SNS Antagonists

Question 1

Describe the effects of each type of adrenoceptor. 
Alpha 1
Alpha 2
Beta 1
Beta 2
Beta 3

Answer 1

Alpha 1
 Vasoconstriction 
 GI tract relaxation 
Alpha 2
 Inhibition of transmitter release 
 Contraction of vascular smooth muscle  
 CNS actions  
Beta 1
 Heart – increased heart rate + contractility 
 Kidneys – increased renin release 
 GI tract relaxation  
Beta 2
 Bronchodilation 
 Vasodilation 
 Relaxation of visceral smooth muscle  
 Hepatic glycogenolysis  
Beta 3
 Lipolysis

Question 2

State five adrenoceptor antagonists including the receptors that they block.

Answer 2

Labetalol = alpha 1 + beta 1 (more beta 1 (4:1)) 
Phentolamine = alpha 1 + alpha 2 
Prazosin = alpha 1 
Propranolol = beta 1 + beta 2  
Atenolol = beta 1

Question 3

State four main clinical uses of SNS antagonists and false transmitters.

Answer 3

Hypertension
Angina
Arrhythmia
Glaucoma

Question 4

State three elements that contribute to hypertension.

Answer 4

Blood volume
Peripheral vascular tone
Cardiac output

Question 5

What is the main control of blood pressure?

Answer 5

Sympathetic drive to the kidneys via beta 1 receptors

This triggers renin release from the kidneys (leads to an increase in angiotensin II and aldosterone)

Question 6

What are beta-1 selective blockers called?

Answer 6

Cardioselective Beta-blockers

Question 7

What effect is responsible for most of the anti-hypertensive effect of beta-blockers?

Answer 7

Beta 1 blockade in the kidneys – this reduces renin release from the kidneys

Question 8

What effect does beta-1 blockade have on the heart?

Answer 8

Decrease in heart rate

Decrease in cardiac output

Question 9

How does the effect of beta-blockers on the heart change?

Answer 9

The effect of beta blockade on the heart disappears with chronic treatment as the heart begins to reset itself

Question 10

What is the effect of presynaptic beta 1 receptors?

Answer 10

They have a positive facilitation effect on the synthesis and release of neurotransmitter

Question 11

State four conditions in which you would not give a patient a betablocker. Explain each of them.

Answer 11

Asthma – blockade of beta 2 receptors in the lungs can take away the beta 2 mediated bronchodilation, which can be fatal in asthmatics
Cardiac Failure – these patients rely on a certain degree of sympathetic drive to the heart to maintain adequate cardiac output
COPD – same reason as asthma
Diabetes – beta blockade masks the symptoms of hypoglycaemia (e.g. tremors, palpitations, sweating) and beta 2 blockade also inhibits hepatic glycogenolysis

Question 12

State some other unwanted actions of beta-blockers.

Answer 12

Fatigue

Cold extremities

Question 13

What effect does propranolol have on heart rate, cardiac output and blood pressure?

Answer 13

It has little effect on these parameters at rest

It decreases all of these parameters when exercising

Question 14

Why would you still not give a cardioselective beta-blocker to anasthmatic patient?

Answer 14

Selectivity is dependent on concentration

Question 15

What are the effects of labetalol?

Answer 15

Acts more on beta 1 than alpha 1
It lowers blood pressure by reducing total peripheral resistance and it induces a change in heart rate and cardiac output (beta 1 mediated)

Question 16

What is the main mediator of total peripheral resistance?

Answer 16

Alpha 1 mediated vasoconstriction

Question 17

What are the effects of alpha blockade?

Answer 17

Vasodilation causing a fall in TPR and hence a fall in blood pressure
NOTE: blocking the sympathetic drive can cause postural hypotension

Question 18

What reflex will be triggered by alpha blockade?

Answer 18

It triggers a baroreceptor mediated reflex tachycardia to increase heart rate and cardiac output

Question 19

State some of the problems with non-selective alpha blockers (e.g. phentolamine).

Answer 19

Alpha 1 blockade will cause vasodilation and a fall in TPR and blood pressure
But the alpha 2 blockade will mean that you take away the negative effect of alpha 2 on the synthesis and release of noradrenaline so more noradrenaline will be released from the nerve terminal
This enhances the reflex tachycardia
Side effects include increased GIT motility and diarrhoea
Phentolamine is no longer used

Question 20

What are the effects of prazosin?

Answer 20

Highly selective alpha-1 antagonist
Leads to vasodilation and a fall in blood pressure
You get less tachycardia than with non-selective alpha blockers because the negative effect of alpha 2 on noradrenaline release has not been removed
NOTE: postural hypotension is troublesome
Prazosin also increases HDL and decreases LDL so is becoming more popular as an anti-hypertensive

Question 21

Describe the mechanism of action of methyldopa.

Answer 21

Methyldopa is taken up by noradrenergic neurones and is decarboxylated and hydroxylated for form alpha-methyl noradrenaline
This is not deaminated by MAO so accumulates more than noradrenaline in the synapse
Alpha-methyl noradrenaline displaces NA from the synaptic vesicles
It is less effective than NA on alpha 1 receptors so does not cause as much vasoconstriction
It is more effective than NA on alpha 2 receptors thus reducing noradrenaline release
It also affects the CNS by inhibiting sympathetic outflow

Question 22

State some other benefits of methyldopa other than its effect as an anti-hypertensive.

Answer 22

It does not have any adverse effects on foetus’ despite crossing the placenta
It maintains renal and CNS blood flow so it is used in patients with renal insufficiency or cerebrovascular disease
Adverse effects: dry mouth, sedation, postural hypotension, male sexual dysfunction
It is RARELY used

Question 23

What are arrhythmias usually caused by and why?

Answer 23

Myocardial ischaemia – damage to the heart muscle can result in re-entry of impulses that messes up the heart rhythm

Question 24

What can precipitate or aggravate arrhythmias?

Answer 24

An increase in sympathetic drive to the heart via beta 1 receptors

Question 25

What part of the heart’s electrical circuit depends heavily on sympathetic activity?

Answer 25

AV conductance depends heavily on sympathetic activity

Question 26

What effect do beta antagonists have on the refractory period of the AV node? How does this help in dealing with arrhythmia?

Answer 26

Beta-blockers INCREASE the refractory period of the AV node
It can interfere with AV conduction in atrial tachycardias and slow downventricular rate

Question 27

What class of drugs are beta-blockers?

Answer 27

Class II anti-arrhythmics

Question 28

What is propranolol particularly effective at treating?

Answer 28

It is particularly successful in arrhythmias that occur during exercise or mental stress

Question 29

Define angina.

Answer 29

Chest pain that occurs when the oxygen supply to the myocardium is insufficient for its needs

Question 30

Describe the three different types of angina.

Answer 30

Stable
 Pain on exertion due to a FIXED narrowing
Unstable
 Pain with less and less exertion culminating with pain at rest
 Atheromatous plaque begins to rupture
 Platelet-fibrin thrombus associated with the ruptured plaque without complete occlusion of the vessel
 High risk of infarction
Variable
 Occurs at rest
 Caused by coronary artery spasm
 Associated with atheromatous disease

Question 31

Describe how beta-blockers can help prevent angina attacks.

Answer 31

They decrease heart rate, decrease contractility and decrease systolic blood pressure meaning that it will reduce the oxygen demand of the heart whilst maintaining the same degree of effort
This means that you are less likely of getting to a situation where theoxygen supply to the myocardium is insufficient for its needs (angina)

Question 32

State some adverse effects of beta-blockers.

Answer 32

Fatigue 
Insomnia 
Dizziness 
Sexual dysfunction 
Bronchospasm 
Bradycardia 
Heart block  
Hypotension  
Decreased myocardial contractility

Question 33

State some other circumstances in which you would not give a beta-blocker.

Answer 33

Hypotension
Bradycardia
Bronchospasm
AV block or severe congestive heart failure

Question 34

Where is aqueous humour produced?

Answer 34

They are produced by the blood vessels in the ciliary body via the actions of carbonic anhydrase

Question 35

What dictates the amount of aqueous humour produced?

Answer 35

Blood flow in the ciliary body (and blood pressure)

Question 36

Where does the aqueous humour drain?

Answer 36

It drains into the trabecular meshwork in the canals of Schlemm

Question 37

How can adrenaline affect intraocular pressure?

Answer 37

Adrenaine can act on alpha-1 receptors to cause vasoconstriction and reduce blood flow through the ciliary body

Question 38

Describe the use of beta antagonists in treating glaucoma.

Answer 38

They reduce the rate of aqueous humour formation by blocking the receptors on the ciliary body
Examples: carteolol hydrochloride, levobunolol hydrochloride, timilol maleate

Question 39

State some other uses of beta antagonists.

Answer 39

Anxiety states (to control somatic symptoms associated with sympathetic ove reactivity such as palpitations and tremor) 
Migraine prophylaxis – maintain good blood supply within the CNS so reduces the risk of migraines  
Benign essential tumour

Question 40

Side effects methyldopa

Answer 40

Dry mouth
Sedation
Postural hypotension
Male sexual dysfunction