  • Overly strong or coordinated activity patterns, mimicking later developmental stages, impaired projection selectivity.

Conclusions:

  • Spinal circuitry formation, specifically Ia to motoneuron connectivity, can be achieved through self-organization driven by muscle activity and neuronal plasticity.
  • This learning-based mechanism provides a generic functionality for musculoskeletal systems to imprint mechanical dynamics onto neural networks.
  • This model offers insights into how connectivity patterns form without explicit genetic rules and may explain adaptations during abnormal development or evolution.