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Nearly one third of acute heart failure (AHF) patients die or are rehospitalized within 90 days after discharge in the United States, with similar numbers in Europe. Despite a decade of intensive research efforts, substantially improving outcomes remains an elusive goal. Reducing morbidity and mortality remains the greatest current challenge of AHF management.
More than 6.5 million Americans have heart failure (HF), with more than 1 million new diagnoses each year. By 2030, the prevalence of HF is projected to increase 46%, with HF related costs exceeding 70 billion US dollars (see also Chapter 18 ). Despite the increasing prevalence, AHF admissions have stayed relatively flat or even decreased, at least by primary discharge diagnosis. Approximately 1 million hospitalizations with a primary discharge diagnosis of AHF occur every year. Although the trajectory of primary discharge diagnoses has stayed flat, when all diagnoses are considered, AHF hospitalizations are rising ( Fig. 36.1 ). Already, AHF is the most common and costliest cause of hospitalization and rehospitalization for older Americans.
While rehospitalization rates have marginally improved, both rehospitalization and mortality rates remain high. In 2008, for Medicare beneficiaries, 30-day readmissions were 23.5% with a 7.9% postdischarge mortality. By 2014, 30-day readmissions had decreased to 22.7%, with an 8.6% postdischarge mortality. Within 5 years, 75% of patients hospitalized with HF will be dead, irrespective of a reduced or preserved ejection fraction (EF) ( Fig. 36.2 ).
Amid such poor outcomes and high health care costs are health inequities; disparities evident by race, gender, and socioeconomic status. For first episodes of AHF, black males and females have the highest incidence ( Fig. 36.3 ). For socioeconomically disadvantaged patients, initial admissions and readmissions are markedly higher.
In 2003, Dr. Braunwald described HF as the “last great battleground in cardiology.” Ironically, as more and more patients live longer with cardiovascular disease—a testament to the tremendous advances in reducing the burden of ischemic heart disease and sudden cardiac death—such patients are at risk for developing HF ( Fig. 36.4 ). As the population ages, unless outcomes improve, the burden of AHF will increase. Disparities may also worsen.
AHF is a clinical diagnosis. No single test or physical exam feature definitively “rules in” or “rules out” AHF. Thus there is no diagnostic “gold standard.” Perhaps unsurprisingly, there is neither a universal, well-accepted definition of AHF, nor a nomenclature to describe the various AHF syndromes. Various names have been used, including acute decompensated heart failure (ADHF), hospitalization for heart failure (HHF), and acute heart failure syndromes (AHFS). Currently, AHF is the most widely used and is the current terminology in several consensus guidelines.
Agreement upon a definition is not an academic exercise; it has significant clinical implications. Describing AHF in an 85-year-old female with no past history of HF and a systolic blood pressure at presentation of 210/120 mm Hg does not appropriately describe the 65-year-old male with known ischemic heart disease, EF of 10%, on maximal guideline recommended HF therapies awaiting transplantation. Such heterogeneity of the AHF presentation broadens when comorbid conditions and precipitants of AHF are considered. Lack of consensus on a definition hinders both policy and research; the slow rate of progress to reduce morbidity and mortality may be directly related to the inability to define exactly what problem we are addressing.
Unfortunately, no universal definition is proposed. For the purposes of this chapter, AHF is defined as “signs of symptoms of heart failure requiring urgent or emergent therapy.”
Unlike chronic HF with reduced ejection fraction (HFrEF), the pathophysiology of AHF is less well understood. In chronic HF, neurohormonal activation (renin-angiotensin-aldosterone—sympathetic nervous system), adverse hemodynamic conditions, energetics, and inflammation, are all well-established, overlapping pathophysiologic constructs. While these mechanisms are undoubtedly also present in AHF, their relative contribution to the AHF presentation is less well known.
A conceptual model for understanding the complexity of the pathophysiology of AHF is shown in Fig. 36.5 . An AHF episode most likely occurs on top of a structural/functional cardiac abnormality (Stage B HF). A precipitant triggers or incites the initial AHF event. This precipitant, combined with the underlying structural/functional abnormality—complicated by other comorbid conditions—ultimately leads to AHF. Once AHF has begun, a cascade of other abnormalities occurs, affecting the heart itself, vasculature, neurohormonal system, kidneys, and liver, as well as inciting inflammatory pathways. These mechanisms act as potential amplifiers, exacerbating the current AHF episode.
Related to this pathophysiological construct is the concept of organ injury. It is common to see myocardial injury in the form of troponin release or acute kidney injury in the setting of AHF. Whether such organ injury contributes to the AHF episode, results from it, or both has not been definitively established. What is clear is the association of organ injury with worse outcomes. Fig. 36.6 graphically demonstrates this concept, as well as the idea that prevention of such injury may alter the patient’s outcome. This concept gained momentum in the RELAX-AHF-1 (Serelaxin, recombinant human relaxin-2, for treatment of acute heart failure) trial, where marked and congruent differences in biomarkers were observed, suggesting such prevention of injury may have resulted in improved 180-day mortality. Unfortunately, the mortality benefits were not replicated in a confirmatory trial.
Ultimately, to what extent and severity each of these overlapping pathways contributes to AHF, remains to be defined. We do not yet know what exactly to target in each patient that will result in improved outcomes. We do know that certain pathologic conditions—such as elevated left ventricular end diastolic filling pressures—are a hallmark of AHF and associated with worse outcomes. However, acutely improving hemodynamics has yet to result in less morbidity or mortality. At present, identifying markers associated with worse outcomes has yet to translate into targets for therapy.
The presence of comorbid conditions adds another layer of complexity to the AHF presentation. The “pure” AHF phenotype, however defined, is rare. Rather, the patient with other underlying medical comorbid conditions (i.e., hypertension, chronic obstructive pulmonary disease, diabetes, ischemic heart disease; see also Chapter 48 ) and social determinants of health (i.e., insurance status, caregiver support, adequate nutrition, lack of housing) is by far the norm. Whether these conditions contribute to AHF or are worsened by AHF is not always clear. During both initial and inpatient management, each potential comorbid condition must be accounted for, as described later.
It is doubtful a single, universal construct exists to encompass the entire pathophysiology of AHF. Although patients present with similar signs and symptoms, their underlying biology is unique. Perhaps this desire to lump all of AHF phenotypes together, rather than divide, has contributed to our limited ability to improve outcomes.
Despite the heterogeneity of the AHF patient, general principles of initial management may be applied and are outlined as follows. Prompt diagnosis, initial decongestive management, as well as management of comorbid conditions, and robust transitional care—followed by guideline adherent disease management—form the foundation of AHF care.
Previously proposed classifications of AHF patients to facilitate initial management categorize patients once; we recommend reassessment and reclassification during the entire course of a patients’ hospital stay. Such reassessments recognize the dynamic nature of AHF.
The majority of hospitalized AHF patients initially present to the emergency department (ED). The traditional axiom of airway, breathing, circulation (ABCs) applies; however, most patients do not present in extremis. The two polar archetypes are the flash pulmonary edema patient, typically due to hypertension, and the cardiogenic shock patient. After ensuring the ABCs, elucidating and managing the precipitant is paramount—for example, AHF secondary to a massive myocardial infarction (MI) or valve rupture. Although such presentations are not common, this principle of management applies to even less urgent cases. Table 36.1 approaches the AHF patient in the ED as a series of clinical questions. Fig. 36.7 shows an algorithmic approach toward the AHF patient in the ED or clinic setting.
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Diagnosis and treatment commonly occur in parallel, unlike the classic teaching of a history, followed by physical examination, followed by orders for ancillary testing, initial differential, revised differential based on test results, then treatment. |
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Delays in diagnosis and subsequent treatment are associated with worse outcomes. Patients rarely present with a diagnosis, however; rather, they present with a “chief complaint.” Thus determining whether the patient’s reported “shortness of breath” is due to AHF or an alternative diagnosis relies on history and physical examination, combined with ancillary studies ( see also Chapter 31 ). Unfortunately, the history and physical exam lack sensitivity. Paroxysmal nocturnal dyspnea and orthopnea should be assessed, but they lack specificity. An S3 gallop (remarkably challenging to hear in a busy ED) and jugular venous distention are the most specific, but insensitive and clinician dependent. Despite congestion being the sine qua non of AHF, measuring congestion reliably, with robust intra- and interobserver agreement, is challenging. Nevertheless, a thorough history (especially a past history of HF) and physical exam, combined with traditional ancillary studies of chest x-ray, EKG, basic metabolic profile, and complete blood count, are recommended.
One of the greatest clinical benefits of the chest x-ray (CXR) is identifying alternative diagnoses; the sensitivity and specificity are less than 80% for the diagnosis of AHF. The imaging modality recommended at the bedside is lung ultrasound ( Fig. 36.8 ). More than any other test, including natriuretic peptides (NPs), lung ultrasound (LUS) has the most robust likelihood ratio (LR) + 7.4 (95% CI 4.2–12.8) and LR − 0.16 [95% CI 0.05–0.51]), to aid in diagnosis. Sonographic detection of pulmonary edema is represented by B-lines, discrete artifacts resulting from the reverberation of sound waves off of fluid-filled pulmonary interstitium. In the proper clinical setting, B-lines represent pulmonary edema. The most recent European Society of Cardiology (ESC) guidelines now include LUS as an adjunct to diagnosis.
Formal echocardiography is rarely done in the United States in the ED setting. This does not obviate its value. For patients with worsening HF, reassessment of myocardial structure and function is recommended, especially if a clear etiology or precipitant is not identified. While point-of-care ultrasound does not replace formal echocardiography, point-of-care ultrasound or FoCUS (focused ultrasound) is often performed by noncardiologists at the bedside. This rapid approach is recommended by cardiology and noncardiology societies. For example, qualitative assessments of right and left ventricular function, identification of tamponade, and hypovolemia may be critical to aid in the management of the shock patient. The European Association of Cardiovascular Imaging outlines three broad frameworks for emergency FoCUS echocardiography: (1) diagnostic, (2) symptom or sign based, and (3) resuscitative. However, FoCUS does not replace formal echocardiography.
NPs facilitate diagnosis. In addition, NPs are excellent discriminators of risk (i.e., prognosis). Despite their value and guideline recommendation, recent meta-analysis suggests their greatest value is in excluding AHF. While very high values help rule in AHF, intermediate values have less diagnostic discrimination. Using thresholds of 100 pg/mL for BNP and 300 pg/mL NTproBNP, a low value significantly reduces the posttest probability of AHF (LR = 0.1).
Guidelines also recommend troponin testing in AHF. Not only does this aid in identification of occult MI, troponin discriminates higher risk patients. With the advent of higher sensitivity assays, the proportion of AHF patients with evidence of myocardial injury outside of ACS exceeds 90%.
Once the diagnosis of AHF has been made, the algorithm ( Fig. 36.9 ) outlined by the European Society of Cardiology outlines a pragmatic approach to initial classification and management of the AHF patient. The vast majority of patients present as “Wet and Warm,” based on the hemodynamic profiles established by Nohria and Stevenson ( Fig. 36.10 ). Thus most AHF management algorithms predominantly focus on this category. While the “Wet and Cold” patient is only a small fraction of AHF presentations, these are the most challenging to manage. In the classification scheme presented as follows, specific doses and types of medications are not discussed, as they will be reviewed in greater detail later in this chapter.
As highlighted in Fig. 36.9 , elevated systolic blood pressure is common. Contemporary registries, such as Get With The Guidelines HF and EurObservational, note mean systolic blood pressure (SBP) of 140 and 133 mm Hg, respectively. These patients benefit from both vasodilators and IV loop diuretic therapy. The flash pulmonary edema patient represents the prototypical AHF patient with elevated blood pressure. Such patients present in extremis, sitting bolt upright (tripod position), gasping, with systolic blood pressures commonly above 180 mm Hg. Jugular venous distention, diffuse crackles, and minimal to no lower extremity edema are common findings. Rapid noninvasive ventilation (assuming an appropriate mental status), sublingual nitrates followed by IV vasodilators, and a small dose of IV loop diuretics often results in dramatic improvement.
This presentation is best represented by the patient with a history of HFrEF who slowly worsens over time. Gradual weight gain, progressive peripheral edema, and worsening dyspnea on exertion are common historical features. Such patients demonstrate more total volume overload instead of the volume redistribution seen in the vascular type presentation. For such patients, aggressive decongestion, starting with IV loop diuretics, are recommended. Such patients might also benefit from vasodilatation.
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