9 Drugs and the CVS

Question 1

What are the action of drugs on the CVS? (what can the drugs alter?)

Answer 1

1. rate and rhythm of heart
2. force of myocardial contraction
3. peripheral resistance and blood flow (changing PR affects BF)
4. blood volume

Question 2

do drugs only act at 1 site?

Answer 2

no

Question 3

What are arrhythmias?

Answer 3

disturbance of cardiac rhythm

abnormality of HR or rhythm

Question 4

What are the different types of arrhythmias?

Answer 4

1. bradycardia - slow HR
2. atrial flutter
3. atrial fibrillation
4. Tachycardia (ventricular + supraventricular)
5. ventricular fibrillation

Question 5

What is atrial fibrillation? How does it arise?

Answer 5

damage to the atria causing multiple re-entry loops to generate

Question 6

What is supraventricular tachycardia?

Answer 6

tachycardia in the atria / AVN

Question 7

What is ventricular tachycardia?

Answer 7

tachycardia in the bundle of His / Purkinje fibres / ventricles

Question 8

Explain how arrhythmias can arise

Answer 8

1. ectopic pacemaker activity
2. afterdepolarisations
3. Re-entry loop

Question 9

How does ectopic pacemaker activity cause arrhythmia?

Answer 9

1. damaged area of myocardium becomes DEPOLARISED and spontaneously active
2. latent (hidden) pacemaker region activated due to ischaemia

(the damaged area of myocardium undergoes ischaemia, so latent pacemaker regions activated for pacemaker function - spontaneously active and depolarise, this latent pacemaker dominates over SAN)

Question 10

How does afterdepolarisations cause arrhythmia?

Answer 10

abnormal depolarisations FOLLOWING the AP (triggered activity)
more likely to occur if intracellular Ca2+ high
if reaches a threshold, can trigger another AP causing arrhythmia

Question 11

How does re-entry loop cause arrhythmia?

Answer 11

1. through conduction delay (slow down conduction) and accessory (other) pathway
2. incomplete conduction damage (unidirectional block) - excitation can take a long route to spread the wrong way through the damaged area, setting up a circus of excitation
   (block allows depolarisation to travel in 1 direction, NOT both, causing a loop of excitation)

Question 12

What happens in early after-depolarisations (triggered activity)? What can it lead to? When is it more likely to occur?

Answer 12

can lead to depolarisations (membrane hasn’t had a chance to fully repolarise)
can lead to oscillations (more likely to happen if AP prolonged)
longer AP = longer QT interval on ECG (because the depolarisation has been ‘extended’)

Question 13

How does multiple re-entry loops occur and what does it lead to?

Answer 13

e.g. several small re-entry loops in the atria (multiple foci) usually atrium damaged (e.g. from stretch - from volume overload)
leads to atrial fibrillation

Question 14

Describe the classes of anti-arrhythmia drugs

Answer 14

1. drugs that block voltage-sensitive Na+ channels
2. antagonists of ß-adrenoreceptors (normally stimulatory of adenylyl cyclase)
3. drugs that block K+ channels
4. drugs that block Ca2+ channels
   all these drugs have ability to cause arrhythmia themselves because they mess with ion channels

Question 15

Describe the principles of the therapeutic use of drugs which block voltage-dependent Na+ channels (class I)

Answer 15

typical example: local anaesthetic 'lidocaine' class 1b
only blocks voltage-gated Na+ channels in open / inactive state (use-dependent block)
dissociates rapidly in time for next AP (little effect in normal cardiac tissue - only those constantly depolarised from ischaemic damage)

-block doesn’t occur at initiation of AP, but ONCE AP has taken place and is in the inactive state-

Question 16

When is lidocaine used? why?

Answer 16

class I anti-arrhythmia, blocks Na+ channels

1. used following MI, if pt shows signs of ventricular tachycardia (fast), given intravenously
2. damaged areas of myocardium may be depolarised and fire automatically
3. more Na+ channels are opened in depolarised tissue: lidocaine blocks these Na+ channels (use-dependent), preventing automatic firing of depolarised ventricular tissue

-NOT used prophylactically (as a prevention drug)-

Question 17

What is the principle of the therapeutic use of ß-adrenoreceptor antagonist (class II)? and examples?

Answer 17

e.g. propranolol, atenolol (ß-blockers)
block sympathetic action: act at ß1-adrenoreceptors in the heart (reduce rate and force of contraction through reducing Ca2+ release / entering from L-type Ca2+ channels)
they decrease the slope of pacemaker potential in SAN (slow depolarisation) - takes longer for AP to be initiated (less Ca2+)

Question 18

When are ß-blockers used? Why?

Answer 18

used following MI, because of increased sympathetic activity (rapid HR)
ß-blockers prevent ventricular arrhythmias (block sympathetic?)
arrhythmias may be partly due to increased sympathetic activity

Question 19

Where does ß-blocker slow down conduction? why?

what else do ß-blockers do?

Answer 19

1. slow down conduction in AVN: prevent supraventricular tachycardias (above ventricles), slows ventricular rate in patients in AF
   (so slows down SAN and AVN, slows down rate of pacemaker and rate of ventricles receiving that signal and transmitting it to the ventricles)
2. reduce O2 demand: reduces myocardial ischaemia (less demand for O2, then less likely tissue will die), beneficial following MI (lack of O2 to myocardium)

Question 20

What is the principle of the therapeutic use of drugs that block K+ channels (class III anti-arrhythmics)?

Answer 20

prolong the AP: mainly blocking K+ channels: lengthens ARP

should prevent another AP occuring too soon, but in reality pro-arrhythmic (can block Na+ as well)

Question 21

Which drug is used to treat Wolff-Parkinson-White syndrome? Which class of drug is it and what are it’s functions?

Answer 21

amiodarone
a type III anti-arrhythmic, but has other actions as well as blocking K+
used to treat tachycardia associated with W-P-W

Question 22

briefly explain what Woldd-Parkinson-White syndrome is?

Answer 22

re-entry loop due to an extra conduction pathway

Question 23

What is the principle of the therapeutic use of drugs that block Ca2+ channels? an example?

Answer 23

e.g. verapamil
decreases slope of AP at SAN (less influx of Ca2+)
decreases AVN conduction (less AP to travel to AVN from SAN)
decreases force of contraction (neg inotropy - due to lack of Ca2+)
some coronary + peipheral vasodilation

Question 24

What is the function of Dihydropyridine Ca2+ channel blockers?

Answer 24

not effective in preventing arrhythmias, but DO act on vascular smooth muscle
e.g. amlopidine, felopidine, nicardipine

Question 25

What is heart failure?

Answer 25

chronic failure of the heart to provide sufficient output to meet the body’s requirements

Question 26

What are the features of heart failure?

Answer 26

1. reduced force of contraction

2. reduced cardiac output –> 3. reduced tissue perfusion –> 4. oedema

Question 27

How does reduced tissue perfusion from reduced cardiac output lead to oedema?

Answer 27

if right side of the heart has failure, then venous return will not be adequate, then congesting the venous system, increasing hydrostatic pressure, causing oedema peripherally

Question 28

What are the drugs used in the treatment of heart failure?

Answer 28

1. positive inotropes increase cardiac output e.g. cardiac glycosides, ß-adrenergic agonists (dobutamine)
2. drugs which reduce work load of the heart: reduce afterload and preload

Question 29

Describe the therapeuti use of ß-adrenoceptor antagonists

Answer 29

1. ß-adrenoceptor antagonists can be used to reduce the force of contraction by preventing the action of sympathetically released NA: prevent the heart’s workload following an MI
2. ß-adrenoceptors also reduce the HR following an MI, preventing any arrhythmias following an MI
3. can also be used to treat angina

Question 30

Define the term ‘inotropic drug

Answer 30

drugs that affect the force of contraction

Question 31

What are the circumstances where inotropic drugs can be used?

Answer 31

1. to increase cardiac output in heart failure e.g. cardiac glycosides
2. cardiac glycosides inhibit: Na+-K+-ATPase: leading to increased [Na+] inside cell, so NCX can pump Ca2+ out of cell, so more intracellular store of Ca2+ for contraction, increasing the force of contraction

Question 32

What are examples of selective ß1-agonist that has inotropic effects? How do they work?

Answer 32

adrenaline + dopamine

INCREASE force of contraction + HR by activating ß1-adrenoreceptors

Question 33

explain the mechanisms by which organic nitrates elevate angina

Answer 33

1. organic nitrates release nitric oxide (NO)
2. NO is a powerful vasodilator: produced naturally by endothelial cells lining the blood vessels
3. organic nitrates dilate the VEINS (venodilation), reducing central venous pressure (preload) - reducing workload of the heart
4. organic nitrates do NOT alleviate angina by dilating arterioles

Question 34

What is a secondary effect of organic nitrates?

Answer 34

dilation of collateral coronary arteries, improving blood supply to the heart
all helping to alleviate angina

Question 35

What are drugs which increase myocardial contractility?

Answer 35

cardiac glycosides e.g. digoxin
improve symptoms but NOT long term
digoxin blocks Na+/K+ ATPase

Question 36

Describe the action of cardiac glycosides

Answer 36

1. block Na+/K+ ATPase
2. increase in Na+ concentration inside the cells, leading to an inhibition of NCX (due to decrease in conc. gradient)
3. increase in [Ca2+] inside cardiac myocytes:
   positive inotropic effect - increasing force of contraction
   (more Ca2+ available for each contraction, AP shoots up higher)

Question 37

What is the action of cardiac glycosides on HR?

Answer 37

cause increased vagal activity:

1. action via CNS to increase vagal activity
2. slows AV conduction (via AVN?)
3. slows HR

Question 38

What are drugs which increase myocardial contractility?

Answer 38

ß-adrenoreceptor agonists (ß-adrenoreceptors normally increase contractility by increasing adenylyl cyclase e.g. NA)
e.g. dobutamine, acts on ß1-receptor
used in: cardiogenic shock (used in inadequate cardiac output to perfuse tissues), acute but reversible heart failure (e.g. following cardiac surgery)

Question 39

What’s the best way to treat heart failure?

Answer 39

reduce workload of the heart

Question 40

What are examples of drugs which reduce the workload of the heart?

Answer 40

ACE-inhibitors
drugs which inhibit the formation of angiotensin converting enzyme (ACE)
prevent conversion of angiotensin I to angiotensin II
angiotensin II acts on kidneys: increase Na+ and water reabsorption (Increase in blood volume - heart works harder)
angiotensin II is a vasoconstrictor (constrict peripheral vessels to increase peripheral resistance: (increase?) afterload)

Question 41

How do ACE-inhibitors work in terms of heart load?

Answer 41

1. reduce preload: decrease fluid retension from angiotensin II (Na+ & water reabsorption), decreasing blood volume
2. Reduce afterload: decrease vasomotor tone (decrease BP - decrease peripheral resistance)

both reduce workload of the heart

Question 42

What are drugs which reduce the work load of the heart?

Answer 42

1. ß-adrenoceptor antagonists (ß-blockers) - decrease contractility (less adenylyl cyclase)
2. diuretics: reduce blood volume (less to pump out)

Question 43

When does angina occur?

Answer 43

when O2 supply to the heart doesn’t meet its need

limited to duration and doesn’t result in death of myocytes

Question 44

What happens in angina?

Answer 44

ischaemia of heart tissue (myocardial ischaemia) - leading to chest pain usually on exertion
due to narrowing of the coronary arteries (atheromatous disease)

Question 45

How do you treat angina?

Answer 45

1. reduce work load of the heart:
   ß-adrenoreceptor blockers (ß-adrenoreceptors stimulate Heart)
   Ca2+ channel antagonists (reduce amount of Ca2+ entering heart via L-type Ca2+ channel, reducing CICR, reducing force of contraction)
   Organic nitrates (venodilator, reduce central venous pressure)
2. improve blood supply to heart: organic nitrates, Ca2+ channel antagonists (reduce vascular SM contraction e.g. organs, vessels- reduce demand)

Question 46

How do organic nitrates become nitric oxide?

Answer 46

reaction of organic nitrates with thiols (-SH groups) in vascular smooth muscle causes NO2- to be released (endothelial cells)
NO2- is reduced to NO (nitric oxide)

Question 47

What are examples of organic nitrates?

Answer 47

glyceryl trinitrate
isosorbide dinitrate

powerful vasodilator

Question 48

Describe the types of drugs used to treat patients with common cardiovascular problems and their mechanisms of action

Answer 48

1. anti-arrhythmia: treat atrial fibrillation, supraventricular tachycardia / ventricular tachycardia, by affecting Na+, K+, Ca2+ channels, ß-adrenoreceptor blockers
2. inotropic drugs: treat force of contraction e.g. increase cardiac output in heart failure
3. ACE-inhibitors treat chronic heart failure: promote vasodilation, reducing preload + afterload of heart

Question 49

How does nitric oxide cause vasodilation?

Answer 49

NO activates guanylate cyclase
increase cGMP –> PKG
lowers intracellular [Ca2+] - (phosphorylating L-type Ca2+ channels to shut them)
causes relaxation of vascular smooth muscle

Question 50

How does NO help to alleviate symptoms? (primary action)

Answer 50

acts on venous system venodilation to lower preload
more blood stored in veins, less in circulation, reducing pre-load heart fills less, doesn’t contract as hard (Starling’s Law), reducing the O2 demand when not contracting as hard

Question 51

How does NO help to alleviate symptoms? (secondary action)

Answer 51

act on coronary arteries: improve O2 delivery to ischaemic myocardium
acts on collateral arteries (joining arterioles) rather than arterioles

Question 52

Describe how organic nitrates work on dilating arterioles?

Answer 52

only helps in a minor contribution

as there aren’t that many collateral arteries, so increase in blood flow to ischaemic area is little

Question 53

What is the main action of organic nitrates?

Answer 53

1. venodilation
   reducing venous pressure + preload (return to heart)
   reducing work of heart (less in , pump less) - Starling’s Law of the heart

Question 54

When are antithrombotic drugs used?

Answer 54

certain heart conditions carry an increased risk of thrombus formation

1. atrial fibrillation (can move into LV –> systemic circulation, if carotid artery –> brain –> stroke)
2. acute myocardial infarction
3. mechanical prosthetic heart valves

Question 55

What are examples of antithrombotic drugs? action?

Answer 55

Anticoagulants:
1. heparin (intravenously): inhibits thrombin (acutely short term)
2. Warfarin (orally): antagonises vit K, can be long term
3. fractionated heparin (subcutaneous injection)
Antiplatelet drugs:
1. aspirin: following acute MI / high risk of MI (prevent thrombus which is platelet rich)

Question 56

What are risks of hypertension?

Answer 56

1. associated with increases in blood volume: Na+ & water retention by kidneys
2. increase in total peripheral resistance (TPR) - increasing BP

Question 57

How do you work out pressure?

Answer 57

pressure = flow x resistance

Question 58

how do you work out BP?

Answer 58

BP = cardiac output x total peripheral resistance

Question 59

How do you work out cardiac output?

Answer 59

stroke volume x HR

Question 60

What are possible targets for hypertension?

Answer 60

1. lower blood volume: lowers cardiac output via Starling’s law (less in, contracts not as hard)
2. lower cardiac output directly: reduce contractility / TPR
3. lower peripheral resistance (pumping against less resistance, less force required)

Question 61

What are the different types of drugs that can be used to treat hypertension?

Answer 61

1. Diuretics: decrease Na+ & water retention by kidney, decrease blood volume (decrease CO & TPR)
2. ACE-inhibitors: decrease Na+ & water retention by kidney, decrease TPR (vasodilation)
3. ß-blockers: decrease cardiac output (aren’t used to treat)
4. Ca2+ blockers selective for vascular SM, vasodilation, reduce VSM contraction, reduce cardiac output through reducing peripheral resistance
5. a1-adrenoceptor antagonist: vasodilation (decrease BP & TRP)

Question 62

Which common cardiovascular problems does cardiovascular drugs treat?

Answer 62

1. arrhythmias - irregular rhythm
2. heart failure
3. angina - lack of oxygen to the myocardium –> chest pain upon exertion
4. hypertension
5. Risk of thrombus formation