Heart Failure PDF

Summary

This document is a pharmacotherapy paper on the treatment of heart failure, covering topics such as definitions, stages, and classifications. It also includes discussions of relevant references, definitions, pathophysiology, and treatment options across different HF stages, including stage A, B, C, and D.

Full Transcript

Heart Failure

PHARMACOTHERAPY (1)
2023-2024
 References
Pharmacotherapy; a pathophysiologic approach (Dipiro 12th
edition). Chapter 36-CHF
Pharmacotherapy; a pathophysiologic approach (Dipiro 12th
edition). Chapter 37-ADHF
Heidenreich P, Bozkurt B, Aguilar D, et al. 2022
AHA/ACC/HFSA Guideline for the Management of Heart
Failure: A Report of the American College of
Cardiology/American Heart Association Joint Committee
on Clinical Practice Guidelines. J Am Coll Cardiol. 2022
May, 79 (17) e263–e421.
2024 ACC Expert Consensus Decision Pathway for
Treatment of Heart Failure With Reduced Ejection
Fraction: A Report of the American College of Cardiology
Solution Set Oversight Committee
 Definition of HF
HF is a complex clinical syndrome with symptoms
and signs that result from any structural or
functional impairment of ventricular filling or
ejection of blood.
– asymptomatic stages with structural heart disease or
cardiomyopathies are not covered under the above
definition as having HF. Such asymptomatic stages
are considered at-risk for HF (stage A) or pre-HF
(stage B)
 ACC/AHA Stages of HF
emphasize the development and progression of disease, and advanced
stages and progression are associated with reduced survival

The ACC/AHA stages of HF are shown.
ACC indicates American College of Cardiology; AHA, American Heart Association; CVD, cardiovascular disease; GDMT, guideline-directed medical therapy; and HF, heart
failure.
 Stages of HF
Stages Definition and Criteria
Stage A: At Risk for HF At risk for HF but without symptoms, structural heart disease, or cardiac biomarkers of
stretch or injury (e.g., patients with hypertension, atherosclerotic CVD, diabetes, metabolic
syndrome and obesity, exposure to cardiotoxic agents, genetic variant for cardiomyopathy,
or positive family history of cardiomyopathy).
Stage B: Pre-HF No symptoms or signs of HF and evidence of 1 of the following:
Structural heart disease*
 Reduced left or right ventricular systolic function
o Reduced ejection fraction, reduced strain
 Ventricular hypertrophy
 Chamber enlargement
 Wall motion abnormalities
 Valvular heart disease
Evidence for increased filling pressures*
 By invasive hemodynamic measurements
 By noninvasive imaging suggesting elevated filling pressures (e.g., Doppler
echocardiography)
Patients with risk factors and
 Increased levels of BNPs* or
 Persistently elevated cardiac troponin
in the absence of competing diagnoses resulting in such biomarker elevations such as acute
coronary syndrome, CKD, pulmonary embolus, or myopericarditis
Stage C: Symptomatic HF Structural heart disease with current or previous symptoms of HF.
Stage D: Advanced HF Marked HF symptoms that interfere with daily life and with recurrent hospitalizations
despite attempts to optimize GDMT.

BNP indicates B-type natriuretic peptide; CKD, chronic kidney disease; GDMT, guideline-directed medical therapy; HF, heart failure; LV, left ventricular; and RV, right ventricular.
 New York Heart Association (NYHA)
Classification
The NYHA classification is used to characterize symptoms and functional
capacity of patients with symptomatic (stage C) HF or advanced HF
(stage D).
It is a subjective assessment by a clinician and can change over time.
Although reproducibility and validity can be limited, the NYHA functional
classification is an independent predictor of mortality, and it is widely used
in clinical practice to determine the eligibility of patients for treatment
strategies.
Clinicians specify NYHA classification at baseline after the initial
diagnosis and after treatment through the continuum of care of a patient
with HF.

Although a patient with symptomatic HF (stage C) may become
asymptomatic with treatment (NYHA class I), that patient will still be
categorized as stage C HF.
 NYHA functional classification of HF:
Functional Physical Limitations and Symptoms
Class
Class I Patients with cardiac disease but without limitations of physical
activity. Ordinary physical activity does not cause undue fatigue,
dyspnea, or palpitation.
Class II Patients with cardiac disease that results in slight limitations of
physical activity. Ordinary physical activity results in fatigue,
palpitation, dyspnea, or angina.
Class III Patients with cardiac disease that results in marked limitation of
physical activity. Although patients are comfortable at rest, less
than ordinary activity will lead to symptoms.
Class IV Patients with cardiac disease that results in an inability to carry
on physical activity without discomfort. Symptoms of congestive
HF are present even at rest. With any physical activity,
increased discomfort is experienced.
 Classification of Heart Failure
ACCF/AHA Stages of HF NYHA Functional Classification
A At high risk for HF but None
without structural heart
disease or symptoms of
HF.
B Structural heart disease but I No limitation of physical activity. Ordinary
without signs or symptoms physical activity does not cause symptoms of HF.
of HF.
C Structural heart disease I No limitation of physical activity. Ordinary
with prior or current physical activity does not cause symptoms of HF.
symptoms of HF.
II Slight limitation of physical activity. Comfortable
at rest, but ordinary physical activity results in
symptoms of HF.
III Marked limitation of physical activity.
Comfortable at rest, but less than ordinary
activity causes symptoms of HF.
IV Unable to carry on any physical activity without
D Refractory HF requiring symptoms of HF, or symptoms of HF at rest.
specialized interventions.
 Classification of HF by LVEF
Type of HF According to LVEF Criteria
HFrEF (HF with reduced EF)  LVEF ≤40%

HFimpEF (HF with improved EF)  Previous LVEF ≤40% and a follow-up measurement of
LVEF >40%
HFmrEF (HF with mildly reduced EF)  LVEF 41%–49%
 Evidence of spontaneous or provokable increased LV filling
pressures (e.g., elevated natriuretic peptide, noninvasive
and invasive hemodynamic measurement)

HFpEF (HF with preserved EF)  LVEF ≥50%
 Evidence of spontaneous or provokable increased LV filling
pressures (e.g., elevated natriuretic peptide, noninvasive
and invasive hemodynamic measurement)

LVEF is considered important in the classification of patients with HF because of
differing prognosis and response to treatments and because most clinical trials
select patients based on ejection fraction (EF).
RCTs with evidence of survival benefit in patients with HF have mainly enrolled
patients with HF with an LVEF ≤35% or ≤40%, often labeled HF with reduced
ejection fraction (HFrEF)
 Classification and Trajectories of HF
Based on LVEF

Patients with HFrEF who improve
their LVEF to >40% are
considered to have HFimpEF and
should continue HFrEF treatment.

There is limited evidence to guide
treatment for patients who
improve their LVEF from mildly
reduced (41%-49%) to ≥50%. It is
unclear whether to treat these
patients as HFpEF or HFmrEF.

Trajectory of LVEF can be important, and a significant reduction in LVEF over time is a poor prognostic factor.
 Epidemiology and Causes of HF
HF is a growing health and economic burden, in large part because of the aging population
In the United States, approximately 115 million people have hypertension, 100 million have obesity, 92
million have prediabetes, 26 million have diabetes, and 125 million have atherosclerotic CVD (1). These
are known risk factors with high relative risk and population attributable risk for development of HF.
Therefore, a large proportion of the U.S. population can be categorized as being at-risk for HF or stage A
HF.
With the increasing ability to detect myocardial injury and with an increasing awareness of cardiotoxicity
and injury patterns including inflammation, pre-HF or stage B HF will likely continue to increase.
The common causes of HF include:
– ischemic heart disease and myocardial infarction (MI),
– hypertension,
– valvular heart disease (VHD).
Other Potential Nonischemic Causes of HF
Chemotherapy and other cardiotoxic medications
Rheumatologic or autoimmune Beyond classifications of
Endocrine or metabolic (thyroid, acromegaly, pheochromocytoma, diabetes, obesity) EF and staging in HF,
Familial cardiomyopathy or inherited and genetic heart disease clinicians should seek the
Heart rhythm–related (e.g., tachycardia-mediated, PVCs, RV pacing)
cause of HF because
Hypertension
appropriate treatment
Infiltrative cardiac disease (e.g., amyloid, sarcoid, hemochromatosis)
may be determined by the
Myocarditis (infectious, toxin or medication, immunological, hypersensitivity)
Peripartum cardiomyopathy
cause
Stress cardiomyopathy (Takotsubo)
Substance abuse (e.g., alcohol, cocaine, methamphetamine)
Self-Reading
 Selected Drugs That May Precipitate or Exacerbate Heart Failure
Negative inotropic effect
Antiarrhythmics (disopyramide, dronedarone, flecainide, propafenone, sotalol)
β-Blockers (eg, propranolol, metoprolol, carvedilol)
Calcium channel blockers—nondihydropyridine type (verapamil, diltiazem)
Itraconazole

Cardiotoxic
Self-Reading
Alkylating agents (eg, cyclophosphamide, ifosfamide, melphalan)
Amphetamines (eg, cocaine, methamphetamine)
Anthracyclines (eg, doxorubicin, daunorubicin, epirubicin, idarubicin)
Antiarrhythmics (eg, disopyramide, dronedarone, flecainide, propafenone, sotalol)
Antimetabolites (eg, fluorouracil, capecitabine, fludarabine, decitabine)
Antimicrotubules (eg, docetaxel, paclitaxel)
BCR-ABL inhibitors (eg, bosutinib, dastinib, imatinib, ponatinib)
BRAF inhibitors (eg, dabrafenib)
Carbamazepine
Chimeric antigen receptor (CAR) T-cell therapy (eg, tisagenlecleucel, axicabtageneciloleucel)
Daunomycin
Ethanol
Hormonal therapy (eg, aplalutamide, bicalutamide, darolutamide, nilutamide)
Human epidermal growth factor receptor (HER/EGFR) inhibitors (eg, lapatinib, osimertinib)
Human epidermal growth factor receptor 2 (HER2) inhibitors (eg, pertuzamab, trastuzumab )
Immune checkpoint inhibitors (eg, nivolumab, ipilimumab, pembrolizumab)
Immunomodulators (eg, lenalidomide, pomalidomide, thalidomide)
MEK inhibitors (eg, binimetinib, cobimetinib, trametinib)
Mitomycin
Mitoxantrone
Mitomycin
Vascular endothelial growth factor (VEGF) inhibitors (eg, axitinib. bevacizumab, cabazantobinib, lenvatinib, pazopanib, sorafenib,
sunitinib, vandetanib
Miscellaneous (eg, entrectinib, fedratinib, ripretinib, tretinoin)

Sodium and water retention
Androgens and estrogens
Cyclooxygenase-2 (COX-2) inhibitors
Rosiglitazone and pioglitazone
Glucocorticoids
Nonsteroidal anti-inflammatory drugs (NSAIDs)
Pioglitazone and rosiglitazone
Salicylates (high dose)
Sodium-containing drugs (eg, carbenicillin disodium, ticarcillin disodium)

Uncertain mechanism
Dipeptidyl peptidase-4 (DPP-4) inhibitors (eg, saxagliptin)
TNF-α inhibitors (eg, adalimumab, infliximab, etanercept)
 Prognosis
Despite earlier diagnosis and aggressive medical management of
HF, the prognosis is poor.

Factors affecting the prognosis of patients with heart failure
include, but are not limited to, age, gender, LVEF, renal function,
blood pressure, heart failure etiology, and drug or device therapy.
The quality of life is adversely affected by progressive functional
disability.
A greater consequence is the high mortality rate.
– 5 year mortality rate is 50% (AHA/ACC 2013)
– 80% of men and 70% of women under age 65 who have CHF will die
within 8 years
– Median survival following onset is 1.7 years for men and 3.2 years for
women

American Heart Association. 2006 Heart and Stroke Statistical Update. Dallas, Tex.: American Heart
Association, 2005 Massie BM, Shah NB. Am Heart J 1997;133:703-712
 Pathophysiology of HF
Self-Reading
Watch the video by Osmosis regarding congestive heart
failure (CHF)—systolic, diastolic, left side, right side, and
symptoms. https://www.youtube.com/watch?v=ypYI_lmLD7g
This video provides an overview of the pathophysiology of
heart failure due to both systolic and diastolic dysfunction. It
also explains how heart failure symptoms relate to the
underlying pathophysiology.

A thorough understanding of heart failure pathophysiology
and symptoms is key for students understanding how
pharmacotherapy affects symptoms and improves overall
outcomes. This will assist students in understanding the
COLLECT and ASSESS steps in the patient care process.
 Pathophysiology of HF
May involve Self-Reading
– The right ventricle,
– The left ventricle
– Or both,

The majority of patients with HF have symptoms due to an
impairment of left ventricular function.

Regardless of the etiology of heart failure, the underlying
pathophysiologic process and principal clinical
manifestations (fatigue, dyspnea, and volume overload) are
similar and appear to be independent of the initial cause.
 Compensatory Mechanisms in HF
The manifestations of  CO Self-Reading
– The major direct consequence
 exercise tolerance
Rapid muscular fatigue

– The Other manifestations result from
The attempts by the body to compensate for the intrinsic cardiac
defect in an attempt to maintain CO and oxygenation of vital organs.

An understanding of the potential benefits and adverse
consequences of the compensatory mechanisms is
essential to understanding the signs, symptoms, and
treatment of HF

What are the compensatory mechanisms of the body?
Compensatory mechanisms
Self-Reading
 Compensatory Mechanisms:
Myocardial Hypertrophy Self-Reading

The most important intrinsic compensatory mechanism
– The increase in muscle mass helps to maintain cardiac performance in
the face of adverse effects such as pressure or volume overload, loss of
functional tissue (e.g. MI) or decrease in the contractility.
However, after initial beneficial effect, there will be:
– Ischemic changes
– Impairment of diastolic filling
– Alteration of ventricular geometry
 HF Models
Older paradigms Self-Reading
– cardiorenal model
problem viewed as excess Na+ & H2O
diuretics main therapy
– cardiocirculatory model (viewed as being due to both reduced
pumping capacity of the heart and systemic vasoconstriction)
problem viewed as impaired CO
main therapies are positive inotropes, vasodilators

Current paradigm: neurohormonal model
– initiating event (MI or long standing HTN) leads to decreased CO
(HF state)
– becomes progressive systemic disease mediated by neurohormones
& autocrine/paracrine factors
– not a full explanation: drug therapies that target neurohormonal
imbalances slow progression but do not stop disease progression
The neurohormonal model of heart failure and
therapeutic insights it provides
Self-Reading
 SGLT2 role in HF
The sodium-glucose-cotransporter-2 (SGLT2) is highly expressed
in the renal proximal tubule and is responsible for reabsorbing
more than 90% of filtered glucose that is coupled with Na+ ions.
The SGLT2 inhibitors (eg, empagliflozin, dapagliflozin) lower
blood glucose by increasing urinary glucose (and sodium)
excretion resulting in diuresis and natriuresis.
Clinical trials reported that these agents also reduce the risk of
cardiovascular events in patients with HF, including
hospitalizations, even in patients without diabetes, suggesting that
mechanism(s) other than simply lowering blood glucose are
important.
Although the exact beneficial mechanisms remain uncertain, these
agents reduce inflammation, oxidative stress, and sympathetic
nervous system activity as well as improve cardiac remodeling and
myocardial energetics.
The impressive outcomes with these medications in patients with
HF further support the notion of HF as a disorder driven by multiple
systemic mechanisms.
 Factors Precipitating/Exacerbating HF
Hospitalization for HF exacerbation consumes large amounts of healthcare dollars
and significantly impairs the patient’s quality of life.
Appropriate therapy can often maintain patients in a “compensated” state,
indicating that they are relatively symptom-free. However, there are many
aggravating or precipitating factors that may cause a previously compensated
patient to develop worsened symptoms necessitating hospitalization.

Often, these precipitating factors are reversible or treatable, thus thorough
evaluation for their presence is imperative.
– Cardiac events are a frequent cause of worsening HF (CAD, Afib, HTN)
– Noncardiac events (Pulmonary infections , PE, DM, CKD, hypothyroidism, and
hyperthyroidism)
– Nonadherence with prescribed HF medications or with dietary recommendations (eg,
sodium intake and fluid restriction)
– Many drugs can precipitate or exacerbate HF

Engaging a pharmacist in HF care is recommended to
– assist with identifying inadequate HF therapy,
– detecting medication nonadherence,
– avoiding drug-drug interactions or other medication-related causes of HF.
 CLINICAL PRESENTATION: Heart Failure
Symptoms Signs
Specific for Heart Failure
Common – Jugular venous distention
– Dyspnea, particularly on exertion – Cardiomegaly, lateral displacement of the
– Orthopnea apical impulse
– Paroxysmal nocturnal dyspnea – Hepatojugular reflux
– S3 gallop
– Exercise intolerance – Cheyne-Stokes respiration (advanced HF)
– Fatigue Less Specific for Heart Failure
– Swollen ankles of other parts of the body – Peripheral edema (lower extremities, sacral,
– Bendopnea scrotal)
– Pulmonary rales
Less Common – Pulmonary edema
– Cough – Weight gain (>2 kg/week)
– Wheezing – Weight loss with muscle wasting/cachexia
(advanced HF)
– Nocturia
– Pleural effusion
– Anorexia, poor appetite, early satiety – Tachycardia/irregular pulse
– Nausea – Tachypnea
– Bloating – Hepatomegaly/ascites
– Weight gain or loss – Cool extremities
– Oliguria
– Dizziness or syncope
– Narrow pulse pressure
– Depression – Cardiomegaly
– Reduced cognitive function (especially in – Peripheral edema
the elderly) – Hepatomegaly
– Venous stasis changes
 Notes on S&S of HF
The primary manifestations of both HFrEF and HFpEF are:
– dyspnea and fatigue, which lead to exercise intolerance, and
– fluid overload, which can result in peripheral edema and pulmonary congestion.
The presence of these signs and symptoms may vary considerably from patient to patient such that some
patients have dyspnea but no signs of fluid retention, whereas others may have marked volume overload
with few complaints of dyspnea or fatigue. However, many patients have both dyspnea and volume
overload.
Clinicians should remember that symptom severity often does not correlate with the degree of LV
dysfunction It is also important to note that symptoms can vary considerably over time in a given patient
even in the absence of changes in ventricular function or medications.
It is difficult to attribute a specific sign or symptom as caused by either right or left ventricular failure.
 CLINICAL PRESENTATION: Heart Failure
Laboratory tests
BNP > 35 pg/mL for ambulatory patients or > 100 pg/mL for patients hospitalized
or with decompensated HF
NT-proBNP >125 pg/mL for ambulatory patients or > 300 pg/mL for patients
hospitalized or with decompensated HF
An electrocardiogram may be normal or it could show numerous abnormalities
including acute ST-T wave changes from myocardial ischemia, atrial fibrillation,
bradycardia, left ventricular hypertrophy
Serum creatinine: It may be increased due to hypoperfusion. Preexisting renal
dysfunction can contribute to volume overload.
Complete blood count is useful to determine if HF is due to reduced oxygen-
carrying capacity
Chest x-ray: Useful for detection of cardiac enlargement, pulmonary edema, and
pleural effusions
Echocardiogram: Used to assess LV size, valve function, pericardial effusion,
wall motion abnormalities, and ejection fraction
Hyponatremia: Serum sodium 1 year, an ICD is recommended for primary
prevention of sudden cardiac death (SCD) to reduce total mortality.
6. In patients with LVEF ≤40%, beta blockers should be used to prevent
1 C-LD
symptomatic HF.
3: 7. In patients with LVEF