Descending Motor Pathways

Question 1

How are most “voluntary” movements initiated?

Answer 1

By the cerebral cortex achieved when the cortex activates “patterns” of function stored in lower brain areas—the cord, brain stem, basal ganglia, and cerebellum.

Question 2

How do the lower brain areas aid the cerebral cortex in initiating movement

Answer 2

They send specific control signals to the muscles

Question 3

How are a rare few movements initiated?

Answer 3

For a few types of movements, the cortex has almost a direct pathway to the anterior motor neurons of the cord, bypassing some motor centers on the way. This is especially true for control of the fine dexterous movements of the fingers and hands.

Question 4

What is needed for goal directed or purposeful movement?

Answer 4

Goal or purpose, 
Activation of relevant movement
Feedback of movement
Refinement/correction of movement
Cessation on completion

Question 5

What are the lower motor neurons (LMNs)?

Answer 5

Lower motor neurons (LMNs)
Located in the anterior grey horn of the spinal cord
Alpha motor neurons activate contraction of extrafusal muscle fibres.
Gamma motor neurons activates contraction of intrafusal muscle fibres, associated with muscle spindles – (monitor muscle stretch)
Both leave spinal cord via ventral roots

Question 6

What are the upper motor neurons (UMNs)?

Answer 6

Collective term for the neurons located in the cerebrum or brainstem that influence the activity of LMN’s

Question 7

Where are the motor regions of the cerebrum?

Answer 7

Anterior to central sulcus of the cerebral hemisphere.

Occupies ~1/3 of frontal lobes

Question 8

What are the sub areas of the motor regions of the cerebrum?

Answer 8

Primary motor cortex

Premotor area

Supplementary motor area

Question 9

Describe the primary motor cortex

Answer 9

Topographical representations mapped by electrical stimulation of motor cortex areas.

> ½ primary motor cortex controls hands and muscles of speech.

Excitation of a single UMN usually excites a specific movement – not one specific muscle.
-A pattern of separate muscles are excited.

Found directly anterior and parallel to somatic area 1

Question 10

Describe he premotor area

Answer 10

On posteriolateral aspect of motor region closest to the lateral sulcus
Similar topographical representation to primary motor cortex.
Nerve signals give more complex “patterns” of movement.
Planning of movements

Question 11

Describe the supplementary motor area

Answer 11

On superior aspect of motor region
Contractions elicited are often bilateral (e.g., grasping movements of both hands).
Usually functions together with premotor area.
Gives background movement onto which premotor and primary motor cortex add finer control.

Question 12

What are the specialised areas of motor control?

Answer 12

Identified by electrical stimulation or observation of loss of motor function with destructive lesions.

Examples:
Broca’s area (motor speech area)
“Voluntary” eye movement field
Head rotation area
Hand skills area

Question 13

Where is the brainstem?

Answer 13

A cranial continuation of the spinal cord.

Question 14

What role does the brainstem have in control of motor functions?

Answer 14

Brainstem nuclei are involved in motor + sensory functions of face and head regions.

Also, provides many special control functions:
Control of respiration, CV system
Partial control of GI function
Control of many stereotyped body movements, equilibrium, eye movements

Also serves as a way station for “command signals” from higher neural centers.

Question 15

What is the corticospinal tract?

Answer 15

AKA pyramidal tract

Carries signals direct from cortex to spinal cord.

Concerned with voluntary, discrete, skilled movements.
Especially distal parts of the limbs.

Question 16

Where do the inputs of the corticospinal tract originate from?

Answer 16

30% from primary motor cortex;
30% premotor/supplementary motor;
40% other areas (primary somatosensory cortex).

Question 17

What tract is also known as the pyramidal tract?

Answer 17

Corticospinal tract

Question 18

What is the pathway of the corticospinal tract?

Answer 18

Primary motor cortex -> pyramids of medulla -> (majority/~90%) decussate in lower medulla -> lateral corticospinal tracts -> mainly terminate on interneurons.

Those axons that do not decussate (~10%) pass ipsilaterally in ventral corticospinal tracts.

Question 19

Where os the decussation of the pyramids in the corticospinal tract?

Answer 19

The medulla

Question 20

What structure of the corticospinal tract is present in the medulla?

Answer 20

The decussation of the pyramids

Question 21

What is the lateral corticospinal tract?

Answer 21

Lateral corticospinal tract innervates mainly distal muscles groups of the extremities via direct communication with the LMN in contact with a specific muscle.

But does influence muscles of the entire limb.

Influences LMN circuits to integrate sensory and motor actions to achieve the desired movement pattern.
E.g., gait cycle

Question 22

Where is the lateral corticospinal tract found?

Answer 22

In the motor region between the dorsal and ventral horns of the grey matter of the spinal cord

Question 23

What is the ventral corticospinal tract?

Answer 23

Postural adjustments to stabilize trunk during limb movements led by LSCp tract.

Ventral corticospinal tract not cross at the pyramidal decussation BUT majority do cross the midline at the relevant spinal cord level.

Bilaterally innervates LMN’s controlling the trunk and proximal musculature.

Question 24

What is posture?

Answer 24

Posture = position of body and its parts relative to each other. Is a compromise between balance and movement.

Question 25

How does the body maintain balance?

Answer 25

Posture is adjusted predominantly by involuntary movement driven both predictively (postural set) and reactively (compensation).
Is controlled and driven by the brainstem and is where the postural set is governed.
Movement changes balance and so one’s posture must compensate.
There are mechanisms for both unexpected and expected movement.

Most important interplay therefore is between sensory information and movements.

Question 26

Where is sensory information integrated from in posture control?

Answer 26

Muscle proprioceptors (detect changes in muscle length and or tension).

Sense of balance derived from movements of the head relative to the earths gravitational field (vestibular apparatus).

Visual inputs (detecting movements in visual field representing movement of the body).

This sensory information is predominantly integrated in the brainstem and acted upon via extra pyramidal tracts.

Question 27

What are the extra pyramidal tracts to know other than the corticospinal tracts*****?

Answer 27

Reticulospinal tracts

Vestibulospinal tracts

Rubrospinal tract

Tectospinal tract

Question 28

What do the Reticulospinal tracts do?

Answer 28

Facilitate or inhibit alpha and gamma motor neurons

Modulate posture, locomotion, autonomic function.

Question 29

What do the Vestibulospinal tracts do?

Answer 29

Received input regarding balance from the inner ear.

Facilitate extensor muscle action and inhibits flexor muscles activity.

Question 30

What do the Rubrospinal tracts do?

Answer 30

Red nucleus, influenced by cerebellum and reticular nuclei
Acts on alpha and gamma motor neurons
Facilitates activity of flexor muscles and inhibits extensor anti-gravity muscles.

Question 31

What do the Tectospinal tracts do?

Answer 31

Postural movements in response to visual stimuli.

Head and neck movements for visual tracking

Question 32

What is the primitive motor system?

Answer 32

Controls:
Movement towards or away from a stimulus
Not requiring dexterity

Loose mesh like distribution of neurons in the brainstem

Also involved in:
Control of breathing
Emotional motor systems

Question 33

What the fuck is the pontine reticular system?

Answer 33

Nuclei transmit excitatory signals down into the cord via pontine reticulospinal tract.

Fibers terminate on medial anterior motor neurons that excite axial muscles which support the body against gravity (i.e., muscles of the vertebral column and the extensor muscles of limbs.

Question 34

What is the excitability of the pontine reticular system and what are the consequences of this?

Answer 34

Have a high degree of natural excitability.
receives strong excitatory signals from vestibular nuclei + from deep nuclei of cerebellum.

Therefore, when pontine reticular excitatory system is unopposed by medullary reticular system => powerful excitation of antigravity muscles throughout the body.

Question 35

What is the pathway of the medullary reticular system?

Answer 35

Nuclei transmit inhibitory signals to same antigravity LMNs via medullary reticulospinal tract in lateral white matter of spinal cord.

Question 36

What are LMNs in this context?

Answer 36

Pretty sure its lower motor neurons

Question 37

Where does the medullary reticular system get its input?

Answer 37

Medullary reticular nuclei receive strong input collaterals from: (1) corticospinal tract (2) rubrospinal tract (3) other motor pathways.
normally activate medullary reticular inhibitory system to counterbalance excitatory signals from the pontine reticular system. Therefore, under normal conditions body muscles are not abnormally tense.

Question 38

Describe the function of the medullary reticular system

Answer 38

Medullary reticular nuclei receive strong input collaterals from: (1) corticospinal tract (2) rubrospinal tract (3) other motor pathways.
normally activate medullary reticular inhibitory system to counterbalance excitatory signals from the pontine reticular system. Therefore, under normal conditions body muscles are not abnormally tense.

Some signals from higher areas of brain can “disinhibit” medullary system when brain wishes to excite pontine system to cause standing.

Excitation of MRS can inhibit antigravity muscles in certain portions of body to allow performance special motor activities.

Question 39

What does the vestibulospinal tract do?

Answer 39

Integrates sensory input of the inner ear associated with balance – vestibular apparatus.

Question 40

What are the 2 main components of the vestibulospinal tract?

Answer 40

Medial vestibulospinal tract

Lateral vestibulospinal tract

Question 41

Describe the medial vestibulospinal tract

Answer 41

From medial and inferior vestibular nuclei
Each tract descends bilaterally through the brain stem to terminate at the upper thoracic and cervical LMNs.
Stabilises head as we move our bodies

Question 42

Describe the lateral vestibulospinal tract

Answer 42

From lateral vestibular nucleus
Axons descend ipsilaterally to terminate at LMNs at all spinal cord levels.
Facilitates antigravity extensor muscles and inhibits flexors musculature.

Question 43

Describe conscious movement - Lateral pathways

Answer 43

Principally controlled by the cerebral cortex via 2 corticospinal tracts.
General control of voluntary movement.
Mainly associated with control of distal muscles.

Question 44

Describe unconscious movement - ventromedial pathways

Answer 44

Principally controlled in the brainstem.
Control of posture and rhythmic movements associated with locomotion.
Control axial and proximal muscles.

Question 45

What are the two main classes of descending (motor) pathways?

Answer 45

Conscious movement
Lateral pathways

Unconscious movement
Ventromedial pathways

Question 46

What are corticospinal tracts at their most simple?

Answer 46

A collection of pathways in spine

Question 47

What are the corticobulbar tracts at their simplest?

Answer 47

for H&N muscles and UMN of Brainstem

Question 48

Describe the action of the vestibulospinal, reticulospinal, rubrospinal and tectospinal tracts

Answer 48

Vestibulospinal – Balance, extensors
Reticulospinal – Posture, extensors/flexors
Rubrospinal – Flexors
Tectospinal – Head movements, visual input

Question 49

What tracts are present in the pyramids of nmedulla?

Answer 49

Lateral Corticospinal tract

Anterior Corticospinal tract

Question 50

What pathway do the corticospinal fibres and extra-pyramidal tracts have in common?

Answer 50

The afferent fibre of lower motor neuron

Question 51

What is the stretch reflex arc?

Answer 51

Simple feedback loop occur without input from supraspinal regions (cerebrum + brainstem).

This reflex arc is modulated by supraspinal inputs and removal of these input will lead to hyperactive reflexes.

Question 52

How may one test the stretch reflex arc?

Answer 52

Tendon hammer causes a perceived stretch in the muscle

Sensory neuron triggers action potential in alpha LMN, which causes contraction of the previously stretched muscle

Question 53

Describe upper motor neurons (UMNs) location and basic function

Answer 53

Restricted to the CNS and do not contact muscle
Found in the cortex and brainstem nuclei
Executive function for lower motor neurons (LMNs) and circuits controlling LMNs

Question 54

Describe lower motor neurons (LMNs) location and basic function

Answer 54

Originate in the brainstem and spinal cord.
Not restricted to the CNS and pass to the PNS
Stimulate motor function to muscle fibres
Both intra- and extra-fusal muscle fibres.

Question 55

What may upper motor neuron (UMN) lesions cause?

Answer 55

Increased tone
Spastic paralysis
Clonus
Increased deep tendon reflexes

Question 56

What may lower motor neuron (LMN) lesions cause?

Answer 56

Flaccid paralysis
Reduced motor tone
Reduced deep tendon reflexes
Fasciculation
Atrophy

Question 57

What is the Babinski sign?

Answer 57

An important neurologic examination based upon what the big toe does when the sole of the foot is stimulated. If the big toe goes up, that may mean trouble.

A Babinski sign in an older child or adult is abnormal. It is a sign of a problem in the central nervous system (CNS), most likely in a part of the CNS called the pyramidal tract.

Babinski sign denotes dysfunction of the pyramidal tract, and should be clearly distinguished from upgoing toes that do not belong to the flexion synergy of the leg. Correct interpretation of the plantar response depends only to a minor degree on the method or site of stimulation of the foot. It is therefore most important to assess the response in the entire leg.

Question 58

Describe upper motor neuron (UMN) lesions

Answer 58

Relatively common as these axons are very long (therefore vulnerable).
Signs of lesions are presented as positive or negative signs
-Negative is a loss of function
-Positive is the appearance of an abnormal response.

Extensor Planter reflex (Babinski sign) is an example of a positive sign seen following corticospinal lesions.

Question 59

Where is the lateral corticospinal tract on a diagram of the spinal cord?

Answer 59

1a motor region

Question 60

Where is the ventral corticospinal tract on a diagram of the spinal cord?

Answer 60

1b motor region

Question 61

Where is the lateral vestibulospinal tract on a diagram of the spinal cord?

Answer 61

2c motor region

Question 62

Where is the medial vestibulospinal tract on a diagram of the spinal cord?

Answer 62

Kinda between 1b and 2b not really sure tbh

Question 63

Where is the medullary reticulospinal tract on a diagram of the spinal cord?

Answer 63

2b (dorsal) motor region

Question 64

Where is the pontine reticulospinal tract on a diagram of the spinal cord?

Answer 64

2b (ventral) motor region

Question 65

What is anterior spinal cord syndrome?

Answer 65

Hyperextension injury
Infarction of anterior spinal artery
Loss of bilateral pain, temp and crude touch below
Maintain bilateral fine touch, vibration and proprioception

Question 66

What is posterior spinal cord syndrome?

Answer 66

Penetration injury
Posterior spinal artery occlusion
Multiple sclerosis
Ipsilateral loss of Fine touch, vibration and proprioception
Maintain contralateral Fine touch, vibration and proprioception
Maintain bilateral pain temp and course touch

Question 67

What is central spinal cord syndrome?

Answer 67

Hyperextension
Cord compression
Loss of Pain and temp from same level
Upper limbs more than lower limbs	
Larger lesion = more involvements
Sacral sparing
Bladder dysfunction

Question 68

What is Brown-Séquard Syndrome?

Answer 68

Penetrating trauma
Same level – ipsilateral total loss of sensation
1-2 levels below – Contralateral loss of pain, temp and course touch
1 level below – ipsilateral loss of fine touch, vibration and proprioception

Question 69

Why did I put this card into the deck?

Answer 69

To reach 69 cards and piss off my gf