Deja review Cardio/Renal agents - Antiarrhythmics

Question 1

Describe what happens during phase 0

Answer 1

sodium ion channels open (inward) -> leads to depolerization

Question 2

Describe what happens during phase 1

Answer 2

sodium ion channels are inactivated, potassium ion channels (outward) are activated; chloride ion channels (inward) are activated

Question 3

Describe what happens during phase 2

Answer 3

Plateau phase; slow influx of calcium ion balanced by outward potassium ion current (delayed rectifier current Ik-funny sodium channel)

Question 4

Describe what happens during phase 3

Answer 4

Repolarization phase; outward K+ current INC and inward calcium ion current DEC

Question 5

Describe what happens during phase 4

Answer 5

Membrane returns to resting potential

Question 6

What phase of cardiac action potential do amiodarone and sotalol work?

Answer 6

phase 0 and 3

Question 7

What phase of cardiac action potential do lidocaine, flecainide, and quinidine work?

Answer 7

phase 0

Question 8

What phase of cardiac action potential do ß blockers work?

Answer 8

phase 2 and 4

Question 9

what is responsible for maintaining the electrochemical gradient at resting membrane potential?

Answer 9

Na+/K+ ATPase

Question 10

What ion current is responsible for the depolarization of sinoatrial (SA) and atrioventricular (AV) nodal fibers?

Answer 10

Calcium ion (inward)

Question 11

What ion current is responsible for the repolarization of SA and AV nodal fibers?

Answer 11

Potassium ion (outward)

Question 12

How does phase 4 of the action potential in slow response fibers (SA and AV nodes) differ from that of fast response fibers?

Answer 12

slow response fibers displays automaticity (ability to depolarize spontaneously); rising phase 4 slope of the action potential = pacemaker potential

Question 13

What ion current is responsible for the “pacemaker current” (rising slope of phase 4) in slow response fibers?

Answer 13

Sodium ion (inward); calcium ion (inward); potassium ion (outward)

Question 14

The pacemaker of the heart has the fastest uprising phase 4 slope; where is this pacemaker in nondisease patients?

Answer 14

SA node

Question 15

Where is the SA node located?

Answer 15

right atrium

Question 16

How do the effective refractory period (ERP) and relative refractory period (RRP) differ from each other?

Answer 16

No stimulus, no matter the strength, can elicit a response with fibers in the ERP, whereas a strong enough stimulus will elicit a response.

Question 17

What are the 3 states the voltage gated Na+ channel exists in?

Answer 17

1) Resting state
2) Open state
3) Inactivated state

Question 18

What state(s) of the voltage gated Na+ channel is/are most susceptible to drugs?

Answer 18

Open state inactivated state

Question 19

What 2 types of gates does the voltage gated Na+ channel have?

Answer 19

1) M (activating)

2) H (inactivating)

Question 20

Why is the rate of recovery from an action potential slower in ischemic tissue?

Answer 20

The cells are already partly depolarized at rest

Question 21

What class of antiarrhythmic agents has membrane-stabilizing effects?

Answer 21

ß-blockers

Question 22

Antiarrhythmic agents are grouped into 4 classes according to what classification system?

Answer 22

Vaughn-Williams classification

Question 23

Give the general mechanism of action for ech of the following antiarrythmic drugs classes:

• Class I
• Class II
• Class III
• Class IV

Answer 23

• Class I: Na+ channel blockers
• Class II: ß-blockers
• Class III: K+ channel blockers
• Class IV: Ca2+ Channel blockers

Question 24

Class I antiarrhythmics are further subdivided into what casses?

Answer 24

1A; 1B; 1C

Question 25

Give examples of antiarrhythmic drugs in class 1a

Answer 25

“ABBA Performed Dancing Queen”

Quinidine (antimalarial antiprotozoal agent); procainamide; disopyramide

Question 26

Give examples of antiarrhythmic drugs in class 1b

Answer 26

“Backstreetboys Mainly Lack Talent (and phenytoin)”

-Mexiletine; lidocaine; tocainide; phenytoin

Question 27

Give examples of antiarrhythmic drugs in class 1c

Answer 27

“Carly (rae jepsen) is Extremely Freaking Painful”

-Encainide; flecainide; propafenone; moricizine

Question 28

Give examples of antiarrhythmic drugs in class 2

Answer 28

Propranolol; esmolol; metoprolol

Question 29

Give examples of antiarrhythmic drugs in class 3

Answer 29

Amiodarone; sotalol; ibutilide; dofertilide

Question 30

Give examples of antiarrhythmic drugs in class 4

Answer 30

Verapamil, diltiazem

Question 31

Name 3 antiarrhythmic drugs that don’t fit in the Vaughn-Williams classification system

Answer 31

1) Digoxin
2) Adenosine
3) Magnesium

Question 32

Magnesium is used to treat what specific type of arrhythmia?

Answer 32

Torsades de pointes (polymorphic ventricular tachycardia)

Question 33

Adenosine is used to treat what types of arrhythmias?

Answer 33

Paroxysmal supraventricular tachycardia (PSVT), specifically narrow complex tachcardia or supraventricular tachycardia (SVT) with aberrancy; AV nodal arrhythmias (adenosine causes transitent AV block).
-Note: synchronized cardioversion and NOT adenosine should be used on symptomatic patients or unstable tachycardia with pulses

Question 34

Where anatomically should the IV be placed to administer adenosine?

Answer 34

As close to the heart as possible, that is, the antecubital fossa since adenosine has an extremely short half-life. Adenosine rapid IV push should be followed immediately by a 5-10 cc (mL) flush of saline to facilitate its delivery to the heart

Question 35

What is the mechanism of action of adenosine?

Answer 35

Stimulates α1 receptors which causes a DEC in cyclic adenosine monophosphate (cAMP) (via G2 coupled second messenger system); INC K+ efflux leading to INC hyperpolarizationl INC refractory period in AV node

Question 36

What are the adverse effects of adenosine?

Answer 36

Flushing, chest pain, dyspnea, hypotension

Question 37

What 2 drugs can antagonize the effects of adenosine?

Answer 37

Theophylline and caffiene

Question 38

How is adenosine dosed?

Answer 38

6mg initially by rapid IV push, if not effective within 1-2 minutes, give 12 mg repeat dose (follow each bolus of adenosine with normal saline flush). The 12 mg dose may be repeated once

Question 39

What is the most deadly ion that can be administered?

Answer 39

Potassium ion

Question 40

What EKG changes are seen in hyperkalemia?

Answer 40

Flattened P waves, widened QRS complex, peaked T waves, sine waves, ventricular fibrillation

Question 41

What EKG changes are seen in hypokalemia?

Answer 41

Flattened or inverted T waves, U waves, ST-segment depression

Question 42

What do class 1a antiarrhythmics do to each of the following?

• Action potential duration:
• ERP:
• Conduction velocity
• Phase 4 slope

Answer 42

• Action potential duration: INC
• ERP: INC
• Conduction velocity: DEC
• Phase 4 slope: DEC

Question 43

What do class Ib antiarrhythmics do to each of the following?

• Action potential duration:
• ERP:
• Conduction velocity
• Phase 4 slope

Answer 43

• Action potential duration: DEC
• ERP: Little or no change
• Conduction velocity: DEC (primarily in ischemic tissue)
• Phase 4 slope: DEC

Question 44

What do class 1c antiarrhythmics do to each of the following?

• Action potential duration:
• ERP:
• Conduction velocity
• Phase 4 slope

Answer 44

• Action potential duration: Little or no change
• ERP: Little or no change
• Conduction velocity: DEC
• Phase 4 slope: DEC

Question 45

Drugs that affect the strength of heart muscle contraction are referred to as what types of agents?

Answer 45

Inotropes (either positive or negative)

Question 46

Drugs that affect the heart rate are referred to as what types of agents?

Answer 46

Chronotropes (either positive or negative)

Question 47

Drugs that affect AV conduction velocity are referred to as what types of agents?

Answer 47

Dromotropes (either positive or negative)

Question 48

QT interval prolongation, and thus torsades de pointes, is more likely to occur with what two classes of antiarrhythmics?

Answer 48

1) class 1a

2) class 3

Question 49

Which class 1a antiarrhythmic also blocks α-adrenergic and muscarinic receptors, thus potentially leading to INC heart rate and AV conduction?

Answer 49

Quinidine

Question 50

What are the adverse effects of quinidine?

Answer 50

Tachycardia, proarrhythmic, INC digoxin levels via protein binding displacement, nausea, vomiting, diarrhea, cinchonism

Question 51

What is cinchonism?

Answer 51

Syndrome that may include tinnitus, high frequency hearing loss, deafness, vertigo, blurred vision, diplopia, photophobia, headache, confusion, delirium

Question 52

What are the adverse effects of procainamide?

Answer 52

Drug induced lupus (25-30% of patients), pro-arrhythmic, depression, psychosis, hallucination, nausea, vomiting, diarrhea, agranulocytosis, thrombocytopenia, hypotension

Question 53

What drugs can cause drug induced lupus?

Answer 53

Procainamide, isoniazid (INH), chlorpromazine, penicillamine, sulfasalazine, hydralazine, methyldopa, quinidine, phenytoin, minocycline, valproic acid, carbamazepine, chlorpromazine

Question 54

Which class 1a antiarrhythmic can cause peripheral vasoconstriction?

Answer 54

Disopyramide

Question 55

What are the adverse effects of disopyramide?

Answer 55

Anticholinergic adverse effects, such as urinary retention, dry mouth, dry eyes, blurred vision, constipation, sedation

Question 56

True or false? Lidocaine is useful in the treatment of atrial arrhythmias?

Answer 56

False

Question 57

True or false? Lidocaine is useful in the treatment of ventricular arrhythmias?

Answer 57

True

Question 58

True or false? Lidocainse is useful in the treatment of AV junctional arrhythmias?

Answer 58

False

Question 59

What are the adverse effects of lidocaine?

Answer 59

Proarrhythmic, sedation, agitation, confusion, paresthesias, seizures

Question 60

What class 1b antiarrhythmic can cause pulmonary fibrosis?

Answer 60

Tocainide

Question 61

Propafenone, even though a class 1c antiarrhythmic, exhibits what other type of antiarrhythmic activity?

Answer 61

ß-adrenergic receptor blockade

Question 62

Encainide and flecaininde INC _____ in postmyocardial infarction (MI) patients with arrhythmias?

Answer 62

sudden cardiac death

Question 63

Sotalol, even though a class III antiarrhythmic, exhibits what other type of antiarrhythmic activty?

Answer 63

ß-adrenergic receptor blockade

Question 64

Even though this agent is labeled as a class III antiarrhythmic, it displays class I, II, III, and IV antiarrhythmic activity

Answer 64

Amiodarone

Question 65

What is the 1/2 life of amiodarone?

Answer 65

40-60 days

Question 66

What are the adverse effects of amiodarone?

Answer 66

Pulmonary fibrosis, tremor, ataxia, dizziness, hyperthyroidism, hypothyroidism, hepatotoxicity, photosensitivity, blue skin discoloration, neuropathy, muscle weakness, proarrhythmic, corneal deposits, lipid abnormalities, hypotension, nausea, vomiting, congestive heart failure (CHF), optic neuritis, pneumonitis, abnormal taste, abnormal smell, syndrome of inappropriate secretion of antiduretic hormone (SIADH)

Question 67

How should patients on amiodarone therapy be monitored?

Answer 67

EKG thyroid function tests (TFTs), pulmonary function tests (PFTs), liver function tests (LFTs), electrolytes, ophthalmology exam

Question 68

Verapamil should not be given in what types of arrhythmias?

Answer 68

Wolff-Parkinson-White (WPW) syndrome, ventricular tachcardia

Question 69

What are the adverse effects of verapamil?

Answer 69

Drug interactions, constipation, hypotension, AV block, CHF, dizziness, flushing

Question 70

Digoxin is used to control ventricular rate in what types of arrhythmias?

Answer 70

Atrial fibrillation, atrial flutter

Question 71

Digoxin induced arrhythmias are treated by what drugs?

Answer 71

Lidocaine, phenytoin

Question 72

Digoxin does what to each of the follow?

• Strength of heart muscle contraction:
• Heart rate:
• AV conduction velocity:

Answer 72

• Strength of heart muscle contraction: INC (positive inotrope)
• Heart rate: DEC (negative chronotrope)
• AV conduction velocity: DEC (negative dromotrope)

Question 73

What does QTc stand for?

Answer 73

Corrected QT interval

Question 74

How is QTc calculated?

Answer 74

(QT)/(square root of R to R interval)

Question 75

Why must the QT interval be corrected?

Answer 75

The QT interval is dependent on heart rate, so higher heart rates will display shorter QT intervals on EKG. It is corrected to remove the variable of the heart rate

Question 76

What is the normal value for QTc?

Answer 76

Less than 440 milliseconds

Question 77

What does a long QT interval put a patient at risk for?

Answer 77

Torsades de pointes, a ventricular arrhythmia that can degenerate into ventricular fibrillation