Neuro Physiology

Question 1

Autoregulation of CBF

Answer 1

Myogenic
Local
Neural

Constant between CPP of 60-160 mmHg

Question 2

Hyperbaric oxygen and cerebral blood flow

Answer 2

Although PaO2 has a far lesser effect on CBF vs PCO2

Hyperbaric oxygen can reduce cerebral blood flow by ~20%

Question 3

Total volume CSF

Answer 3

130-150 ml

100ml spinal cord
40ml in ventricles

Question 4

Normal CSF pressure

Answer 4

0.5-1 kPa

Question 5

Production of CSF

Answer 5

Choroid plexus in lateral, third and fourth ventricles

L, 3rd and 4th

~500ml / day

Question 6

Foramin of Luschka

Answer 6

Lateral

Question 7

Foramin of Magendie

Answer 7

Medial

Question 8

Areas in which blood-brain barrier is permeable - fenestrated endothelium

Answer 8

Third and fourth ventricles

• Chemoreceptor trigger zone at floor of fourth ventricle
• Angiotensin II passes to the vasomotor centre in this region to increase sympathetic outflow and causes vasoconstriction of peripheral vessels

Posterior pituitary
-Allows production of ADH and oxytocin into circulation

Hypothalamus
-this allows the release of releasing or inhibitory hormones into the portal–hypophyseal tract (to anterior pituitary)

Question 9

Consequences of rising ICP

Answer 9

Hydrocephalus
-Seen in posterior fossa lesions due to compression of aqueduct

Ischaemia
-Rising ICP reduces CPP and therefore CBF

Herniation
-Compression of brain via herniation

Question 10

Pupillary dilatation and raised ICP

Answer 10

–> oculomotor nerve compression

= Transtentorial herniation

Question 11

Cortical blindness and raised ICP

Answer 11

= Transtentorial herniation

Question 12

Resting membrane potential of axon

Answer 12

negative 70mV

-70mV

Question 13

Depolarisation

Answer 13

Axon membrane potential goes from -70 –> +50mV

Question 14

Absolute and relative refraction

Answer 14

During action potential = absolute refraction

During repolarisation = relative refraction, larger stimulus can cause another action potential

Question 15

Mechanism of depolarisation and repolarisation

Answer 15

The Na+ channel activates much faster than the K+
channel.

This explains the rapid influx of Na+; the
channel also closes much faster; the K+ channel
remains open over a longer period than the Na+
channel and is responsible for repolarisation as K+
is released and the membrane potential falls back
to its negative value

Question 16

Nodes of Ranvier

Answer 16

Gaps in between myelinated axons

Points of depolarisation

Increases speed of transmission as between nodes the axon depolarises quickly and entirely

= saltatory conduction

Question 17

Aα axons

Answer 17

Motor

Propioception

Question 18

Aβ axons

Answer 18

Touch

Pressure

Question 19

Aγ axons

Answer 19

Muscle spindles

Question 20

Aδ axons

Answer 20

Pain

myelinated version of pain fibres

Question 21

C-fibres axons

Answer 21

Unmyelinated pain neurons

Question 22

B axons

Answer 22

Autonomic

Question 23

Breakdown of amine neurotransmitters

Answer 23

Monoamine oxidase: breaks down neurotransmitter taken up at PRE-synaptic neuron

Catechol-O-methyl transferase breaks down catecholamine in post-synaptic neuron

Question 24

Glutamate + Aspartate

Answer 24

Excitatory

Question 25

Glycerol

Answer 25

Inhibitory

Question 26

Substance P

Answer 26

Pain transmission

Question 27

Kehr’s sign

Answer 27

Referred pain

Left-sided diaphragmatic irritation and left shoulder tip pain

Question 28

Gate control theory

Modulation of pain

Answer 28

Descending
Periaqueductal grey matter and raphe magnus –> releasing serotonin

Locus coeruleus –> noradrenaline

Local
Naturally occurring enkephalins and endorphins at point of transmission synapse in spinal cord

Question 29

Proteins on actin filament

Answer 29

Actin: double strand helix

Tropomyosin: lies in groove between double-stranded helix of actin

Troponin: regular arrangement along actin filament

• Attached to both actin and tropomysin
• Has binding sites for Ca2+ and is involved in the regulation of contraction.
• Troponin and tropomyosin block the myosin-binding site on actin.

Rise in calcium allows removal and binding of myosin

Question 30

Proteins on myosin

Answer 30

Head section has binding site for ATP
–> allows release of head from actin filament

Structure: head + long tail

Question 31

Troponin

Answer 31

• Attached to both actin and tropomysin
• Has binding sites for Ca2+ and is involved in the regulation of contraction.
• Troponin and tropomyosin block the myosin-binding site on actin.

Rise in calcium allows removal and binding of myosin

Question 32

Tropomyosin

Answer 32

Tropomyosin: lies in groove between double-stranded helix of actin

Rise in calcium allows removal and binding of myosin

Question 33

Type I muscle fibre

Answer 33

Slow / postural

Question 34

Type IIa muscle fibre

Answer 34

Type IIa or fast oxidative fibres

e.g. calf muscles

They rely on aerobic metabolism and contain myoglobin; they have moderate resistance to fatigue

Question 35

Type IIb muscle fibre

Answer 35

Type IIb or fast glycolytic fibres

e.g. extraocular muscle

Do not contain myoglobin and thus appear white

They contain a large amount of glycogen and rely on anaerobic metabolism.

Question 36

Intrafusal muscle fibres

Answer 36

Respond to stretch

“stretch sensory” receptor for stretch-contraction reflex arc

Question 37

Precentral gyrus

Answer 37

Motor cortex

Frontal lobe immediately anterior to central sulcus

Question 38

Corticobulbar tracts

Answer 38

Motor supply to cranial nerve

Question 39

Corticospinal tracts

Answer 39

Supply spinal motor neurons

–> voluntary movement

Question 40

Four descending motor inputs from brainstem

Answer 40

Rubrospinal tract: red nucleus

Tectospinal tract: superior colliculus of midbrain

Vestibulospinal tract: vestibular nuclei

Reticulospinal tracts: pons and medulla

Question 41

Rubrospinal tract

Answer 41

Descending motor input from the brainstem

• Red nucleus
• Primarily innervates distal limb muscles

Question 42

Tectospinal tract

Answer 42

Descending motor input from brainstem

• Superior colliculus of midbrain
• Receives inputs from the visual cortex
• Controls reflex activity in response to visual stimuli

Question 43

Vestibulospinal tract

Answer 43

Descending motor input from brainstem

• Vestibular nuclei
• Supplies muscles of the ipsilateral side of the body.
• Innervates muscles concerned with balance and posture in response to inputs from the vestibular apparatus

Question 44

Reticulospinal tract

Answer 44

Descending motor input from brainstem

• Arises from pons and medulla
• Supply muscles on the ipsilateral side of the body and are important in maintaining posture and muscle tone

Question 45

Cerebellum

Answer 45

No descending tracts

Modulation of motor coordination directly into motor cortex in precentral gyrus

Receives information from:

• Vestibular apparatus
• Visual system
• Corticospinal tracts
• Peripheral proprioceptors