Motor learning and neurological syndromes

Question 1

Hierarchy of motor control

• Level
• Function
• Structures involved

Answer 1

Low: Execution
- Brainstem and spinal cord

Medium: Tactic
- Motor cortex, cerebellum

High: Strategy

• Association areas of neocortex
• Basal ganglia

Question 2

Ventromedial pathways

Answer 2

Descending pathways, involuntary:

• Reticulospinal
• Tectospinal
• Vestibulospinal

Uses sensory information about balance, body position and vision
- Maintains balance and posture

Question 3

Pyramidal/ corticospinal tract

Answer 3

Lateral descending motor pathway

• Initiates at the motor cortex
• Brodman areas 4 +6
• Cells are mainly from layer V [Betz cells]

Travels through internal capsule and cerebral peduncle

90% of the fibres cross in lateral tract, the rest are ipsilateral in anterior tract.

Fibres synapse directly onto motor neurones.

Question 4

Rubrospinal tract

• Function
• Path

Answer 4

Lateral descending motor pathway
- Stimulates the flexor muscles in the upper limb.

Path:

• Initiates at red nucleus
• Crosses at the midbrain
• Travels down the lateral columns of the spinal cord

Question 5

Vestibulospinal tract

• Function
• Path

Answer 5

Ventromedial descending motor pathway

• Tract originates in vestibular nuclei of the medulla [medial and lateral]
• Sensory information originates from vestibular labyrinth in the ear.

Medial vestibulospinal tract

• Controls neck and back muscle to guide head movements
• Keeps eyes stable as body moves

Lateral vestibulospinal [projects ipsilaterally]

• Stimulates extensor motor neurones in the legs
• Maintains upright and balanced posture.

Question 6

Tectospinal tract

• Function
• Path

Answer 6

Ventromedial descending motor pathway

• Controls muscles of the neck, upper trunk and shoulders.
• Co-ordinates head and eye movements

Path:

1. Originates in the superior colliculus of the tectum.
   - Receives visual information from retina and visual cortex.
2. Fibres cross in the midbrain and travels down the anterior white column of the spinal cord- contralateral control

Question 7

Reticulospinal tract

• Function
• Path

Answer 7

Ventromedial descending motor pathway

• Facilitates extension of the limbs
• Locomotion and postural control

Path:
1. Originates in reticular formation of the brainstem

2. Descends down the spinal cord to form medial [pontine] and lateral [medullary] tract

Question 8

Decorticate posturing in coma

Answer 8

Stimulation from:
- Supraorbital pressure
- Nail bed
- Sternum
Causes extension of legs and flexion of arms.

Due to lesion above the red nucleus
- Rubrospinal tract intact and more active as regulation from cortex is disrupted [disinhibition]

Question 9

Decerebrate posturing in coma

• Description
• Pathophysiology

Answer 9

Stimulation from:
- Supraorbital pressure
- Nail bed
- Sternum
Causes extension in all limbs.

Mechanism:

• Lesion below the red nucleus, rubrospinal tract is inhibited due to disruption
• Upper limbs are extended due to activation of lateral vestibulospinal and reticulospinal tract

Question 10

Stroke and posture

Answer 10

Stroke in middle cerebral artery can affect motor cortex and corticospinal tract

• Lower limb extension
• Upper limb flexion

Other features:

• Plasticity
• Brisk reflex [overactive reflex due to upper motor neurone lesion]
• Babinski reflex
• Clonus

Question 11

Babinski reflex

Answer 11

Extension of the feet when stimulated.

• Seen in those who have lost corticospinal tract [loss of descending inhibition]
• Normal response is to flex feet
• Corticospinal tract is not developed in humans until around the age od 2

Question 12

Brisk reflex

Answer 12

Spasticity caused by a loss of descending inhibition

• Spinal inhibitory interneurones have been altered
• Increased tone

Question 13

Corticobulbar pathway

Answer 13

Axons project from

• Cingulate motor area
• Primary motor area
• Layer 5 of the motor neurones inn brainstem

Facilitates

• Mastication via CN V
• Vocal cords/ swallowing via CN IX and X
• Tongue movements via CN XII

Question 14

Facial palsy and Bell’s palsy

Answer 14

The top half of the face is innervated by CN 7 bilaterally
- Damage in one CN 7 can still give sensation to top half of face

Lower half of the face is contralaterally innervated
- Lesion causes loss of control on lower face

Lesion in upper motor neurone affects the entire half of the face

Question 15

Parasagittal meningioma

Answer 15

Non benign [usually] neoplasm of the meninges
- Can press on specific areas of the motor cortex, the the one controlling the legs

Can represent as bilateral leg weakness and spasticity

Question 16

Middle cerebral occlusion and its effects

Answer 16

Proximal lesion = complete hemiparesis
- As it affects the internal capsule, connected to the cortical area of leg motor supply

Distal lesion can allow legs to still have function
- But affect hand and face

Question 17

Anterior cerebral artery stroke

Answer 17

ACA supplies medial cortex and frontal lobe
- Includes motor control of legs

Stroke can cause:

• Leg paresis [leg motor cortex lesion]
• Abulia: inability to make decisions or act independently [frontal lobe lesion]

Question 18

Jacksonian mark

Answer 18

Partial seizure

• Associated with lesion close/ in motor cortex
• Progression starting distally from hands to legs.

Question 19

Posterior parietal cortex

Answer 19

Contains:

• Somatosensory afferent paths [area 5]
• Visual afferent paths [area 7]

Function:

• Body and environmental image
• Exploratory movements
• Lesion causes neglect

Question 20

Premotor area

Answer 20

Structure
- Inputs from the cerebellum

Controls/ plans visually guided movements

• Prehension [grasping and object via orientation of hand]
• Controls postural and proximal limb muscles

Damage:

• Perseveration of motor activity despite lack of success
• Disrupts learned response to visual cues

Question 21

Supplementary motor area function

Answer 21

Involved in mental rehearsal of movement

Question 22

Bereithschaftspotential

Answer 22

Measured the activation of the supplementary motor area before performing an action.

This potential preceded potential from the motor cortex 500-1000ms in self-initiated movements

Question 23

Apraxia

Answer 23

The inability to carryout purposeful movements

• In absence of paralysis or paresis
• Inability to sequence and execute movements successfully

Ideational

• Cannot report sequence
• Damage to parietal

Ideomotor

• Unable to perform action despite reporting sequence
• damage to SMA

Question 24

Task specific dystonia

Answer 24

Repeated use of the hand can cause changes in functional organisation of the brain areas that process and execute motor control
- Causes sustained muscle contraction [twisting, abnormal posture]

Question 25

Anterior cingulate gyrus

and stroke

Answer 25

Connects to facial nerve

- In stoke- causes smiling when something is amusing despite not voluntarily moving it