NEUR 0010 - Chapter 14

Question 1

What are the high, middle, and low levels of motor control?

Answer 1

Strategy, tactics, and execution

Question 2

What are the structures associated with each level of the motor control hierarchy?

Answer 2

High = strategy (association areas of neocortex, basal ganglia), middle = tactics (motor cortex, cerebellum), low = execution (brain stem, spinal cord)

Question 3

What are the lateral pathways for?

Answer 3

Voluntary control of distal musculature; under direct cortical control

Question 4

What are the ventromedial pathways for?

Answer 4

Control of posture and locomotion, under brain stem control

Question 5

What brain areas control the lateral vs ventromedial pathways?

Answer 5

Cortex vs brainstem

Question 6

What is the most important component of the lateral tract?

Answer 6

Corticospinal tract

Question 7

Where do the axons of the CS tract originate?

Answer 7

Mostly in the motor cortex, some in the SS areas of the parietal lobe

Question 8

Where do the axons of the CS tract go?

Answer 8

Start in the motor cortex or SS area of parietal lobe; pass through internal capsule between telencephalon and thalamus; through cerebral peduncles in the midbrain; through the pons; tract at the base of the medulla in the medullary pyramid

Question 9

What happens to the CS tract after it becomes the medullary pyramids?

Answer 9

Decussates and continues down to the spinal cord’s lateral column

Question 10

When does the CS tract decussate?

Answer 10

After becoming the medullary pyramids, right before it continues onto the lateral column of the spinal cord

Question 11

Where do the CS tract axons terminate?

Answer 11

In the dorsolateral region of the ventral horns and intermediate gray matter (same location as motor neurons/interneurons that control distal muscles, esp. flexors)

Question 12

What is the rubrospinal tract?

Answer 12

a smaller component of the lateral pathways

Question 13

Where does the rubrospinal tract originate?

Answer 13

The red nucleus in the midbrain’s tegmentum

Question 14

Where do the axons in the rubrospinal tract go?

Answer 14

Start in the red nucleus of the midbrain; decussate in the pons; join corticospinal tract in the lateral column of the spinal cord

Question 15

What is the main source of input to the rubrospinal tract?

Answer 15

Frontal cortex that contributes to the corticospinal tract

Question 16

What happens after lesions in the lateral pathways?

Answer 16

No fractionated movements of arms/hands; slower movement, less accuracy; functions can gradually recover if only damage to CS tract, but no recovery if damage to both CS and RS tracts; contralateral paralysis if damage to the motor cortex or CS tract

Question 17

What are the four descending tracts of the VM pathways?

Answer 17

Vestibulospinal, tectospinal, pontine reticulospinal, medullary reticulospinal

Question 18

What does the VM pathway do?

Answer 18

Uses sensory info about balance/body position/visual environment to maintain balance and posture

Question 19

What do the vestibulospinal and tectospinal tracts do?

Answer 19

Keep head balanced, turn head to stimuli

Question 20

Where do the vestibulospinal tracts originate and go?

Answer 20

Start in vestibular nuclei of the inner ear (input from vestibular labyrinth of the inner ear); go bilaterally down spinal cord and activate cervical spinal circuits to guide head movement

Question 21

Where does the tectospinal tract originate and go?

Answer 21

Starts in superior colliculus of midbrain (input from retina, V1, SS, audition, etc.); maps the world around us and causes the head to focus on a new stimulus

Question 22

What do the pontine and medullary reticulospinal tracts arise from?

Answer 22

The reticular formation of the brain stem: just under the cerebral aqueduct and fourth ventricle

Question 23

What does the pontine reticulospinal tract do?

Answer 23

Enhances antigravity reflexes of the spinal cord; facilitates lower limb extensors; maintain standing posture

Question 24

What does the medullary reticulospinal tract do?

Answer 24

Liberates antigravity reflexes of the spinal cord from reflex control; allows a fine balance of posture vs not

Question 25

Where are Areas 4 and 6?

Answer 25

4 is anterior to the central sulcus, on precentral gyrus; 6 is just anterior to Area 4

Question 26

What is primary motor cortex M1?

Answer 26

Area 4

Question 27

What two components make up Area 6, and what do they do?

Answer 27

PMA and SMA: premotor area and supplementary motor area; specialized for skilled voluntary movement

Question 28

How do the processes of PMA and SMA differ?

Answer 28

SMA sends axons to distal motor units directly; PMA connects with reticulospinal neurons to innervate proximal motor units

Question 29

Which activates distal vs proximal, PMA or SMA?

Answer 29

SMA is distal, PMA is proximal

Question 30

What kind of signals/messages/functions does Area 6 carry out? Why?

Answer 30

What actions to convert into signals, and how to do so; because it receives information from the prefrontal and parietal lobes

Question 31

When you’re instructed to only think about performing a practiced movement, what areas are active?

Answer 31

Area 6, but not area 4

Question 32

What is the ready/set/go of the prefrontal/parietal/area 6?

Answer 32

Ready is the parietal and frontal lobes and attention centers; Set is the SMA and PMA strategizing; Go is the performance after the trigger stimulus

Question 33

Where are the basal ganglia?

Answer 33

In the telencephalon

Question 34

What is the major subcortical input to Area 6?

Answer 34

From the VLo nucleus (ventral lateral nucleus)

Question 35

Where does input to the VLo come from?

Answer 35

Basal ganglia

Question 36

What are the four components of the basal ganglia?

Answer 36

Caudate nucleus, putamen, globus pallidus, subthalamic nucleus

Question 37

What is the striatum?

Answer 37

The combination of the putamen and globus pallidus

Question 38

What structure is the source of output to the thalamus?

Answer 38

Globus pallidus

Question 39

What is the direct path from cortex back to cortex by way of the SMA?

Answer 39

Cortex to striatum to globus pallidus to VLo to SMA in the cortex again

Question 40

What is the direct motor loop?

Answer 40

Cortex synapses (E) with putamen, which synapses (I) with globus pallidues, which synapses (I) with VLo, which synapses with cortex (E) and discharges movement-related SMA cells

Question 41

What is Parkinson’s disease?

Answer 41

Hypokinesia: too much inhibition by basal ganglia of thalamus; helped by administering dopamine

Question 42

What is Huntington’s disease?

Answer 42

Hyperkinesia: too little inhibition by basal ganglia of thalamus; characterized by chorea/ballism

Question 43

What layer of motor cortex activates motor neurons?

Answer 43

Layer V

Question 44

Where does layer V of the motor cortex receive input from?

Answer 44

Other cortical areas (area 6) and the thalamus (VLc)

Question 45

What does VLc do?

Answer 45

In the thalamus: relays info from the cerebellum

Question 46

How does M1 command voluntary movement?

Answer 46

Employs most of itself as active, and each cell represents a “vote” that gets tallied and averaged to determine the direction of motion by vectors

Question 47

What is the cerebellum for?

Answer 47

Controlling the finely-tuned sequence of events that occur during movement

Question 48

What does the vermis do?

Answer 48

Sends output to brainstem structures that contribute to VM descending spinal pathways to control axial musculature

Question 49

What do the cerebellar hemispheres do?

Answer 49

Related to brain structures that contribute to lateral pathways, esp. cortex

Question 50

What is the motor loop through the lateral cerebellum?

Answer 50

Layer V, areas 4/6, SS areas, posterior parietal areas project to pontine nuclei; project to cerebellum; project back to motor cortex through thalamic VLc

Question 51

What is the purpose of the motor loop through the lateral cerebellum?

Answer 51

Planned, voluntary, multi-joint movements; compared intentions with outcomes