Drugs and the Cardiovascular System: The Heart

Question 1

Describe what occurs during an AP in the heart.

Answer 1

• cells in the SA node are the pacemaker of the heart, they generate spontaneous APs
• Funny channels (If) switch on during hyperpolarised states, use cAMP (on their own they are not enough to cause depolarisation, but they start the process) - (hyperpolarization-activated cyclic nucleotide–gated (HCN) channels)
• transient calcium channels open (ICa(t))
• long lasting calcium channels open (ICa(l))
• the calcium influx is what causes the depolarisation and drives HR
• IK current: Potassium channels initiate depolarisation

The entire process is spontaneous, there is no specific stimulus that causes depolarisation however it can be influenced by PNS and SNS actions

Question 2

What is different about the cardiac AP?

Answer 2

• the depolarizing current is carried into the cell primarily by relatively slow Ca++ currents instead of by fast Na+ currents. There are, in fact, no fast Na+ channels and currents operating in SA nodal cells.
• the cells in the heart have no true resting potential
• cells in the SA node are the pacemaker of the heart, they generate SPONTANEOUS APs (there is no particular stimulus that drives depolarisation but it is influenced by SNS and PNS

Question 3

If current

Answer 3

• hyperpolarization-activated cyclic nucleotide–gated (HCN) channels
• require cAMP
• cause depolarisation in a hyper polarised state, but not enough depolarisation for an AP

Question 4

What are the cellular effects of the PNS and SNS on HR?

Answer 4

SNS:
- increased cAMP
- increased If current (depo initiation)
- increased Ica current (demo)
=> increased HR

PNS:
- decreased cAMP
- increased IK current (repo)
=> decreased HR

Question 5

What are the mechanisms that control contractility?

Answer 5

1. AP from adjacent cell (down t-tubule)
2. VGCC opens and Ca2+ enters the cell
3. Ca2+ induces Ca2+ release (CICR) through Rhyanodine receptor channels (RyR channels)
4. local release causes Ca2+ spark
5. summed Ca2+ sparks create Ca2+ signal
6. Ca2+ ions bind to troponin to initiate contraction
7. relaxation occurs when Ca2+ unbinds from troponin
8. Ca2+ is pumped back into the SR for storage
9. Ca2+ is exchanged for Na+
10. Na+ gradient is maintained by Na+/K+-ATPase

Question 6

What are the sources of Ca2+ in cardiac cells during contraction?

Answer 6

• Depolarization-induced influx of Ca2+ current (ICa) through the L-type channels contributes approximately 20–25% of the free Ca2+ in a cardiac twitch.
• The release of Ca2+ through the RyRs contributes the remaining 75–80% of Ca2+ necessary for cardiac contraction.

=> 75% from SR, 25% from outside (ec)

Question 7

What are the mechanisms regulating myocardial oxygen supply and demand?

Answer 7

Oxygen Supply:

• increased Coronary blood flow
• increased Arterial O2 content

Oxygen Demand:

• increased HR (more contractions)
• increased preload (small increase in FOC, 25% in 100& volume increase; increases work of heart due to starlings law, linked to SV)
• increased afterload (the more resistance there is the harder the heart has to work to pump blood through the system -> greater FOC)
• increased contractility (greater FOC)

Myocyte contraction = primary determinant of myocardial oxygen demand

Question 8

Name the main drugs influencing HR and their mechanism to do so.

Answer 8

• beta-blockers (decrease If and ICa; inhibits the SNS from increasing HR, especially if you have a beta-1-selective blocker)
• calcium antagonists (decrease ICa)
• Ivabradine (decrease If and speed of depolarisation)

Question 9

Which Ca2+ channels do CCBs block?

Answer 9

L-type

Question 10

How do beta blockers decrease HR?

Answer 10

• beta adrenoceptors are the predominant receptors on the heart
• the SNS increases nodal activity by increasing cAMP which increases If as well as by having a positive effect on Calcium influx
• if these actions are blocked by a beta blocker (beta-1-selective in particular) the heart will beat slower

Question 11

How do Calcium antagonists/CCBs decrease HR?

Answer 11

• Ca2+ is the predominant ion driving HR

- if you decrease the amount of Ca2+ you will slow the heart down

Question 12

How does ivabradine decrease HR?

Answer 12

• blocks the If current

- if you block this current you decrease the depolarisation speed by creating more space between depolarisations

Question 13

Name the drugs that influence contractility of the heart.

Answer 13

• beta-blockers
• Calcium antagonists
• organic nitrates
• potassium channel openers

Question 14

How do beta-blockers decrease contractility?

Answer 14

• contractility is SNS driven
• b1 is important for calcium entry
• if you block the beta-1-R you
• ability to initiate contraction is impaired

Question 15

How do CCBs decrease contractility?

Answer 15

• if you directly decrease the inward calcium current you decrease contractile force

Question 16

What are the 2 classes of CCBs?

Answer 16

• rate slowing

- non-rate slowing

Question 17

Name examples of rate-slowing CCBs. When would you use them?

Answer 17

• (Cardiac and smooth muscle actions; slow HR and decrease contractility)
• Phenylalkylamines (e.g. Verapamil)
• Benzothiazepines (e.g. Diltiazem)

Question 18

Name examples of non-rate-slowing CCBs. When would you use them?

Answer 18

• (smooth muscle actions – more potent; cause vasodilation; great in vasculature, not much action in the heart)
• Dihydropyridines (e.g. amlodipine)

-> No effect on the heart. Profound vasodilation can lead to reflex tachycardia

Question 19

How does NO work?

Answer 19

• it increases cGMP (via positive actions on sGC (soluble guanylate cyclase) which causes
  a) relaxation and (directly)
  b) opening of potassium channels which in turn causes hyper polarisation and makes contraction more difficult to initiate) -> making it more difficult to contract

Question 20

How do potassium channel openers work?

Answer 20

• cause K+ efflux
• this causes hyperpolarisation
• this makes it more difficult for the cell to contract

Question 21

What are the effects of organic nitrates and potassium channel openers on coronary BF?

Answer 21

increase CBF

Question 22

What are the effects of organic nitrates and potassium channel openers on preload and after load?

Answer 22

• decrease preload due to venodilation
• decrease afterload due to vasodilation

=> their effects are not only on the heart but also on Bis

Question 23

Summary of drugs acting on the heart in angina

Answer 23

• CCB: decreases contractility and HR
• Beta-blockers: decreases contractility and HR
• Ivabradine: decreases HR
• nitrates: improves coronary BF via vasodilation (relaxation and hyperpolarisation), decreases preload and afterload
• K+ channels openers: improve coronary BF via vasodilation (hyperpolarisation)

Question 24

What is stable angina?

Answer 24

• e.g. only during exercise or in the presence of exacerbating factors
• predictable

Question 25

What are the guidelines in treating stable angina?

Answer 25

• 1st line: CCB or BB (decide based on comorbidities, contraindications and the patients preferences)
• if not tolerated, consider switching CCB and BB
• if unsatisfactory control of symptoms either switch CCB and BB or use in combination
• if the person cannot tolerate CCB and BB or they are contraindicated give:
  a) a long acting nitrate OR
  b) ivabradine OR
  c) nicorandil
  (decide based on comorbidities, contraindications, patient’s preferences and drug costs)
• do not routinely offer other anti-anginal drugs other than CCB and BB routinely

Question 26

What is the first line treatment for angina?

Answer 26

BB or CCB

Question 27

What are the side effects of beta blockers?

Answer 27

• worsens HF
• reduces CO
• increased vascular resistance (because b2 receptors are vasodilation and their effect is blocked)
• bradycardia
• Heart block – decreased conduction through AV node
• cold extremities
• Fatigue*
• Impotence (sexual dysfunction)*
• Depression*
• CNS effects (lipophilic agents) e.g. nightmares*

*not quite proven

Question 28

When do you have to be particularly careful when giving beta-blockers?

Answer 28

• If the patient has HF
• it can worsen HF (due to increased resistance and decreased CO)
• if needed in HF you have to give it in a very controlled and monitored way gradually increasing the dosage
  Beta 2 receptor blockade will reduce vasodilation and increase TPR which can worsen heart failure.

Also in patients with:

• asthma (beta activation causes dilation)
• diabetes (beta 2 (and a1) is important for HGO; masks hypoglycaemia, if you were getting hypoglycaemic the SNS would give you a warning effect)
• ❤️block (if someone has HB or any conductive problems, bradycardia could become a problem)

Question 29

Pindolol in HF and angina

Answer 29

• has ISA (intrinsic sympathomimetic activity)
• good for HF AND Angina
• at rest, during daily activities it does not have much effect
• beta-blocking effects kick in when you exercise

Question 30

Mixed blockers in angina

Answer 30

• if you want to prevent the increased vascular resistance from being a problem
• if you also give alpha blockade it will cause dilation rather than constriction
• this can also help a bit with HF
• e.g. carvedilol (b1,b2,a1)

Question 31

Why do beta-blockers cause cold extremities?

Answer 31

• Loss of β2 receptor mediated cutaneous vasodilation in
  extremities
• removing this vasodilation capacity makes it hard for blood to reach the fingers

Question 32

What are the questionable/not quite proven SEs of beta blockers>

Answer 32

• Fatigue
• Impotence (sexual dysfunction)
• Depression
• CNS effects (lipophilic agents) e.g. nightmares

=> evidence base is not fantastic, RCTs would be needed

Question 33

What are the side effects of verapamil?

Answer 33

=> CCB (rate-slowing)

• constipation (annoying but not dangerous) -> in 25% patients (gut Ca2+ channel block)
• bradycardia and AV block (Ca2+ channel block)

less dangerous SE profile than BB

Question 34

What are the side effects of dihydropiridines?

Answer 34

=> CCB (non-rate-slowing; e.g. amlodipine)
-> you don’t tend to use these in angina.

They are very effective at vasodilation: you tend to get vasodilating side effects.

In 10-20% patients:

• ankle oedema
• flushing/headaches (due to vasodilation in the brain)
• palpitations (reflex sympathetic response, baroreceptors increase HR)

Question 35

What are arrhythmia?

Answer 35

• Abnormalities of cardiac rhythm (arrhythmias/dysrhythmias)
• May be associated with decreased heart rate (bradyarrhythmias) or increased heart rate (tachyarrhythmias).
• affect around 700,000 people in UK.

Question 36

What are the aims in treatment of arrhythmias?

Answer 36

Reduce sudden death (e.g. sudden cardiac arrest)
Prevent stroke (clots)
Alleviate symptoms

Management is complex; usually undertaken by specialists; and may involve cardioversion, pacemakers, catheter ablation therapy and implantable defibrillators as well as drug therapy

Question 37

What is a simple classification of arrhythmias?

Answer 37

Based on site of origin:

• Supraventricular arrhythmias (e.g. amiodarone, verapamil)
• Ventricular arrhythmias (e.g. flecainide, lidocaine).
• Complex (supraventricular + ventricular arrhythmias) (e.g. disopyramide).

Question 38

Vaughan Williams Classification

Answer 38

Classification of Arrhythmic drugs

1. Na+ channel blockade
2. beta-adrenergic blockade
3. Prolongation of repolarisation (membrane stabilisation; mainly due to potassium channel blockade)
4. CCB

=> classification is of limited clinical significance

Question 39

Adenosine

Answer 39

• Used intravenously to terminate supraventricular tachyarrhythmias (SVT). Its actions are short-lived (20-30s) and it is consequently safer than verapamil.
• if you slow the heart down there is a greater chance of restoring normal rhythm,

Question 40

MOA of Adenosine

Answer 40

• binds to A1R on SA and AV node cells: causes decrease in cAMP which decreases HR and dromotropy (conduction speed)
• binds to A2R on (coronary) vascular smooth muscle, increases ic cAMP and causes relaxation

Question 41

Verapamil in arrhythmias

Answer 41

• Reduction of ventricular responsiveness to atrial arrhythmias
• preferred to adenosine in asthma
• rate-slowing CCB

Question 42

MOA of verapamil in arrhythmias

Answer 42

• Depresses SA automaticity and subsequent AV node conduction
• block the calcium channels and decrease the ability to depolarise and try to restore normal rhythm

Question 43

Amiodarone

Answer 43

• can be used in a number of different arrhythmias
• superventricular and ventricular tachyarrhythmias – often due to reentry
• can be used for tachyarrhythmais associated with wolff-parkison-white syndrome
• MOA:
• Complex action probably involving multiple ion channel block
• mainly blocks potassium channels and prolongs repolarisation (likelihood that a re-entry rhythm causes contraction reduces because the cells are still in repolarising state)

Question 44

Re-entry arrhythmias

Answer 44

• you can get areas of dead or damages tissue and the AP can travel in the wrong direction (dead tissue seems to be unidirectional)
• If you have this dead tissue, the AP can move up and it can reactivate the tissue -> more likely to have jerky contraction (not relax-contract-relax-contract…)
• not every re-ernty rhythm automatically causes contraction (it depends on what state the cardiac tissue is in when it gets there)

Question 45

Does every re-ernty rhythm cause contraction?

Answer 45

No

-> it depends on what state the cardiac tissue is in when it gets there

Question 46

What are adverse effects of amiodarone?

Answer 46

Amiodarone accumulates in the body (t½ 10 - 100days)
Has a number of important adverse effects including:
- photosensitive skin rashes
- hypo- or hyper-thyroidism
- pulmonary fibrosis

=> be careful with this drug because it has dangerous Uses and it accumulates. Use it in very controlled situations.

Question 47

Re-entry rhythms and amiodarone

Answer 47

• you are not stopping the re-ernty rhythms
• by prolonging the repolarisation you are decreasing the probability that they will cause contraction because a re-entry rhythm won’t cause contractions if the cells are in a depolarising state

Question 48

Digoxin drug type

Answer 48

• Cardiac glycoside
• slows ventricular responses in
• used in atrial fibrillation and atrial flutter
• used in AF with stroke risk
• makes heart beat slower but more powerfully

Question 49

MOA of digoxin

Answer 49

• Inhibition of Na-K-ATPase (Na/K pump).
• This results in increased intracellular Ca2+ via effects on Na+/Ca2+ exchange → positive inotropic effect
• increase in Ca2+ is because there is a NA+/Ca2+ exchanger and if the NA+/K+ ATPase is working less there is Ca2+ accumulation
• It also has PS like effects -> slows the heart down more rhythmical contractions, also each contraction is more powerful and also improivng CO.
• central vagal stimulation causes increased refractory period and reduced rate of conduction through the AV node

Question 50

What are adverse effects of digoxin?

Answer 50

• dysrhythmias (e.g. AV conduction block, ectopic pacemaker activity)
• Note: Hypokalaemia (usually a consequence of diuretic
  use) lowers the threshold for digoxin toxicity because they compete for the same site

Question 51

Why should you be careful when giving digoxin in hypokalaemia?

Answer 51

• digoxin and K+ bind to the same binding site
• in hypokalaemia digoxin toxicity is more likely
• so always watch the patients potassium levels.

Question 52

What is the threshold of the AP in the heart?

Answer 52

-30 mv

Question 53

What are the effects of the SNS and PNS on the heart AP?

Answer 53

SNS: ↑ cAMP, ↑ If & Ica

PNS: ↓ cAMP, ↑ IK

Question 54

Phenylalkylamines

Answer 54

• (e.g. Verapamil)
• Rate slowing calcium antagonist
• (Cardiac and smooth muscle actions)

Question 55

Benzothiazepines

Answer 55

• (e.g. Diltiazem)
• Rate slowing calcium antagonist
• (Cardiac and smooth muscle actions)

Question 56

Name some rate slowing calcium antagonsits

Answer 56

Phenylalkylamines (e.g. Verapamil)

Benzothiazepines (e.g. Diltiazem)

Question 57

Dihydropyridines

Answer 57

• (e.g. amlodipine)
• non-rate slowing Calcium channel antagonist
• smooth muscle actions – more potent
• No effect on the heart. Profound vasodilation can lead to reflex tachycardia

Question 58

Example of a non rate slowing calcium channel antagonist

Answer 58

Dihydropyridines (e.g. amlodipine)

Question 59

You shouldn’t prescribe beta blockers if a patient has the following confitions

Answer 59

• DM
• HF
• Asthma