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Monday Jan. 16 Chapter 15 rm 357

Monday Jan. 16 Chapter 15 rm 357. Threshold for activation Examples of motor units Motor unit recruitment The muscle spindle The influence of sensory activity on movement Other sensory feedback affects motor performance. Threshold for activation.

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Monday Jan. 16 Chapter 15 rm 357

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  1. Monday Jan. 16Chapter 15rm 357 • Threshold for activation • Examples of motor units • Motor unit recruitment • The muscle spindle • The influence of sensory activity on movement • Other sensory feedback affects motor performance 03-44-485

  2. Threshold for activation • Small slow motor units have low threshold of activation • Are tonically active (posture) 03-44-485

  3. Threshold of activation • For large, fast motor units • Reached for rapid movements with great force (eg. Jumping) 03-44-485

  4. Examples of motor units • In the soleus (posture) • Small motor units (180) • In the gastrocnemus • Mixture of small and large motor units (up to 2000) • In extra-ocular muscle • Tiny motor units (3) 03-44-485

  5. Motor unit recruitment • Progressive increase in muscle tension from motor units recruiting according to their size. • Weak stimulus activates small motor units 03-44-485

  6. Motor unit recruitment • Low threshold S units • --> FR units • --> FF units • The size principle: systematic relationship for orderly recruitment. • Fig. 15.6 03-44-485

  7. Effect of action potential frequency • Contributes to muscle tension • Summation of muscle contractions • Unfused tetanus for normal conditions • Smooth contraction because of asynchronous firing of different motor neurons and tension averages. 03-44-485

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  9. Muscle stretch reflexes • Response to muscle stretch • --> direct excitatory feedback to motorneurons for the stretched muscle • Help to regulate the degree of muscle contraction. 03-44-485

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  11. Muscle spindle • 8 - 10 intrafusal fibers • Large sensory fibers (1 afferents) • Largest axons in the nerves. • Rapid conduction 03-44-485

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  13. Muscle spindle • Rapid reflex adjustments • Afferent axons have mechanically gated ion channels around the spindle • Monosynaptic excitatory connections with motor neurons 03-44-485

  14. Reciprocal innervation • Excitatory synapse on the muscle that was stretched • Local circuit neurons make inhibitory synapse on antagonist muscle • Rapid contraction of stimulated muscle • Relaxation of antagonist muscle. 03-44-485

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  16. Muscle spindle • Unusual monosynaptic reflex • Responsible for muscle tone • A negative feedback loop to keep muscle at desired length. 03-44-485

  17. Sensory activity and movement • The activity of the motor neuron can be adjusted by: • Upper motor neurons • Local reflex circuits • The motor neuron is the gain that adjusts functional requirements. • motor neuron works with  motor neurons during voluntary adjustments 03-44-485

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  19. An example of motor neuron modulation of muscle spindle responses: • Activate  mn, but not mn • --> extrafusal muscle contracts • --> intrafusal muscle does not contract • --> spindle afferent (1a) is not stimulated 03-44-485

  20. An example of motor neuron modulation of muscle spindle responses: • Both  and  mns are activated. • --> extrafusal and intrafusal muscles contract • --> 1a fiber keeps firing. • The  mns are needed for the 1a fibers to function and for the muscle spindle to function during changes in muscle length. 03-44-485

  21. Another sensory feedback for locomotion • Golgi tendon organ • Encapsulated • Located at tendon/muscle junction • 1b sensory fiber • In series with muscle • Muscle contraction exerts force on tendon and on Golgi tendon organ 03-44-485

  22. Golgi tendon organ • Sensitive to changes in tension 03-44-485

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