Pathways through Vestibular Nuclei and Reticular Formation: Postural Control and Motor Coordination

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2. Pathways through vestibular nuclei • Cranial nerve VIII --> vestibular nuclei --> descending axons Lateral vestibular tract OR Medial vestibular tract 03-55-485

3. Pathways through vestibular nuclei • Also, pathways from upper motor neurons to lower motor neurons that control eye movements. 03-55-485

4. Reticular Formation • Network of circuits • Located at the brainstem core, from midbrain to medulla. • Descending motor control pathways to the spinal cord - terminate primarily in the medial parts of the gray matter where they influence the local circuit neurons that co-ordinate axial and proximal limb muscles. 03-55-485

5. Reticular formation: functions • cardiovascular & respiratory control. • sensory motor reflexes • org. of eye movements • regulate sleep and wakefullness • * temporal and spatial co-ordination of movement 03-55-485

6. Posture • In response to disturbances in body position (env or self) • -->Vestibular nuclei and reticular formation • --> information to the spinal cord 03-55-485

7. Vestibular nuclei • response from inner ear to change in balance • Inner ear • Vestibular nuclei • Direct projections to the spinal cord • Compensation in stability 03-55-485

8. Adjustments to stabilize posture during ongoing movements • Motor centers in cortex or brain stem • reticular formation • Appropriate neurons are activated 03-55-485

9. How do upper motor neurons of the reticular formation maintain posture? • Look at voluntary movements. • Fig. 16.5. A subject uses his arm to pull a handle in response to an auditory tone 03-55-485

10. Feedforeward • “predicts” body stability disturbance and body can generate appropriate stabilizing response 03-55-485

11. Hear the auditory tone • activity in the biceps begins about 200 ms after the tone. 03-55-485

12. This shows that posture control entails an anticipation effect (feed forward). • Effect of contracting the biceps will move the body forward, and you need the gastroc to be contracted to hold the body weight. 03-55-485

13. Animal models (cats): • Forepaw movement • feedforward postural adjustment to other legs Expt: electrical stimulation of motor cortex forepaw lifted and postural adjustment. 03-55-485

14. Pharmacological blockade of the reticular formation • electrical stimulation of motor cortex • forepaw lifted and NO postural adjustment. 03-55-485

15. Cortical upper motor neurons initiate both forepaw movement and posture adustment. • Direct • Upper motor neurons from motor cortex project directly to spinal cord Indirect • Upper motor neurons from the motor cortex • project to brain stem areas (including reticular formation) • Activate neurons that project to the spinal cord 03-55-485

16. Damage to direct corticospinal pathway at medulla • indirect projections from cortex to brainstem and brainstem itself can sustain motor behaviour involving proximal muscles. • Direct projections for the motor cortex to the spinal cord provide the speed and agility of movements, these enable precision of finger movement. • Eg. After motor cortex damage in humans, get partial recovery of voluntary movements. These may be the indirect projections through the brainstem centers. 03-55-485