Block 3 ANS neuro SG+slides

Question 1

ANS neurotransmission

Answer 1

sympathetic and parasympathetic

Question 2

sympathetic

Answer 2

preganglionic fibers-short
acethylcholine-nicotinic receptor
posganglionic fibers- NE noropinephrine-Aplha & Beta
-involves with ‘fright/flight/fight’ response to stress or arousal

Question 3

parasympathetic

Answer 3

long-acetycholine
nicotinic
posganglionic- Ach- muscarinic rec.

Question 4

Cholinergic receptors

Answer 4

nicotinic and muscarinic

Question 5

what are adrenergic/muscarinic receptors

Answer 5

they are on effector tissues (cardiac,smooth muscle,glands)

Question 6

ANS drugs bind to adrenergic receptors on effectors and stimulate fight/flight response are?

Answer 6

adrenergic agonist & sympathomimetics

Question 7

ANS drugs that bind to adrenergic receptors on effectors and block fight/flight response are?

Answer 7

adrenergic antagonist & sympatholytics

Question 8

ANS drugs that bind to muscarinic receptors on

effectors and stimulate a rest/digest response:

Answer 8

cholinergic/muscarinic agonists & parasympathomimetics

Question 9

ANS drugs that bind to muscarinic receptors on

effectors and block a rest/digest response:

Answer 9

Cholinergic/Muscarinic antagonists and

parasympatholytics

Question 10

what are adrenergic receptors

Answer 10

All adrenoreceptors are similar in structure and belong to the family
of G-protein-coupled receptors

Question 11

Alpha receptors:

Answer 11

a1- sympathetic effector tissue:brain

a2- presynaptic neuron

Question 12

Beta receptors

Answer 12

b1- sympathetic effector tissue-heart,adipose tissue,GI tract,renal aterioles
b2- mast cells;brain
b3- adipose tissue

Question 13

Non-selective Adrenergic Agonists MOA

Answer 13

Bind to α and β receptors
and stimulate a sympathetic nervous system
response

Question 14

Clinical Uses

Answer 14

Treatment for cardiac arrest, hypotension, shock

• Management of acute anaphylaxis

Question 15

Non-selective Adrenergic Agonists drugs

Answer 15

adrenaline
noradrenaline
ephedrine
dopamine

Question 16

α1-Adrenergic Agonists MOA & drugs

Answer 16

Bind to α1 receptors and stimulate a sympathetic nervous system response
-phenylephrine

Question 17

Clinical Uses

Answer 17

Treat hypotension, nasal congestion, red eyes (by
promoting vasoconstriction)
• Also used as a vasoconstrictor administered in combination with local anaesthetic

Question 18

a1-Agonist : Common Adverse Effects

Answer 18

• Hypertension
• Blurred vision
• Constipation
• Urinary retention

Question 19

α1-Adrenergic Antagonists MOA & drugs

Answer 19

Bind to α1 receptors and block a sympathetic nervous system response
- doxazosin

Question 20

Clinical Uses?

Answer 20

Treat mild-moderate hypertension, decreases urinary retention in benign prostatic hyperplasia

Question 21

Adverse Effects

Answer 21

Postural hypotension, urinary frequency, erectile

disorders, nasal congestion, fatigue

Question 22

β1-Adrenergic Agonists MOA & drug

Answer 22

Bind to β1 receptors and stimulate a sympathetic nervous system response
• dobutamine

Question 23

Clinical Uses?

Answer 23

Treat cardiac arrest, circulatory shock, hypoperfusion (by increasing heart rate and stroke volume)

Question 24

Common adverse effects:

Answer 24

hypertension, tachycardia, constipation

Question 25

β2-Adrenergic Agonists MOA & drugs

Answer 25

Bind to β2 receptors and stimulate a sympathetic nervous system response
• salbutamol, terbutaline, salmeterol, formoterol

Question 26

• Clinical Uses?

Answer 26

• COPD, asthma (by promoting bronchodilation); stop premature labour (tocolytic)

Question 27

Common adverse effects:

Answer 27

Fine muscle tremor, tachycardia, ↑ blood glucose

Question 28

β–antagonists/ Beta-blockers MOA & drugs

Answer 28

Bind to β receptors and block a sympathetic nervous system response
-carvedilol, labetalol

Question 29

• Clinical Uses?

Answer 29

• Cardiac disease, hypertension, migraine prophylaxis

Question 30

β–antagonists/ Beta-blockers

Examples of b1 cardio-selective blockers

Answer 30

metoprolol, atenolol

Question 31

Clinical Uses?

Answer 31

Ischemic Heart Disease -
Lowering of HR and force of contraction. Lessens work of heart
Hypertension - Effective only in hypertensive patients
Drop in BP is gradual
Reflex vasoconstriction is preserved. Less postural hypotension

Question 32

Adverse Effects:

Answer 32

• Dizziness
• Lethargy
• Insomnia
• Diarrhoea

Question 33

α2-Agonists-neg feedback mechanism

Answer 33

Majority of α2 receptors are located on the presynaptic neuron – binding of drugs to
these receptors stops release of more
catecholamines

Question 34

Clinical Uses?
clonidine
apraclonidine

Answer 34

Clonidine and its derivative Apraclonidine are selective α2 receptor agonists. They block sympathetic nerve transmission associated with vasomotor tone

Question 35

what is Clonidine used for?

Answer 35

hypertension

Question 36

what is apraclonidine used for?

Answer 36

used as an adjunct in controlling glaucoma

Question 37

Adverse effects

Answer 37

dizziness, drowsiness, dry nose/ mouth, nausea

Question 38

Nicotinic receptors:

Answer 38

respond to stimulation by

nicotine

Question 39

Muscarinic receptors:

Answer 39

respond to Muscarinic

extract obtained from toadstool mushroom. 5 subtypes M1-M5

Question 40

where is nicotinic receptors found?

Answer 40

in the brain, autonomic ganglia , neuromuscular junction (skeletal muscle), adrenal medulla

Question 41

where is muscarinic receptors found?

Answer 41

in all parasympathetic effectors

Question 42

what is anticholinesterases?

Answer 42

• acetylcholine esterase inhibitors

Question 43

Muscarinic Agonist Drugs MOA & drugs

Answer 43

Bind to muscarinic receptors and stimulate
a parasympathetic nervous system response
-acetylcholine, pilocarpine

Question 44

Clinical Uses?

Answer 44

Miotics (by constricting pupils) for cataract surgery;

decrease intraocular pressure in glaucoma (by increasing drainage of aqueous humour)

Question 45

Common adverse effects:

Answer 45

Problems with eye accommodation; can get salivation or bronchospasm at high doses

Question 46

Nicotinic Agonists

Answer 46

Binding of nicotinic agonists to nicotinic receptors

Question 47

Nicotinic Agonists- Centrally in the brain

Answer 47

feeling of well-being and

relaxation

Question 48

Nicotinic Agonists- All autonomic ganglia

Answer 48

> Increase in autonomic tone
resulting in increased activity of both sympathetic
and parasympathetic nervous system

Question 49

Nicotinic Agonists-Adrenal Medulla

Answer 49

Release of adrenaline causing increased sympathetic activity

Question 50

Nicotinic Agonists-Skeletal Muscle

Answer 50

Depolarises skeletal muscle cells

Question 51

Nicotinic Agonists two main uses

Answer 51

-assist smoking cessation
(nicotine patch, gum, lozenge)
-short-acting muscle relaxant

Question 52

Nicotinic Agonist –

Depolarizing Muscle Relaxant MOA

Answer 52

Mimics ACh and binds to nicotinic receptors at the neuromuscular junction – causes a quick muscle contraction following by relaxation (AND short-lived blocking of the receptor to further stimulation)

Question 53

nicotinic agonist drug and clinical use

Answer 53

-suxamethonium

Short acting muscle relaxant for endoscopy, intubation or orthopaedic reductions

Question 54

Adverse effects

Answer 54

muscle spasms, hyperkalemia and malignant hyperthermia

Question 55

Anticholinesterase Drugs & MOA

Answer 55

Inhibits the enzyme acetylcholine esterase, effectively increasing the amount of ACh and hence cholinergic effects.

• pyridostigmine
• neostigmine

Question 56

Clinical Uses?

Answer 56

– Treat Myasthenia gravis

– Post-op reversal of neuromuscular blockade and treatment of urinary retention

Question 57

Adverse Effects

Answer 57

salivation, diarrhoea, bradycardia, hypotension, bronchospasm, urinary urgency

Question 58

Muscarinic Antagonists

Answer 58

antimuscarinics or anticholinergics

Question 59

Muscarinic Antagonists MOA & drugs

Answer 59

binds to muscarinic receptors and blocks
ACh from binding; inhibits a parasympathetic response
-atropine
-glycopyrronium

Question 60

Clinical Uses: atropine

Answer 60

“Pre-med” pre-surgery to counter-balance the effect of
vagal nerve stimulation associated with general
anaesthesia; decreases respiratory secretions
• Dilation of the pupil prior to eye surgery
• Antidote for organophosphate poisoning

Question 61

Clinical uses: glycopyrronium

Answer 61

treatment of gastric ulcers or pre-med (by decreasing gastric secretions)
• treatment of asthma/COPD - long-acting muscarinic antagonist
asthma inhaler/LAMA (by promoting bronchodilation)

Question 62

Clinical uses: ipratropium

Answer 62

treatment of asthma/COPD – short-acting muscarinic antagonist inhaler/SAMA (by promoting bronchodilation)

Question 63

clinical uses: benzatropine

Answer 63

anticholinergic drug use to Treatment of Parkinson’s disease (crosses blood-brain
barrier to reduce tremor and rigidity by fixing balance
of dopamine/acetylcholine activity)

Question 64

clinical uses: hyoscine

Answer 64

Treatment of GI spasm or nausea/vomiting

Question 65

Typical anticholinergic adverse effects

Answer 65

• Dry Mouth
• Blurred vision
• Urinary retention
• Constipation
• Tachycardia

Question 66

Nicotinic Antagonists -

Non Depolarizing Muscle Relaxant MOA & drug

Answer 66

binds to nicotine receptors at neuromuscular junction and blocks ACh from binding and leads to complete paralysis of the muscle
-rocuronium

Question 67

Clinical Uses?

Answer 67

Pre-med for neuromuscular blockade (muscle relaxant) -
slower onset of action and longer half life than
suxamethonium so can be used for longer procedures

Question 68

Adverse Effects:

Answer 68

Decreased BP (then reflex tachycardia – Marey’s Law!

Question 69

what are organophosphates?

Answer 69

anticholinesterases

acetylcholinesterase inhibitors

Question 70

What would happen to a person who is poisoned with

organophosphates?

Answer 70

mnemonic SLUDGEM (Salivation, Lacrimation, Urination, Defecation, Gastrointestinal motility, Emesis, Miosis)

Question 71

What would the antidote be?

Answer 71

atropine

Question 72

stimulation of the sympathetic nervous system results in

Answer 72

an increase in heart rate and blood pressure and dilation of the bronchioles to the lungs promoting an increased supply of oxygen to the tissue.

Question 73

stimulation of Parasympathetic nervous system

Answer 73

opposite stimulation. ‘rest and repose’. Blood pressure and heart rate drop, less
oxygen is needed so the bronchioles constrict while increased blood flow
is supplied to the digestive system with concurrent stimulation of peristalsis and increased release of digestive secretions such as saliva.

Question 74

drugs that stimulate sympathetic NS are

Answer 74

sympathomimetics- mimic

the neurotransmitter involved in the sympathetic nervous system and produce a sympathetic nervous system response.

Question 75

Drugs that stimulate the parasympathetic nervous system

Answer 75

parasympatholytics- they block the parasympathetic

nervous system response.

Question 76

MOA of ANS drugs

Answer 76

(neuron) receives impulses/input signals at specialized projections termed dendrites. If the stimulus reaches a threshold, a nerve
impulse (action potential) will be conducted down the axon to the terminal branches, stimulating the release of specialised chemical messenger molecules called neurotransmitters

Question 77

noradrenaline binds only to

Answer 77

adrenergic receptors.

Question 78

Adrenergic receptors are found on

Answer 78

effectors in the sympathetic nervous system

Question 79

adrenergic antagonists are drugs that will bind to

Answer 79

adrenergic receptor and stop the neurotransmitter,

noradrenaline from binding.

Question 80

Removal of Neurotransmitters from the Synaptic Cleft

Answer 80

To avoid continual stimulation by neurotransmitters remaining in the synaptic cleft forever removal mechanisms must exist.

Question 81

There are two main mechanisms used for this: Re-uptake

Answer 81

of the released neurotransmitter by the neuron that released
it.eg. one way in which noradrenaline is removed is by the amine re-uptake pump located on the presynaptic neuron (the neuron in which noradrenaline was released from).

Question 82

There are two main mechanisms used for this: Enzymatic breakdown

Answer 82

by the action of enzymes that degrade or breakdown the neurotransmitter. eg.enzyme
acetylcholinesterase breaks down the neurotransmitter acetylcholine.

Question 83

how is noradrenaline removed?

Answer 83

y removed by both mechanisms. It is removed from the synapse by the amine re-uptake pump and then degraded by an enzyme called monoamine oxidase.

Question 84

If a drug inhibits or blocks the enzymes involved in neurotransmitter breakdown the neurotransmitter is going to be around for longer.

Answer 84

result of this will be prolonged stimulation of the receptors and hence further
stimulation of either the parasympathetic or sympathetic nervous system

Question 85

Each neurotransmitter has a process for its removal after release.

Answer 85

Drugs may selectively modify this process.

Question 86

Neurotransmitters transmit impulses between what?

Answer 86

neurons or from a

neuron to an effector tissue.

Question 87

drugs may do what to neurotransmitter

Answer 87

• mimic
• block neurotransmitter’s receptor
• affect concentrations

Question 88

Neurotransmitters vary between different nerve tracts.

Answer 88

key ones are acetylcholine (binds to cholinergic receptors) and noradrenaline (binds to adrenergic receptors). Depending on their molecular shape, drugs may also bind to these receptors. This enables drug action to be more
specific.

Question 89

what is dopamine and where can it be found?

Answer 89

a neurotransmitter found in the CNS

Question 90

what is the clinical use of dopamine?

Answer 90

restoring circulation and tissue perfusion in circulatory shock

Question 91

Adrenergic Adverse Effects occur how?

Answer 91

occur as a result of
drug action on adrenergic receptors at sites other than where the desired
effect is wanted.

Question 92

What is the role of the 2-receptors?

Answer 92

Binding of noradrenaline to the 2-receptor results in inhibition of further release of neurotransmitter from the same axon terminal

Question 93

what is a Apraclonidine?

Answer 93

It is a selective 2-

agonist used to treat glaucoma

Question 94

how is Acetylcholine released?

Answer 94

released in a cholinergic synapse, diffuses across and

combines with a postsynaptic cholinergic receptor.

Question 95

what is Autonomic ganglion ?

Answer 95

continuation of impulse to postganglionic fibres in BOTH the sympathetic and parasympathetic fibres

Question 96

nicotinic receptors-Somatic NS effect

Answer 96

increase in skeletal muscle tone, muscle contraction

Question 97

nicotinic receptors- what happen when there is a release of adrenaline and
noradrenaline from adrenal
medulla ?

Answer 97

increased heart rate.

Question 98

Muscarinic receptors- ANS parasympathetic NS results in?

Answer 98

m1- GI tract – increased gastric acid & saliva secretion
m2- Heart -decreased rate and force of contractions
m3- Increased GI tract secretions –saliva, pancreatic juice, bile and motility
-Increased insulin secretion
-Pupils contract (miosis) as eyes accommodate for close vision
-Bronchoconstriction, increased mucus secretion
-Promotion of micturition &
defecation

Question 99

Muscarinic receptors- Sympathetic NS- cholinergic synapses results in?

Answer 99

m3- vasodilation in skeletal

muscles; sweating

Question 100

Muscarinic receptors- CNS

Answer 100

effect improves memory enhanced cognition