Week 110 - Peripheral Neuropathy

Question 1

What are the spaces on the axon between myelination called?

Answer 1

Nodes of Ranvier

Question 2

What are the signs and symptoms of motor neuropathy?

Answer 2

Weakness, Wasting, Muscle fasciculation, loss of reflexes.

Question 3

What are the signs and symptoms of sensory neuropathy?

Answer 3

anaesthesia, paraesthesia, burning, hypersensitivity, ataxia (loss of proprioception), ulcers, areflexia.

Question 4

What are the signs and symptoms of autonomic neuropathy?

Answer 4

Dry mouth, dry eyes, orthostatic hypotension, loss of heart rate variability, GI disturbance, bladder urgency/frequency, impotence, dry skin/ excess sweating, pupil reactions.

Question 5

What are the three main types of peripheral nerve damage?

Answer 5

Axonal neuropathy, demyelinating and axonotmesis.

Question 6

What change would you get in conducting velocity in a demyelinating neuropathy?

Answer 6

Reduced.

Question 7

What changes would you get to the conducting velocity and compound motor action potential in an axonal neuropathy?

Answer 7

Normal CV but a slow CMAP.

Question 8

Which type of neuropathy tends to be demyelinating and which tend to be axonal?

Answer 8

Inflammatory neuropathies tend to be demyelinating whilst chronic conditions tend to be axonal.

Question 9

What is the likely cause of a mononeuropathy?

Answer 9

Compression.

Question 10

How does compression cause damage to a nerve?

Answer 10

Conduction velocity is slowed or blocked, the AP may also be dispersed. Damage is also caused to the myelin.

Question 11

What are the symptoms and signs of carpal tunnel syndrome?

Answer 11

Numbness - waking at night, lateral 3 1/2 fingers.
Weakness - Thumb abduction
Wasting - Thenar eminence

Question 12

What are the treatment options for carpal tunnel syndrome?

Answer 12

Wrist splints, injection of steroids.

Carpal tunnel decompression.

Question 13

A man presents with 3/7 h/o of sensory loss in hands and feet, has progressively got weaker and can’t lift arms above head, bladder and bowel function is normal. What is the likely diagnosis?

Answer 13

Guillain Barre Syndrome.

Question 14

What is Guillain Barre Syndrome?

Answer 14

An acute, demyelinating, polyridiculo neuropathy, with preceding infection, vaccination, trauma, surgery. (Inflammation of spinal roots)

Question 15

What are the investigations for Guillain Barre Syndrome?

Answer 15

Lumbar puncture - high level of protein will indicate inflammation.
Never conduction studies - show reduced CV and AP delayed and dispersed.

Question 16

What are the treatment options for Guillain Barre Syndrome?

Answer 16

Intravenous immunoglobin - probably blocks pathogenic antibodies but reactions are relatively common, expensive and there is a world wide shortage.
Plasma exchange - Washes out pathogenic antibodies, venous access may be restricted, electrolyte disturbances common, BP fluctuations common.

Question 17

A lady presents with numbness and burning sensation in her feet to the ankles it has progressed over the last few years, she is a controlled type II diabetic. What is the likely diagnosis?

Answer 17

Chronic diabetic neuropathy.

Question 18

What are some of the aetiologies of chronic peripheral neuropathy?

Answer 18

Idiopathic, diabetes, drugs (statins,cytotoxic drugs) B12 deficiency, Alcohol, Inherited.

Question 19

At resting membrane potential where are the higher concentrations of Na, K and Cl.

Answer 19

Na and Cl are at higher concentrations outside of the cell. K is at higher concentration inside the cell.

Question 20

How does the membrane of a nerve cell maintain the resting potential?

Answer 20

A pump, using ATP, exchanges 3 Na out of the cell and brings 2 K into the cell.

Question 21

What if the resting potential of a neurone?

Answer 21

-65mV

Question 22

What triggers an action potential?

Answer 22

A neurotransmitter binds to a ligand-gated channel allowing sodium to enter the cell.

Question 23

What is the threshold potential and what is its value in mV?

Answer 23

The threshold potential is the level of depolarisation that is required to open voltage-gated Na channels, it is followed by the rising phase of an action potential. It has a value between 40-55mV.

Question 24

At which point to the rising phase of an action potential end?

Answer 24

At approximately +40mV the Na channels close so no more Na can enter the cell.

Question 25

Explain the falling phase of an action potential.

Answer 25

Depolarisation of the membrane also opens K channels after a slight delay, there is now an eflux of K which begins to restore the resting membrane potential and there is a slight hyper=polarisation.

Question 26

Why can an action potential not fire straight after a previous one?

Answer 26

The Na and K are in the wrong place, there is a period where this is restored by the ion exchanger, this period is called the refractory period.

Question 27

What are the insulating cells of the central nervous system?

Answer 27

Oligodendrocytes.

Question 28

What are the insulating cells of the peripheral nervous system called?

Answer 28

Schwann cells.

Question 29

Which disease is caused by the genetic mutation of Schwann cells?

Answer 29

Charcot Marie Tooth disease.

Question 30

What occurs at the synapse when an action potential arrives?

Answer 30

Voltage gated Ca2+ gates open allowing an influx of calcium ions. This causes vesicles of neurotansmitter to exocytose. This then diffuses across the synaptic cleft and binds to receptors on the postsynaptic terminal which triggers an action potential.

Question 31

How do we remove neurotransmitter from the synaptic cleft?

Answer 31

There are three main ways;

1) Enzyme in the cleft to breakdown excess.
2) Pumps in the presynaptic terminal to actively pump neurotransmitter back into the neurone.
3) Receptors on the presynaptic terminal help to control the release.

Question 32

What are the two broad types of receptor that neurotransmitters act on?

Answer 32

Ionotropic and metabotropic.

Question 33

What are Ionotropic receptors?

Answer 33

Receptors which, when a neurotransmitter binds, opens as a channel to allow the passage of ions. They act fast.

Question 34

What are metabotropic receptors and how do they work?

Answer 34

Neurotransmitter binds to the metabotropic receptor which activates the associated G-protein, this then causes intracellular messengers to modulate the ion channels. These act more slowly than iontropic receptors.

Question 35

What level does the sympathetic system arise from? And where are the ganglia located?

Answer 35

T1-L2, ganglia are located in the sympathetic chain.

Question 36

What are the prevertebral ganglia of the sympathetic system named after?

Answer 36

Adjacent arteries, eg. Coeliac ganglia.

Question 37

Which neurotransmitter do the preganglionic neurones of the sympathetic system release?

Answer 37

Acetylcholine

Question 38

Which neurotransmitter do the postganglionic neurones of the sympathetic system release?

Answer 38

Noradrenaline (except in sweat glands which is Acetylcholine.

Question 39

Where are the preganglionic cells of the parasympathetic located? (2 locations)

Answer 39

1) The brain stem (Many cranial nerves).
2) S2-4
Known as craniosacral.

Question 40

The parasympathetic nervous system uses acetylcholine as it’s neurotransmitter, which receptor does it use at the ganglion and which receptor at the effector?

Answer 40

Ganglion - Nicotinic Acetylcholine receptor.

Effector - Muscarinic Acetylcholine receptor.

Question 41

Which receptor and neurotransmitter does the sympathetic system use at the ganglion and at the effector?

Answer 41

Ganglion - Acetylcholine - Nicotinic

Effector - Noradrenaline - Adrenergic

Question 42

What are the two main types of the Acetylcholine receptors?

Answer 42

Nicotinic and Muscarinic.

Question 43

Nicotinic is a receptor type of which neurotransmitter? What type of receptor is it and where are they located?

Answer 43

Acetylcholine, Ionotropic, On postganglionic neurons of the parasympathetic and sympathetic nervous system and also at neuromuscular junctions.

Question 44

Muscarinic is a receptor type for which neurotransmitter? What type of receptor is it and where is it located?

Answer 44

Acetylcholine, Metabotropic, On effector cells of the parasympathetic nervous system.

Question 45

Which type of receptor does the adrenal medulla have?

Answer 45

Nicotinic, cells of the adrenal medulla are basically postganglionic neurones.

Question 46

What is an agonist of nicotinic receptors? And what effect does this have?

Answer 46

Nicotine, increased HR and BP.

Question 47

How many muscarinic receptor subtypes are there?

Answer 47

5, M1-5

Question 48

Where are M1,4&5 receptors found?

Answer 48

In the CNS.

Question 49

Where are M2 receptors found?

Answer 49

Present on myocardium, smooth muscle and presynaptic sites.

Question 50

Where are M3 receptors found?

Answer 50

Exocrine glands, vessels, iris sphincter muscles.

Question 51

Name an agonist of muscarinic receptors.

Answer 51

Muscarine, found in poisonous mushrooms.

Question 52

What is an antagonist of muscarinic receptors and what clinical use does it have?

Answer 52

Atropine, pupil dilation for eye exams.

Question 53

What are the two major subtypes of adrenergic receptors?

Answer 53

Alpha and Beta.

Question 54

Alpha are subtype of which receptor type? What are the forms of Alpha receptors?

Answer 54

Adrenergic, Alpha-1, Alpha-2

Question 55

Alpha-1 are a type of which receptor? Where are they located? What are the effects of agonists and antagonists? Name one Alpha antagonist.

Answer 55

• Adrenergic.
• Vascular smooth muscle, pupillary dilator muscle, prostate, heart.
• Agonists - treat hypotension.
• Antagonists - treat hypertension.

Question 56

Alpha-2 are a type of which receptor? Where are they located? What are the effects of agonists and antagonists?

Answer 56

• Adrenergic.
• CNS, platelets, nerve terminals, smooth muscle, fat cells.
• Agonists - treat hypertension.
• Antagonists - limited clinical application found.

Question 57

Beta receptors are a subtype of which receptor? What are the different types?

Answer 57

Adrenergic, Beta 1-3

Question 58

Which type of receptor are Beta1-3 and where is each type located?

Answer 58

• Adrenergic
• B1 - Heart
• B2 - Repiratory, uterine and vascular smooth muscle, skeletal muscle, liver.
• B3 - Fat cells

Question 59

Name a B2 agonist and what is used to treat?

Answer 59

Salbutamol, asthma.

Question 60

What is Salbutamol and what is it used for?

Answer 60

B2 agonist used in the treatment of asthma.

Question 61

Name two B-antagonists, their use and which subtype they act upon.

Answer 61

• Timolol - non-specific - used to treat glaucoma.

* Bisoprolol - Beta-1 - used to treat hypertension and cardiac ischaemia.

Question 62

How many subunits make up the nicotinic receptor?

Answer 62

5

Question 63

The influx of what into the presynaptic terminal (of a neuromuscular junction) stops the release of acetylcholine?

Answer 63

K+

Question 64

Name three autoimmune diseases of the neuromuscular junction.

Answer 64

1) Lambert Eaton Myasthenic Syndrome
2) Myasthenia Gravis
3) Neuromyotonia

Question 65

What is LEMS and what is the pathophysiology?

Answer 65

Lamber Eaton Myasthenic Syndrome, an autoimmune disease of the neuromuscular junction, antibodies block the Ca2+ channels. Causes weakness of movement but enough APs can trigger an AP in the post-synaptic terminal.

Question 66

What is Neuromyotonia?

Answer 66

An autoimmune disease of the neuromuscular junction, antibody against the voltage-gated K+ channels, Acetylcholine continually released causing stiffness and cramps.

Question 67

What is Myasthenia Gravis?

Answer 67

Autoimmune disease in which antibodies are produced against most acetylcholine receptors. Causes fatiguable weakness in the yes, bulbar muscles, neck extension, respiratory failure and limb muscles.

Question 68

What treatments are available for Myanthesia Gravis?

Answer 68

• Intravenous immunoglobin / plasma exchange
• Acetylcholinesterase inhibitors
• Immunosupressants