Ascending Neural Pathways

Question 1

Where in the brain does sensory information go ?

Answer 1

Through talamus, to primary (somatic) sensory cortex

Question 2

How many somatosensory areas are there? What is their main differences ?

Answer 2

2

• Area I much more extensive
• Area 1 does not need area II but area II needs area I to function
• Area I: Is a high degree of localisation of different body parts (Thigh, Thorax, Neck, Shoulder, Hand, Fingers, Tongue, Intra-abdominal)
• Area II: poor localisation of different body parts (face, leg, arm)

Question 3

Does each lateral side gets sensory info from the same, opp side of body, or both ?

Answer 3

Each lateral side gets sensory info almost exclusively from opp side of body.

Question 4

Identify organs/body parts whose representation in somatosensory area I of the cortex is large.
Identify organs/body parts whose representation in somatosensory area I of the cortex is small.

Answer 4

Lips, face, thumb get large amounts of space

Trunk and lower limbs assigned small amount of space

Question 5

How do almost all sensory info from somatic segments of body enters the spinal cord ?

Answer 5

Through the dorsal roots of the spinal nerves.

Question 6

What are the names of the possible pathways for sensory information once they have entered the spinal cord, to arrive to the brain ? Do these systems meet at any point ?

Answer 6

1. Dorsal column–medial lemniscal system
2. Anterolateral system (=Spinothalamic tracts)

Two systems come back together partially at the level of the thalamus.

3. Spinocerebellar system

Question 7

What are the different ascending tracts of the spinal cord ?

Answer 7

FASCICULUS GRACILIS and FASCICULUS CUNEATUS (make up Dorsal column–medial lemniscal system)

DORSAL AND VENTRAL SPINOCEREBELLAR

SPINOTHALAMIC TRACTS (anterolateral system)

Question 8

Where does fasciculus gracilis tract carry sensory information from ?

Answer 8

-From lower body extremities

Question 9

Where does fasciculus cuneatus tract carry sensory information from ?

Answer 9

-From upper body extremities

Question 10

Where does dorsal spinocerebellar tract carry sensory information from ?

Answer 10

-From muscle spindles

Question 11

Where does ventral spinocerebellar tract carry sensory information from ? Does it carry a specific kind of information ?

Answer 11

• From Golgi Organs, touch receptors

- Yes, prioreceptive information

Question 12

Where do spinothalamic tracts carry sensory information from ? Does it carry a specific kind of information ?

Answer 12

-Yes, pain

Question 13

Where in the spinal cord does the Fasciculus gracilis enter ?

Answer 13

Up to T6

Question 14

Where in the spinal cord does the Fasciculus Cuneatus enter ?

Answer 14

Above T6

Question 15

What are the main differences between the path of sensory information in the Dorsal column-Medial Lemniscal System, and in the Anterolateral system ?

Answer 15

DORSAL COLUMN-MEDIAL LEMNISCAL SYSTEM
Nerve fibres entering dorsal columns pass
uninterrupted up to the dorsal medulla –> Synapse in dorsal column nuclei (the cuneate and gracile nuclei) –> Second-order neurons cross immediately to opposite side of brain stem and continue up through medial lemnisci to the thalamus –> In the thalamus, the medial lemniscal fibres terminate in the thalamic sensory relay area, called the ventrobasal complex –> From the ventrobasal complex, third-order nerve fibres project mainly to the post-central gyrus of the cerebral cortex ie somatic sensory area I.

ANTEROLATERAL SYSTEM
Enter spinal cord via dorsal spinal root nerves –> Synapse in dorsal horns of spinal grey matter –> Cross immediately in the anterior commissure of the cord to the opposite anterior and lateral white columns. –> Then turn up towards brain via the anterior spinothalamic and lateral spinothalamic tracts –> Upper Terminus:
(1) throughout the reticular nuclei of the brain stem and
(2) in two different nuclear complexes of the thalamus, the ventrobasal complex and the intralaminar nuclei.

Question 16

What are the main differences in myelination and signal velocity between the DORSAL COLUMN-MEDIAL LEMNISCAL SYSTEM, and ANTEROLATERAL SYSTEM.

Answer 16

DORSAL COLUMN-MEDIAL LEMNISCAL SYSTEM
• Large myelinated fibres.
• Signal velocity to brain ~30-110m/s.

ANTEROLATERAL SYSTEM
• Smaller myelinated fibres.
• Signal velocity to brain ~8-40m/s.

Question 17

What are the main differences in modalities transmitted between the DORSAL COLUMN-MEDIAL LEMNISCAL SYSTEM, and ANTEROLATERAL SYSTEM.

Answer 17

DORSAL COLUMN-MEDIAL LEMNISCAL SYSTEM

1. Touch sensations requiring a high degree of localisation of the stimulus
2. Touch sensations requiring transmission of fine gradations of intensity
3. Phasic sensations, such as vibratory sensations
4. Sensations that signal movement against the skin
5. Position sensations from the joints
6. Pressure sensations related to fine degrees of judgment of pressure intensity

ANTEROLATERAL SYSTEM

1. Pain
2. Thermal sensations: both warmth and cold sensations
3. Crude touch and pressure sensations capable only of crude localising ability on the surface of the body
4. Tickle and itch sensations
5. Sexual sensations

Question 18

Which kind of nerve fibers make up the dorsal column-medial lemniscal pathway ?

Answer 18

large diameter, fast Aβ fibres

Question 19

What are some pathologies associated with the Dorsal column-medial lemniscal pathway ?

Answer 19

• Gait ataxia (brain is deprived of information about the position of the feet)
• Upper extremity ataxia

-Paraesthesias in the distal parts of the extremities (due to ectopic discharge in damaged dorsal column axons and may be present before any abnormalities are detectable on neurologic examination)

Question 20

How can patients affected by sensory ataxia minimise this ?

Answer 20

Compensate with vision

Question 21

How may Dorsal column function be tested ?

Answer 21

By testing the ability to feel changes in the position of toes and fingers or feel a tuning fork vibration without lookin (Finger/toe proprioception is not lost until about 75% of posterior column axons have ceased to function)

Question 22

Do signals in the anterolateral system require:

1. Highly discrete localisation
2. Discrimination of fine gradations of intensity

Answer 22

1. No

2. No

Question 23

What are the main upper terminuses of the two spinothalamic tracts ? Where are tactile signals mainly transmitted ? Where are pain signals mainly transmitted ?

Answer 23

(1) throughout the reticular nuclei of the brain stem and
(2) in two different nuclear complexes of the thalamus, the ventrobasal complex and the intralaminar nuclei.

In general, the tactile signals are transmitted mainly into the ventrobasal complex, terminating in some of the same thalamic nuclei
where the dorsal column tactile signals terminate. From here, the signals are transmitted to the somatosensory cortex along with the signals from the dorsal columns.

Conversely, only a small fraction of the pain signals project directly to the ventrobasal complex of the thalamus.
Instead, most pain signals terminate in the reticular nuclei of the brain stem and from there are relayed to the intralaminar nuclei of the thalamus where the pain signals are further processed.

Question 24

What kinds of fibres do the lateral Spinothalamic route contain ? Which modality does that transmit ?

Answer 24

Lateral Spinothalamic route
– Mixture of Aδ and C fibres carrying information about pain and temperature via Aδ heat or cold activated fibres and C fibres (dull pain and itch).

Question 25

What kinds of fibres do the anterior Spinothalamic route contain ? Which modality does that transmit ?

Answer 25

Anterior Spinothalamic route

– C fibres carrying information about coarse, non discriminating touch via mechanosensitive fibres

Question 26

What are some pathologies associated with the Spinothalamic pathway ?

Answer 26

• Decreased perception of pain and temperature on the contralateral side of the body, always one or two dermatomes below the level of the lesion.
• Paraesthesia
• Patients become aware of their pain and temperature deficit when they experience painless cuts or burns

Question 27

What kinds of receptors detect pain ? How ?

Answer 27

Nociceptors, using nerve free endings

Question 28

What are the 3 which stimuli excite pain receptors ?

Answer 28

Mechanical, thermal, chemical.

Question 29

Which of the 3 stimuli which excites pain receptors elicits fast pain ? slow pain ?

Answer 29

Fast pain: mechanical and thermal stimuli

Slow pain: elicited by all 3 types

Question 30

Do nociceptors show adaptation ?

Answer 30

Show little adaptation, sometimes not at all.

Question 31

Give an example where excitation of nociceptors can become progressively greater.

Answer 31

Hyperalgesia

Question 32

How fast is fast-sharp pain transmitted ? Via which types of nerve fibers ?

Answer 32

Transmitted via small Aδ fibres at ~6-30m/s

Question 33

How fast is slow-chronic pain transmitted ? Via which types of nerve fibers ?

Answer 33

Transmitted via C fibres at ~0.5-2m/s.

Question 34

What is meant by double pain sensation ?

Answer 34

Sharp pain transmitted by Aδ fibres followed second or so later by slow pain transmitted by C fibres.

Question 35

What is the point of both pains in double pain sensation ?

Answer 35

Fast pain allows for immediate (re)action, slow pain

tends to gets greater over time and stimulates person to keep trying to relieve cause of pain.

Question 36

What is the function of Capsaicin wrt Nociception ?

Answer 36

-Mimics chemicals produced by the body at sites of tissue damage

Question 37

How does Capsaicin mimic chemicals produced by the body at sites of tissue damage ?

Answer 37

• Capsaicin activates the Trp1 channel in nociceptor neurons which opens to allow Ca2+ and Na+ into the cell
• This causes depolarisation and the production of an action potential.

Question 38

What is the result of over stimulation of Trp1 receptors with capsaicin ? How is this applied clinically ?

Answer 38

Causes desensitisation.
Capsaicin used (with varying success) in the treatment of chronic pain conditions such as arthritis.

Question 39

What is referred pain ?

Answer 39

Pain in a location remote from tissue causing pain.

Question 40

What is the likely mechanism for referred pain ?

Answer 40

• Branches of visceral pain fibres synapse in spinal cord on same 2nd- order neurons that receive signals from skin.
• When visceral pain receptors are stimulated, pain signals from viscera are conducted through some of the same neurons conducting pain signals from skin, so person feels sensations originate in skin.

Question 41

What is the main objective of the spinocerebellar pathways ?

Answer 41

Takes information about the body’s position and movements to the cerebellum for integration.

Question 42

What are the two principal routes for information in the spinocerebellar pathway ?

Answer 42

– anterior (ventral) route

– posterior (dorsal) route

Question 43

How many neurons does each of ventral spinocerebellar pathway and dorsal spinocerebellar pathway have ?

Answer 43

Each pathway (ventral tract or dorsal tract) contains only two neurons along its length (1st and 2nd order).

Question 44

Describe the path of the nerve fibers in the spinocerebellar pathway.

Answer 44

Cell bodies of the second order neurons are located in the dorsal horn of the spinal cord, and terminate in the vermis of the cerebellum –> Dorsal tract neurons ascend ipsilaterally and enter the cerebellum via the inferior peduncle –> Ventral tract neurons ascend contralaterally and enter the cerebellum via the Superior peduncle

Question 45

What are some pathologies associated with the spinocerebellar pathway ?

Answer 45

1. FRIEDREICH’S ATAXIA

- Inherited disease where spinocerebellar tract becomes increasingly ineffective.

Question 46

What is the cause of Friedreich’s Ataxia ?

Answer 46

Caused by multiple repeats of a gene for the protein Frataxin which is responsible for iron metabolism in mitochondria.

Question 47

What are the symptoms of Friedreich’s Ataxia ?

Answer 47

1. Progressively uncoordinated arm and leg movements
2. Wide based ‘reeling’ gait
3. Intention tremor
4. Similar to other spinocerebellar dysfunctions