12. Drugs for Heart Disease

Question 1

What are the 8 classes of drugs for congestive heart disease (CHD)?

Answer 1

1. ACE Inhibitor (analapril, lisinopril) use 1 or 3
2. β1-blocker (atenolol, metoprolol) use 2 or 4
3. Ang II receptor blocker (ARB, losartan)
4. α/β adrenergic blocker (carvedilol, labetalol)
5. Tailored diuretics- decrease edema (loop diuretic) furosemide + K sparing (spironolactone)
6. Digoxin (inhibits Na pump (NaK ATPase) barrow therapeutic window
7. Vasodilators (hydralazine and nitrates)
8. Donuts mine (β1 agonist, milrinone)

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Question 2

What is congestive heart failure?

Symptoms?

Answer 2

Reduced cardiac output relative to the body’s needs (failure of heart to provide adequate CO)
Systolic emptying (EF<45%)
Diastolic filling (preserved EF)

Symptoms- dyspnea on exertion, then at rest, orthopnea
Difficulty in breathing- shortness of breath when lying flat
Fatigue
Edema reduced renal function
Heart- big on x ray (mainly in systolic HF)
Echocardiogram (reduced EF, diastolic function)

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Question 3

What are the antecedents (precursors) to congestive heart failure (CHF)?

Answer 3

Increased workload- hypertension, aortic stenosis, mitral regurgitation, pregnancy, hyperthyroid

Decreased muscle- coronary artery disease (infarction), myocarditis, cardiomyopathy

Question 4

What are the 3 most common precipitating causes of heart failure?

Answer 4

Hypertension

Coronary artery disease

Diabetes

Question 6

What are the factors (compensatory mechanisms) that come into play with congestive heart failure (CHF)?

Answer 6

⬇️CO ⬇️BP ⬆️SNS activity ⬆️sweating ⬇️renal blood flow ⬆️renin release ⬆️ANG II ⬆️aldosterone ⬆️TPR ⬆️Na retention ⬆️blood volume ⬆️edema ⬆️venous pressure ⬆️work load ⬆️demand on heart ⬆️preload ⬆️afterload

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Question 7

What is afterload and contractility’s effect from heart failure?

Answer 7

Afterload- increases so lowers stroke volume

Contractility- since preload afterload increase and CO decreases, to compensate the heart muscle stretches to enhance contractility
Unable to compensate, the heart quits (systematic & pulmonary congestion sets in resulting in decreased blood supply to all organs) resulting in edema and CHF

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Question 8

What are the 2 compensatory mechanisms in heart failure?

Answer 8

Sympathetic nervous system (extrinsic control system)- increase contractility, sympathetic is a result of some of symptoms of heart failure like tachycardia and sweating and increase renin levels

Frank starling law of the heart (local control system)- increase contractility

Goal is to reduce preload afterload edema congestion enlarged heart and restore/enhance cardiac output

Question 9

Why is preload and afterload increased?

Answer 9

Preload is increased because of incomplete emptying of the heart

Afterload is increased because of elevated SNS activity and activation of the renin-angiotensin-aldosterone system (RAAS)

Question 10

What are the role of diuretics in CHF?

Rationale for combining furosdemide + spironolactone

Answer 10

Relieve congestion - edema first decrease preload

Thiazides used more as antihypertensives

Loop diuretics furosemide mainly for CHF
Problem: AE: hypovolemia, hypokalemia

Add spironolactone (K sparing diuretic) to overcome hypokalemia, blocks aldosterone action on heart remodelling & cardiac fibrosis

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Question 11

What is cardiac output?

It’s affect in CHF?

Answer 11

CO= HR x SV
SV is proportional to preload, afterload, contractility

Despite increase preload and increase left ventricular end diastolic pressure (venous return), strike volume elevation is lower in heart failure

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Question 12

What are the drugs that decrease afterload?

Answer 12

ACE inhibitors and ARBs decrease ANG II effect which decreases TPR and blood pressure

The vasodilators hydralazine and nitrates
Hydralazine is arteriolar dilator
Nitrates are veno and arteriolar dilators

If dry cough is a serious problem, use ARBs

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Question 13

What drugs increase contractility?

Answer 13

Digoxin, milrinone, β agonists
Digoxin inhibits Na-K ATPase (Na pump)

Increases [Na]i, increases Na-Ca exchange, increase [Ca2+]i, increase contractility, no O2 consumption, no increase work load on heart
Causes depolarization, reduced phase 0 slope, reduced conduction velocity, causes A-V block
Increase BP, increases vagal tone

Low therapeutic index

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Question 14

What are the 4 steps of cardiac contractility initiated by β1 and β2 receptor kinked adenylate cyclase activation?

Answer 14

1. Binding of β-adrenergic agonist (dopamine/dobutamine) activates adenylyl cyclase, which produces cAMP
2. cAMP activates protein kinase, which in turn phosphorylates a calcium channel
3. Phosphorylation of a calcium Chen el increases calcium flow into the cell causing increases force of contraction of heart muscle
4. Phosphodiesterase inhibitors prevent hydrolysis of cAMP and, thus, prolong the action of protein kinase

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Question 15

What are the 3 steps of digoxin increasing contractility?

Answer 15

1. Digoxin inhibits Na/K exchange by Na/K ATPase
2. The concentration of intracellular Na increases, and the concentration gradient across the membrane decreases
3. Increased Na decreases the driving force for the Na/Ca exchanger, so there is decreased extrusion of Ca into the extracellular space

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Question 16

What are the 5 steps of positive ionotropic mechanism of digoxin?

Answer 16

1. Digoxin blocks Na pump, Na can’t move out
2. Na moves out through the bidirectional Na-Ca exchanger, Ca comes in exchange
3. Ca triggers massive Ca release
4. Elevated [Ca]i promotes cardiac contraction
5. Without energy utilization, no consumption of ATP

Digoxin causes a secondary increase/release of Ca from the intracellular SR calcium stores and elevate [Ca] triggered by Ca coming through the Na-Ca exchanger

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Question 17

What are cardiac glycosides?
Mechanism?
How do K levels affect?
(Digoxin)

Answer 17

Digoxin
Inhibit Na/K ATPase in the plasma membrane - positive ionotropic effect
Decrease automaticity and decreases AV conduction and prevents rapid ventricular rate in response to atrial fibrillation associated with CHF

Increase in extracellular K causes dephosphorylation of ATPase and reduces the binding and effect of digoxin
Digoxin and K compete at the Na pump binding site

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Question 18

What are the adverse effects of digoxin?

Answer 18

More common: ectopic beats, first degree AV block, slow ventricular rate in patients with atrial fibrillation
Less common: sinus bradycardia, sinus arrest, 2nd or 3rd degree AV block

Higher doses can increase sympathetic activity and increase the risk of atrial and ventricular arrhythmias

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Question 19

What aggregates digoxin toxicity?

Answer 19

Hypokalemia aggrevates digoxin toxicity since K and digoxin compete for Na pump

Question 20

What are β agonists and PDE3 inhibitors use for heart failure?

Answer 20

β agonists- dobutamine, epinephrine
PDE3 inhibitors- milrinone, ionotropes

Mostly β1 in myocardium- dobutamine
G protein coupled, cAMP, PKA, increase [Ca]i

These agents are rarely used, last ditch, temporary while waiting for heart transplant to activate and maintain a failing heart when nothing works. Energy (ATP) utilization

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Question 21

What is aldosterone antagonist (spironolactone) used for?

Answer 21

Helpful to overcome K loss and overcome aldosterone induced cardiac fibrosis. Loop diuretics are better for volume control and reduction of edema and congestion

Question 22

What are hydralazine and prazosin side in congestive heart failure?

Answer 22

Increase CO by decreasing the resistance that the heart must pump against (afterload)
Tolerance or desensitization is problem with these agents