09 - 317 Cardiovascular Collapse, Cardiac Arrest, and Sudden Cardiac Death
317 Cardiovascular Collapse, Cardiac Arrest, and Sudden Cardiac Death
For pulmonary edema resulting from upper airway obstruction, recognition of the obstructing cause is key because treatment then is to relieve or bypass the obstruction.
■ ■FURTHER READING Alviar CL et al: For the ACC Critical Care Cardiology Working Group. Positive pressure ventilation in the cardiac intensive care unit. J Am Coll Cardiol 72:1532, 2018. Amin AP et al: The evolving landscape of Impella use in the United States among patients undergoing percutaneous coronary intervention with mechanical circulatory support. Circulation 141:273, 2020. Baran DA et al: SCAI clinical expert consensus statement on the classification of cardiogenic shock. Cathet Cardiovasc Interv 94:29, 2019. Damluji AA et al: Mechanical complications of acute myocardial infarction. A scientific statement from the American Heart Association. Circulation 144:e16, 2021. Dhruva SS et al: Association of use of intravascular microaxial left PART 8 Critical Care Medicine ventricular assist device vs intra-aortic balloon pump on in-hospital mortality and major bleeding among patients with acute myocardial infarction complicated by cardiogenic shock. JAMA 323:734, 2020. Heidenreich PA et al: 2022 AHA/ACC/HFS guideline for the management of heart failure. Circulation 145:895, 2022. Ingbar DH: Cardiogenic pulmonary edema: Mechanisms and treatment—An intensivists view. Curr Opin Crit Care 25:371, 2019. Møller JE et al: Microaxial flow pump or standard care in infarctrelated cardiogenic shock. N Engl J Med 390:1382, 2024. Naidu SS et al: SCAI SHOCK stage classification expert consensus update: A review and incorporation of validation studies. J Am Coll Cardiol 79:933, 2022. Thiele H et al: Intraaortic balloon support for myocardial infarction with cardiogenic shock. N Engl J Med 367:1287, 2012. Thiele H et al: PCI strategies in patients with acute myocardial infarction and cardiogenic shock. N Engl J Med 377:2419, 2017. Thiele H et al: Percutaneous short-term active mechanical support devices in cardiogenic shock: A systematic review and collaborative meta-analysis of randomized trials. Eur Heart J 38:3523, 2017. Thiele H et al: One-year outcomes after PCI strategies in cardiogenic shock. N Engl J Med 379:1699, 2018. Thiele H et al: Management of cardiogenic shock complicating myocardial infarction: An update 2019. Eur Heart J 40:2671, 2019. Thiele H et al: Extracorporeal life support in infarct-related cardiogenic shock. N Engl J Med 389:1286, 2023. van Diepen S et al: Contemporary management of cardiogenic shock: A scientific statement. Circulation 136:e232, 2017. Zeymer U et al: Veno-arterial extracorporeal membrane oxygenation in patients with infarct-related cardiogenic shock: An individual patient data meta-analysis of randomised trials. Lancet 402:1338, 2023. Christine M. Albert, William H. Sauer
Cardiovascular Collapse,
Cardiac Arrest, and
Sudden Cardiac Death
OVERVIEW AND DEFINITIONS
(SEE TABLE 317-1)
Cardiovascular collapse is severe hypotension from acute cardiac dysfunction or loss of peripheral vasculature resistance resulting in cerebral
hypoperfusion and loss of consciousness. This condition can be the
result of a cardiac arrhythmia, severe myocardial or valvular dysfunction, loss of vascular tone, and/or acute disruption of venous return.
When effective circulation is restored spontaneously, patients present with syncope (see Chap. 23). In the absence of spontaneous resolution, cardiac arrest occurs, ultimately resulting in death if resuscitation attempts are unsuccessful or not initiated. Underlying etiologies for cardiovascular collapse include benign conditions, such as neurocardiogenic syncope, but also life-threatening conditions including ventricular tachyarrhythmias, severe bradycardia, severely depressed myocardial contractility, as with massive acute myocardial infarction (MI) or pulmonary embolus, and other catastrophic events interfering with cardiac function such as myocardial rupture with cardiac tamponade or papillary muscle rupture with torrential mitral regurgitation. Sudden cardiac arrest (SCA) refers to an abrupt loss of cardiac function resulting in complete cardiovascular collapse due either to an acute life-threatening cardiac arrhythmia or abrupt loss of myocardial pump function that requires emergency medical intervention for restoration of effective circulation. Most SCAs occur outside the hospital, and fewer than 10% of these victims survive to be discharged from the hospital despite undergoing attempted resuscitation by emergency medical services (EMS). For those who die prior to hospital admission, a cardiovascular cause for the arrest is often presumed based upon the absence of evidence for a traumatic or other noncardiac cause at the time of the arrest. If the patient does not survive a SCA, the death is classified as a sudden cardiac death (SCD). Deaths that occur during hospitalization or within 30 days after resuscitated cardiac arrest are usually counted as SCDs in epidemiologic studies. SCD also includes a broader category of unexplained rapid deaths thought to be due to cardiac causes where resuscitation was not attempted. In epidemiologic studies, SCD is usually defined as an unexpected death without obvious extracardiac cause that occurs in association with a witnessed rapid collapse or within 1 hour of symptom onset. This definition is based on the presumption that rapid deaths are often due to an arrhythmia, an assumption that cannot always be validated. Approximately half of all SCDs are not witnessed. In the United States, few deaths undergo autopsies, and noncardiac conditions that evolve rapidly such as acute cerebral hemorrhage, aortic rupture, and pulmonary embolism cannot be excluded without an autopsy. Therefore, definitive information necessary to establish the cause of death is usually not available. In unwitnessed cases, the definition is often further expanded to include unexpected deaths where the subject was documented to be well when last observed within the preceding 24 hours. This expanded definition further decreases the certainty that the death was due to an arrhythmia or other cardiac causes, and recent data suggest that noncardiac causes may comprise a larger than expected percentage of these unwitnessed sudden deaths. Most countries, including the United States, do not have national surveillance systems or reporting requirements for SCD; thus, the true incidence and frequency of SCD and its different mechanisms can only be estimated. EPIDEMIOLOGY ■ ■DEMOGRAPHICS SCA and SCD are major public health problems that account for 15% of all deaths and comprise 50% of all cardiac deaths. In the United States alone, there are an estimated 350,000 EMS-attended out-of-hospital cardiac arrests and 210,000 SCDs in the adult population annually. The estimated societal burden of premature death due to SCD is 2 million years of potential life lost for men and 1.3 million years of potential life lost for women, which is greater than most other leading causes of death. Although cardiac pathology, particularly coronary heart disease (CHD), underlies the majority of SCDs, up to two-thirds of all SCDs occur as the first clinical expression of previously undiagnosed heart disease. SCD rates have declined but not as steeply as rates for CHD in general. Age, gender, race, and geographic region all influence the incidence of SCD. Rates of out-of-hospital cardiac arrest are lower in Asia (52.5 per 100,000 person-years) than Europe (86.4 per 100,000 personyears), North America (98.1 per 100,000 person-years), and Australia (111.9 per 100,000 person-years), and also vary within geographic regions of the United States. SCD is rare in individuals younger than 35 years of age (1–3 per 100,000 per year) and increases markedly with age as the incidence of coronary artery disease (CAD), heart failure (HF),
TABLE 317-1 Distinction Between Cardiovascular Collapse, Cardiac Arrest, and Death TERM DEFINITION QUALIFIERS MECHANISMS Cardiovascular collapse Sudden loss of effective circulation due to cardiac and/or peripheral vascular factors that may reverse spontaneously (e.g., neurocardiogenic syncope transient hypotension) or require interventions (e.g., hypovolemia, tamponade, ventricular fibrillation). Cardiac arrest Abrupt cessation of cardiac function resulting in loss of effective circulation that may be reversible by prompt emergency medical intervention. Sudden cardiac death Sudden unexpected death attributed to cardiac arrest, which occurs within 1 hour of symptom onset. and other predisposing conditions also increases. Although absolute SCD rates increase with age, the proportion of deaths that are due to SCD decreases as other causes of death increase. Women have a lower incidence of SCD and SCA than men, and women are more likely to present with pulseless electrical activity (PEA) and to have their SCD occur at home as compared with men. Possibly related to these factors, the SCD rate has not declined as much for younger women compared to men in recent years. Black as opposed to white Americans have higher rates of SCD, are more likely to have unwitnessed arrests and to be found with PEA, and have lower rates of survival. Socioeconomic disparities, with resuscitation being less likely in low-income neighborhoods, are contributing factors but do not appear to account for the entirety of the elevated SCD rate in blacks. Alternatively, individuals of Hispanic ethnicity appear to have lower rates of SCD, despite having a higher prevalence of cardiac risk factors. It appears that the incidence of SCD may be relatively low among Asian populations as well, both within the United States and globally. These gender and racial differences in SCD/SCA incidence and survival are poorly understood and warrant further research. ■ ■RISK FACTORS (SEE FIG. 317-1) The presence of overt structural heart disease and/or certain types of inherited arrhythmia syndromes markedly elevates SCD risk (see Chaps. 261 and 262). Preexisting CHD and HF are the most prevalent predisposing cardiac conditions and are associated with a four- to tenfold increase in SCD risk. Correspondingly, SCD shares many of the same risk factors with CHD and heart failure (HF), including hypertension, diabetes, hypercholesterolemia, obesity, and smoking. Diabetes is a particularly strong risk factor for SCD even in patients with established CHD. Hypertension and resultant left ventricular hypertrophy (LVH) appear to be particularly important markers of SCD risk in blacks, in whom the prevalence of these condi tions is greater. Smoking markedly elevates risk, and smoking cessation lowers risk particularly among individuals who have not yet developed overt CHD. Serum cholesterol appears to be more strongly related to SCD at younger ages, and the benefits of cholesterol lowering on SCD incidence have not been firmly established. There also appears to be a genetic component to SCD risk that is distinct from that associated with other manifestations of atherosclerosis. A history of SCD in a first-degree relative is associated with an increased risk for SCD, and with the occurrence of ventricular fibrillation (VF) during acute MI, but is not associated with an increased risk for acute MI. These data suggest that genetic factors may predispose to fatal ventricular arrhyth mia in the setting of ischemia, rather than to CHD in general. Obstructive sleep apnea and seizure disorders are also associated with increased SCD risk; the underlying mechanism is not clear but may be due to hypoxia-induced cardiac arrest. Atrial fibrillation also appears to be associated with an increased risk of SCD, which is partly, but not entirely, accounted for by its association with underlying heart disease. Patients with chronic kidney disease are also at higher SCD
Broad term that includes cardiac
arrest as well as transient events that
characteristically revert spontaneously
presenting as syncope.
Same as cardiac arrest, plus
neurocardiogenic syncope or other causes
of transient loss of blood flow.
Rare spontaneous reversions; likelihood
of successful intervention relates to
mechanism of arrest, clinical setting,
availability of emergency medical
services, and prompt return of
circulation.
Ventricular fibrillation, ventricular
tachycardia, asystole, bradycardia,
pulseless electrical activity, noncardiac
mechanical factors (e.g., pulmonary
embolism).
In unwitnessed cases, the definition is
often expanded to include unexpected
deaths where the subject was
documented to be well within the
preceding 24 hours.
Same as cardiac arrest.
CHAPTER 317
risk with annualized SCD rates approaching 5.5% in patients under
going dialysis. Electrolyte shifts and LVH, which are common in this
population, have been suggested to play a role. There are also potential
dietary influences on SCD risk. Individuals with higher intakes of
polyunsaturated fatty acids, particularly n-3 fatty acids, and other
components of a Mediterranean-style diet have lower SCD risks in
observational studies, possibly due to antiarrhythmic effects of dietary
components. Low levels of alcohol intake may be beneficial, but heavy
intake (>3 drinks/day) appears to elevate risk.
Cardiovascular Collapse, Cardiac Arrest, and Sudden Cardiac Death
■
■PRECIPITATING FACTORS
SCD/SCA occurs with higher frequency at certain times, locations,
and in association with certain activities and exposures. Although not
consistently observed across all studies, there do appear to be circa
dian variations in the incidence of SCD and cardiac arrest, with peaks
in incidence in the morning hours and again in the later afternoon.
There is also seasonal variability in SCD rates, which may be related to
temperature and light exposure. Rates are highest during winter in the
northern hemisphere and summer in the southern hemisphere. SCD
rates also acutely peak during disasters such as earthquakes and terror
ist attacks. SCA arrests are more likely to occur in certain locations as
well, with notable clustering around train stations, airports, and other
public places where there is significant population transit. SCD rates
tend to be higher in urban areas, and individuals who live near major
roadways are at elevated SCD risk. There is also a well-recognized
acute elevation in SCD risk that occurs during or shortly after bouts
of vigorous exertion, and men appear to be more susceptible. Habitual
exercise and training lower this acute risk but do not eliminate it
entirely. Exertion-associated SCDs are particularly tragic and highly
publicized when they occur in highly trained athletes; however, the
majority of such deaths actually occur in the general population. The
common thread among these precipitating factors is likely heightened
autonomic tone, which can promote ischemia and has direct proar
rhythmia and electrophysiologic actions that lower the threshold for
sustained VF.
CAUSES OF SUDDEN CARDIAC DEATH
■
■UNDERLYING HEART DISEASE (FIG. 317-1)
Our understanding regarding the diseases that contribute to SCD
is derived primarily from autopsy series and cardiac evaluations in
cardiac arrest survivors, which are highly variable in level of detail.
Despite the limitations of these data, it is generally accepted that
sudden death due to cardiac causes is most commonly due to CAD,
although the proportion with CAD varies markedly by age, race, and
sex. It is estimated that ~70% of SCDs in white men are due to CAD,
as compared with only 40–50% in women and blacks. The proportion
of SCDs with underlying CAD may be even lower in Asian ethnicities.
Recent data suggest that the proportion of SCDs with CAD on autopsy
may be declining in some parts of Europe and the United States, and,
Idiopathic VF/Others Valvular heart disease 1–5% Inherited arrhythmia syndrome (LQTS, BrS, CPVT, ERS, etc.) 1–2% in Western countries 10% in Asia Myocardial Substrates: Myocardial scar Hypertrophy Fibrosis Myocardial stretch Electrical heterogeneity Ion channel functional modification Abnormal calcium handling Sudden Cardiac Death Causes Cardiomyopathies (NIDCM, HCM, ARVC, etc.) 10–15% in Western countries 30–35% in Asia PART 8 Critical Care Medicine Population‐Based Risk Factors Male sex Black race Diabetes Current smoking Hypertension Chronic kidney disease ECG features (QT, QRS prolongation, early repolarization, LVH) Family history of SCD (genetics) Diet low in N-3 PUFA Atrial fibrillation Obstructive sleep apnea Heavy alcohol intake Low magnesium levels A CPVT, LQTS
HCM, ARVC Age of SCD onset NIDCM BrS, ERS B FIGURE 317-1 A. Proportionate causes, substrates, risk factors, and triggers of sudden cardiac death (SCD). B. Variation of causes by age of onset. ARVC, arrhythmogenic right ventricular cardiomyopathy; BrS, Brugada syndrome; CPVT, catecholaminergic ventricular tachycardia; ECG, electrocardiogram; ERS, early repolarization syndrome; HCM, hypertrophic cardiomyopathy; LQTS, long QT syndrome; LVH, left ventricular hypertrophy; NICDM, nonischemic cardiomyopathy; PUFA, polyunsaturated fatty acid; SCD, sudden cardiac death; VF, ventricular fibrillation. (Reproduced with permission from M Hayashi et al: The spectrum of epidemiology underlying sudden cardiac death. Circ Res 116:1887, 2015.) at the same time, increasing in parts of Japan and other parts of Asia. Beyond CAD, nonischemic cardiomyopathies (hypertrophic, dilated, and infiltrative) are the second most frequent cause of SCD in the United States and European countries. Other less common causes include valvular heart disease, myocarditis, myocardial hypertrophy (often from hypertension), and rare primary electrical heart diseases such as long QT and Brugada syndromes. On average, 5–10% of SCA victims do not have a significant cardiac abnormality at the time of autopsy or after extensive premortem cardiac evaluation, and this also varies by gender and race. Before 35 years of age, atherosclerotic CAD accounts for a much smaller proportion of deaths, with hypertrophic cardiomyopathy (HCM), coronary artery anomalies, myocarditis, arrhythmogenic right ventricular cardiomyopathy, and primary ion channelopathies accounting for a significant number of these deaths. ■ ■CARDIAC RHYTHMS AND SUDDEN DEATH The initial rhythm found when EMS arrive at the scene of an out-ofhospital cardiac arrest is an important indication of the potential cause of the arrest and of the prognosis. In the early days of EMS systems, over half of victims were found in VF, giving rise to the hypothesis that ischemic VF or ventricular tachycardia (VT) degenerating to VF was the most common event. The proportion of cardiac arrests found in VF has decreased markedly since the 1970s, to only 20–25% in more recent studies, and PEA and asystole are now the most common scenarios. However, the vast majority of cardiac arrests are not monitored at the time of collapse, and since arrhythmias are inherently unstable once hemodynamic collapse occurs, the rhythm at the time of EMS arrival
Coronary heart disease ~ 40–70% White Men: 70% Women and Black Men 40–50% Asians < 40% Triggers Heart failure/Stretch Ischemia Myocardial inflammation Vigorous exertion Electrolyte abnormality Environmental stress Psychological stress/Depression Coronary Heart Disease Valvular Heart Disease may not reflect the rhythm that initially precipitated the SCA because VF and primary bradycardias can degenerate into asystole. Nonethe less, VF as an initial rhythm still predominates in public locations or in other situations when there is a short time frame between witnessed arrest and arrival of EMS, suggesting that VF remains a common initial precipitating rhythm. However, there are also data to support an absolute decrease in VF incidence. Proposed explanations include decreases in underlying CHD incidence, increased use of beta blockers in CHD, and implantable cardioverter defibrillators (ICD) in high-risk patients. There also appears to be an increase in PEA incidence over the past several years, suggesting that the proportion of SCD due to abrupt hemodynamic collapse in the absence of preceding fatal arrhythmia may be increasing. Proposed explanations for these proportional changes in PEA versus VF include the aging of the population and the increased prevalence of end-stage cardiovascular disease and other severe comorbidities. These older, sicker patients may be more likely to have arrests in the home and to have acute precipitants leading to PEA (i.e., respiratory, metabolic, vascular) and/or be less likely to sustain VF up to the point of EMS arrival. ■ ■DISEASE-SPECIFIC MECHANISMS CAD can cause SCD through several mechanisms (Table 317-2). The most common cause is acute MI or transient myocardial ischemia that leads to polymorphic VT and VF (see Chap. 262). Other primary mechanisms include severe bradyarrhythmias such as heart block with a slow escape rhythm, or PEA due to a massive MI or associated myo cardial rupture. Areas of ventricular scar from prior infarcts increase
TABLE 317-2 Causes of Cardiovascular Collapse and Sudden Cardiac Arrest CAUSE PATHOPHYSIOLOGIC SUBSTRATE RHYTHM PRESENTATION Cardiac Causes Coronary artery disease Atherosclerotic, coronary spasm, congenital anomalies Acute myocardial ischemia/infarction, ventricular rupture, tamponade Ventricular scar from healed infarction Cardiomyopathies Dilated, hypertrophic, ARVC, infiltrative disease, valvular Ventricular scar Ventricular hypertrophy Pump failure disease with LV failure Congenital heart disease (Tetralogy of Fallot, VSD, others) Ventricular scar from surgical repair Hypertrophy Aortic stenosis Obstruction to aortic outflow Ventricular hypertrophy Mitral valve prolapse/mitral regurgitation Pump failure Ventricular scar Arrhythmia syndromes without structural heart disease: Genetic: Long QT Brugada CPVT Idiopathic VF, early repolarization Drug toxicities (acquired long QT, others) Electrolyte abnormalities (severe hypokalemia) Abnormal cellular electrophysiology Polymorphic VT/VF Wolff-Parkinson-White syndrome Accessory atrioventricular connection Pre-excited AF/VF Commotio cordis Blunt precordial impact Polymorphic VT/VF Noncardiac Causes of Cardiovascular Collapse Pulmonary embolism PEA Stroke PEA, bradyarrhythmia Aortic dissection PEA, VF Exsanguination/hypovolemia PEA Tension pneumothorax PEA Sepsis PEA Neurogenic PEA, bradyarrhythmia Drug overdose PEA, bradyarrhythmia Abbreviations: AF, atrial fibrillation; ARVC, arrhythmogenic right ventricular cardiomyopathy; CPVT, catecholaminergic polymorphic ventricular tachycardia; LV, left ventricle; PEA, pulseless electrical activity; VF, ventricular fibrillation; VSD, ventricular septal defect; VT, ventricular tachycardia. the predisposition to reentrant VT, which often degenerates to VF. Once patients have suffered an MI, their risk of SCD elevates up to 10-fold, with the highest absolute rates in the first 30 days after MI. The mechanisms underlying SCD vary at different time points after MI, with nonarrhythmic causes such as myocardial rupture and/or exten sive reinfarction predominating early, within the first 1–2 months, and ischemic polymorphic VT and/or scar-related ventricular arrhythmias prevailing later. VT and sudden death can, and often do, occur years after an initial MI. Cardiomyopathies and Other Forms of Structural Heart Disease Scar-mediated reentrant VT can also occur in a host of nonischemic cardiomyopathies in which replacement fibrosis and/or inflammatory ventricular infiltrates occur (Chap. 261). In congenital heart disease, surgical scars created during corrective surgery, such as those performed to correct ventricular septal defects in tetralogy of Fallot, can also serve as the substrate for ventricular reentry. Other common predisposing processes such as LVH, ventricular stretch due to fluid overload, and cardiomyocyte dysfunction can result in electri cal heterogeneity and other electrophysiologic changes that predispose
Polymorphic VT/VF
Bradyarrhythmia
Pulseless electrical activity
VT
VF
VT
Polymorphic VT/VF
Pulseless electrical activity
Bradyarrhythmia
VT
Bradyarrhythmias
Polymorphic VT/VF
CHAPTER 317
Bradyarrhythmia
Pulseless electrical activity
Bradyarrhythmia
Polymorphic VT/VF
Cardiovascular Collapse, Cardiac Arrest, and Sudden Cardiac Death
Polymorphic VT/VF
to ventricular arrhythmias, including ion channel alterations that
prolong action potential duration, impair cellular calcium handling,
and diminish cellular coupling. These processes occur in a wide vari
ety of diseases associated with depressed ventricular function and/or
hypertrophy, including CAD, valvular heart disease, myocarditis, and
nonischemic cardiomyopathies.
Absence of Structural Heart Disease
In the absence of structural
heart disease, VF can be due to an inherited ion channel abnormality,
as in long QT and Brugada syndromes (Chap. 262), rapid atrial fibrilla
tion associated with Wolff-Parkinson-White syndrome (Chap. 256), or
drug toxicities, such as polymorphic VT due to drugs that prolong the
QT interval (Chap. 263). Blunt, nonpenetrating precordial impact over
the (left) chest wall can lead to commotio cordis and is a rare cause of
SCD in otherwise healthy individuals. PEA can result from pulmonary
emboli, exsanguination, or the terminal phase of respiratory arrest.
MANAGEMENT OF CARDIAC ARREST
As the ability to predict SCA in the population is very limited, com
munity approaches to reduce death focus on the rapid identification
of victims and implementation of resuscitation measures by those
who first encounter the victim, most likely the lay public, who ide ally summon EMS and initiate basic life-support measures with chest compressions. The approach is codified in the “out-of-hospital chain of survival,” which includes: (1) initial evaluation and recognition of the SCA and activation of the emergency response system; (2) rapid initiation of cardiopulmonary resuscitation (CPR) with an emphasis on chest compressions; (3) defibrillation as quickly as possible usually with an automatic external defibrillation applied by the lay rescuer or emergency medical technician (EMT); (4) advanced life support; (5) postcardiac arrest care; and (6) recovery from cardiac arrest. There have been major advances in each of these areas, and survival rates to hospital discharge for out-of-hospital cardiac arrest have increased, particularly for patients found in VT or VF, where survival rates can approach 30% in some regions. Overall survival rates for out-of-hospital cardiac arrest are also higher for patients receiving CPR, with recent studies in Europe reporting survival rates of 16%. Multiple studies have pointed to socioeconomic disparities in the administration of CPR and application of automatic external defibrillators (AEDs) contributing to reduced survival rates from out-of-hospital cardiac arrest in black and Hispanic populations in the United States.
PART 8 Critical Care Medicine The initial goal of resuscitation is to achieve the return of spon taneous circulation (ROSC). Success is strongly related to the time between collapse and initiation of resuscitation, decreasing markedly after 5 min, and the rhythm at the time of EMT arrival, being best for VT, worse for VF, and poor for PEA and asystole. Outcomes are also determined by the age, clinical state, and comorbidities of the victim prior to the arrest. ■ ■INITIAL EVALUATION AND INITIATION OF CPR The rescuer should check for a response from the victim, shout for help, and call or ask someone else to call their local emergency number (e.g., 911), ideally on a cell phone that can be placed on speaker mode at the patient’s side such that the responding dispatcher can provide instruc tions and queries to the rescuer. Consideration of aspiration or airway obstruction is important, and if suspected, a Heimlich maneuver may dislodge the obstructing body. A trained health care provider would also check for a pulse (taking no longer than 10 seconds so as not to delay initiation of chest compressions) and assess breathing. Gasping respirations and brief seizure activity are common during SCA and may be misinterpreted as breathing and responsiveness. Chest com pressions should be initiated without delay and administered at a rate of 100–120/min depressing the sternum by 5 cm (2 in.) and allowing full chest recoil between compressions. Chest compressions generate forward cardiac output with sequential filling and emptying of the car diac chambers, with competent valves maintaining forward direction of flow. Interruption of chest compressions should be minimized to reduce end-organ ischemia. Ventilation may be administered with two breaths for every 30 compressions if a trained rescuer is present, but for lay rescuers without training, chest compressions alone (“hands-only CPR”) are more likely to be effectively applied and of similar benefit. If a second rescuer is present, they should be sent to seek out an AED, which are now widely available in many public areas. ■ ■RHYTHM-BASED MANAGEMENT (SEE FIG. 317-2) The rapidity with which defibrillation/cardioversion is achieved is an important predictor of outcome. A defibrillator, most often an AED, should be applied as soon as available. AEDs are easily used by lay res cuers and trained first responders, such as police officers and trained security guards. When the arrest is witnessed, the use of AEDs by lay responders can improve cardiac arrest survival rates. Once patches are applied to the chest, a brief pause in chest compressions is required to allow the AED to record the rhythm. An AED will advise delivery of a shock if the recorded rhythm meets criteria for VF or VT. Chest compressions are continued while the defibrillator is being charged. As soon as a diagnosis of VF or VT is established, a 200-J biphasic waveform shock should be delivered. Chest compressions are resumed immediately and continue for 2 min until the next rhythm check. If VT/VF is still present, a second maximal energy shock is delivered. This sequence is continued until personnel to administer advanced life
support are available or ROSC is achieved. Electrocardiogram (ECG) rhythm strips produced by the AED should be retrieved, as the initial rhythm can be an important consideration in determining the cause of the arrest and to guide further therapy and evaluation if resuscitation is successful. When advanced cardiac life support is available, an intravenous line is established for administration of medication and consideration given to placement of an advanced airway (endotracheal tube or supraglottic airway device). Intraosseous access may be considered if attempts at intravenous access are not successful or are not feasible. Epinephrine 1 mg every 3–5 min may be administered intravenously or intraos seously. If circulation is not restored or the patient is less than fully conscious despite return of circulation, confirmation that acidosis and hypoxia are adequately addressed should be assessed with arte rial blood gas analysis. If metabolic acidosis persists after successful defibrillation and with adequate ventilation, 1 mEq/kg NaHCO3 may be administered. The cardiac rhythm guides resuscitation when monitoring is avail able. VT is treated with external shocks synchronized to the QRS when VT is monomorphic, and asynchronous shocks for polymorphic VT or VF. If VT/VF recurs after one or more shocks, amiodarone 300 mg can be administered as a bolus via intravenous or intraosseous route in the hope that arrhythmia recurrence will be prevented after the next shock, followed by a 150-mg bolus if the arrhythmia recurs. If amiodarone fails, lidocaine can be administered. Consideration of etiology should also guide therapy (Chaps. 261 and 262). Commonly encountered causes of recurrent VT/VF may be due to ongoing myocardial ischemia or infarction that would benefit from emergent coronary angiography and revascularization, or QT prolongation causing the polymorphic VT torsades des pointes that may respond to administration of magnesium. Hyperkalemia should respond to administration of calcium, while other measures are imple mented to reduce serum potassium. PEA/asystole should be managed with CPR, ventilation, and admin istration of epinephrine. Causes of PEA/asystole that require specific therapy should be considered including airway obstruction, hypoxia, hypovolemia, acidosis, hyperkalemia, hypothermia, toxins, cardiac tamponade, tension pneumothorax, pulmonary embolism, and MI. Naloxone should be administered if opiate overdose is suspected. ■ ■POSTCARDIAC ARREST ACUTE MANAGEMENT Following restoration of effective circulation, the possibility of acute MI should be immediately assessed. The majority of patients who have ST elevation consistent with acute MI will be found to have a culprit coronary stenosis/occlusion and emergent coronary angiography with percutaneous angioplasty, and stenting is recommended. Emergent angiography may also be considered if cardiogenic shock, electrical instability, signs of significant myocardial damage, or ongoing isch emia is present. Emergent or early angiography has not been found to result in better outcomes compared to delayed angiography in patients presenting with out-of-hospital cardiac arrest due to a VT/VF with no ECG evidence of ST-segment elevation. Thus, decisions regard ing which patients without ST-segment elevation should undergo urgent angiography are complex, and factors such as hemodynamic or electrical instability and evidence of ongoing ischemia are taken into consideration. Hemodynamic instability is often present following resuscitation, and further ischemic end-organ damage is a major consideration. Optimizing ventilation with consideration of acidosis, hypoxemia, and electrolyte abnormalities is important. Maintaining systolic blood pressure at >90 mmHg and mean blood pressure >65 mmHg is desir able and may require administration of vasopressors and adjustment of volume status. Potentially treatable reversible causes, including hyperkalemia, severe hypokalemia, and drug toxicity with QT prolon gation causing torsades des pointes, should be identified and treated (Chap. 262). After stable spontaneous circulation is achieved, brain injury due to ischemia and reperfusion is a major determinant of survival and accounts for over two-thirds of deaths. The probability of successful
Ventricular Fibrillation or Pulseless Ventricular Tachycardia Chest compressions at 100–120/min Immediate defibrillation and resume CPR for 2 min 2 min of chest compressions/ventilation and repeat shock Continue chest compressions, I.V. or I.O. access, advanced airway Epinephrine 1 mg q 3–5 min Repeat shock I.V. amiodarone 300 mg (may repeat 150 mg), continue CPR Repeat shock Monomorphic VT Polymorphic VT/VF Acute coronary syndrome: lidocaine, PCI Acquired long QT: Mg, transvenous pacing, isoproterenol. Brugada syndrome, idiopathic VF: isoporterenol, quinidine. lidocaine procainamide A Bradyarrhythmia/Asystole Pulseless Electrical Activity CPR, intubate, I.V. access [Assess pulse] [Confirm asystole] Identify and treat reversible causes
- Hypoxia
- Hyper-/hypokalemia
- Severe acidosis
- Drug overdose
- Hypothermia Epinephrine — 1 mg I.V. {repeat 3–5 min} For Bradycardia: Atropine 1 mg I.V. Pacing — external or pacing wire B FIGURE 317-2 Algorithm for approach to cardiac arrest due to ventricular tachycardia (VT) or ventricular fibrillation (VF; shockable rhythm). A. Chest compressions with ventilation and defibrillation or cardioversion should be initiated as soon as possible. Defibrillation should be repeated with minimal interruption of chest compressions. Once an intravenous or intraosseous access is established, administration of epinephrine defibrillation and amiodarone and defibrillation are performed. Further therapy can be guided by possible causes as suggested by the initial or recurrent cardiac rhythm as shown. CPR, cardiopulmonary resuscitation; I.O., intraosseous; I.V., intravenous; PCI, percutaneous coronary intervention; ROSC, return of spontaneous circulation. B. Algorithm for approach to cardiac arrest due to bradyarrhythmias/asystole and pulseless electrical activity. Chest compressions with ventilation (and intubation) should be initiated as soon as possible, and intravenous access should be obtained. Once an intravenous or intraosseous access is established, administration of epinephrine is performed. At the same time, an investigation for potential reversible causes should be made and any such causes should be treated if present. For bradycardic rhythms, atropine 1 mg administered intravenously and external subcutaneous or transvenous pacing are also performed. Defibrillation should be repeated with minimal interruption of chest compressions. Further therapy can be guided by possible causes. CPR, cardiopulmonary resuscitation; I.O., intraosseous; I.V., intravenous; M.I., myocardial infarction.
No ROSC No ROSC No ROSC CHAPTER 317 Specific therapies Sinusoidal VT Pulseless electrical activity Asystole Hyperkalemia: Ca, NaHCO3. Acute coronary syndrome Drug toxicity Cardiovascular Collapse, Cardiac Arrest, and Sudden Cardiac Death
- Pulmonary embolus
- Drug overdose
- Hyperkalemia
- Severeacidosis
- Massive acute M.I.
- Hypovolemia
- Hypoxia
- Tamponade
- Pneumothorax
- Hypothermia
neurologic recovery decreases rapidly with time from collapse to ROSC and is <30% at 5 min in the absence of bystander CPR. The time between collapse and restoration of circulation is generally imprecise, and some patients have a period of hypotensive VT prior to complete collapse, such that a reported long period before the arrival of rescu ers does not always preclude good neurologic recovery. Therapeutic hypothermia (targeted temperature management) has been shown to improve the likelihood of survival and neurologic recovery in patients who present with shockable (VT or VF) rhythms and is recom mended for all cardiac arrest patients who remain comatose, regard less of presenting rhythm, who have lack of purposeful response to verbal commands following ROSC. A constant target temperature of 32–37.5°C for at least 24 h is recommended, although a recent trial failed to demonstrate benefit compared with a strategy of targeted normothermia with early and aggressive treatment of fever. Shivering suppression with analgesics and sedatives may be needed. Induction of hypothermia should be started in the hospital, as no benefit was shown for implementation before hospital arrival, and administration of large volumes of cold saline for this purpose increased the risk of pulmonary edema. Brain injury is often accompanied by seizures and status epi lepticus that may have further deleterious effects, warranting periodic or continuous electroencephalography (EEG) monitoring. Treatment of clinically apparent seizures is indicated and may also be reasonable in those with EEG patterns on the ictal-interictal continuum on moni toring. Several other therapies hoped to improve postarrest outcomes have been assessed but have not been shown to be beneficial, including administration of corticosteroids, hemofiltration, and efforts to tightly control blood glucose.
PART 8 Critical Care Medicine Hypothermia and sedation preclude reliable prognostication for neurologic recovery. Functional neurologic assessment for neurologic recovery is generally deferred for at least 72 hours after return to nor mothermia, typically 4–5 days after the cardiac arrest. Features that predict poor outcome include the absence of pupillary reflex to light, status myoclonus, absence of EEG reactivity to external stimuli, and persistent burst suppression on EEG. ■ ■LONG-TERM MANAGEMENT AFTER SURVIVAL OF OUT-OF-HOSPITAL CARDIAC ARREST For patients who survive cardiac arrest and have neurologic recovery, the likely underlying cause of the arrest guides further treatment. For arrests not due to an obvious noncardiac cause, a full evaluation for the forms of structural heart disease outlined in Fig. 317-1 and Table 317-2 should be performed including an assessment for underlying CAD and ischemia as well as echocardiography and/or cardiac magnetic reso nance imaging (MRI) to look for evidence of prior MI, valvular disease, and nonischemic cardiomyopathies, and to provide an assessment of left ventricular ejection fraction (LVEF). If the initial evaluation is not definitive or is suggestive of an inflammatory cardiomyopathy (i.e., sarcoidosis, myocarditis), a cardiac positron emission tomography (PET) scan and/or endomyocardial biopsy may also be performed. Patients without obvious structural abnormalities should undergo an evaluation for primary electrical disease (long QT syndrome [LQTS], Brugada syndrome, early repolarization syndrome, or WolffParkinson-White syndrome). In cases where a heritable syndrome is suspected, further genetic evaluation should be considered. Diagnostic electrophysiology studies are warranted in selected patients to assess inducible arrhythmias, or provocative testing, such as with epinephrine challenge for LQTS, or sodium channel blocker (e.g., procainamide) challenge for Brugada syndrome. Patients with shockable rhythms at arrest (VF and VT) that are not deemed to have been due to a transient reversible cause and have reasonable life expectancy should undergo insertion of an ICD for sec ondary prevention of SCA/SCD. Most of these patients will be found to have CAD. Patients with a VF arrest that occurs within the first 48 h of a documented acute MI generally do not require an ICD because they have a similar risk of sudden death over the next 5 years as infarct survivors who did not have a cardiac arrest. However, patients who have a large infarction with acutely depressed LVEF (e.g., <35%) have an increased risk for future development of life-threatening ventricular
autonomic function and altered repolarization, and QRS prolonga tion. The majority of these tests, with the exception of the EP study in post-MI patients, broadly predict death from cardiovascular causes and are not able to discriminate between patients who will die suddenly from an arrhythmia and those who will die of other cardiac causes. For example, patients with the greatest degree of systolic HF and/or lowest LVEF, although at elevated risk for SCD, are more likely to die from pump failure. Although sustained VT at EP study does identify individuals at a higher risk of SCA versus non-SCA in certain subsets of patients, the sensitivity of the test is generally inadequate when LV function is significantly reduced. ■ ■PREVENTIVE THERAPIES FOR SCD IN
HIGH-RISK POPULATIONS Therapy with beta-adrenergic blockers has been demonstrated to reduce SCD risk in a multitude of settings, including after MI, among patients with ischemic and nonischemic cardiomyopathy, and in TABLE 317-3 Implantable Cardioverter Defibrillator (ICD) Indications ESC GUIDELINES Secondary Prevention All Disease States with VT or VF Cardiac arrest due to VF or hemodynamically unstable sustained VT after evaluation to define the cause of the event and to exclude any completely reversible causes Structural heart disease and spontaneous hemodynamically stable sustained VT Class IIa Class I B Structural heart disease and spontaneous hemodynamically not-tolerated sustained VT Class I Class I B Sustained VT and normal or near-normal ventricular function – Class IIa C Syncope Patients with syncope and inducible VT or VF at EP study – Class I B Patients with syncope and structural heart disease in whom invasive and noninvasive studies have failed to determine a cause Primary Prevention Coronary Artery Disease LVEF ≤35% + NYHA functional class II–III Class I Class I A LVEF ≤35% (ESC) + NYHA functional class I Class IIa – B LVEF ≤30% (AHA) + NYHA functional class I – Class I A LVEF ≤40% + NSVT + inducible monomorphic VT Class IIa Class I B LVEF ≤40% + unexplained syncope + inducible monomorphic VT Class IIa Class I B Nonischemic Cardiomyopathy LVEF ≤35% + NYHA functional class II–II Class IIa Class I A LVEF ≤35% + NYHA functional class I – Class IIb B Pathogenic mutation in LMNA gene + 2 or more risk factors (NSVT, LVEF <45%, nonmissense mutation, male sex) – Class IIa C LMNA mutation with estimated 5-year risk of VA ≥10% + NSVT or LVEF <50% or AV conduction delay Class IIa – C LVEF >35% and ≥ 2 risk factors (syncope, LGE on CMR, inducible VT at PES, pathogenic mutations in PLN, FLNC, and RBM20 genes) NYHA Functional Class IV Candidates for Advanced Heart Failure Therapy Awaiting cardiac transplant Class IIa Class IIa C With destination LVAD and sustained VT Class IIa – B With destination LVAD – Class IIa B Arrhythmogenic Right Ventricular Cardiomyopathy Arrhythmic syncope Class IIa Class IIa B Moderate right (<40%) or left (<45%) ventricular dysfunction and NSVT or inducible monomorphic VT Class IIa – C Significant right ventricular dysfunction with LVEF ≤35% – Class I B Significant right ventricular dysfunction with RVEF ≤35% Class IIa Class I C Hypertrophic Cardiomyopathy Maximum left ventricular wall thickness >30 mm – Class IIa B SCD in first-degree relative presumably due to HCM – Class IIa B Unexplained syncope – Class IIa B NSVT or abnormal blood pressure response during exercise + additional SCD risk modifiers or high-risk features
LQTS. Angiotensin-converting enzyme inhibitors, aldosterone antago nists, and more recently angiotensin receptor/neprilysin inhibitors and sodium-glucose cotransporter 2 inhibitors (SGLT2i) have been associated with reductions in SCD in subsets of patients with structural heart disease, primarily ischemic and nonischemic cardiomyopathy accompanied by HF. Coronary artery bypass grafting has also been associated with reductions in SCD risk, and revascularization may lower SCD risk through reduction in ischemic events and resultant improvements in left ventricular systolic function by reducing areas of hibernating myocardium.
For patients whose disease continues to confer a substantial risk
of sustained VT or VF on optimal medical therapy, an ICD is rec
ommended (Table 317-3). The ICD indication in these patients is
referred to as “primary prevention of sudden death.” The indications
for primary prevention ICDs vary depending on the type of underlying
structural heart disease and its severity, and the strength of evidence
varies by indication. In some cases, there are slight differences in the
CHAPTER 317
AHA/ACC/HRS
GUIDELINES
LEVEL OF
EVIDENCE
Cardiovascular Collapse, Cardiac Arrest, and Sudden Cardiac Death
Class I
Class I
A
–
Class IIb
C
Class IIa
–
C
–
Class IIa
C
(Continued)
TABLE 317-3 Implantable Cardioverter Defibrillator (ICD) Indications ESC GUIDELINES NSVT or abnormal blood pressure response during exercise without additional SCD risk modifiers or high-risk features Estimated 5-year risk of sudden death based on the HCM Risk–SCD Calculator ≥6% Class IIa – B Estimated 5-year risk of sudden death based on HCM Risk–SCD Calculator (≥4 to <6%) AND Class IIa – B Significant LGE on CMR or LVEF <50% or Abnormal blood pressure during exercise test or Left ventricular apical aneurysm or Presence of sarcomeric pathogenic mutation Estimated 5-year risk of sudden death based on the HCM Risk–SCD Calculator ≥4 to <6% Class IIb – B Estimated 5-year risk of sudden death based on the HCM Risk–SCD Calculator <4% AND Class IIb – B Significant LGE on CMR or PART 8 Critical Care Medicine LVEF <50% or Left ventricular apical aneurysm Congenital Long QT Syndrome Symptomatic high-risk patients + ineffectiveness or intolerance of β-blocker therapy (high risk: QTc >500 ms, genotypes LQTS 2 and LQTS 3, LQTS 2 females, age <40 years, onset of symptoms <10 years, recurrent syncope) Unexplained syncope during β-blocker and genotype-specific therapy Class I – B Symptomatic patients + intolerance or contraindication of β-blocker and genotype-specific therapy Class IIa – B Asymptomatic patients with QTc >500 ms during β-blocker treatment – Class IIb B Asymptomatic patients with high-risk profile according to 1-2-3- LQTS-Risk calculator Class IIb – Catecholaminergic Polymorphic Ventricular Tachycardia (CPVT) Syncope during β-blocker treatment – Class I C Syncope during combined β-blocker and flecainide treatment Class IIa – C Brugada Syndrome Spontaneous type 1 Brugada ECG + recent history of syncope presumed due to ventricular arrhythmia Class IIa Class I C Asymptomatic patients with type 1 Brugada ECG and inducible ventricular fibrillation Class IIb – C Cardiac Sarcoidosis Cardiac sarcoidosis with 1 or more risk factors for SCD – Class IIa C Indication for permanent pacemaker implantation regardless of LVEF Class IIa – C LVEF >35% and significant LGE on CMR after resolution of acute inflammation Class IIa – C LVEF 35–50% and inducible VT at PES Class IIa – C Familial Cardiomyopathy Patients with familial cardiomyopathy associated with SCD – Class IIb C Left Ventricular Noncompaction Patients with left ventricular noncompaction – Class IIb C Abbreviations: ACC, American College of Cardiology; AHA, American Heart Association; AV, atrioventricular; CMR, cardiac magnetic resonance; ECG, electrocardiogram; EP, electrophysiologic; ESC, European Society of Cardiology; HCM, hypertrophic cardiomyopathy; HRS, Heart Rhythm Society; LGE, late gadolinium enhancement; LQTS, long QT syndrome; LVAD, left ventricular assist device; LVEF, left ventricular ejection fraction; NSVT, nonsustained ventricular tachycardia; NYHA, New York Heart Association; PES, programmed electrical stimulation; RVEF, right ventricular ejection fraction; SCD, sudden cardiac death; VA, ventricular arrhythmia; VF, ventricular fibrillation; VT, ventricular tachycardia. strength of recommendation among professional societies in Europe and America for implantation of an ICD, but overall, there is agree ment on ICD implantation for the highest-risk patients. In patients with a history of MI >40 days ago, primary prevention ICDs are indi cated for those with class II–III New York Heart Association (NYHA) HF and LVEF <35% and those who are NYHA functional class I with LVEF <30%. Although ICDs have not been found to be beneficial when implanted within 40 days of an MI, those with recent or old MI, non sustained VT, LVEF <40%, and inducible sustained VT at EP study also warrant an ICD. In general, these criteria are not applied to patients who are within 90 days of myocardial revascularization, since some will experience improvement in ventricular function and older trial data suggested there was no benefit with ICDs in these patients. High-risk patients with low LVEFs may be considered for a wearable defibrillator with later reassessment of ventricular function and ICD placement. ICDs for primary prevention of sudden death are also recom mended for patients with diseases other than CAD that put them
(Continued) AHA/ACC/HRS GUIDELINES LEVEL OF EVIDENCE – Class IIb C – Class I B at risk for SCD. Primary prevention ICDs are currently indicated in select high-risk patients with HCM, arrhythmogenic right ventricular dysplasia, cardiac sarcoidosis, Brugada syndrome, and congenital LQTS. ICDs are currently also recommended for those with nonisch emic dilated cardiomyopathy (DCM) who have an LVEF ≤35% and who have NYHA functional class II or III symptoms on guidelinedirected medical therapy. In addition to invasive electrophysiologic testing, new risk stratification methods for certain conditions have emerged, including genetic findings and the presence of late gado linium enhancement (LGE) on MRI. For example, the European guidelines account for pathogenic mutations associated with a high risk of ventricular arrhythmias in patients with nonischemic cardio myopathy, hypertrophic cardiomyopathy, and long QT syndrome. The presence of LGE has been shown to be a risk factor for sudden death in patients with cardiac sarcoidosis and hypertrophic cardiomyopa thy, and thus, this imaging finding has been incorporated into ICD implantation guidelines.
TABLE 317-4 Implantable Cardioverter Defibrillator (ICD) Not Indicated Patients who do not have a reasonable expectation of survival with an acceptable functional status for at least 1 year, even if they meet ICD implantation criteria. Patients with incessant VT or VF. Patients with significant psychiatric illnesses that may be aggravated by device implantation or that may preclude systematic follow-up. Patients with drug-refractory New York Heart Association class IV congestive heart failure who are not candidates for cardiac transplantation or cardiac resynchronization therapy. Syncope of undetermined cause in a patient without inducible ventricular tachyarrhythmias and without structural heart disease. VF or VT is amenable to surgical or catheter ablation in patients
without other disease predisposing to sudden cardiac arrest (e.g., atrial arrhythmias associated with Wolff-Parkinson-White syndrome, RV or LV
outflow tract VT, idiopathic VT, or fascicular VT in the absence of structural heart disease). Patients with ventricular tachyarrhythmias due to a completely reversible disorder in the absence of structural heart disease (e.g., electrolyte imbalance, drugs, or trauma). Abbreviations: LV, left ventricular; RV, right ventricular; VF, ventricular fibrillation; VT, ventricular tachycardia. Source: Adapted from H Könemann et al: Management of ventricular arrhythmias worldwide: comparison of the latest ESC, AHA/ACC/HRS, and CCS/CHRS guidelines. JACC Clin Electrophysiol 9:715, 2023. Proportion of Sudden Cardiac Death by Clinical Subgroups Sustained VT/VF 5% Patients treated with ICDs LVEF <30–35% 15% A Absolute Risk of Sudden Cardiac Death by Clinical Subgroups 7.2% SCD Rate Per Year (%) 3%Year: 6.0% 3.0% Threshold for ICD Demonstrate benefit 1.5% 1.5% Sustained VT/VF Arrest Ischemic CM, LVEF<30% (MADIT) B FIGURE 317-3 A. Proportion of sudden cardiac deaths that occur in clinical subgroups of the population treated and not treated with implantable cardioverter defibrillators (ICDs). B. Absolute risk of sudden cardiac death within clinical subgroups in comparison to the threshold of risk where ICDs demonstrated benefit.
Although the ICD is very effective for treatment of arrhythmic sudden death, competing causes of mortality must be considered in patients with severe cardiomyopathy. Data from a recent random ized trial, the Danish Study to Assess the Efficacy of ICDs in Patients with Non-ischemic Systolic Heart Failure on Mortality (DANISH), performed in patients with nonischemic DCM and LVEF ≤35%, who also had elevated N-terminal pro-B-type natriuretic peptide levels and NYHA class II–IV HF, have resulted in some debate regarding the utility of ICDs in this population. This trial did not demonstrate an overall mortality benefit of the ICD despite a reduction in the inci dence of SCD. In subgroup analyses, mortality benefits were observed in younger patients in whom the competing risk of dying from other causes of death was lower. These data underscore the importance of considering competing risks for other causes of mortality when decid ing to implant a primary prevention ICD. Patients who are likely to die from other causes are unlikely to benefit from an ICD. Patients who do not have a reasonable expectation of survival with an acceptable functional status for at least 1 year should not undergo ICD placement. There are also other circumstances where an ICD is not indicated even if there is a significant sudden death risk (Table 317-4).
CHAPTER 317
■
■THE CHALLENGE OF SCD PREVENTION
(FIG. 317-3)
Cardiovascular Collapse, Cardiac Arrest, and Sudden Cardiac Death
The Greatest Number of Sudden Deaths Occur in “LowRisk” Patients
While patients with reduced left ventricular
Post-MI, CHD,
CM, or HF with
LVEF>35%
Other
80%
No known heart
disease
50%
1.0%
0.8%
0.08%
General
Population
POST-MI,
LVEF>35%
Multiple
Cardiac
Risk Factors
Heart Failure
with
Preserved
Ejection
Fraction
(HFPEF)
Ischemic +
Non-Ischemic
CM, LVEF
≤35%, NYHA
HF Class II-III
(SCD-HEFT)
Non-Ischemic
CM, LVEF
≤35% NYHA
HF Class IIIV, NTproBNP>200
(DANISH Trial)
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