anti-arrythmics + anti-angina + cardiac glycosides

Question 1

what is a non-pacemaker blockade

Answer 1

suppress abnormal atrial or ventricular cells to restore normal sinus rhythm (RHYTHM control)
- Na channel blocker and potassium channel blocker

Question 2

what is an AVN blockade

Answer 2

suppress AV node to prevent high atrial rate from causing high ventricular rate (RATE control)
- beta blocker and calcium channel blocker

Question 3

types of sodium channel blocker

Answer 3

increasing degree of blockade of Na channel: B,A,C

Question 4

MOA of Class 1C Na channel blocker

Answer 4

eg flerainide
MOA: slows phase 0 depolarisation

use: refractory ventricular tachycardia

1C=no change

Question 5

MOA of Class 1A Na channel blocker

Answer 5

eg procainamide
MOA: slow phase 0 depolarisation
prolonged effective refractory period (moment cell starts repolarising) and action potential duration becase drug has K channel blockade

1A = after = prolong AP

Question 6

MOA of CLass 1B Na channel blocker

Answer 6

eg lidocaine
MOA : slow phase 0 depolarisation and shorten phase 3 repolarisation

decrease action potential duration but ERP unchanged

1B=before=shorten AP

Question 7

MOA of K channel blocker

Answer 7

eg SAD
Sotalol
Amiodarone
Dofelitide
MOA: slow down phase 3 repolarisation -> increase ERP and APD

Question 8

use of K channel blocker

Answer 8

• atrial fibrillation
• prevent reentrant ventricular tachycardia => instead of completing normal circuit, electrical signal has alt loop back upon itself (self perpetuating rapid and abnormal activation)

Question 9

special quality about K channel blocker

Answer 9

Amiodarone is metabolised by liver into active metabolites
this means that effect persist even after discontinuation of the drug (long half life: effect maintained 1-3mths after discontinuation)

Question 10

MOA of beta blockers

Answer 10

block binding of NE to beta receptor so voltage gated Ca channels cannot open and calcium cannot enter

reduced slope of 4 (depolarisation to threshold potential and slope of 0 (when calcium channels supposed to open)

takes longer time before can depoalrise so reduced frequency of action potential moving through AV node -> decrease HR and contractility

Question 11

uses of beta blockers

Answer 11

tachycardia
atrial fibrillation
protective effect after MI

Question 12

AE of beta blockers

Answer 12

bradycardia
hypotension -> decrease contractility if beta blockers block contractile portion of myocardium

Question 13

MOA of calcium channel blocker

Answer 13

non dihydropridine calcium channel blockers: (primarily affect myocardium)(IV)
diltiazem
verapamil

block calcium entry into cell -> decrease slope of 4 and 0 in AV node
block atrial signals from processing through AV node and into ventricles

• prolonged ERP and APD (prolong both depol and repol)

Question 14

use of calcium channel blockers

Answer 14

supraventricular tachycardia
hypertension
angina

Question 15

AE of calcium channel blockers

Answer 15

hypotention
contraindicated: pre-existing depressed cardiac output -> further inhibit AV nodal conduction

Question 16

types of anti angina drugs

Answer 16

• vasodilators: nitrates, calcium channel blockers
• cardiac depressants: calcium channel blockers, beta blockers
• ivabradine

Question 17

MOA of nitrates

Answer 17

form NO which activates guanylyl cyclase which phosphorylates GTP to cGMP

inactivates myosin-LC so relaxation, causing vasodilation

effect of vasodilation on
- veins: decrease venous return, hence preload (at low conc)
- arteries: reduce peripheral resistance, decrease afterload (at high conc)
- coronary arteries: lower pressure in arteries because heart does not stretch as much so improvement in subendocardial blood flow

decreased workload on heart so increase supply of blood and oxygen to coronary arteries

Question 18

types of nitrates

Answer 18

glycerol nitrate
PK: injecton-> slow onset but long DOA
sublingual (under tongue) -> quick onset but slow DOA

isosorbide dinitrate
isosorbide mononitrate
PK: oral -> slow onset but long DOA

Question 19

how are nitrates angina pectoris prophylaxis

Answer 19

if end diastolic pressure and volume is high, heart would enlarge and press on coronary arteries. This would affect subendocardial blood flow.

nitrates would dilate coronary arteries so it is able to receive greater blood flow

Question 20

AE of nitrates

Answer 20

reflex tachycardia (baroreflex)
hypotension
headache -> meningeal artery vasodilation

Question 21

MOA of calcium channel blockers in anti-angina

Answer 21

decrease contractility -> decrease O2 requirement -> decrease workload on heart

Question 22

ranking of calcium channel blockers as cardiac depressants

Answer 22

verapamil> diltiazem > nifedipine

Question 23

MOA of ivabradine

Answer 23

inhibit cardiac pacemaker current that controls spontaneous diastolic depolarization in SA node -> lower HR

results in decreased cardiac workload -> decreased myocardial o2 consumption

Uses: stable angina, chronic HF

Question 24

AE of ivabradine

Answer 24

visual problems
bradycardia associated symptoms: hypotension, dizziness, fatigue, malaise

Question 25

what are cardiac glycosides (digitalis)

Answer 25

late stage HF drug
- goal: increase HR

PK:
oral
digitoxin
- extensive metabolism in liver and excreted through faeces
- slow onset, long DOA
digoxin
- not metabolised in liver and excreted through urine
- quick onset, short DOA

Question 26

MOA of digitalis

Answer 26

inhibit Na/K ATPase. Efflux of Na from cell through the pump maintains the sodium gradient across the cell membrane and Na-Ca exchanger ruses energy from sodium gradient to pump calcium out of cell.

by inhibiting Na/K ATPase, cannot maintain sodium gradient so calcium cannot be pumped out and accumulates in cell. More calcium available for contraction, resulting in stronger contractions

Question 27

effects of digitalis

Answer 27

mechanical effect: increase contractility -> increase CO -> decrease sympathetic activity and increase renal blood flow which would release more renin -> decrease preload and afterload

electrical effect: increase contractility -> more parasympathetic activity ->decrease AV conduction -> decrease ventricular rate

Question 28

AE of digitalis

Answer 28

dysrhythmia (AV block, A F, VF)
GI effects
CNS effects

Question 29

digitalis toxicity

Answer 29

increased intracellular Ca can lead to
- tachycardia, atrial fibrillation, automaticity, extra systole

what to do
- discontinue
- anti-arrthymic drugs (eg lidocaine, propanaol)
- digoxin antibody

Question 30

for angina, which drug is the most appropriate for long term therapy aimed at reducing the incidence and severity of vasospasm

Answer 30

Diltiazem

Question 31

anti-arrthymatics drug classes

Answer 31

some block potassium channels

class 1- sodium blocker
class 2- beta blockers
class 3- potassium
class 4- Ca2+ channel