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Voluntary Movement II.

Voluntary Movement II. Cortical representation of movements and parameters. Claude Ghez, M.D. 1. Primary motor cortex: how are movement parameters coded Distal movements CM neurons. Population coding. 2. Premotor areas higher order features of movement Supplementary motor area: Sequences

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Voluntary Movement II.

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  1. Voluntary Movement II. Cortical representation of movements and parameters. Claude Ghez, M.D.

  2. 1. Primary motor cortex: how are movement parameters coded • Distal movements • CM neurons. • Population coding. 2. Premotor areas higher order features of movement • Supplementary motor area: Sequences • Lateral dorsal premotor area: sensorimotor transformations • Lateral ventral premotor area: grasping 3. Experience modifies representations

  3. Corticospinal neurons (PTN) code direction and force

  4. Target muscles can be identified by “spike triggered averaging”CM neurons: divergence CM neurons to distal muscles have small “muscle fields” (1-4 muscles) CM neurons to proximal muscles have large (6+) “muscle fields”

  5. Single corticospinal axons diverge to terminate in several motor nuclei

  6. Phasic-tonic type (59%) 50 Unit (Hz) 0 ECU EDC ECRL Torque Tonic firing frequency (Hz) Tonic type (28%) 50 Unit (Hz) 0 ECU EDC ECRL Torque Static torque (x105 dyne/cm) CM neurons code for force exerted

  7. CM neuron EMG of muscle Precision grip Power grip CM neurons are preferentially recruited for tasks requiringtopographical precision

  8. Intact (normal) After section of corticospinal fibers Section of pyramidal tracts in monkeys produces loss of independent “individuated” digit control

  9. Neurons in proximal motor cortex regions are broadly tuned for direction

  10. Movement direction can be coded precisely by the population responses of broadly tuned neurons

  11. Primary motor cortex receives direct input from 5 premotor areas These premotor areas also project to the spinal cord

  12. “Self initiated”voluntary movement are preceded by premotor activation:early evidence from evoked potentials

  13. Repeated simple finger flexion Repeating sequence finger-thumb apposition Supplementary motor area Motor cortex Sensory cortex Mental rehearsal of finger sequence Planning movement sequence without moving activates SMA First neuroimaging data

  14. Primary motor cortex Lateral premotor area Supplementary motor area 1st key touch 1st key touch 1st key touch Visual Cue Learned Sequence Activation of motor areas depend different on behavioral context

  15. Supplementary motor area neurons code movements in specific context of movement sequence. Cell fires with pull followed by turn but not followed by pull Cell fires with turn followed by pull and push but not just with pull

  16. Primary Motor Reaching Grasping Separate pathways convey visual inputs to premotor areas for reaching and grasping

  17. Instruction: Left Instruction: Right LED= trigger signal Panel= instruction signal • Instructed delay task: coding of “preparatory set” for directed reachby dorso-lateral premotor neurons Instruction stimulus Trigger stimulus Instruction stimulus Trigger stimulus

  18. Contralateral movement Ipsilateral movement Precision grip Rec. Ventral PM Power grip Neurons in ventral premotor area (PMv) code for hand configuration of grasp

  19. “Mirror neurons” in PMv represent types of movementindependent of its actualization: motor vocabulary

  20. Practice and learning of finger sequence can alter motor representations in primary motor cortex

  21. Elbow & shoulder Infarct Infarct Damage to local region of motor cortex induceschange in representation of nearby areas

  22. Post infarct with Rehabilitative therapy Preinfarct Infarct Infarct Digit, wrist & forearm No response Digit Proximal Wrist & forearm Motor practice can alter functionality and motor mapping In motor cortex

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