Author + information
- Heart Failure Pathway Writing Committee,
- Clyde W. Yancy, MD, MSc, MACC, Chair,
- James L. Januzzi Jr., MD, FACC, Vice Chair,
- Larry A. Allen, MD, MHS, FACC,
- Javed Butler, MD, MBA, MPH, FACC,
- Leslie L. Davis, PhD, RN, ANP-BC,
- Gregg C. Fonarow, MD, FACC,
- Nasrien E. Ibrahim, MD, FACC,
- Mariell Jessup, MD, FACC,
- JoAnn Lindenfeld, MD, FACC,
- Thomas M. Maddox, MD, MSc, FACC,
- Frederick A. Masoudi, MD, MSPH, FACC,
- Shweta R. Motiwala, MD,
- J. Herbert Patterson, PharmD,
- Mary Norine Walsh, MD, FACC and
- Alan Wasserman, MD, FACC
- Expert Consensus Decision Pathway
- angiotensin receptor–neprilysin inhibitor
- beta blockers
- Expert Consensus Decision Pathway
- heart failure
Task Force on Expert Consensus Decision Pathways
James L. Januzzi, Jr, MD, FACC, Chair
Luis C. Afonso, MBBS, FACC
Brendan Everett, MD, FACC
Adrian F. Hernandez, MD, MHS, FACC
William Hucker, MD, PhD
Hani Jneid, MD, FACC
Joseph Edward Marine, MD, FACC
Pamela Bowe Morris, MD, FACC
Robert N. Piana, MD, FACC
Karol E. Watson, MD, FACC
Dharam Kumbhani, MD, SM, FACC
Barbara S. Wiggins, PharmD, FACC
Table of Contents
1. Introduction ▪
2. Methods ▪
3. Assumptions and Definitions ▪
4. Pathway Summary Graphic ▪
5. Description and Rationale: Answers to 10 Pivotal Issues in HF
1. How to Initiate, Add, or Switch to New Evidence-Based Guideline-Directed Therapy for HFrEF ▪
2. How to Achieve Optimal Therapy Given Multiple Drugs for HF Including Augmented Clinical Assessment That May Trigger Additional Changes in GDMT (e.g., Imaging Data, Biomarkers, and Filling Pressures) ▪
3. When to Refer to an HF Specialist ▪
4. How to Address Challenges of Care Coordination ▪
5. How to Improve Adherence ▪
6. What Is Needed in Specific Patient Cohorts: African Americans, the Frail, and Older Adults ▪
7. How to Manage Your Patients’ Cost of Care for HF ▪
8. How to Manage the Increasing Complexity of HF ▪
9. How to Manage Common Comorbidities ▪
10. How to Integrate Palliative Care and Transition to Hospice Care ▪
6. Discussion and Implication of Pathway ▪
ACC President and Staff ▪
Author Relationships With Industry and Other Entities ▪
Peer Reviewer Information ▪
The American College of Cardiology (ACC) develops a number of policy documents to provide members with guidance on clinical topics. Although clinical practice guidelines remain the primary mechanism for offering evidence-based recommendations, such guidelines may contain gaps in how to make clinical decisions, particularly when equipoise is present. Expert Consensus Documents are intended to provide guidance for clinicians in areas where evidence may be limited or new and evolving, or where insufficient data exist to fully inform clinical decision making. These documents therefore serve to complement clinical practice guidelines, providing practical guidance for transforming guideline recommendations into clinically actionable information.
To re-evaluate the clinical documents published by the ACC, an ACC Presidential Task Force was formed in 2014 to examine the processes of ACC’s clinical documents. The main recommendation of the Task Force was a new focus on concise decision pathways and/or key points of care, instead of the traditional longer documents. The Task Force also established criteria for identifying high-value clinical topics to be addressed, as well as an innovative approach to collecting stakeholder input through a roundtable or think tank meeting. To complement the new focus on brief decision pathways and key points, Expert Consensus Documents were rebranded “Expert Consensus Decision Pathways” (ECDPs).
Although ECDPs have a new format, they maintain the same goal of Expert Consensus Documents: to develop policy based on expert opinion in areas where important clinical decisions are not adequately addressed by available data. ECDPs are designed to complement existing or newly published guidelines and bridge the gaps in clinical guidance that remain. In some cases, topics covered by ECDPs will be addressed subsequently by ACC/American Heart Association (AHA) guidelines as the evidence base evolves. The writing groups are charged with developing algorithms that are more actionable and can be implemented into tools or apps to accelerate the use of these documents at point of care. Decision Pathways are intended not to provide a single correct answer, but to encourage clinicians to ask certain questions and consider important factors as they come to their own decision on a treatment plan to be recommended and discussed with their patients. There may be multiple pathways that can be taken for treatment decisions, and the goal is to help clinicians make a more informed decision.
James L. Januzzi, Jr, MD, FACC
Chair, ACC Task Force on Expert Consensus Decision Pathways
The 2017 ACC/AHA/Heart Failure Society of America (HFSA) heart failure (HF) guidelines (1) reflect a focused update of the ACC/AHA 2013 HF guidelines (2) and include guidance based on new evidence supporting novel drug therapies, a new treatment algorithm replete with more options for care than before, an updated approach to prevention, and important updates regarding various forms of HF and important comorbidities. The care of patients with HF is more involved than ever. Current care for the patient with HF with reduced ejection fraction (EF) includes no fewer than 7 evidence-based medications, 3 evidence-based device strategies, and a number of recommend processes of care. The opportunity to change the natural history of HF with reduced EF has never been better, but with more choices comes greater complexity. This necessitates careful guidance to clinicians, emphasis on best principles for initiating and titrating guideline-directed medical therapy for HF with reduced EF, and advice on managing the overall complexity of the condition.
This ACC Expert Consensus Decision Pathway addresses steps to follow when introducing numerous evidence-based therapies, improving adherence, overcoming treatment barriers, acknowledging contraindications and situations for which little data exist, affording expensive therapies, treating special cohorts, and making the transition to palliative care. Rather than focusing on expansive text, the document provides practical tips, tables, and figures to make clear the steps, tools, and provisos needed to successfully and expeditiously treat the patient with HF with reduced EF. Many of the pivotal issues addressed in this document are not the substance of clinical trials; rather, they represent the challenge of clinical practice. Whenever possible, resources are included or hyperlinked. The treatment of HF with reduced EF can feel overwhelming, and many opportunities to improve patient outcomes are being missed; hopefully, this Expert Consensus Decision Pathway may streamline care to realize best possible patient outcomes in HF.
The prevalence of HF is escalating rapidly. Compounding this, HF is an illness that consumes significant health care resources, inflicts significant morbidity and mortality, and greatly impacts quality of life. Important breakthroughs have redefined opportunities to change the natural history of the disease with a broad range of medical therapies, devices, and care strategies, including readmission reduction programs and ambulatory outpatient disease management for those with more advanced disease.
HF exists in several phenotypes, in part reflected by differences in left ventricular ejection fraction (LVEF). These include heart failure with reduced ejection fraction (HFrEF), HF with preserved EF, as well as HF with improved EF. Although the evidence base for the treatment of HFrEF has expanded substantially, much work remains for the other forms of HF. New therapies for HF with preserved EF are under exploration, and the evidence base addressing HF with improved EF is just emerging.
The purpose of this document is to complement the 2017 ACC/AHA/HFSA Focused Update of the 2013 ACC/AHA Guideline for the Management of Heart Failure (1) by addressing new medical therapies, prevention, and comorbidities relevant to HFrEF for which data are available. Despite new guideline statements, information voids exist, and a practical, consensus approach is needed for areas that have incomplete evidence. To that end, we have identified 10 pivotal issues that remain unresolved in the guidelines. This document attempts to address these issues.
Ten Pivotal Issues in HFrEF
1. How to initiate, add, or switch therapy to new evidence-based guideline-directed treatments for HFrEF.
2. How to achieve optimal therapy given multiple drugs for HF including augmented clinical assessment that may trigger additional changes in guideline-directed therapy (e.g., imaging data, biomarkers, and filling pressures).
3. When to refer to an HF specialist.
4. How to address challenges of care coordination.
5. How to improve adherence.
6. What is needed in specific patient cohorts: African Americans, the frail, and older adults.
7. How to manage your patients’ cost of care for HF.
8. How to manage the increasing complexity of HF.
9. How to manage common comorbidities.
10. How to integrate palliative care and transition to hospice care.
A structured format was created subsequent to the release of the 2016 ACC/AHA/HFSA Focused Update on New Pharmacological Therapy for Heart Failure: an Update of the 2013 ACCF/AHA Guideline for the Management of Heart Failure, addressing new pharmacological therapies (3). Questions were developed to identify evidence gaps. A multidisciplinary panel of stakeholders was configured and a literature review was completed to aggregate relevant evidence addressing contemporary HF care. The references were separately reviewed by the Chair and Vice-Chair, and an agreed-upon compendium was developed. Print copies of the references were provided to each member of the panel prior to a live roundtable meeting held on July 19, 2016, at the ACC Heart House. Participants attending the HF roundtable meeting included cardiologists, internists, emergency physicians, hospitalists, nurses, representatives from patient advocacy groups, pharmacists, fellows-in-training, quality improvement experts, epidemiologists, and biostatisticians.
Structured discussions were held addressing new therapies, unanswered questions, adherence, and implementation strategies. Multidisciplinary panel discussions were convened and archived for online distribution. (Discussions can be found at http://www.acc.org/tools-and-practice-support/quality-programs/succeed-in-managing-heart-failure-initiative/emerging-strategies-for-heart-failure-roundtable.) A writing group was invited to participate, as representative of all stakeholders. A review of outstanding questions was facilitated by a survey of constituent members of the stakeholder groups, with editing of the questions carried out by the writing panel. Subsequent writing assignments were configured according to areas of expertise. Teleconferences were used to edit contributed content. Conference calls of the writing committee were confidential and were attended only by committee members and ACC staff. When consensus within the writing committee was deemed necessary by the Chair and Vice Chair, either a roll call vote or an e-mail–generated ballot was implemented. A simple majority prevailed; in the presence of a tie, chair prerogative reconciled the final decision.
The work of the writing committee was supported exclusively by the ACC without commercial support. Writing committee members volunteered their time to this effort. All members of the writing committee, as well as those selected to serve as peer reviewers of this document, were required to disclose relationships with industry (RWI) and other entities (see Appendixes 1 and 2, respectively). The Chair was without any RWI and is responsible for the content of this document. In keeping with ACC policy, the majority of the writing committee were without relevant relationships with industry. The formal peer review process was completed consistent with ACC policy, and included a public comment period to obtain further feedback. Following reconciliation of all comments, this document was approved for publication by the Clinical Policy Approval Committee.
3 Assumptions and Definitions
To limit inconsistencies in interpretation, specific assumptions (e.g., treatment effect in varied populations) were considered by the writing group in development of the decision pathway. References are supplied when applicable or appropriate.
General Clinical Assumptions
1. Although many topics are generalizable to all patients with HF, the focus of this effort, including pathway recommendations, only applies to patients with HFrEF.
2. Although some of the recommendations may be relevant to patients hospitalized with acute HF, this document mainly deals with the management of patients with chronic ambulatory HFrEF.
3. The expert consensus writing committee endorses the evidence-based approaches to HF therapy and management enumerated in the 2013 ACC/AHA Guideline for the Management of Heart Failure (2) and the 2016 and 2017 ACC/AHA/HFSA focused updates (1,3).
4. These algorithms assume the clinician will seek input as needed from a pharmacist, cardiologist, HF specialist and/or disease management program, and other relevant medical specialist (e.g., endocrinologist or nephrologist) to guide clinical management, and will consider patient preference in all clinical decision-making.
5. These algorithms are based on best available data; all clinical decisions should be governed by judgment and influenced by discussions with the patient about treatment preferences.
6. At any point in time, these suggestions and algorithms may be superseded by new data.
HFrEF: Clinical diagnosis of HF and LVEF ≤40%.
New York Heart Association (NYHA) functional classification:
▪ Class I: No limitation of physical activity. Ordinary physical activity does not cause symptoms of HF.
▪ Class II: Slight limitation of physical activity. Comfortable at rest, but ordinary physical activity results in symptoms of HF.
▪ Class III: Marked limitation of physical activity. Comfortable at rest, but less than ordinary activity causes symptoms of HF.
▪ Class IV: Unable to perform any physical activity without symptoms of HF, or symptoms of HF at rest.
GDMT: Guideline-directed medical therapy.
Optimal therapy: Treatment provided at either the target or the highest-tolerated dose for a given patient.
Target dose: Doses targeted in clinical trials.
ACC/AHA Stages of HF:
▪ Stage A: At high risk for HF but without structural heart disease or symptoms of HF.
▪ Stage B: Structural heart disease but without signs or symptoms of HF.
▪ Stage C: Structural heart disease with prior or current symptoms of HF.
▪ Stage D: Refractory HF requiring specialized interventions.
4 Pathway Summary Graphic
Figure 1 summarizes the 2017 ACC Expert Consensus Decision Pathway for Optimization of Heart Failure Treatment: Answers to 10 Pivotal Issues About Heart Failure With Reduced Ejection Fraction.
5 Description and Rationale: Answers to 10 Pivotal Issues in HF
1 How to Initiate, Add, or Switch to New Evidence-Based Guideline-Directed Therapy for HFrEF
Established therapies for chronic HFrEF include angiotensin-converting enzyme inhibitors (ACEIs), angiotensin receptor blockers (ARBs), beta blockers, loop diuretics, aldosterone antagonists, and hydralazine/isosorbide dinitrate (HYD/ISDN); with the exception of loop diuretics, all have been shown in randomized controlled trials to improve symptoms, reduce burden of hospitalization, and/or provide survival benefit (2). Recently, in addition to established GDMT, an angiotensin receptor-neprilysin inhibitor (ARNI) and the hyperpolarization channel blocker ivabradine have been added to the treatment guidelines for HFrEF (3). Understanding when and how to add, switch, and titrate all therapies to maximally tolerated doses and ideally target doses (Figure 1, Table 1) is important.
HF is a complex syndrome typically associated with multiple comorbidities; most patients are on multiple medications. No clinical trials have specifically evaluated the potential for greater benefit or excessive risk of indicated therapies among patients with multimorbidity. To assess tolerability of medications and best assess the trajectory of HF, it is often necessary for patients to have more frequent follow-up, especially after initiation or titration of therapy.
Recommendations for starting GDMT in a patient with a new diagnosis of HFrEF are detailed in Figure 2.
In a patient with new-onset HFrEF, a common question is whether to initiate a beta blocker or ACEI/ARB first. Data from the randomized CIBIS (Cardiac Insufficiency Bisoprolol) III trial suggest that either is safe (4). Initiation of ACEI or ARB (Table 1, Figures 2 and 3) is often better tolerated when the patient is still congested (“wet”; when renin-angiotensin-aldosterone system activation is less), whereas beta blockers are better tolerated when the patient is less congested (“dry”) with adequate resting heart rate. Only evidence-based beta blockers should be used in patients with HFrEF (Table 1, Figures 2 and 3).
In selected patients with HFrEF, a clinician may choose to start a low dose of a beta blocker and an ACEI/ARB; in persistently symptomatic patients who tolerate an ACEI or ARB, switching to an ARNI would be recommended (Table 1, Figure 2).
Titration of ACEI/ARB and beta blockers is discussed in Issue 2.
Angiotensin Receptor-Neprilysin Inhibition
Neprilysin, also known as neutral endopeptidase, is a zinc-dependent metalloprotease that inactivates several vasoactive peptides, including the natriuretic peptides, adrenomedullin, bradykinin, and substance P, each of which has an important role in the pathogenesis and progression of HF (5). Because angiotensin II is also a substrate for neprilysin, neprilysin inhibitors raise angiotensin levels, which explains the rationale for coadministration of ARB. Neprilysin inhibitors are not combined with ACEI due to a higher risk of angioedema (6).
Sacubitril/valsartan (7,8) was tested among patients with chronic HFrEF in a randomized controlled trial, PARADIGM HF (Prospective Comparison of ARNI with ACEI to Determine Impact on Global Mortality and Morbidity in Heart Failure). The trial enrolled patients with NYHA class II to IV symptoms with an EF ≤40% (modified to ≤35% 1 year into the trial), stable on doses of ACEI/ARB, and on other background GDMT. Patients with a history of angioedema, estimated glomerular filtration rate (eGFR) <30 mL/min/1.73 m2, symptomatic hypotension, or current decompensated HF were excluded. The trial began with a sequential run-in period to ensure that every patient randomized could tolerate both sacubitril/valsartan and the comparator enalapril target doses. Of the 10,513 candidates screened, 2,079 were not randomized due to the inability to achieve target dose therapy on enalapril or sacubitril/valsartan. Most patients enrolled in PARADIGM-HF had NYHA class II to III symptoms (<100 patients with NYHA class IV symptoms).
PARADIGM-HF demonstrated a 20% reduction in the primary outcome of cardiovascular death or HF hospitalization (hazard ratio: 0.80; 95% confidence interval: 0.73 to 0.87; p < 0.001) in patients treated with sacubitril/valsartan. The number needed to treat to prevent 1 primary endpoint over 27 months was 21. These differences in outcomes included a 20% reduction in sudden cardiac death.
Symptomatic hypotension was more common with sacubitril/valsartan but was not associated with a worsening of renal function. Angioedema was numerically higher but not statistically significantly different from enalapril in the sacubitril/valsartan group. It should be noted that most patients likely to have angioedema were excluded by the requirement to tolerate enalapril.
The most recent clinical HF guidelines (3) recommend ARNI, ACEI, or ARB to reduce morbidity and mortality in patients with chronic HFrEF and that patients with NYHA class II to III symptoms who can tolerate an ACEI or ARB should transition to an ARNI to further reduce morbidity and mortality (Class I, Level of Evidence: B-R) (1,2). Use of an aldosterone antagonist, although also recommended to improve outcomes, is not considered mandatory prior to changing a patient to ARNI. Guidance for the transition from an ACEI or ARB to ARNI are detailed in Figures 2 and 3 and in Tables 1 to 4⇓⇓⇓.
When making the transition from an ACEI to ARNI, a 36-hour washout period should be strictly observed to avoid angioedema, a delay that is not required when switching from an ARB to ARNI. In a recent study (9), a condensed and conservative approach to initiation of sacubitril/valsartan was explored; the investigators compared titration to a target dose between 3 and 6 weeks. Both approaches were tolerated similarly, but the gradual titration approach maximized attainment of the target dose of sacubitril/valsartan in patients previously receiving low doses of ACEI/ARB.
Initiation of an ARNI de novo without prior exposure to ACEI or ARB
It is possible that a patient may be identified who meets all criteria for initiation of ARNI, but the patient has not yet been treated with an ACEI or ARB. The committee is aware that clinicians may occasionally consider initiating ARNI in patients who have not previously been treated with ACEI or ARB. To be explicitly clear, no predicate data supports this approach. For well-informed patients who, within a framework of shared-decision making, accept the uncertainty about effectiveness and safety as well as potentially greater out-of-pocket costs, de novo initiation of ARNI with close follow-up and serial assessments (blood pressure, electrolytes, and renal function) might be considered. Any such usage should consider concerns regarding risk of angioedema or hypotension (Figures 2 and 3, and Tables 1 to 4).
Heart rate independently predicts outcomes in HFrEF. Evidence from beta-blocker trials suggests that heart rate lowering is directly related to improved outcomes (10). A dose-response relationship for evidence-based beta blockers used in HFrEF has been demonstrated (i.e., the higher the dose, the better the outcome). Prior to initiating any other agent with heart-rate slowing effects, the dose of an evidence-based beta blocker should be optimized. However, some apparently well-compensated patients on optimal beta blocker therapy continue to have a persistent resting heart rate over 70 bpm.
Ivabradine is an adjunctive means to reduce heart rate in patients with chronic HFrEF who are in sinus rhythm. Ivabradine is a specific inhibitor of the If current involved in sinoatrial nodal activity and reduces the heart rate of patients in normal sinus rhythm without lowering blood pressure. In the SHIFT (Systolic HF Treatment with the If Inhibitor Ivabradine Trial) trial of 6,505 subjects with stable, chronic, predominantly NYHA class II and III HFrEF, ivabradine therapy, when added to GDMT, resulted in a significant reduction in HF hospitalizations (11). Benefits were noted especially for those patients with: contraindications to beta blockers, beta blocker doses <50% of GDMT targets (12), and resting heart rate ≥77 bpm at study entry (13). It is important to emphasize that ivabradine is indicated only for patients in sinus rhythm, not in those with atrial fibrillation, patients who are 100% atrially paced, or unstable patients. From a safety standpoint, patients treated with ivabradine had more bradycardia and developed more atrial fibrillation as well as transient blurring of vision (11).
In the 2016 ACC/AHA/HFSA HF guidelines focused update (3), ivabradine was recommended as a Class IIa, Level of Evidence: B-R (1,2) therapy to reduce the risk of HF hospitalization in patients with HFrEF (LVEF ≤35%) already receiving GDMT (including a beta blocker at maximally tolerated dose), and who are in sinus rhythm with a heart rate greater than 70 bpm at rest (Figures 2 and 3, Tables 1 and 5). The contraindications to ivabradine are enumerated in Table 4.
Consensus Pathway Algorithm for Initiation and Titration of HFrEF Therapies
A strategy for initiating and titrating evidence-based therapies for patients with HFrEF is depicted in Figures 2 and 3. As noted in the previous text, after a diagnosis of HF is made, GDMT should be initiated and therapies should be adjusted no more frequently than every 2 weeks to target doses (or maximally tolerated doses). Clinicians should aim to achieve this within 3 to 6 months of an initial diagnosis of HF (however, this rapid timeline may not be logistically feasible for some patients). GDMT should continue to be up-titrated to achieve maximally tolerated doses of these therapies. During follow-up, frequent reassessment of the clinical status of the patient, blood pressure, and kidney function (and electrolytes) should be performed. Reassessment of ventricular function should occur after target or maximally tolerated doses of GDMT are achieved for 3 months to determine the need for device therapies such as implantable defibrillators and cardiac resynchronization therapy (2). Structured medication titration plans embedded in disease management programs have been shown to be useful in obtaining target doses of GDMT within 6 months of hospital discharge (14).
Patients in Whom New Therapies May Not be Indicated
Contraindications may preclude the initiation of some agents. Additionally, a well-informed patient may make a personal judgment, in terms of benefits and risks, after being presented with all evidence in favor of these therapies and decide against initiation.
In a patient whose life expectancy is short (<1 year) due to other comorbidities, some therapies (such as implantable devices) may not be appropriate. Similarly, in patients with NYHA class IV and Stage D HF being considered for advanced therapies (i.e., transplant or left ventricular (LV) assist device), home inotropes, or hospice, initiation of new drug therapies may not be appropriate, especially given the absence of evidence addressing efficacy in such patients.
2 How to Achieve Optimal Therapy Given Multiple Drugs for HF Including Augmented Clinical Assessment That May Trigger Additional Changes in GDMT (e.g., Imaging Data, Biomarkers, and Filling Pressures)
To achieve the maximal benefits of GDMT in patients with chronic HFrEF, therapies must be initiated and titrated to maximally tolerated doses (7,16–18). Doses of GDMT higher than those studied in randomized clinical trials, even if tolerated, are not known to provide incremental benefits and are generally not recommended.
Strategies for titration are detailed in Figures 2 and 3. Achieving target or maximally tolerated doses of GDMT is the goal. Beta-blocker doses should be adjusted every 2 weeks (19) in a patient with no evidence of decompensated HF and no contraindications to higher doses. Longer time periods may be needed for frail patients or those with marginal hemodynamics, whereas more rapid titration may be reasonable in clinically stable patients without hypotension. Following adjustment, patients should be cautioned that there may be a transient worsening of HF symptoms such as dyspnea, fatigue, or dizziness.
ACEI and ARB may be titrated similarly to beta blockers with monitoring of renal function, potassium, and blood pressure; more rapid titration is also reasonable in clinically stable patients. In the absence of hypotension, electrolyte/renal instability, or angioedema on an ACEI or ARB, it is reasonable to change to ARNI. For those taking ARNIs, doses can be increased every 2 to 4 weeks to allow time for adjustment to the vasodilatory effects of the combined angiotensin receptor and neprilysin inhibition while also monitoring renal function, potassium, and especially blood pressure. For optimal titration of ACEI, ARBs, or ARNI, lower loop diuretic doses may be necessary to permit titration; in this circumstance, careful attention to potassium concentrations is needed, as the kaliuretic effects of loop diuretics may no longer be present, and restriction of supplemental and/or dietary potassium may be necessary.
Aldosterone antagonists are added in patients with chronic HFrEF already receiving beta blockers and ACEI/ARB/ARNI who do not have contraindications to this therapy (2). It is not necessary to achieve target or maximally tolerated doses of other drugs before adding aldosterone antagonists. The dose of aldosterone antagonists used in clinical trials, which is typically below that which might influence blood pressure, is sufficient for clinical efficacy. Adherence to the guideline recommendations for monitoring of renal function and potassium is required.
For a number of reasons, HYD/ISDN-indicated therapy for HF is often neglected in eligible patients. However, given the benefits of this combination (43% relative reduction in mortality and 33% relative reduction in HF hospitalization ), African-American patients should receive these drugs once target or maximally tolerated doses of beta blocker and ACEI/ARB/ARNI are achieved (2). This is especially important for those patients with NYHA class III to IV symptoms.
Finally, following assiduous titration of beta blockers, in patients whose heart rate remains ≥70 bpm on target or maximally tolerated doses of beta blockers, ivabradine (3) can be added and titrated every 2 weeks to lower heart rate.
Barriers to Medication Titration
In some instances, it may not be possible to titrate GDMT to the target doses achieved in clinical trials. Patients in clinical practice may differ substantially from those enrolled in the trials; such differences may limit the ability to titrate therapies. For example, patients in clinical practice are typically older, may experience more side effects, and are likely to have more comorbidities that will limit titration.
Abnormal renal function and/or hyperkalemia are common barriers to initiation and titration of GDMT. For patients with established renal disease, caution may be necessary when starting GDMT, though ACEI/ARB are generally considered safe in patients with creatinine <3.0 mg/dL. In patients with mild-moderate renal impairment (eGFR ≥30 mL/min/1.73 m2 and <60 mL/min/1.73 m2), no adjustment is needed when deciding the starting dose of the ARNI sacubitril/valsartan. In those with severe renal impairment (eGFR <30 mL/min/1.73 m2), the starting dose of sacubitril/valsartan should be reduced to 24/26 mg twice daily (This population was not studied in PARADIGM HF. The statement is consistent with FDA approved labeling indications) (Table 4). Aldosterone antagonists are contraindicated in patients with severe renal impairment (eGFR <30 mL/min/1.73 m2, or creatinine >2.5 mg/dL in men or creatinine >2 mg/dL in women) or with potassium >5.0 mEq/dL (Figure 1).
Renal function and potassium should be assessed within 1 to 2 weeks of the initiation or dose increase of ACEI/ARB/ARNI. In patients with preserved renal function or mild to moderate renal impairment, renal function and potassium after initiation and titration of aldosterone antagonists should be assessed within 2 to 3 days and again at 7 days. The schedule for subsequent monitoring should be dictated by the clinical stability of renal function and volume status but should occur at least monthly for the first 3 months and every 3 months thereafter (2). After the initiation or titration of loop diuretics, renal function should be assessed within 2 to 3 days.
During initiation and titration of agents that affect renal function, a decrease in eGFR of >30% or the development of hyperkalemia should alert the clinician that a reduction in doses may be necessary, even though short-term changes in eGFR during intense diuretic therapy or with the initiation of ACEI or ARB do not predict longer-term adverse outcomes (21). In patients with evidence of hypovolemia, the dose of diuretics should be reduced. Doses of ARNI may also need to be reduced in the setting of renal insufficiency or hypotension. Hyperkalemia may also require changes in medical therapy. Clinical assessment and renal stability in each patient dictates whether clinicians may need to monitor certain patients more closely than others.
Social or economic barriers to care may also undermine ability to achieve GDMT. For example, homebound patients or those with limited ability to travel may be unable to have blood pressure, heart rate, or renal function assessed in a timely fashion. Cost may also pose a substantial barrier to care, particularly for ARNI and ivabradine therapy. In such cases, if all solutions are exhausted, optimizing care with the most financially manageable program is recommended (see answer to Issue 7).
Figure 4 details a reasonable strategy for patient evaluation and management following a diagnosis of HFrEF. After GDMT is initiated and titrated with the goal of achieving clinical trial doses or maximally tolerated doses, patients with chronic HFrEF should be evaluated on a regularly scheduled basis. For most patients, a reasonable interval is every 3 to 6 months, although many may require more frequent follow-up to monitor clinical stability and revisit opportunities for further GDMT titration. Cardiac rehabilitation is beneficial and remains underutilized.
High-risk features (conveniently summarized in the acronym “I NEED HELP” in Figure 4 and Table 6) should trigger consideration for referral for advanced HF consultation (22); features triggering referral to advanced HF care are also discussed in the answers to Issue 3 and Table 6.
Imaging—When to Order an Echocardiogram
An echocardiogram is recommended in the evaluation of the patient with incident HF to assess LVEF, diastolic function, chamber size, ventricular wall thickness, valvular abnormalities, strain imaging when available, and hemodynamic parameters including estimated right ventricular systolic pressure, central venous pressure, and LV filling pressures. Once optimal doses of GDMT have been achieved for 3 to 6 months, repeat imaging can be useful in making decisions regarding device therapy (implantable cardioverter-defibrillator and/or cardiac resynchronization therapy) or referral for advanced therapies (ventricular assist device or transplant). Repeat imaging may also be considered at the time of clinically important changes in clinical status (2). Routine surveillance echocardiograms (e.g., annually) in the absence of change in clinical status or some other signal of risk are unwarranted. If echocardiography does not provide an assessment of LVEF, guidelines recommend other modalities including radionuclide ventriculography or magnetic resonance imaging (2).
When recovery of LVEF to >40% is noted in the setting of prior HFrEF, it is likely that outcomes may improve as well. However, there are no data to guide what adjustment (if any) should be made with GDMT in most cases, and in the absence of a defined, reversible cause for HFrEF (e.g., tachycardia-mediated cardiomyopathy), current therapies should be continued.
Biomarkers—When to Order Natriuretic Peptides
B-type natriuretic peptide (BNP) and N-terminal pro–B-type natriuretic peptide (NT-proBNP) are the most studied biomarkers in HF. They play a role in diagnosis and prognostication. Higher concentrations of BNP or NT-proBNP in an ambulatory patient with HFrEF informs high risk, particularly when the concentrations are rising. Current clinical practice guidelines give a Class I recommendation to measure NT-proBNP or BNP to support a clinical diagnosis of HF, to assess disease severity, or to establish prognosis (2).
More recently, biomarkers have been examined for their role as a marker of clinical responsiveness to GDMT. This is, in part, due to the fact that a wide range of GDMT may reduce BNP and NT-proBNP concentrations, in parallel with the benefits of these therapies. Patients whose natriuretic peptide concentrations do not fall with GDMT (“nonresponders”) have a worse prognosis and more deleterious LV remodeling (23). Therefore, measurement of BNP or NT-proBNP is useful to monitor risk, to assist in decision making regarding the ordering of imaging studies to evaluate LV remodeling, to support clinical judgment with respect to prescription of GDMT, and to provide helpful objective data regarding decision-making for referral to advanced HF therapies (See Figure 4 and Table 6). Concentrations of BNP or NT-proBNP are supported with a Class I guideline recommendation to determine prognosis. In the setting of worsening symptoms (24), the reassessment of BNP or NT-proBNP may be informative. However, serial assessment of BNP or NT-proBNP to guide aggressive titration of GDMT is not indicated and not warranted (25). Severe renal dysfunction may interfere with the interpretation of natriuretic peptide concentrations.
While rising natriuretic peptide concentrations are correlated with adverse outcomes, this relationship can be confounded with the use of sacubitril/valsartan. Due to neprilysin inhibition, concentrations of BNP rise in patients treated with sacubitril/valsartan and tend not to return to baseline despite chronic therapy. In contrast, NT-proBNP concentrations typically decrease, as NT-proBNP is not a substrate for neprilysin (26). Therefore, clinicians should interpret natriuretic peptides in the context of GDMT; BNP concentrations will increase (while NT-proBNP will most often fall) with ARNI therapy, and thus it may be more prudent to check only NT-proBNP in patients on ARNI. Also, transient increases in natriuretic peptide levels have been documented in the initial phases of beta-blocker initiation; such changes should not preclude up-titration of beta-blocker therapy, which should be guided by patient tolerance instead of asymptomatic change in natriuretic peptide levels.
Filling Pressure Assessment—When and How to Measure Filling Pressures
Whereas routine pulmonary artery catheterization is not recommended to manage congestion, invasive hemodynamic and filling pressure assessment may occasionally be useful to support decision making. For example, in patients who have refractory symptoms despite perceived adequate use of diuretics, those who develop worsening renal function with attempts to increase doses of diuretic, or those with repeated hospitalization for congestion, a better understanding of filling pressures and hemodynamics might assist in pivotal changes in HF therapies. Pulmonary artery catheterization results may also help select candidates for advanced therapies, including transplantation or mechanical circulatory support.
Recent attention has focused on the use of implantable sensors to guide filling pressure assessment in ambulatory patients with HF. In the CHAMPION (CardioMEMS Heart Sensor Allows Monitoring of Pressure to Improve Outcomes in NYHA Class III Heart Failure Patients) study, patients with NYHA class III HF symptoms were randomly assigned to receive a wireless implantable pulmonary artery pressure monitor versus usual care (27). Patients managed with data from implantable pulmonary artery pressure monitoring had more changes in GDMT and diuretic doses (28). Those managed with implantable pulmonary artery pressure monitoring had a 37% relative reduction in HF hospitalization (p<0.001). Such improvement was seen in patients with both HFrEF and HF with preserved EF. This suggests that in well-selected patients with recurrent congestion, this highly specialized monitoring strategy may guide therapeutic decision making. The impact on mortality is unknown. A team-based approach may be necessary to best deploy this monitoring strategy (see answers to Issue 8).
Patients on optimal GDMT who have either high-risk features (see Issue 3 and Table 6) or a poor response to therapy should be considered for referral to an advanced HF specialist, as discussed in the next section.
3 When to Refer to an HF Specialist
Referrals are made for consultation and, if indicated, for comanagement as well as consideration of advanced therapies (heart transplantation or mechanical circulatory support), recognition and management of specific or unusual cardiomyopathies, or annual review (2,29–34). Clinical triggers for referral (Table 6) include persistent or worsening symptoms, adverse clinical events, or other features suggesting that the patient is at high risk for disease progression or death (22,35–38).
4 How to Address Challenges of Care Coordination
Delivering optimal HF care is complex. The range of treatments available, particularly those for patients with HFrEF, include multiple medications, cardiac devices, surgery, and lifestyle adaptations, all of which require education and monitoring. For example, patients with HFrEF frequently require consultative care delivered by electrophysiology specialists to implant, monitor, and adjust devices such as implantable cardioverter-defibrillator or cardiac resynchronization therapy devices. This complexity is further exacerbated by the frequent coexistence of both cardiac and noncardiac comorbidities found in patients with HF. Comorbidities are particularly common in the elderly. More than 50% of HF Medicare patients have 4 or more noncardiovascular comorbidities and more than 25% have 6 or more (39). The care needs for comorbidities can complicate, and in some cases prevent, the optimal use of HF therapies. Finally, the medical complexity inherent in most patients with HF generally requires the involvement of multiple clinicians across many care settings (e.g., hospitals, rehabiliatation facilities, and ambulatory clinics). This raises the risks of inefficiencies in care delivery, miscommunication, potential drug–drug interactions and drug–disease interactions, and missed opportunities to achieve optimal HF outcomes.
Team-based care may be the most effective approach to complex HF care (40). By definition, team-based care is the delivery of health services to individuals, families, and/or their communities by at least 2 healthcare providers who work collaboratively with patients and their caregivers, in concordance with patient preference, to achieve shared goals within and across settings (41). Randomized trials have demonstrated the superiority of the team-based approach over usual care in patients with HF (42–45) with respect to the risks of death, hospitalization, lengths of stay, and quality of life (46–49). These outcomes are generally attributed to greater adherence to GDMT, higher proportions of patients receiving effective medication doses, and earlier recognition of HF signs and symptoms (50,51). Team-based HF care is thus recommended in the most recent HF guidelines (2).
Necessary skills for care teams include proficiency in monitoring for HF progression and exacerbation, care coordination, treatment prescription and monitoring, and education for patients and their caregivers (Table 7). Effective team-based HF care may be possible with small teams as long as the requisite skills are available. Recent innovations in patient and clinician education, such as group visits, remote specialist video consultation, and telemonitoring programs, may also be useful (52–57).
The necessary infrastructure components to support team-based HF care are detailed in Table 8. Electronic health records are essential to communication and coordination of care. Patient monitoring and engagement tools that can detect early signs of HF decompensation and encourage adherence to effective therapies are also important adjuncts. Many recent technological innovations in this area, such as implantable pulmonary arterial pressure monitoring devices (27), wearable activity monitors (58), and smartphone applications (59), have potential to improve monitoring and patient engagement. However, these innovations are largely unproven, so the focus should remain on the effectiveness and evidence, rather than the form of these tools. “Low-tech” approaches, such as daily weights and algorithms for management of HF, may be sufficient for some patients to assist in self-management. In all cases, understanding who receives and acts upon the data is as important as having established programs for monitoring objective data. Patient and caregiver educational tools also support team-based HF care. Recent advances in optimizing health literacy and empowering patient engagement and self-management in HF care are promising in this respect (60,61). Ongoing monitoring of team-based care implementation, outcomes, and safety through periodic data collection, analysis, benchmarking, and—as needed—process improvements is an essential aspect of optimal team-based HF care.
5 How to Improve Adherence
Patient adherence is fundamental to the therapeutic effectiveness of GDMT. Medication adherence is defined as the extent to which medications are taken as prescribed, such that nonadherence is not dichotomous but rather a spectrum of types and degrees of discordance with medication prescribing (62). Estimates of significant nonadherence are as high as 50% (63,64); such nonadherence is associated with worse outcomes in HF (65). Reasons for nonadherence are complex, and vary for different medications in different illnesses (66,67). Unintentional nonadherence is thought to be more common than intentional nonadherence (62,68). The ability of patients to follow treatment plans in an optimal manner is frequently compromised by more than 1 barrier (Table 9) (69,70).
Patients with HF are prescribed an average of 6 different medications, totaling more than 10 daily doses (71), with multiple new medications required to achieve GDMT (72). Consequently, interventions that target adherence in HF must be multidisciplinary, multifactorial, and tailored to the particular demands experienced by the patient.
General Approaches to Improving Adherence
The past decade has seen a transition from a hierarchical approach to a shared approach around medications, with greater focus on systems solutions (Tables 10 and 11⇓⇓). Appropriately, the language has shifted from patient “compliance” to “adherence” and now to “activation,” “engagement,” and “empowerment” (73). Patients need support; blame is counterproductive. Shared decision making, personal responsibility, and behavioral theories underlie many of the evolving approaches to enhancing medication adherence (74,75). Regularly assessing adherence helps guide individual approaches and tailor the intensity and type of adherence interventions. Notably, however, clinicians tend to overestimate actual adherence, and no perfect measure of adherence exists.
Specific Patient Interventions
A number of adherence interventions have been developed and tested, some specifically for patients with HF (Table 10) (76). Formal assessments generally show benefit from a variety of adherence strategies. In a systematic review of 57 studies (77), interventions to enhance adherence for patients with HF included medication education, disease education, improved integration of care, self-management teaching, self-monitoring, and other strategic combinations. Interventions were associated with lower mortality (relative risk: 0.89; 95% confidence interval: 0.81 to 0.99) and hospital readmission (odds ratio: 0.79; 95% confidence interval: 0.71 to 0.89). A systematic review of 27 studies of mobile health interventions for cardiovascular diseases including HF (78) found that mobile health improved adherence to medical therapy (odds ratio: 4.51; p<0.00001), including both to pharmacological and nonpharmacological therapy (odds ratio: 3.86; p<0.00001).
System and Policy Solutions
Individual patients and clinicians must be supported by systems that promote adherence (79). Value-based insurance designs that tailor cost sharing to value are promising. The CMS Innovation Center aims to support patient adherence through the Beneficiary Engagement and Incentives models (https://innovation.cms.gov/initiatives/Beneficiary-Engagement/). Monetary incentives or other rewards for adherence to medications may be cost saving for highly efficacious and inexpensive drugs such as beta blockers in HFrEF. Automated screening and assessment tools can identify and target patients who are at the greatest risk for nonadherence (e.g., those with dementia, depression, homelessness, or drug use) (80). Health information technologies increasingly have the ability to assess rates of filling and refilling of prescriptions as well as to share these data across care providers and care settings.
6 What Is Needed in Specific Patient Cohorts: African Americans, the Frail, and Older Adults
Randomized clinical trials typically enroll highly selected patients, which results in uncertainty about the benefits and risks of patients not resembling those studied (Table 12). In the latter group of patients, only approximations of risks and benefits must guide therapy (81).
African Americans. Sacubitril/valsartan and ivabradine were tested in populations with few African Americans receiving HYD/ISDN. Thus, for this population, there are no data for the efficacy or safety of ARNI in patients with an indication for HYD/ISDN. Moreover, both HYD/ISDN and ARNI purportedly act via up-regulation of cGMP pathways, which may increase the risk of hypotension. Additionally, the risk of angioedema with ACEI and ARNI is particularly high in African-American patients (0.5% with ACEI and 2.4% with ARNI) (82); this risk, however, should not preclude initiation of these agents absent a documented history of angioedema.
Two options exist:
A. Establish GDMT with ACEI/ARB, beta blocker, and an aldosterone antagonist, then switch to ARNI (akin to patients studied in PARADIGM); if stable, follow with HYD/ISDN if patient has persistent class III to IV symptoms with careful blood pressure monitoring.
B. Establish GDMT with ACEI/ARB, beta blocker, and an aldosterone antagonist and then proceed with HYD/ISDN if persistent class III to IV symptoms (akin to patients studied in A-HeFT ); if stable, follow with ARNI substitution for ACEI/ARB with careful blood pressure monitoring.
In the absence of randomized controlled data, it is reasonable to treat an African-American patient using either approach. However, the risk for hypotension with either strategy is uncertain. The treatment decision should be determined after an informed shared decision-making discussion with the patient, indicating the uncertainty of benefit.
HYD/ISDN are available as a fixed-dose combination or as individual medications. The ACC/AHA/HFSA guideline considers either as acceptable in this context.
Older adults, especially the very elderly, represent yet another conundrum. The upper range for inclusion in HF clinical trials has typically been age 75 ± 5 years; there are essentially no randomized data for drugs or devices in patients older than age 80 years. However, observational data support similar treatment benefits in older patients, but also suggest higher risks of adverse events (81). The pharmacokinetic profile for all GDMT as a function of age is not known. Optimal doses for older patients may be lower than those studied in trials or tolerated in younger patients. Nevertheless, targeting clinical trial recommended doses with close surveillance for adverse drug reactions is recommended.
Frailty is a specific pathophysiological entity affecting at least 20% of those over the age of 80 years and amplifies cachexia, muscle wasting, and neurological decline. Frailty increases the risk for HF and when HF is present, exaggerates both morbidity and mortality. Standard assessments of frailty are available (83). We do not yet have evidence that any current therapies should be withheld or dose modified in the setting of frailty.
7 How to Manage Your Patients’ Cost of Care for HF
The economic burden of HF is substantial and is expected to increase markedly in parallel with increases in HF prevalence. Between 2012 and 2030, total direct medical costs for HF are projected to increase from $21 billion to $53 billion, while total costs (including indirect outlay) are estimated to increase from $31 billion to $70 billion (84). After hospital costs, the cost of cardiovascular medications is the second most important for patients with HF, accounting for 15.6% of direct costs (85).
Strategies to Reduce Costs. Several potential strategies to reduce the cost of HF have been identified (Table 13) (84). Implementing new therapies for the treatment of HF as well as improving utilization of existing therapies provide opportunities to reduce costs by slowing the progression of disease, thus reducing hospitalizations and death (86). Unfortunately, GDMT is still underutilized. Therefore, one significant challenge is how to effectively disseminate information that supports evidence-based therapies to healthcare professionals. Programs, such as accountable care organizations, alternative payment models, quality improvement initiatives as championed by the AHA Get With The Guidelines, and practice improvement as exemplified by the ACC Practice Innovation and Clinical Excellence (PINNACLE) and the AHA/ACC accreditation programs, are designed to identify candidates for evidence-based care, provide practitioners with useful reminders based on the guidelines, and continuously assess success achieved in providing GDMT (84). Care, including labs and imaging, should be coordinated among clinicians, preferably within 1 healthcare system.
Cost and Access to Medications. As mentioned previously, the cost and number of medications (polypharmacy) prescribed for HF continues to grow and presents a barrier to many patients. This barrier is compounded as most patients also have several comorbidities requiring additional medications. For example, diabetes is present in over 40% of all patients with HF, and the polypharmacy for diabetes treatment is also growing rapidly (87).
Whenever possible, generic equivalents for GDMT should be considered, although this is not feasible for some therapies such as ARNI or ivabradine. Costs can still be prohibitive even after following these cost-reduction measures. Pricing for common generic HF drugs (digoxin, carvedilol, and lisinopril) varies widely, even in a limited geographic area (88). This issue could have potential negative implications on adherence while increasing time and travel costs, and encourages patients to “shop around” for the best price, leading to obtaining drugs at multiple pharmacies. Use of multiple pharmacies negates having a single pharmacist who can oversee all of a patient’s medications, identify potential drug interactions, perform medication synchronization and assess adherence, as well as provide disease management programs and ensure that vaccinations are current. Patients and clinicians should be encouraged to work with pharmacists to help identify copay assistance programs and request “price matching” when possible, should medication be found at a lower cost at another pharmacy.
Having access to newer proven therapies can be even more daunting, as these drugs are typically associated with higher monthly costs and copays and frequently require more time and effort to obtain them; obtaining prior authorization from payers is a central aspect of this process. Recently, the ACC and a coalition of 16 medical organizations called for reform of the prior authorization process and utilization management requirements that increase clinical workload and limit patient access to care (see: https://www.aacap.org/App_Themes/AACAP/docs/homepage/2017/PA_Reform_Principles.pdf) (89).
Managing approvals for medications may be time consuming; tips for managing such processes are outlined in Table 14. It is important to consider the cost effectiveness of any new therapy to justify out-of-pocket costs. Cost effectiveness analyses of sacubitril-valsartan and ivabradine showed an incremental cost-effectiveness ratio that compares favorably to other accepted cardiovascular therapies when they were first adopted or approved (90–92). Pharmacists can help navigate insurance coverage and patient assistance programs to make sure that patients have access to the appropriate medications. Supplementary Tables 1 and 2 provide product-specific information for assistance in payment for newer HF therapies and appropriate use criteria to assist in the prior authorization process (Online only: URL to come).
8 How to Manage the Increasing Complexity of HF
Ten Pathways and Principles to Guide Optimal Therapy
Therapeutic advances for the management of HFrEF have led to both improvements in outcomes for patients as well as increasing decision-making complexity for clinicians. As detailed in Table 15, modulation of 9 pathophysiological targets has been shown to improve symptoms and/or outcomes for patients with HFrEF.
These targets are related to direct treatments for HF and do not include management of comorbidities, which are discussed separately.
Several guiding principles can improve decision making and adherence with GDMT, which in turn, is likely to improve patient outcomes. For the purpose of this section, the term target dose is used to denote doses targeted in clinical trials and optimal therapy is used to denote treatment provided at the highest dose tolerated by a given patient up to the target dose. These principles apply for medication use in the absence of absolute contraindications.
Principle 1: Target doses are associated with best outcomes
Action: Attempt to achieve target doses of all recommended therapies, in the absence of contraindications and intolerance. Titration should occur even if the patient appears “stable”; change of ACEI or ARB to ARNI should not be reserved for onset of clinical decompensation.
Principle 2: When facing clinical scenarios that limit the ability to use target doses of all relevant therapies, a top priority should be to address the factor(s) limiting GDMT.
Scenario 1: Worsening renal function or hyperkalemia.
Action: Use less than target doses of ACEI/ARB/ARNI and discontinue aldosterone antagonist if estimated creatinine clearance <30 cc/min or serum K+ >5.5 mEq/dL. Available data support a survival benefit even with low-dose ACEI, which may be the default choice in the setting of renal insufficiency and marginal blood pressure.
Scenario 2: Symptomatic hypotension.
Hypotensive symptoms may be due to overdiuresis, other vasoactive medication, autonomic dysfunction, or taking multiple medications together. All of these should be addressed prior to deciding to lower doses of evidence-based therapies.
Action: After excluding other causes of hypotension, use best-tolerated doses of GDMT, accepting that less data exist for the impact of lower doses in HF management.
Principle 3: Optimal SNS modulation with target doses of beta blocker appears to have the best effect on HFrEF outcomes (cardiovascular mortality, pump failure mortality, and sudden cardiac death).
Scenario: Patient is able to tolerate target doses of one and less than target doses of the other therapeutic agent.
Action: Use target doses of beta blocker and, as necessary and if needed, lower doses of RAAS blockade.
Principle 4: Although high heart rate is associated with worse outcomes, not all medications that lower heart rate impact outcomes equally.
Scenario: Patients in sinus rhythm with a heart rate >70 bpm.
Action: Optimize beta-blocker doses, then consider ivabradine.
Important caveat: Persistent tachycardia may be a manifestation of severe cardiac dysfunction or noncardiovascular disease, such as thyroid dysfunction.
Principle 5: African-American patients experience further benefit from the use of HYD/ISDN therapy.
Scenario: African-American patients on optimal doses of all other therapies with persistent NYHA class III symptoms.
Action: Add HYD/ISDN therapy.
Principle 6: Primary prevention device therapy and cardiac resynchronization therapy should only be considered after consistent use of optimal doses of all medications for 3 to 6 months.
Scenario: Persistent low EF after at least 3 to 6 months of optimal doses of all medications.
Action: Evaluate or refer for candidacy for implantable cardioverter-defibrillator and/or cardiac resynchronization therapy.
Principle 7: Symptomatic congestion should be treated with diuretics irrespective of other therapies.
Action: Use adequate (but avoid excessive) diuretic therapy to relieve congestion. In select patients with a volume status that is challenging to assess based on bedside clinical parameters, pulmonary artery catheterization and/or implanted pulmonary artery monitoring may be useful. Continuous hemodynamic monitoring with implantable devices may improve outcomes, but the infrastructure to support use and the optimal patient population for implantation must be addressed prior to widespread deployment.
Principle 8: Optimize team-based care.
Action: Employ multidisciplinary teams that include advanced practice nurses, clinical nurses, and pharmacists to help titrate GDMT. Team management also facilitates serial assessment and longitudinal care, including management of comorbidities.
Principle 9: Tolerability and side effects in part depend on how and when the therapy is prescribed.
Action: Start at low doses and up-titrate based on tolerability. Patient education and frequent contact will shorten the time to achieve optimal therapy.
Important caveat: Frequent visits may include telephone contact or virtual visits.
Principle 10: Focus on both the patients’ symptoms and functional capacity as well as improving cardiac function.
Action: Reassess functional status and health state and refer appropriate patients when stable after recent hospitalization for HF for a formal supervised cardiac rehabilitation program.
Optimizing therapy not only involves addressing each of these 10 principles, but also involves dose titration, monitoring of response, interactions (e.g., hypotension, renal function), and side effects. This occurs over a minimum of months. Furthermore, multiple clinicians are often required (e.g., HF and electrophysiology experts, physicians, nurses, pharmacists, and other clinicians). A team-based approach is an ideal strategy to attain optimal therapy for HF.
9 How to Manage Common Comorbidities
There is a bidirectional relationship between HF and comorbidities whereby,
1. The presence of one increases the risk of incident development of the other,
2. Prognosis for the patient is worse if both are present simultaneously.
Targeting comorbidities does not uniformly improve HF outcomes, although encouraging data are emerging with the new antidiabetic class of sodium-glucose cotransporter-2 inhibitors (93). Nevertheless, comorbidities should be evaluated and treated to improve overall patient outcomes, as these are the cause of a large proportion of hospitalizations in patients with HF and are associated with worsening symptoms and progression. Being on high alert for and appropriately evaluating these comorbidities is necessary, as their symptoms may overlap with those of HF. Appropriate referral to clinicians with relevant experience treating the various comorbidities is an important aspect of management. Table 16 classifies comorbidities into cardiac and noncardiac comorbidities, and provides guidance on appropriate management options.
10 How to Integrate Palliative Care and Transition to Hospice Care
Advances in care have delayed the progression of disease but rarely lead to a cure, such that the palliative care needs of patients, caregivers, and healthcare systems are as great as ever. Most palliative care is provided by nonpalliative care specialists. Accordingly, such clinicians shoulder the primary responsibility for coordinating an end-of-life plan consistent with values and goals expressed by patient and family. The following are important points to consider regarding palliative care and transition to hospice.
Principle 1: Palliative care strives to reduce suffering through the relief of pain and other distressing symptoms while integrating psychological and spiritual aspects of care.
Action: Soliciting goals of care and focusing on quality of life are appropriate throughout the clinical course of HF, and become increasingly important as disease progresses.
Principle 2: Good HF management is the cornerstone of symptom palliation.
Action: Meticulous management of HF therapies—particularly diuretics—is a critical component of symptom management and should continue through end of life.
Principle 3: Palliative care consultation and complementary approaches to care may further ameliorate refractory HF symptoms of dyspnea, fatigue, and pain, although study results have been mixed.
Action: Targeted specialty palliative care consultation can be helpful for especially complex decisions, refractory symptoms, and end of life.
Principle 4: Patients with HF often face major treatment decisions over time and should be provided with support when thinking through the benefits and burdens of each treatment option.
Action: Decision support tools (patient decision aids) help frame options, which should then be followed by dynamic and personalized conversations.
Principle 5: Proactive shared decision-making discussions simplify difficult decisions in the future.
Action: Preparedness planning discussions should occur at least annually between patients and clinicians leading to review of clinical status and current therapies, estimates of prognosis, clarification of patient values and beliefs, anticipation of treatment decisions, and advanced care directives that identify surrogate decision-makers (healthcare proxies) (2). Resources to assist patients in these difficult discussions may be useful (e.g., the Advanced Care Training module from HFSA: http://www.hfsa.org/module-9/). Similar preparedness-planning discussions should occur at the time of major procedural interventions (e.g., LV assist device implantation, heart transplantation).
Principle 6: Attention to clinical trajectory is required to calibrate expectations and guide timely decisions, but prognostic uncertainty is inevitable and should be included in discussions with patients and caregivers.
Action: Worsening disease and “milestone events” (e.g., recurrent hospitalization or progressive intolerance of medications due to hypotension and kidney dysfunction) should trigger heightened preparation with patients and families, but without specific estimates of how much time remains due to high levels of unpredictability in the clinical course of HF.
Principle 7: The transition from “do everything” to “comfort only/hospice” is often bridged through a phase of “quality survival,” during which time patients increasingly weigh the benefits, risks, and burdens of initiating or continuing life-sustaining treatments.
Action: Revising the medical regimen for symptom relief and quality of life may involve discontinuation of some recommended therapies (e.g., reducing neurohormonal antagonists in the setting of symptomatic hypotension, deactivation of defibrillator therapy) and the addition of therapies not usually recommended (e.g., opioids for refractory dyspnea).
6 Discussion and Implication of Pathway
The primary objective of this document is to provide a framework for the many decisions required in the management of patients with HFrEF. Most importantly, the checklists and algorithms provided in this Decision Pathway should be applied only in the context of the most recent update to the AHA/ACC guideline for management of adults with chronic HF, and in this case, patients with HFrEF. No guideline, pathway, or algorithm should ever supersede clinical judgment.
Management of HFrEF often involves multidisciplinary care, may require complex decision making, and benefits from a solid foundation of knowledge to manage these occasionally fragile patients. HF is a major public health concern, one in which broader clinician experience in GDMT would be expected to significantly benefit affected patients. With recent changes in available diagnostics and therapeutics for HFrEF along with evolution in recommended management strategies for affected patients, many questions have emerged regarding optimal deployment of these newer approaches to patient care. Additionally, clinical practice guidelines continue to evolve. In this context, we have highlighted important literature citations explaining the rationale for this changing picture in HFrEF care, candidate best practices, and, where evidence or best practices are lacking, templates for clinical decision making to rationally manage patients. As more evidence emerges, many topics will be clarified.
ACC Presidents and Staff
Mary Norine Walsh, MD, FACC, President
Shalom Jacobovitz, Chief Executive Officer
William J. Oetgen, MD, MBA, FACC, Executive Vice President, Science, Education, Quality, and Publications
Joseph M. Allen, MA, Team Leader, Clinical Policy and Pathways
Lea G. Binder, MA, Team Leader, Physician Clinical Pathways
Severa Chavez, Associate, Clinical Policy and Pathways
Amanda Ladden-Stirling, MPP, Associate, Clinical Policy and Pathways
Shira Klapper, Publications Manager, Science, Education, Quality, and Publications
Appendix 1: Author Relationships With Industry and Other Entities (Relevant)—2017 ACC Expert Consensus Decision Pathway for Optimization of Heart Failure Treatment
To avoid actual, potential, or perceived conflicts of interest that may arise as a result of industry relationships or personal interests among the writing committee, all members of the writing committee, as well as peer reviewers of the document, are asked to disclose all current healthcare-related relationships, including those existing 12 months before initiation of the writing effort. The ACC Task Force on Clinical Expert Consensus Decision Pathways reviews these disclosures to determine what companies make products (on market or in development) that pertain to the document under development. Based on this information, a writing committee is formed to include a majority of members with no relevant relationships with industry (RWI), led by a chair with no relevant RWI. RWI is reviewed on all conference calls and updated as changes occur. Author RWI pertinent to this document is disclosed in the following table, and peer reviewer information is disclosed in Appendix B. Additionally, to ensure complete transparency, authors’ comprehensive disclosure information—including RWI not pertinent to this document—is available online (See Online Appendix). Disclosure information for the ACC Task Force on Clinical Expert Consensus Decision Pathways is also available Online, as is the ACC disclosure policy for document development.⇓
Appendix 2: Peer Reviewer Information—2017 ACC Expert Consensus Decision Pathway for Optimization of Heart Failure Treatment
This table represents the individuals, organizations, and groups that peer reviewed this document. A list of corresponding comprehensive healthcare-related disclosures for each reviewer is available as Online Appendix 2⇓.
Appendix 3: Abbreviations
ACC = American College of Cardiology
ACEI = angiotensin-converting enzyme inhibitor
AHA = American Heart Association
ARB = angiotensin receptor blocker
ARNI = angiotensin receptor–neprilysin inhibitor
BNP = B-type natriuretic peptide
EF = ejection fraction
GDMT = guideline-directed medical therapy
HF = heart failure
HFrEF = heart failure with reduced ejection fraction
HFSA = Heart Failure Society of America
HYD/ISDN = hydralazine/isosorbide dinitrate
LV = left ventricular
LVEF = left ventricular ejection fraction
NT-proBNP = N-terminal pro–B-type natriuretic peptide
NYHA = New York Heart Association
A Report of the American College of Cardiology Task Force on Expert Consensus Decision Pathways
This document was approved by the American College of Cardiology Clinical Policy Approval Committee in November 2017.
The American College of Cardiology Foundation requests that this document be cited as follows: Yancy CW, Januzzi JL Jr, Allen LA, Butler J, Davis LL, Fonarow GC, Ibrahim NE, Jessup M, Lindenfeld J, Maddox TM, Masoudi FA, Motiwala SR, Patterson JH, Walsh MN, Wasserman A. 2017 ACC expert consensus decision pathway for optimization of heart failure treatment: answers to 10 pivotal issues about heart failure with reduced ejection fraction: a report of the American College of Cardiology Task Force on Clinical Expert Consensus Decision Pathways. J Am Coll Cardiol 2017;71:XXX-xxxx.
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- Task Force on Expert Consensus Decision Pathways
- Table of Contents
- 1 Introduction
- 2 Methods
- 3 Assumptions and Definitions
- 4 Pathway Summary Graphic
- 5 Description and Rationale: Answers to 10 Pivotal Issues in HF
- 6 Discussion and Implication of Pathway
- ACC Presidents and Staff
- Appendix 1: Author Relationships With Industry and Other Entities (Relevant)—2017 ACC Expert Consensus Decision Pathway for Optimization of Heart Failure Treatment
- Appendix 2: Peer Reviewer Information—2017 ACC Expert Consensus Decision Pathway for Optimization of Heart Failure Treatment
- Appendix 3: Abbreviations