Block 5 W2

Question 1

What is the conus medullar is?

Answer 1

Terminal of spinal cord

Question 2

What is filum terminale?

Answer 2

Terminal filament (end of nerves)

Question 3

What is cauda equina?

Answer 3

Collection of nerves - lumbar and sacral

Question 4

What is white commissure?

Answer 4

White matter fibres cross midline

Question 5

What are 1st order neurones?

Answer 5

Convey info from external receptors, run through dorsal root with cell bodies in dorsal root ganglion. PNS

Question 6

What are 2nd order neurones?

Answer 6

Convey info from brainstem or spinal cord and decussates.

Question 7

What are 3rd order neurones?

Answer 7

Convey info from thalamus to primary sensory cortex via internal capsule.

Question 8

What are the conscious and unconscious tracts?

Answer 8

Conscious:

• dorsal column
• spinothalamic

Unconscious:

• spinocerebellar
• spinotectal
• spinoreticular
• spino-olivary

Question 9

Describe the dorsal column pathway.

Answer 9

1st order -> ipsilateral until gracile (medial, lower 1/2) and cuneate (lateral, upper 1/2) nuclei in medulla.

2nd order - decussate as internal arcuate fibres -> medial lemniscus.

3rd order -> medial lemniscus -> thalamus

Question 10

What info does the PCML pathway convey?

Answer 10

• fine touch
• pressure
• vibration
• proprioception

Question 11

What is the consequence of lesions in the DCML?

Answer 11

Loss of proprioception and fine touch. Patient still able to perform tasks requiring tactile info processing.
Lesion at SC -> sensory loss = ipsilateral.

Question 12

Describe the spinothalamic pathway.

Answer 12

Rise ipsilaterally 1-2 spinal segments then decussates and ascends contra-laterally

Question 13

What info does the spinothalamic tract convey?

Answer 13

Anterior spinothalamic -> crude touch

Lateral spinothalamic -> pain and temperature

Question 14

What is the consequence of spinothalamic lesion?

Answer 14

Contralateral loss of pain and temperature sensations. 2 segment difference (T8 lesion -> loss of sensation below T10).

Question 15

Describe the spinocerebellar pathway.

Answer 15

Dorsal - muscle spindles, Golgi tendon organs enter at T1-L2 -> ipsilateral ascent to inferior cerebellar peduncle (ipsilateral proprioception).
Ventral - decussates -> contralateral ascent.

Question 16

Describe spine-olivary pathway.

Answer 16

Travels to accessory olivary nuclei and cerebellum.

For movement coordination associated with balance e.g. tight rope.

Question 17

Describe spinotectal pathway.

Answer 17

Travels to superior colliculi.

For reflex turning of head and eyes to cutaneous stimuli.

Question 18

Describe spinoreticular pathway.

Answer 18

Travels to reticular activating system.

For arousing consciousness through cutaneous stimulation.

Question 19

What is the consequence of a brainstem lesion?

Answer 19

Pain, temp, touch, position and vibration loss - contralateral.

Question 20

What is the consequence of spinal cord lesion?

Answer 20

Pain and temp - contralateral.

Touch, position and vibration - ipsilateral.

Question 21

What is Brown-Sequard syndrome?

Answer 21

Refers to a hemisection of the spinal cord. Due to traumatic injury and involves DCML and spinothalamic pathways.

DCML - ipsilateral loss of tactile sensation and proprioception.
Spinothalamic - contralateral loss of pain and temp. Ipsilateral hemiparesis.

Question 22

Define action potential.

Answer 22

Rapid change in electrical potential across the plasma membrane of a cell.

Question 23

Define resting membrane potential.

Answer 23

-70mV
Inside of neurone is negatively charged relative to outside.
Set up by electrochemical gradient across cell membrane.

Question 24

What are ion channels - passive transport?

Answer 24

Made up of proteins in plasma membrane.
Allow selective transfer of ions across membrane.
Passive - no energy required.

Question 25

List ion channel types.

Answer 25

Leak -> always open and continually leaks ions.
Voltage-gated -> open/close in response to voltage change.
Ligand-gated -> open/close in response to chemical/drug.

Question 26

What is Na+/K+ pump - active transport?

Answer 26

Allows ions to travel across membrane against their concentration gradient.
Active -> requires energy.
3 Na+ out, 2 K+ in.

Question 27

How is resting potential set up?

Answer 27

1. Low-protein permeability -> negatively charged intracellular proteins can’t leave.
2. Na+/K+ pump
3. High K+ permeability -> K+ leaks.

Question 28

What is the electrochemical gradient?

Answer 28

Extracellular charge is positive (high Na+) and intracellular charge is negative (low Na+, high K+).
Overall, more positive outside than inside.

Question 29

What is the equilibrium potential?

Answer 29

Voltage at which ion’s net flow across membrane is 0. Calculated by Nernst equation.
Depends on:
- Valence (charge)
- concentration gradient

Question 30

Why is KCL used in assisted suicides?

Answer 30

Increasing extracellular K+ = resting potential is less negative (depolarisation) -> interferes with cardiac muscle contraction and stops the heart.

Question 31

What does the Goldman equation depend on?

Answer 31

Valence
Concentration gradient
Permeability of multiple ions

Question 32

Why is resting potential now -80mV, the same as K+ potential?

Answer 32

Poor permeability to Na+ allows Na+ to leak back into the cell = -70mV.

Question 33

Describe the resting state.

Answer 33

-70mV

All voltaged-gated Na+ and K+ channels closed.

Question 34

Describe the depolarisation phase.

Answer 34

-55mV (threshold potential)

Voltage-sensitive (fast activation) Na+ channels open.

Question 35

Describe the repolarisation phase.

Answer 35

Absolute refractory period
+40mV
Voltage-sensitive K+ channels open.
Inactivation gate of Na+ channels close.

Question 36

Describe the hyper-repolarisation phase

Answer 36

Relative refractory phase
-80mV
Voltage sensitive K+ channels remain open.
K+ leak
Fast activation Na+ gate closes.

Question 37

Summarise the action potential stages.

Answer 37

-55 mV: Depolarisation - Voltage-gated Na+ channels open
+40mV: Repolarisation - Na+ channels inactivated (absolute refractory period)
+ 40mV: Repolarisation - Voltage-gated K+ channels open
-80 mV: Afterhyperpolarisation Voltage-gated K+ channels slow to close (relative refractory period)
-70 mV: Resting state - Leaky K+ channels restore RMP

Question 38

Describe the mechanism of neurone AP transmission.

Answer 38

• Signals arrive via synaptic transmission from presynaptic neurons
• Electronic potentials spread passively (graded response) from dendrites to soma
• Negative and positive electronic potentials are integrated (summed) within the soma.
• Sum of electrotonic potentials reaches axon hillock.
• If net electric potential > threshold at axon hillock = action potential occurs in an all or nothing response.

Question 39

What does axon conduction velocity depend on?

Answer 39

Axon diameter

Myelination

Question 40

Describe the different stimulus strengths.

Answer 40

Subthreshold - magnitude of graded response.

Suprathreshold - freq. of APs increases (same amplitude but fire more rapidly).

Question 41

Describe unmyelinated axon conductance.

Answer 41

• Na+ entry at axon hillock locally depolarises.
• depolarises adjacent region -> opens voltage-gated Na+ channels.
• previous Na+ channels inactivate (absolute refractory).
• 1 way propagation of AP down axon.

Question 42

Describe myelinated axon conductance.

Answer 42

• Na+ entry at axon hillock locally depolarises.
• myelin sheath insulates axon -> prevents ion leakage.
• Na+ and K+ channels concentrated at nodes of Ranvier.
• AP jumps nodes -> saltatory conduction.

Question 43

Describe the action of local anaesthetics.

Answer 43

Reversibly prevent transmission of AP within local region.
Blocks voltage-gated Na+ channels
Types:
- esters (cocaine)
- amides (lidocaine)
Local effect prolonged by vasoconstrictors (epinephrine).
Small diameter neurones.

Question 44

What is carbamazepine?

Answer 44

Treats epilepsy and nerve pain.

Prolongs inactivated state of Na+ channel and absolute refractory period.

Question 45

What is multiple sclerosis?

Answer 45

Autoimmune disease - demylination as T cell attack myelin sheath causing inflammation, lesions and scarring in axon bundles -> APs can’t propagate as fast.

Question 46

What is tetrodotoxin?

Answer 46

Product of symbiotic bacteria of pufferfish.
Blocks fast voltage-gated Na+ channels.
Death by respiratory paralysis.

Question 47

Define pain.

Answer 47

Unpleasant sensory and emotional experience associated with actual or potential tissue damage -> psychological emotional experience.

Question 48

Define nociception.

Answer 48

Neural processes of detecting, encoding and processing noxious stimuli - physiological response.

Question 49

What are the advantages of pain?

Answer 49

• early cue
• protective
• educational -> avoid harmful situations and changes our behaviour
• prevents infections
• prevents bedsores

Question 50

What are the disadvantages of pain?

Answer 50

• No useful function in chronic, rheumatic, cancer, neuropathic, amputation pain.
• Persists after tissue heals.

Question 51

What is acute pain?

Answer 51

• pain resolves when injury heals
• recent with well-defined onset
• ends in days or weeks
• vital warning function
• forces rest and avoidance of further pain
• treatable

Question 52

What is chronic pain?

Answer 52

• pain persists with ill-defined onset
• longer and unpredictable duration
• no apparent biological function
• resting doesn’t improve pain
• persists after tissue heals
• poorly treatable

Question 53

What are nociceptor?

Answer 53

Sensors found in most body tissue that respond to noxious stimuli.
Unspecialised nerve cell endings.
Brain has no no nociceptors.

Question 54

What are the types of nociceptors?

Answer 54

Thermal - burning, frost
Mechanical - pinch, incision
Chemical - capsaicin
Polymodal - all (most nociceptors are polymodal)
Sleeping/silent - inflammation

Question 55

Describe the primary afferent fibres.

Answer 55

Large diameter - rapidly conducting afferents (Aa and Ab) associated with low-threshold mechanoreceptors e.g. touch.
Small diameter - slow conducting afferents (Ad and c) associated with nociceptors and thermo-receptors.

Polymodal nociceptors have c fibres.

Question 56

Describe the difference between first and second pain.

Answer 56

First - fast (Ad fibres), sharp, easily located, rapid, short duration, mechanical and thermal nociceptors.

Second - slow (c fibres), dull, aching, burning, poorly localised, slow, long duration. polymodal nociceptors.

Question 57

Describe the transduction of pain.

Answer 57

Different noxious stimuli open different receptor channels.

1. receptors at nociceptor free endings are selectively activated by noxious stimuli -> generates receptor potential.
2. depolarises membrane, opening Na+ channels -> generating AP.
3. AP enters spinal cord via dorsal root ganglion.
4. voltage-gated Ca2+ channels trigger release of NT (glutamate and substance P) -> activates 2nd order neurones in spinal cord -> ascends to brain.

Question 58

What is congenital analgesia?

Answer 58

Mutation in genes encoding Na+ channels specific to nociceptors.
Inability to feel pain.
Associated symptoms:
- recurrent bruises, cuts, burns, eye damage (pain ignored -> dangerous)
- limb and joint deformity as improperly healed bones causing chronic infection (osteomyelitis)
- missing body parts
Reduced life expectancy

Question 59

Where does the termination of primary afferents occur in the spinal cord?

Answer 59

• Ad and C fibres enter dorsal horn and innervate laminae I and II.
• 2nd order neurones take info to laminae IV-VI.
  Also cross the midline and ascend to brain.

Question 60

Describe the spinothalamic pathway.

Answer 60

Sensory inputs cross at spinal cord and ascend on opposite side.
Info relayed via medulla to thalamus.
Pain relayed from thalamus to primary somatosensory cortex.

Question 61

Describe the ascending pathway of pain.

Answer 61

Noxious stimuli activate nociceptors and spinal neurones that project to higher brain centres including thalamus (perception), cortex (localisation), limbic system (emotional)

Question 62

Describe the nociceptive pathway for face and head.

Answer 62

1. info enters at pons via CN 5, 7, 9, 10.
2. small diameter afferents descend in spinal trigeminal tract to brainstem
3. synapse with 2nd order neurones in medulla
4. axons then ascend contra laterally to thalamus in trigeminothalamic tract
5. projects to cortex via ventral posteromedial nucleus

Question 63

What is dissociated sensory loss?

Answer 63

Unilateral spinal lesion -> sensory loss of touch, proprioception on same side and pain, temp on opposite side.

Question 64

Describe the gate theory.

Answer 64

Local interneurones in spinal cord act as gate.
Co-activation of Aa/b and C fibres suppresses projection of C fibres.
Explains why pain reduced by stimulating mechanoreceptors e.g. rubbing.

Question 65

What can suppress pain?

Answer 65

Perception of pain modulated in higher brain centres -> strong emotions, stress and stoic determination suppresses pain e.g. soldiers and placebo effect.

Question 66

Define hyperalgesia.

Answer 66

Increased sensitivity (reduced threshold) to pain from stimulus that normally provokes pain.

Question 67

Define allodynia.

Answer 67

Pain from stimulus that doesn’t normally provoke pain e.g. light touch

Question 68

What are the chemical modulators of pain?

Answer 68

Tissue damage and inflammation triggers release of substances that can sensitise peripheral nociceptors and induce hyperalgesia e.g. substance P, prostaglandins, bradykinin, histamine

Question 69

Differentiate between primary and secondary hyperalgesia.

Answer 69

Primary - occurs in site of the tissue damage.

Secondary - occurs around the site of tissue damage.

Question 70

What is fibromyalgia?

Answer 70

Chronic widespread pain and allodynia.
Other symptoms: fatigue, IBS, headache, muscle stiffness.
Mainly affects females.
Treatments: analgesics, antidepressants, counselling and exercise.

Question 71

What is referred pain?

Answer 71

Caused by convergence of nociceptor inputs from viscera and skin.
Few neurones specialised for visceral pain so nociceptive afferents from viscera and skin enter SC through same route and target overlapping populations of spinal neurones.
Cross-talk -> visceral nociceptor activation is perceived as cutaneous sensation.

Question 72

Give examples of referred pain.

Answer 72

Angina - pain localised to upper chest wall, left arm and hand.
Appendicitis - pain referred to umbilicus.
Bladder pain - perineum.
Ureter - lower abdomen and back.
Prostate - lower trunk and legs.

Question 73

What is phantom limb?

Answer 73

Sensation that a missing limb is still attached to body and moving appropriately (80% amputees).

Question 74

What is phantom limb pain?

Answer 74

Chronic pain in phantom.

Stabbing/burning pain or phantom limb contorted in uncomfortable position.

Question 75

What are the treatment for phantom limb pain?

Answer 75

Pain associated with central brain changes - re-organisation of somatosensory map.

Mirror therapy.

Question 76

Give an overview of pain relief treatments.

Answer 76

Pharmacological (opioids, NSAIDs)
Stimulation (TENS, acupuncture, physiotherapy)
Psychological (placebo, hypnosis)
Neurosurgery (hemisection, rhizotomy)

Question 77

What are opioids?

Answer 77

Any substance that produces morphine-like effects.
Produces profound analgesia.
Binds opioid receptors in brain (mu, delta, kappa).
Brain has endogenous opioids e.g. endorphins, enkephalins.

Question 78

Describe the nociceptive descending pathway.

Answer 78

Periaqueductal grey matter and raphe nuclei decrease NT release from nociceptive primary afferents by binding opioids with opioid receptors.

Placebo and acupuncture effects occurs though stimulation of endogenous pain relief systems.

Question 79

List common clinical opioids.

Answer 79

• morphine sulphate
• diamorphine
• codeine
• fentanyl (operative)
• pethidine (obstetrics)
• tramadol (opioid effect + enhances serotinergic and adrenergic pathways)
• naloxone (antagonist)

Question 80

What are upper motor neurones?

Answer 80

• CNS
• origin in cerebral cortex, cerebellum and brainstem
• form descending tracts
• projects to LMN in brainstem or spinal cord.

Question 81

What are lower motor neurones?

Answer 81

• brainstem cranial nerve nuclei or spinal anterior horn
• PNS -> cranial nerves and spinal nerves
• projects to muscle.

Question 82

What are ventromedial UMNs involved in?

Answer 82

Postural and girdle muscles e.g. trunk and proximal limbs.

For righting movements and posture.

Question 83

What are dorsolateral UMNs involved in?

Answer 83

Distal muscles, elbow to finger, knees to toes.

For fine movement.

Question 84

What are the tracts of ventromedial and dorsolateral?

Answer 84

Ventromedial:

• anterior corticospinal
• vestibulospinal
• reticulospinal
• tectospinal

Dorsolateral:

• lateral corticospinal
• rubrospinal

Question 85

Describe the reticulospinal tract.

Answer 85

• Function - increased extensors and decreased flexors. For automatic posture and gait-related movements -> adapts to environ.
• Arise - pontine and medullary reticular formation (arousal)
• Rise ipsilaterally (no decussation).
• Polysegmental

Question 86

Describe the tectospinal tract.

Answer 86

• Function - orienting and flinching movements, ballistic reaching. Coordination of head and eye movement.
• Arise - superior colliculus (tectum) -> cervical spinal cord. Proximal shoulder girdle muscle and neck.
• Decussates midbrain -> dorsal tegmental decussation.

Question 87

Describe the vestibulospinal tract.

Answer 87

• Function - increased gravity stance and increased extensors.
  Medial VST:
• arise -> medial and inferior vestibular nuclei -> cervical and thoracic cords.
• for positioning of head and neck.
  Lateral VST:
• arise -> lateral vestibular nuclei -> all SC
• for balance.

Question 88

What are the effects of lesions on the ventromedial tracts?

Answer 88

• loss of righting reactions
• loss of navigational control
• axial immobility and forward slump
• can’t reach out (no extensor action)
• can flex elbow and individual digits.
  e. g. pianist - can’t walk but can play but needs support as slumps forward.

Question 89

Describe the rubrospinal tract.

Answer 89

• Functions - increased flexors and active in swing phase. Control and coordination of movement.
• Arise - red nucleus -> cervical segments.
• Mesencephalic decussation (midbrain)

Question 90

What does injury to rubrospinal tract cause?

Answer 90

Impaired distal arm and hand movement, intention tremors and decorticate posturing.

Question 91

Describe the origin and decussation of the corticospinal tract.

Answer 91

Arises -> premotor cortex, primary motor and sensory cortex -> contralateral anterior horn. Corticospinal and corticobulbar tracts.
Posterior limb of internal capsule.
- Pyramid decussation -> 90% contralateral LCST, 10% ipsilateral ACST.

Question 92

What is the function of the corticospinal tract?

Answer 92

• voluntary skilled motor activity e.g. writing and typing.
• independent flexion of single distal joint
• not fully myelinated until 2 years.
• small % dorsal grey projection -> write through pain.

Question 93

What are the consequences of transections above and below decussation?

Answer 93

Above -> contralateral spastic paresis and + babinski’s.

Below -> ipsilateral spastic paresis and babinski’s.

Question 94

What does injury to corticospinal tract cause?

Answer 94

• normal walking and navigation, righting reactions and axial posture
• arms hang limply (loose fine control)
• reach by shoulder circumduction
• elbow inactive and fingers flex together
  e. g. pianist - can’t lift elbow or fingers individually but flexes together.

Question 95

Define brainstem death.

Answer 95

Irreversible loss of capacity for consciousness (pontine reticular activating system), combined with irreversible loss of capacity to breathe (medullary cardioresp. centres).