Pharmacology of Angina

Question 1

What are the aims of angina drug treatment?

Answer 1

1) Limit the number, severity and sequelae of angina attacks, thereby improve QoL
2) Protect against future, potentially more lethal ischaemic syndromes e.g. MI and lower the risk of atherosclerosis progression e.g. to unstable

Question 2

What is the main mechanism for the pharmacological treatment of angina of effort?

Answer 2

To decrease cardiac oxygen demand bc can’t dilate stenosis so difficult to get more blood to affected part of heart (except in some types using a vasodilator)

Question 3

What is a secondary mechanism for pharmacological treatment of angina?

Answer 3

To increase the oxygen supply to the ischaemic zone by decreasing the HR and increasing the blood flow in coronary arteries

Question 4

How do we protect against future, potentially more lethal ischaemic syndromes?

Answer 4

1) Decrease risk factors (smoking/BP/cholesterol)
2) Aspirin
3) Beta blockers
4) ACE inhibitors
5) Statins

Question 5

What drug is used for immediate relief/short term prevention?

Answer 5

Sublingual glyceryl trinitrate (GTN) - short acting nitrate

Question 6

What is the NICE treatment pathway for ongoing prophylaxis?

Answer 6

1) Beta blocker OR calcium channel blocker (CCB)
2) Beta blocker + vascular selective CCB
3) Beta blocker + vascular selective CCB + long acting nitrate/ivabradine/nicorandil/ranolazine
(which one depends on type of angina and co-morbidities)

Question 7

What is cardiac oxygen demand a function of?

Answer 7

Wall tension, contractility and HR

Question 8

What is calcium transport vital for?

Answer 8

Regulation of vascular smooth muscle tone

Question 9

How do organic nitrates work?

Answer 9

They dilate and relax veins and venules, lowering CVP, cardiac wall tension and cardiac oxygen demand (F-S mechanism)

Question 10

What is the cellular mechanism of organic nitrates?

Answer 10

NO donor e.g. in GTN, one of the nitrate groups is enzymatically cleaved off the molecule to form NO

Question 11

What is the haemodynamic mechanism of organic nitrates?

Answer 11

Low CVP/preload, increased coronary blood flow

Question 12

What is the main example of an organic nitrate?

Answer 12

GTN

Question 13

How is GTN taken and why?

Answer 13

Sublingually → it has a v rapid effect as it is absorbed by vasculature in the tongue within a minute (if taken orally it is broken down)

Question 14

What is GTN used for?

Answer 14

For cutting short an angina attack or preventing an anticipated attack

Question 15

What is an example of a longer acting organic nitrate?

Answer 15

Isosorbide dinitrate

Question 16

How are longer acting organic nitrates taken?

Answer 16

• On an ongoing basis e.g. pills, ointments, patches

Question 17

What is the problem with longer acting organic nitrates and how can this be avoided?

Answer 17

• Their effectiveness is limited by the development of tolerance after roughly 12 hours
• This can be avoided by a daily 8 hour drug-free period (typically at night when don’t really get angina anyway as usually brought on by exercise)

Question 18

What are the minor haemodynamic effects of nitrates?

Answer 18

• Dilate larger coronary arteries, increasing blood flow through coronary collaterals
• Lower TPR and afterload, thus lowering oxygen demand

Question 19

What are side effects of organic nitrates and what are they due to?

Answer 19

Due to vasodilation → headache, facial flushing, lower BP, reflex increase of HR

Question 20

What does the heart do to bypass stenosis and slow down the course of angina and why might vasodilators aid this?

Answer 20

Grow new blood vessels = coronary collaterals (inter-arterial anastomoses) → vasodilators can increase blood flow in these collaterals

Question 21

Explain why GTN is not a good vasodilator in arteries by how it is metabolised

Answer 21

1) GTN is metabolised by mitochondrial enzyme Mt ALDH-2
2) This also generates a superoxide which increases release of endothelin-1 by the endothelium
3) Endothelin-1 is a vasoconstrictor and also increases the ability of the arteries to respond to other vasoconstrictors nearby e.g. NA
4) Superoxide also inhibits guanylate cyclase (involved in how NO leads to vasodilation)
5) So any vasodilating effect of GTN is counteracted

Question 22

How does tolerance to GTN form?

Answer 22

1) Superoxide combines with NO to form peroxynitrate which inhibits Mt ALDH-2
2) So the build up of peroxynitrate over a long time causes tolerance to GTN

Question 23

Why is superoxide generally not good for the CV system?

Answer 23

Oxidative stress

Question 24

How do beta blockers work?

Answer 24

• They inhibit sympathetic stimulation of the heart so reduce cardiac contractility
• They also increase coronary blood flow and reduce oxygen demand

Question 25

What is the aim when dosing beta blockers?

Answer 25

• Aim for a resting HR of 55-60 bpm and an increase of <75% of the rate causing ischaemia during exercise
• So aiming to give a dose that will reduce the increase in rate by at least 75%

Question 26

Why are beta blockers contraindicated in vasospastic angina?

Answer 26

Tend to make vasospasm worse

Question 27

Why do beta blockers increase life expectancy post-MI?

Answer 27

They reduce the risk of developing chronic heart failure as you spend more time in diastole (?)

Question 28

What is an example of a beta blocker?

Answer 28

Bisoprolol

Question 29

To what beta receptor do you want beta blockers to be selective to and why?

Answer 29

Beta-1 selective e.g. bisoprolol so it has fewer effects on the lungs bc doesn’t block beta-2 receptors v much but does to same extent

Question 30

What other effect do beta blockers have on the kidneys?

Answer 30

They reduce renin release bc stimulation of renin is via beta-1 receptors in the kidney (sympathetic stimulation)

Question 31

What are 3 examples of calcium channel blockers (CCBs)

Answer 31

1) DHPs (dihydropyridine)
2) Diltiazem
3) Verapamil

Question 32

How do CCBs work?

Answer 32

• They block L-type calcium channels which initiate constriction → arterial vasodilation
• They reduce afterload, reducing work of the heart
• They dilate coronary arteries

Question 33

In which types of angina is the coronary vasodilation of CCBs most useful?

Answer 33

1) Angina associated with coronary vasoconstriction e.g. Prinzmetal’s
2) Mixed angina

Question 34

How do DHPs mainly act?

Answer 34

By vasodilation, reducing afterload and therefore cardiac work

Question 35

How does verapamil mainly act?

Answer 35

By direct negative inotropic effect, with some reduction in afterload as it is also a vasodilator

Question 36

Which drug has the middle action of DHP and verapamil?

Answer 36

Diltiazem

Question 37

Give the order of effectiveness of CCBs at vasodilation

Answer 37

DHPs > diltiazem > verapamil

Question 38

Give the order of effectiveness of CCBs at negative inotropy

Answer 38

Verapamil > diltiazem > DHPs

Question 39

What are some other potentially beneficial actions of CCBs?

Answer 39

1) Reduced reperfusion injury (cardiac damage occurring after ischaemia) - increase in oxidative stress
2) Endothelial ‘protection’
3) Reduced atheroma progression
4) Reduction of left ventricular hypertrophy

Question 40

What is an example of a DHP?

Answer 40

Amlodipine

Question 41

What is an example of a potassium ATP channel activator?

Answer 41

Nicorandil

Question 42

What is the dual cellular action of nicorandil?

Answer 42

1) Opens ATP-sensitive K+ channels in vascular smooth muscle cells → vasodilating influence, as K channels open, membrane potential becomes more negative so less voltage-gated calcium channels are open (like CCBs)
2) Stimulates guanylate cyclase (activated by NO)

Question 43

What effects does nicorandil have?

Answer 43

1) Relaxation of vascular smooth muscle through muscle mechanisms incl. hyperpolarisation, removal of calcium from the cytoplasm, calcium desensitisation
2) As a result, this leads to venous and arterial vasodilation → decreased preload and afterload → decreased cardiac work and oxygen demand

Question 44

Why are KATP channel blockers not used v wildly?

Answer 44

Don’t seem to be any better than CCBs and were released after

Question 45

How does ranolazine work?

Answer 45

1) Acts by inhibiting the late Na current in myocytes caused by ischaemia which triggers the action potential by opening calcium channels, causing contraction in the heart
2) Therefore it reduces cardiac wall tension → reduces cardiac work

Question 46

What happens in ischaemia and reactive oxygen species due to the late sodium current?

Answer 46

1) Calcium concentration increases due to late sodium current (lack of proper sodium calcium exchange)
2) Therefore the heart is stiff in diastole (not relaxed), so using energy when it shouldn’t be and can’t receive all the blood that it is supposed to

Question 47

What type of angina is ranolazine the most effective drug for?

Answer 47

Microvasculature angina

Question 48

Why is the funny current funny?

Answer 48

• Because it is activated by hyperpolarisation and is a mixed sodium and potassium current → causes inwards current
• This + inactivation of the potassium current causes depolarisation

Question 49

How does ivabradine work?

Answer 49

1) Blocks the funny current (not completely) which is involved in SAN pacemaking by entering the open channel from inside the cell and then it gets trapped when the channel shuts
2) This leads to a reduced HR

Question 50

Why is ivabradine an open channel blocker and what does this mean for the effectiveness of the drug?

Answer 50

1) Because the binding of ivabradine in the channel builds up when the channel is opening more frequently
2) This ‘use-dependency’ means that ivabradine tends to block more when the HR goes up (good)
3) Therefore, the faster the heart is beating and the channel is opening, the better ivabradine works as the more chances it has to act on the open channels

Question 51

How does the slowing action of ivabradine treat angina?

Answer 51

Slows down heart → increasing length of diastole → allows more time to perfuse myocardium

Question 52

What are the haemodynamic effects of ivabradine?

Answer 52

1) Lower HR allows more time for blood to perfuse the myocardium which reduces ischaemia
2) Lower HR → lower afterload → lower oxygen demand

Question 53

What are statins used for?

Answer 53

They are used long term in people with elevated LDL cholesterol levels to reduce the risk of developing coronary heart disease

Question 54

How do statins work?

Answer 54

1) They block the rate-limiting enzyme which produces cholesterol
2) Less LDL is taken up from the plasma by the liver

Question 55

What is revascularisation?

Answer 55

Opening up the blocked coronary artery e.g. percutaneous coronary intervention (PCI) using an inflated balloon

Question 56

What is the problem and solution with PCI?

Answer 56

Problem = restenosis in 30% over 6 months so symptoms return 
Solution = stents

Question 57

Describe coronary artery bypass grafting

Answer 57

• Uses pieces(s) of saphenous vein or diverted internal mammary artery
• Used in preference to PCI in patients with more serious/advanced coronary artery disease
• Much more invasive than PCI → chest must be opening, patient is usually on cardiopulmonary bypass
• Unlike PCI it improves survival
• e.g. triple bypass (look at diagram)

Question 58

What is stable angina?

Answer 58

Chest pain or discomfort which occurs when the presence of atherosclerotic plaque in one or more coronary arteries prevent the heart from receiving enough blood when its metabolic needs increase

Question 59

What is the main aim of drug treatment?

Answer 59

To reduce the number and seriousness of episodes of angina

Question 60

How is the main aim of drug treatment for angina achieved?

Answer 60

1) Mist if the drugs used act by reducing one or more of the 4 factors which determine CO and therefore work → preload, afterload, HR and cardiac contractility
2) Vasodilating drugs may also increase coronary perfusion, but this is seen as a secondary mechanism for treating angina

Question 61

How else can angina be treated?

Answer 61

• Angina can also be treated using percutaneous intervention and stunting or in more severe disease, coronary bypass
• The former approach is much more common, but is generally not more effective than drug treatment in the long term