Cardiac arrest (also known as sudden cardiac arrest ''SCA is when the heart suddenly and unexpectedly stops beating. When the heart stops beating, blood cannot properly circulate around the body and the blood flow to the brain and other organs is decreased. When the brain does not receive enough blood, this can cause a person to lose consciousness and brain cells can start to die due to lack of oxygen.

Coma A coma is a deep state of prolonged unconsciousness in which a person cannot be awakened, fails to Nociception, respond normally to Pain, painful stimuli, light, or sound, lacks a normal Circadian rhythm, sleep-wake cycle and does not initiate ...

and

persistent vegetative state A vegetative state (VS) or post-coma unresponsiveness (PCU) is a disorder of consciousness in which patients with severe brain damage are in a state of partial arousal rather than true awareness. After four weeks in a vegetative state, the patie ...

may result from cardiac arrest. Cardiac arrest is also identified by a lack of central pulses and abnormal or absent breathing. Cardiac arrest and resultant hemodynamic collapse often occur due to

arrhythmia Arrhythmias, also known as cardiac arrhythmias, are irregularities in the cardiac cycle, heartbeat, including when it is too fast or too slow. Essentially, this is anything but normal sinus rhythm. A resting heart rate that is too fast – ab ...

s (irregular heart rhythms).

Ventricular fibrillation Ventricular fibrillation (V-fib or VF) is an abnormal heart rhythm in which the Ventricle (heart), ventricles of the heart Fibrillation, quiver. It is due to disorganized electrical conduction system of the heart, electrical activity. Ventricula ...

and

ventricular tachycardia Ventricular tachycardia (V-tach or VT) is a cardiovascular disorder in which fast heart rate occurs in the ventricles of the heart. Although a few seconds of VT may not result in permanent problems, longer periods are dangerous; and multiple ...

are most commonly recorded. However, as many incidents of cardiac arrest occur out-of-hospital or when a person is not having their cardiac activity monitored, it is difficult to identify the specific mechanism in each case.

Structural heart disease Structural heart disease, also known as structural cardiac disease, is a collection of heart diseases that includes heart failure, coronary artery disease, hypertrophic cardiomyopathy, and congenital heart disease A congenital heart defect (CHD ...

, such as

coronary artery disease Coronary artery disease (CAD), also called coronary heart disease (CHD), or ischemic heart disease (IHD), is a type of cardiovascular disease, heart disease involving Ischemia, the reduction of blood flow to the cardiac muscle due to a build-up ...

, is a common underlying condition in people who experience cardiac arrest. The most common risk factors include age and cardiovascular disease. Additional underlying cardiac conditions include

heart failure Heart failure (HF), also known as congestive heart failure (CHF), is a syndrome caused by an impairment in the heart's ability to Cardiac cycle, fill with and pump blood. Although symptoms vary based on which side of the heart is affected, HF ...

and inherited

arrhythmias Arrhythmias, also known as cardiac arrhythmias, are irregularities in the heartbeat, including when it is too fast or too slow. Essentially, this is anything but normal sinus rhythm. A resting heart rate that is too fast – above 100 beats ...

. Additional factors that may contribute to cardiac arrest include major

blood loss Bleeding, hemorrhage, haemorrhage or blood loss, is blood escaping from the circulatory system from damaged blood vessels. Bleeding can occur internally, or externally either through a natural opening such as the mouth, nose, ear, urethra, v ...

, lack of oxygen, electrolyte disturbance (such as very low potassium),

electrical injury An electrical injury (electric injury) or electrical shock (electric shock) is damage sustained to the skin or internal organs on direct contact with an electric current. The injury depends on the density of the current, tissue resistance an ...

, and intense physical exercise. Cardiac arrest is diagnosed by the inability to find a pulse in an unresponsive patient. The goal of treatment for cardiac arrest is to rapidly achieve

return of spontaneous circulation Return of spontaneous circulation (ROSC) is the resumption of a sustained heart rhythm that perfuses the body after cardiac arrest. It is commonly associated with significant respiratory effort. Signs of return of spontaneous circulation include b ...

using a variety of interventions including

CPR Cardiopulmonary resuscitation (CPR) is an emergency procedure used during cardiac or respiratory arrest that involves chest compressions, often combined with artificial ventilation, to preserve brain function and maintain circulation until sp ...

defibrillation Defibrillation is a treatment for life-threatening cardiac arrhythmias, specifically ventricular fibrillation (V-Fib) and non-perfusing ventricular tachycardia (V-Tach). Defibrillation delivers a dose of electric current (often called a ''count ...

or cardiac pacing. Two protocols have been established for CPR:

basic life support Basic life support (BLS) is a level of medical care which is used for patients with life-threatening condition of cardiac arrest until they can be given full medical care by advanced life support providers (paramedics, nurses, physicians or any ...

(BLS) and advanced cardiac life support (ACLS). If return of spontaneous circulation is achieved with these interventions, then sudden cardiac arrest has occurred. By contrast, if the person does not survive the event, this is referred to as sudden cardiac death. Among those whose pulses are re-established, the care team may initiate measures to protect the person from brain injury and preserve neurological function. Some methods may include airway management and mechanical ventilation, maintenance of blood pressure and end-organ perfusion via fluid resuscitation and vasopressor support, correction of electrolyte imbalance, EKG monitoring and management of reversible causes, and temperature management.

Targeted temperature management Targeted temperature management (TTM), previously known as therapeutic hypothermia or protective hypothermia, is an active treatment that tries to achieve and maintain a specific body temperature in a person for a specific duration of time in an ...

may improve outcomes. In post-resuscitation care, an

implantable cardiac defibrillator An implantable cardioverter-defibrillator (ICD) or automated implantable cardioverter defibrillator (AICD) is a device implantable inside the body, able to perform defibrillation, and depending on the type, cardioversion and pacing of the h ...

may be considered to reduce the chance of death from recurrence. Per the 2015 American Heart Association Guidelines, there were approximately 535,000 incidents of cardiac arrest annually in the United States (about 13 per 10,000 people). Of these, 326,000 (61%) experience cardiac arrest outside of a hospital setting, while 209,000 (39%) occur within a hospital. Cardiac arrest becomes more common with age and affects males more often than females. In the United States, black people are twice as likely to die from cardiac arrest as white people. Asian and Hispanic people are not as frequently affected as white people.

Signs and symptoms

Cardiac arrest is not preceded by any warning symptoms in approximately 50 percent of people. For individuals who do experience symptoms, the symptoms are usually nonspecific to the cardiac arrest. For example, new or worsening

chest pain Chest pain is pain or discomfort in the chest, typically the front of the chest. It may be described as sharp, dull, pressure, heaviness or squeezing. Associated symptoms may include pain in the shoulder, arm, upper abdomen, or jaw, along with n ...

fatigue Fatigue is a state of tiredness (which is not sleepiness), exhaustion or loss of energy. It is a signs and symptoms, symptom of any of various diseases; it is not a disease in itself. Fatigue (in the medical sense) is sometimes associated wit ...

blackout Blackout(s), black out, or The Blackout may refer to: Loss of lighting or communication * Power outage, a loss of electric power * Blackout (broadcasting), a regulatory or contractual ban on the broadcasting of an event * Blackout (fabric), a t ...

dizziness Dizziness is an imprecise term that can refer to a sense of disorientation in space, vertigo, or lightheadedness. It can also refer to Balance disorder, disequilibrium or a non-specific feeling, such as giddiness or foolishness. Dizziness is a ...

shortness of breath Shortness of breath (SOB), known as dyspnea (in AmE) or dyspnoea (in BrE), is an uncomfortable feeling of not being able to breathe well enough. The American Thoracic Society defines it as "a subjective experience of breathing discomfort that con ...

weakness Weakness is a symptom of many different medical conditions. The causes are many and can be divided into conditions that have true or perceived muscle weakness. True muscle weakness is a primary symptom of a variety of skeletal muscle diseases, ...

, or

vomiting Vomiting (also known as emesis, puking and throwing up) is the forceful expulsion of the contents of one's stomach through the mouth and sometimes the nose. Vomiting can be the result of ailments like food poisoning, gastroenteritis, pre ...

. When cardiac arrest is suspected by a layperson (due to signs of unconsciousness, abnormal breathing or no pulse) it should be assumed that the victim is in cardiac arrest. Bystanders should call

emergency medical services Emergency medical services (EMS), also known as ambulance services, pre-hospital care or paramedic services, are emergency services that provide urgent pre-hospital treatment and stabilisation for serious illness and injuries and transport to d ...

(such as 911, 999 or 112) and initiate

Risk factors

Major risk factors for cardiac arrest include age and underlying

cardiovascular disease Cardiovascular disease (CVD) is any disease involving the heart or blood vessels. CVDs constitute a class of diseases that includes: coronary artery diseases (e.g. angina, heart attack), heart failure, hypertensive heart disease, rheumati ...

. A prior episode of sudden cardiac arrest increases the likelihood of future episodes. A 2021 meta-analysis assessing the recurrence of cardiac arrest in out-of-hospital cardiac arrest survivors identified that 15% of survivors experienced a second event, most often in the first year. Furthermore, of those who experienced recurrence, 35% had a third episode. Additional significant risk factors include

cigarette smoking Tobacco smoking is the practice of burning tobacco and ingesting the resulting smoke. The smoke may be inhaled, as is done with cigarettes, or released from the mouth, as is generally done with pipes and cigars. The practice is believed to hav ...

high blood pressure Hypertension, also known as high blood pressure, is a long-term medical condition in which the blood pressure in the arteries is persistently elevated. High blood pressure usually does not cause symptoms itself. It is, however, a major ri ...

high cholesterol Hypercholesterolemia, also called high cholesterol, is the presence of high levels of cholesterol in the blood. It is a form of hyperlipidemia (high levels of lipids in the blood), hyperlipoproteinemia (high levels of lipoproteins in the blood), ...

, history of

, lack of

physical exercise Exercise or workout is physical activity that enhances or maintains fitness and overall health. It is performed for various reasons, including weight loss or maintenance, to aid growth and improve strength, develop muscles and the cardio ...

obesity Obesity is a medical condition, considered by multiple organizations to be a disease, in which excess Adipose tissue, body fat has accumulated to such an extent that it can potentially have negative effects on health. People are classifi ...

diabetes Diabetes mellitus, commonly known as diabetes, is a group of common endocrine diseases characterized by sustained high blood sugar levels. Diabetes is due to either the pancreas not producing enough of the hormone insulin, or the cells of th ...

family history Genealogy () is the study of families, family history, and the tracing of their lineages. Genealogists use oral interviews, historical records, genetic analysis, and other records to obtain information about a family and to demonstrate kins ...

cardiomyopathy Cardiomyopathy is a group of primary diseases of the heart muscle. Early on there may be few or no symptoms. As the disease worsens, shortness of breath, feeling tired, and swelling of the legs may occur, due to the onset of heart failure. A ...

alcohol Alcohol may refer to: Common uses * Alcohol (chemistry), a class of compounds * Ethanol, one of several alcohols, commonly known as alcohol in everyday life ** Alcohol (drug), intoxicant found in alcoholic beverages ** Alcoholic beverage, an alco ...

use, and possibly caffeine intake. Current cigarette smokers with coronary artery disease were found to have a two to threefold increase in the risk of sudden death between ages 30 and 59. Furthermore, it was found that former smokers' risk was closer to that of those who had never smoked. A statistical analysis of many of these risk factors determined that approximately 50% of all cardiac arrests occur in 10% of the population perceived to be at greatest risk, due to aggregate harm of multiple risk factors, demonstrating that cumulative risk of multiple comorbidities exceeds the sum of each risk individually.

Causes and mechanisms

Basic representation of cardiac conduction

The underlying causes of sudden cardiac arrest can result from cardiac and non-cardiac causes. The most common underlying causes are different, depending on the patient's age. Common cardiac causes include

, non-atherosclerotic coronary artery abnormalities, structural heart damage, and inherited arrhythmias. Common non-cardiac causes include respiratory arrest, diabetes, medications, and trauma. The most common mechanism underlying sudden cardiac arrest is an arrhythmia (an irregular rhythm). Without organized

electrical activity Electricity is the set of physical phenomena associated with the presence and motion of matter possessing an electric charge. Electricity is related to magnetism, both being part of the phenomenon of electromagnetism, as described by Maxwel ...

in the

heart muscle Cardiac muscle (also called heart muscle or myocardium) is one of three types of vertebrate muscle tissues, the others being skeletal muscle and smooth muscle. It is an involuntary, striated muscle that constitutes the main tissue of the wall of ...

, there is inconsistent contraction of the ventricles, which prevents the heart from generating adequate

cardiac output In cardiac physiology, cardiac output (CO), also known as heart output and often denoted by the symbols Q, \dot Q, or \dot Q_ , edited by Catherine E. Williamson, Phillip Bennett is the volumetric flow rate of the heart's pumping output: tha ...

(forward pumping of blood from the heart to the rest of the body). This hemodynamic collapse results in poor blood flow to the brain and other organs, which if prolonged causes persistent damage. There are many different types of arrhythmias, but the ones most frequently recorded in sudden cardiac arrest are

and ventricular fibrillation. Both ventricular tachycardia and ventricular fibrillation can prevent the heart from generating coordinated ventricular contractions, thereby failing to sustain adequate blood circulation. Less common types of arrhythmias occurring in cardiac arrest include pulseless electrical activity, bradycardia, and asystole. These rhythms are seen when there is prolonged cardiac arrest, progression of ventricular fibrillation, or efforts like defibrillation executed to resuscitate the person.

Cardiac causes

Coronary artery disease

Coronary artery disease (CAD), also known as atherosclerotic cardiovascular disease, involves the deposition of cholesterol and subsequent inflammation-driven formation of Atherosclerosis, atherosclerotic plaques in the arteries. CAD involves the accumulation and remodeling of the Coronary circulation, coronary vessels along with other systemic blood vessels. When an atherosclerotic plaque dislodges, it can block the flow of blood and oxygen through small arteries, such as the coronary arteries, resulting in Ischemia, ischemic injury. In the heart, this results in myocardial tissue damage which can lead to structural and functional changes that disrupt normal conduction patterns and alter heart rate and contraction. CAD underlies 68 percent of sudden cardiac deaths in the United States. Indeed, postmortem examinations have shown that the most common finding in cases of sudden cardiac death is chronic, high-grade stenosis of at least one segment of a major Coronary arteries, coronary artery. While CAD is a leading contributing factor, this is an age-dependent factor, with CAD being a less common cause of sudden cardiac death in people under the age of 40.

Non-atherosclerotic coronary artery abnormalities

Abnormalities of the coronary arteries not related to atherosclerosis include inflammation (known as coronary arteritis), embolism, vasospasm, mechanical abnormalities related to connective tissue diseases or trauma, and congenital Coronary artery anomaly, coronary artery anomalies (most commonly anomalous origin of the left coronary artery from the pulmonary artery). These conditions account for 10-15% of cardiac arrest and sudden cardiac death. * Coronary arteritis commonly results from a pediatric febrile inflammatory condition known as Kawasaki disease. Other types of vasculitis can also contribute to an increased risk of sudden cardiac death. * Embolism, or clotting, of the coronary arteries most commonly occurs from septic emboli secondary to endocarditis with involvement of the aortic valve, tricuspid valve, or prosthetic valves. * Coronary vasospasm may result in cardiac arrhythmias, altering the heart's electrical conduction with a risk of complete cardiac arrest from severe or prolonged rhythm changes. * Mechanical abnormalities with an associated risk of cardiac arrest may arise from coronary artery dissection, which can be attributed to Marfan syndrome or trauma.

Structural heart disease

Examples of structural heart diseases include: cardiomyopathy, cardiomyopathies (hypertrophic cardiomyopathy, hypertrophic, dilated cardiomyopathy, dilated, or Arrhythmogenic cardiomyopathy, arrhythmogenic), Cardiac arrhythmia, cardiac rhythm disturbances, myocarditis, and congestive heart failure. Left Ventricular Hypertrophy Unlabeled

Left ventricular hypertrophy is a leading cause of sudden cardiac deaths in the adult population. This is most commonly the result of longstanding

, or hypertension, which has led to maladaptive overgrowth of muscular tissue of the Ventricle (heart), left ventricle, the heart's main pumping chamber. This is because elevated blood pressure over the course of several years requires the heart to adapt to the requirement of pumping harder to adequately circulate blood throughout the body. If the heart does this for a prolonged period of time, the left ventricle can experience hypertrophy (grow larger) in a way that decreases the heart's effectiveness. Left ventricular hypertrophy can be demonstrated on an Echocardiography, echocardiogram and Electrocardiography, electrocardiogram (EKG). Abnormalities of the cardiac conduction system (notably the atrioventricular node and Purkinje fibers, His-Purkinje system) may predispose an individual to arrhythmias with a risk of progressing to sudden cardiac arrest, albeit this risk remains low. Many of these conduction blocks can be treated with internal cardiac defibrillators for those determined to be at high risk due to severity of fibrosis or severe electrophysiologic disturbances. Structural heart diseases unrelated to coronary artery disease account for 10% of all sudden cardiac deaths. A 1999 review of sudden cardiac deaths in the United States found that structural heart diseases accounted for over 30% of sudden cardiac arrests for those under 30 years.

Inherited arrhythmia syndromes

Arrhythmias not due to structural heart disease account for 5 to 10% of sudden cardiac arrests. These are frequently caused by genetic disorders. The genetic mutations often affect specialized proteins known as ion channels that conduct Ion, electrically charged particles across the cell membrane, and this group of conditions is therefore often referred to as Channelopathy, channelopathies. Examples of these inherited arrhythmia syndromes include long QT syndrome (LQTS), Brugada syndrome (BrS), catecholaminergic polymorphic ventricular tachycardia (CPVT), and short QT syndrome (SQTS). Many are also associated with environmental or neurogenic triggers such as response to loud sounds that can initiate lethal arrhythmias. LQTS, a condition often mentioned in young people's deaths, occurs in one of every 5000 to 7000 newborns and is estimated to be responsible for 3000 deaths annually compared to the approximately 300,000 cardiac arrests seen by emergency services. These conditions are a fraction of the overall deaths related to cardiac arrest but represent conditions that may be detected prior to arrest and may be treatable. The symptomatic expression of LQTS is quite broad and more often presents with Syncope (medicine), syncope rather than cardiac arrest. The risk of cardiac arrest is still present, and people with family histories of sudden cardiac arrests should be screened for LQTS and other treatable causes of lethal arrhythmia. Higher levels of risk for cardiac arrest are associated with female sex, more significant QT prolongation, history of unexplained syncope (fainting spells), or premature sudden cardiac death. Additionally, individuals with LQTS should avoid certain medications that carry the risk of increasing the severity of this conduction abnormality, such as certain anti-arrhythmics, anti-depressants, and Quinolone antibiotic, quinolone or macrolide antibiotics. Although it is not recognized as an inherited condition, Wolff–Parkinson–White syndrome in which an accessory conduction pathway bypassing the atrioventricular node is present and can cause abnormal conduction patterns leading to supraventricular tachycardia, pre-excited atrial fibrillation, and cardiac arrest. Ebstein's anomaly has an increased risk of accessory pathways as well.

Non-cardiac causes

Non-cardiac causes account for 15 to 25% of cardiac arrests. Common non-cardiac causes include respiratory arrest,

, certain medications, and blunt trauma (especially to the chest). * Respiratory arrest will be followed by cardiac arrest unless promptly treated. Respiratory arrest can be caused by pulmonary embolus, choking, drowning, trauma, drug overdose, and poisoning. Pulmonary embolus carries a high mortality rate and may be the triggering cause for up to 5% of cardiac arrests, according to a retrospective study from an urban tertiary care emergency department. * Diabetes-related factors contributing to cardiac arrest include silent myocardial ischemia, nervous system dysfunction, and electrolyte disturbances leading to abnormal cardiac repolarization. * Certain medications can worsen an existing arrhythmia. Some examples include antibiotics like macrolides, diuretics, and heart medications such as anti-arrhythmic medications. Additional non-cardiac causes include Bleeding, hemorrhage, aortic rupture, hypovolemic shock, pulmonary embolism, poisoning such as from the Jellyfish#Toxicity, stings of certain jellyfish, and

. Circadian patterns are also recognized as triggering factors in cardiac arrest. Per a 2021 systematic review, throughout the day there are two main peak times in which cardiac arrest occurs. The first is in the morning hours and the second is in the afternoon. Moreover, survival rates following cardiac arrest were lowest when occurring between midnight and 6am. Many of these non-cardiac causes of cardiac arrest are reversible. A common mnemonic used to recall the reversible causes of cardiac arrest is referred to as the Hs and Ts. The Hs are hypovolemia, Hypoxia (medicine), hypoxia, hydrogen cation excess (acidosis), hyperkalemia, hypokalemia, hypothermia, and hypoglycemia. The Ts are toxins, (cardiac) Cardiac tamponade, tamponade, Pneumothorax, tension pneumothorax, thrombosis (myocardial infarction), Thrombosis, thromboembolism, and trauma.

Mechanism

The definitive electrical mechanisms of cardiac arrest, which may arise from any of the functional, structural, or physiologic abnormalities mentioned above, are characterized by arrhythmias.

and pulseless or sustained

are the most commonly recorded arrhythmias preceding cardiac arrest. These are rapid and erratic arrhythmias that alter the circulatory pathway such that adequate blood flow cannot be sustained and is inadequate to meet the body's needs. The mechanism responsible for the majority of sudden cardiac deaths is ventricular fibrillation. Ventricular fibrillation is a tachyarrhythmia characterized by turbulent electrical activity in the ventricular myocardium leading to a heart rate too disorganized and rapid to produce any meaningful cardiac output, thus resulting in insufficient perfusion of the brain and essential organs. Some of the electrophysiologic mechanisms underpinning ventricular fibrillations include ectopic automaticity, re-entry, and triggered activity. However, structural changes in the diseased heart as a result of inherited factors (mutations in ion-channel coding genes, for example) cannot explain the sudden onset of cardiac arrest. In ventricular tachycardia, the heart also beats faster than normal, which may prevent the heart chambers from properly filling with blood. Ventricular tachycardia is characterized by an altered QRS complex and a heart rate greater than 100 beats per minute. When V-tach is sustained (lasts for at least 30 seconds), inadequate blood flow to heart tissue can lead to cardiac arrest. Bradycardia, Bradyarrhythmias occur following dissociation of spontaneous electrical conduction and the mechanical function of the heart resulting in pulseless electrical activity (PEA) or through complete absence of electrical activity of the heart resulting in asystole. Similar to the result of tachyarrhythmias, these conditions lead to an inability to sustain adequate cardiac output.

Diagnosis

Cardiac arrest is synonymous with clinical death. The physical examination to diagnose cardiac arrest focuses on the absence of a pulse. In many cases, lack of a pulse, central pulse (carotid arteries or subclavian arteries) is the gold standard (test), gold standard. Lack of a pulse in the periphery (radial/pedal) may also result from other conditions (e.g. Shock (circulatory), shock) or be the rescuer's misinterpretation. Obtaining a thorough history can help inform the potential cause and prognosis. The provider taking the person's clinical history should try to learn whether the episode was observed by anyone else, when it happened, what the patient was doing (in particular whether there was any trauma), and whether drugs were involved. During resuscitation efforts, continuous monitoring equipment including EKG leads should be attached to the patient so that providers can analyze the electrical activity of the cardiac cycle and use this information to guide the management efforts. EKG readings will help to identify the arrhythmia present and allow the team to monitor any changes that occur with the administration of CPR and defibrillation. Clinicians classify cardiac arrest into "shockable" versus "non-shockable", as determined by the Electrocardiogram, EKG rhythm. This refers to whether a particular class of cardiac dysrhythmia is treatable using

. The two "shockable" rhythms are ventricular fibrillation and pulseless ventricular tachycardia, while the two "non-shockable" rhythms are asystole and pulseless electrical activity. Moreover, in the post-resuscitation patient, a 12-lead EKG can help identify some causes of cardiac arrest, such as STEMI which may require specific treatments. Emergency ultrasound, Point-of-care ultrasound (POCUS) is a tool that can be used to examine the movement of the heart and its force of contraction at the patient's bedside. POCUS can accurately diagnose cardiac arrest in hospital settings, as well as visualize cardiac wall motion contractions. Using POCUS, clinicians can have limited, two-dimensional views of different parts of the heart during arrest. These images can help clinicians determine whether electrical activity within the heart is pulseless or pseudo-pulseless, as well as help them diagnose the potentially #Mnemonic for reversible causes, reversible causes of an arrest. Published guidelines from the American Society of Echocardiography, American College of Emergency Physicians, European Resuscitation Council, and the American Heart Association, as well as the 2018 preoperative Advanced cardiac life support, Advanced Cardiac Life Support guidelines, have recognized the potential benefits of using POCUS in diagnosing and managing cardiac arrest. POCUS can help predict outcomes in resuscitation efforts. Specifically, use of transthoracic ultrasound can be a helpful tool in predicting mortality in cases of cardiac arrest, with a systematic review from 2020 finding that there is a significant positive correlation between presence of cardiac motion and short term survival with CPR. Owing to the inaccuracy diagnosis solely based on central pulse detection, some bodies like the European Resuscitation Council have de-emphasized its importance. Instead, the current guidelines prompt individuals to begin CPR on any unconscious person with absent or abnormal breathing. The Resuscitation Council in the United Kingdom stands in line with the European Resuscitation Council's recommendations and those of the American Heart Association. They have suggested that the technique to check carotid pulses should be used only by healthcare professionals with specific training and expertise, and even then that it should be viewed in conjunction with other indicators like agonal respiration. Various other methods for detecting circulation and therefore diagnosing cardiac arrest have been proposed. Guidelines following the 2000 International Liaison Committee on Resuscitation recommendations were for rescuers to look for "signs of circulation" but not specifically the pulse. These signs included coughing, gasping, color, twitching, and movement. Per evidence that these guidelines were ineffective, the current International Liaison Committee on Resuscitation recommendation is that cardiac arrest should be diagnosed in all casualties who are unconscious and not breathing normally, a similar protocol to that which the European Resuscitation Council has adopted. In a non-acute setting where the patient is expired, diagnosis of cardiac arrest can be done via molecular autopsy or postmortem molecular testing, which uses a set of molecular techniques to find the ion channels that are cardiac defective. This could help elucidate the cause of death in the patient. Other physical signs or symptoms can help determine the potential cause of the cardiac arrest. Below is a chart of the clinical findings and signs/symptoms a person may have and potential causes associated with them.

Prevention

Primary prevention

With the lack of positive outcomes following cardiac arrest, efforts have been spent finding effective strategies to prevent cardiac arrest events. The approach to primary prevention promotes a healthy diet, exercise, limited alcohol consumption, and smoking cessation. Exercise is an effective preventative measure for cardiac arrest in the general population but may be risky for those with pre-existing conditions. The risk of a transient catastrophic cardiac event increases in individuals with heart disease during and immediately after exercise. The lifetime and acute risks of cardiac arrest are decreased in people with heart disease who perform regular exercise, perhaps suggesting the benefits of exercise outweigh the risks. A 2021 study found that diet may be a modifiable risk factor for a lower incidence of sudden cardiac death. The study found that those who fell under the category of having "Southern [United States] diets" representing those of "added fats, fried food, eggs, organ and processed meats, and sugar-sweetened beverages" had a positive association with an increased risk of cardiac arrest, while those deemed following the "Mediterranean diets" had an inverse relationship regarding the risk of cardiac arrest. According to a 2012 review published, omega-3 PUFA supplementation is not associated with a lower risk of sudden cardiac death. A Cochrane review published in 2016 found moderate-quality evidence to show that blood pressure-lowering drugs do not reduce the risk of sudden cardiac death. In certain high-risk patient populations, implantable cardioverter-defibrillators (ICD) are also used to prevent sudden cardiac death. Such conditions include the inherited arrhythmias (long QT syndrome, Brugada syndrome, etc) and heart failure.

Secondary prevention

Blausen 0543 ImplantableCardioverterDefibrillator

An implantable cardioverter-defibrillator (ICD) is a battery-powered device that monitors electrical activity in the heart, and when an arrhythmia is detected, can deliver an electrical shock to terminate the abnormal rhythm. ICDs are used to prevent sudden cardiac death (SCD) in those who have survived a prior episode of sudden cardiac arrest (SCA) due to ventricular fibrillation or ventricular tachycardia. Numerous studies have been conducted on the use of ICDs for the secondary prevention of SCD. These studies have shown improved survival with ICDs compared to the use of anti-arrhythmic drugs. ICD therapy is associated with a 50% relative risk reduction in death caused by an arrhythmia and a 25% relative risk reduction in all-cause mortality. Prevention of SCD with ICD therapy for high-risk patient populations has similarly shown improved survival rates in several large studies. The high-risk patient populations in these studies were defined as those with severe ischemic cardiomyopathy (determined by a reduced Ejection fraction, left ventricular ejection fraction (LVEF)). The LVEF criteria used in these trials ranged from less than or equal to 30% in MADIT-II to less than or equal to 40% in MUSTT. Alternatively, a wearable cardioverter defibrillator (eg, LifeVest) can be used instead of an implantable defibrillator, and the wearable option can be used as a temporary bridge to an implantable device. Such instances are endocarditis where an implantable device is at high risk of becoming infected if implanted too soon.

Crash teams

In hospital, a cardiac arrest is referred to as a "crash", or a "code". This typically refers to code blue on the hospital emergency codes. A dramatic drop in vital sign measurements is referred to as "coding" or "crashing", though coding is usually used when it results in cardiac arrest, while crashing might not. Treatment for cardiac arrest is sometimes referred to as "calling a code". Patients in general wards often deteriorate for several hours or even days before a cardiac arrest occurs. This has been attributed to a lack of knowledge and skill amongst ward-based staff, in particular, a failure to measure the respiratory rate, which is often the major predictor of a deterioration and can often change up to 48 hours prior to a cardiac arrest. In response, many hospitals now have increased training for ward-based staff. A number of "early warning" systems also exist that aim to quantify the person's risk of deterioration based on their vital signs and thus provide a guide to staff. In addition, specialist staff are being used more effectively to augment the work already being done at the ward level. These include: * Crash teams (or code teams) – These are designated staff members with particular expertise in resuscitation who are called to the scene of all arrests within the hospital. This usually involves a specialized cart of equipment (including a defibrillation, defibrillator) and drugs called a "crash cart" or "crash trolley". * Medical emergency teams – These teams respond to all emergencies with the aim of treating people in the acute phase of their illness in order to prevent a cardiac arrest. These teams have been found to decrease the rates of in-hospital cardiac arrest (IHCA) and improve survival. * Critical care outreach – In addition to providing the services of the other two types of teams, these teams are responsible for educating non-specialist staff. In addition, they help to facilitate transfers between Intensive care unit, intensive care/high dependency units and the general hospital wards. This is particularly important as many studies have shown that a significant percentage of patients discharged from critical care environments quickly deteriorate and are re-admitted; the outreach team offers support to ward staff to prevent this from happening.

Management

Sudden cardiac arrest may be treated via attempts at resuscitation. This is usually carried out based on

, advanced cardiac life support (ACLS), pediatric advanced life support (PALS), or neonatal resuscitation program (NRP) guidelines. CPR training-04

Cardiopulmonary resuscitation

Early cardiopulmonary resuscitation (CPR) is essential to surviving cardiac arrest with good neurological function. It is recommended that it be started as soon as possible with minimal interruptions once begun. The components of CPR that make the greatest difference in survival are chest compressions and defibrillating shockable rhythms. After defibrillation, chest compressions should be continued for two minutes before another rhythm check. This is based on a compression rate of 100-120 compressions per minute, a compression depth of 5–6 centimeters into the chest, full chest recoil, and a ventilation rate of 10 breath ventilations per minute. Mechanical chest compressions (as performed by a machine) are no better than chest compressions performed by hand. It is unclear if a few minutes of CPR before defibrillation results in different outcomes than immediate defibrillation. Correctly performed bystander CPR has been shown to increase survival, however it is performed in fewer than 30% of out-of-hospital cardiac arrests (OHCAs) . A 2019 meta-analysis found that use of dispatcher-assisted CPR improved outcomes, including survival, when compared with undirected bystander CPR. Likewise, a 2022 systematic review on exercise-related cardiac arrests supported early intervention of bystander CPR and AED use (for shockable rhythms) as they improve survival outcomes. If high-quality CPR has not resulted in return of spontaneous circulation and the person's heart rhythm is in asystole, stopping CPR and pronouncing the person's death is generally reasonable after 20 minutes. Exceptions to this include certain cases with hypothermia or drowning victims. Some of these cases should have longer and more sustained CPR until they are nearly Normothermia, normothermic. If cardiac arrest occurs after 20 weeks of pregnancy, the uterus should be pulled or pushed to the left during CPR. If a pulse has not returned by four minutes, an emergency Cesarean section is recommended.

Airway management

High levels of oxygen are generally given during CPR. Either a bag valve mask or an advanced airway may be used to help with breathing particularly since vomiting and regurgitation are common, especially in OHCA. If this occurs, then modification to existing oropharyngeal suction may be required, such as using Suction Assisted Laryngoscopy Airway Decontamination, suction-assisted airway management. Tracheal intubation has not been found to improve survival rates or neurological outcomes in cardiac arrest, and in the prehospital environment, may worsen it. Endotracheal tubes and supraglottic airways appear equally useful. Mouth-to-mouth as a means of providing respirations to the person has been phased out due to the risk of contracting infectious diseases from the affected person. When done by emergency medical personnel, 30 compressions followed by two breaths appear to be better than continuous chest compressions and breaths being given while compressions are ongoing. For bystanders, CPR that involves only chest compressions results in better outcomes as compared to standard CPR for those who have gone into cardiac arrest due to heart issues.

Defibrillation

Defibrillation is indicated if an shockable rhythm is present; the two shockable rhythms are ventricular fibrillation and

. These shockable rhythms have a 25-40% likelihood of survival, compared with a significantly lower rate (less than 5%) in non-shockable rhythms. The non-shockable rhythms include asystole and pulseless electrical activity. Ventricular fibrillation involves the Ventricle (heart), ventricles of the heart rapidly contracting in an disorganized pattern, and thereby limiting blood flow from the heart. This is due to an uncoordinated electrical activity. The electrocardiogram (ECG) shows irregular QRS complexes at a very high rate (>300 beats per minute). In ventricular tachycardia, the ECG will show a wide complex rhythm at a rate higher than 100 beats per minute. These two rhythm lead to hemodynamic instability and compromise, resulting in poor perfusion to vital organs (including the heart itself). Defibrillation Electrode Position

A defibrillator — either implanted or external — delivers an electrical current that results in the entire myocardium simultaneously depolarized thereby stopping the arrhythmia. Defibrillators can deliver energy as monophasic or biphasic waveforms, although biphasic defibrillators are now the most common. Prior studies suggest that biphasic shock is more likely to produce successful defibrillation after a single shock, however rate of survival is comparable between the methods. In out-of-hospital arrests (OHA), the defibrillation is made by an automated external defibrillator (AED), a portable machine that can be used by any user. The AED provides voice instructions that guide the process, automatically checks the person's condition, and applies the appropriate electric shocks. Some defibrillators even provide feedback on the quality of cardiopulmonary resuscitation, CPR compressions, encouraging the lay rescuer to press the person's chest hard enough to circulate blood. There is increasing use of public access to defibrillators. This typically involves placing AEDs in publicly-accessible places and training staff in these areas on how to use them. This allows defibrillation to occur prior to the arrival of emergency services, which has been shown to increase the chances of survival. People who have cardiac arrests in remote locations have worse outcomes. Defibrillation cannot be applied to asystole and CPR must be initiated first in this case. A similar concept, cardioversion, utilizes the same defibrillation machine but is used for other rhythms such as atrial fibrillation and supraventricular tachycardia. In these rhythms, the machine is "synchronized" to the QRS complex to avoid shocking on the T wave (and inducing VT or VF). Cardioversion can be done electively for rhythm control, or urgently if the rhythm is unstable.

Medications

Medications recommended in the ACLS protocol include epinephrine, amiodarone, and lidocaine. The timing and administration of these medications depends on the underlying arrhythmia of the arrest. Epinephrine acts on the alpha-1 receptor, which in turn increases the blood flow that supplies the heart. Epinephrine in adults improves survival but does not appear to improve neurologically normal survival. In ventricular fibrillation and pulseless ventricular tachycardia, 1 mg of epinephrine is given every 3–5 minutes, following an initial round of CPR and defibrillation. Doses higher than 1 mg of epinephrine are not recommended for routine use in cardiac arrest. If the person has a non-shockable rhythm, such as asystole, following an initial round of CPR, 1 mg of epinephrine should be given every 3–5 minutes, with the goal of obtaining a shockable rhythm. Amiodarone and lidocaine are anti-arrhythmic medications. Amiodarone is a class III antiarrhythmic. Amiodarone may be used in cases of ventricular fibrillation,

, and wide complex tachycardia. Lidocaine is a Class IB anti-arrhythmic, also used to manage acute arrhythmias. Anti-arrhythmic medications may be used after an unsuccessful defibrillation attempt. However, neither lidocaine nor amiodarone improves survival to hospital discharge, despite both equally improving survival to hospital admission. The first dose is given as a 300 mg bolus. The second dose is given as a 600 mg bolus.

Additional medications

Sodium bicarbonate, Bicarbonate, given as sodium bicarbonate, works to stabilize Metabolic acidosis, acidosis and hyperkalemia, both of which can contribute to and exacerbate cardiac arrest. If acid-base or electrolyte disturbance is evident, bicarbonate may be used. However, if there is little suspicion that these imbalances are occurring and contributing to the arrest, routine use of bicarbonate is not recommended as it does not provide additional benefit. Calcium chloride, Calcium, given as calcium chloride, works as an inotrope and vasopressor. Calcium is used in specific circumstances such as electrolyte disturbances (hyperkalemia) and Calcium channel blocker toxicity, calcium-channel blocker toxicity. Overall, calcium is not routinely used during cardiac arrest as it does not provide additional benefit (compared to non-use) and may even cause harm (poor neurologic outcomes). Vasopressin overall does not improve or worsen outcomes compared to epinephrine. The combination of epinephrine, vasopressin, and methylprednisolone appears to improve outcomes. The use of atropine, lidocaine, and amiodarone have not been shown to improve survival from cardiac arrest. Atropine is used for symptomatic bradycardia. It is given at a dose of 1 mg (iv), and additional 1 mg (iv) doses can be given every 3–5 minutes for a total of 3 mg. However, the 2010 guidelines from the American Heart Association removed the recommendation for atropine use in pulseless electrical activity and asystole for lack of evidence supporting its use.

Special considerations

Hemodialysis patients carry a greater risk of cardiac arrest events. Multiple factors contribute including increased cardiovascular risk factors, electrolyte disturbances (calcium and potassium, caused by accumulation and aggressive removal), and acid-base disturbances. Calcium levels are considered a key factor contributing to cardiac arrests in this population. Tricyclic antidepressant overdose, Tricyclic antidepressant (TCA) overdose can lead to cardiac arrest with typical ECG findings including wide QRS and prolonged QTc. Treatment for this condition includes Activated carbon, activated charcoal and sodium bicarbonate. Magnesium can be given at a does of 2 g (iv or oral bolus) to manage Torsades de pointes, torsades de points. However, without specific indication, magnesium is not generally given in cardiac arrest. In people with a confirmed pulmonary embolism as the cause of arrest, thrombolytics may be of benefit. Evidence for use of naloxone in those with cardiac arrest due to opioids is unclear, but it may still be used. In people with cardiac arrest due to a local anesthetic, lipid emulsion may be used.

Targeted temperature management

Current international guidelines suggest cooling adults after cardiac arrest using targeted temperature management (TTM) with the goal of improving neurological outcomes. The process involves cooling for a 24-hour period, with a target temperature of , followed by gradual rewarming over the next 12 to 24 hrs. There are several methods used to lower the body temperature, such as applying ice packs or cold-water circulating pads directly to the body or infusing cold saline. The effectiveness of TTM after OHCA is an area of ongoing study. Several recent reviews have found that patients treated with TTM have more favorable neurological outcomes. However, pre-hospital TTM after OHCA has been shown to increase the risk of adverse outcomes. The rates of re-arrest may be higher in people who were treated with pre-hospital TTM. Moreover, TTM may have adverse neurological effects in people who survive post-cardiac arrest''.'' Osborn wave, Osborn waves on ECG are frequent during TTM, particularly in patients treated with 33 °C. J wave, Osborn waves are not associated with increased risk of ventricular arrhythmia, and may be considered a benign physiological phenomenon, associated with lower mortality in univariable analyses.

Do not resuscitate

Some people choose to avoid aggressive measures at the end of life. A do not resuscitate order (DNR) in the form of an advance health care directive makes it clear that in the event of cardiac arrest, the person does not wish to receive cardiopulmonary resuscitation. Other directives may be made to stipulate the desire for intubation in the event of respiratory failure or, if comfort measures are all that are desired, by stipulating that healthcare providers should "allow natural death".

Chain of survival

Several organizations promote the idea of a chain of survival. The chain consists of the following "links": * Early recognition. If possible, recognition of illness before the person develops a cardiac arrest will allow the rescuer to prevent its occurrence. Early recognition that a cardiac arrest has occurred is key to survival, for every minute a patient stays in cardiac arrest, their chances of survival drop by roughly 10%. * Early CPR improves the flow of blood and of oxygen to vital organs, an essential component of treating a cardiac arrest. In particular, by keeping the brain supplied with oxygenated blood, the chances of neurological damage are decreased. * Early defibrillation is effective for the management of ventricular fibrillation and pulseless

. * Early advanced care. * Early post-resuscitation care, which may include percutaneous coronary intervention. If one or more links in the chain are missing or delayed, then the chances of survival drop significantly. These protocols are often initiated by a Code Blue (emergency code), code blue, which usually denotes impending or acute onset of cardiac arrest or respiratory failure.

Other

Resuscitation with extracorporeal membrane oxygenation devices has been attempted with better results for in-hospital cardiac arrest (29% survival) than OHCA (4% survival) in populations selected to benefit most. Cardiac catheterization in those who have survived an OHCA appears to improve outcomes, although high-quality evidence is lacking. It is recommended to be done as soon as possible in those who have had a cardiac arrest with ST elevation due to underlying heart problems. The precordial thump may be considered in those with witnessed, monitored, unstable ventricular tachycardia (including pulseless VT) if a defibrillator is not immediately ready for use, but it should not delay CPR and shock delivery or be used in those with unwitnessed OHCA.

Prognosis

The overall rate of survival among those who have OHCA is 10%. Among those who have an OHCA, 70% occur at home, and their survival rate is 6%. For those who have an in-hospital cardiac arrest (IHCA), the survival rate one year from at least the occurrence of cardiac arrest is estimated to be 13%. For IHCA, survival to discharge is around 22%. Those who survive to return of spontaneous circulation and hospital admission frequently present with post-cardiac arrest syndrome, which usually presents with neurological injury that can range from Amnesia, mild memory problems to coma. One-year survival is estimated to be higher in people with cardiac admission diagnoses (39%) when compared to those with non-cardiac admission diagnoses (11%). A 1997 review found rates of survival to discharge of 14%, although different studies varied from 0 to 28%. In those over the age of 70 who have a cardiac arrest while in hospital, survival to hospital discharge is less than 20%. How well these individuals manage after leaving the hospital is not clear. The global rate of people who were able to recover from OHCA after receiving CPR has been found to be approximately 30%, and the rate of survival to discharge from the hospital has been estimated at 9%. Survival to discharge from the hospital is more likely among people whose cardiac arrest was witnessed by a bystander or emergency medical services, who received bystander CPR, and who live in Europe and North America. Relatively lower survival to hospital discharge rates have been observed in Asian countries. Prognosis is typically assessed 72 hours or more after cardiac arrest. Rates of survival are better in those who had someone witness their collapse, received bystander CPR or had either Ventricular fibrillation, V-fib or Ventricular tachycardia, V-tach when assessed. Survival among those with V-fib or V-tach is 15 to 23%. Women are more likely to survive cardiac arrest and leave the hospital than men. Cerebral hypoxia, Hypoxic ischemic brain injury is a concerning outcome for people suffering a cardiac arrest. Most improvements in cognition occur during the first three months following cardiac arrest, with some individuals reporting improvement up to one year post-cardiac arrest. 50 – 70% of cardiac arrest survivors report fatigue as a symptom.

Epidemiology

United States

The risk of cardiac arrest varies with geographical region, age, and gender. The lifetime risk is three times greater in men (12.3%) than women (4.2%) based on analysis of the Framingham Heart Study. This gender difference disappeared beyond 85 years of age. Around half of these individuals are younger than 65 years of age. Based on death certificates, sudden cardiac death accounts for about 20% of all deaths in the United States. In the United States, approximately 326,000 cases of out-of-hospital and 209,000 cases of IHCA occur among adults annually, which works out to be an incidence of approximately 110.8 per 100,000 adults per year. In the United States, during-pregnancy cardiac arrest occurs in about one in twelve-thousand deliveries or 1.8 per 10,000 live births. Rates are lower in Canada.

Other regions

Non-Western regions of the world have differing incidences. The incidence of sudden cardiac death in China is 41.8 per 100,000 and in South India is 39.7 per 100,000.

Society and culture

Names

In many publications, the stated or implicit meaning of "sudden cardiac death" is sudden death from cardiac causes. Some physicians call cardiac arrest "sudden cardiac death" even if the person survives. Thus one can hear mentions of "prior episodes of sudden cardiac death" in a living person. In 2021, the American Heart Association clarified that "heart attack" is often mistakenly used to describe cardiac arrest. While a heart attack refers to death of heart muscle tissue as a result of blood supply loss, cardiac arrest is caused when the Electrical conduction system of the heart, heart's electrical system malfunctions. Furthermore, the American Heart Association explains that "if corrective measures are not taken rapidly, this condition progresses to sudden death. Cardiac arrest should be used to signify an event as described above, that is reversed, usually by CPR and/or

or cardioversion, or Artificial cardiac pacemaker, cardiac pacing. Sudden cardiac death should not be used to describe events that are not fatal".

Slow code

A "slow code" is a slang term for the practice of deceptively delivering sub-optimal

to a person in cardiac arrest, when CPR is considered to have no medical benefit. A "show code" is the practice of faking the response altogether for the sake of the person's family. Such practices are ethically controversial and are banned in some jurisdictions. The European Resuscitation Council Guidelines released a statement in 2021 that clinicians are not suggested to participate/take part in "slow codes". According to the American College of Physicians, half-hearted resuscitation efforts are deceptive and should not be performed by physicians or nurses.

Children

In children, the most common cause of cardiac arrest is Shock (circulatory), shock or respiratory failure that has not been treated. Cardiac arrhythmias are another possible cause. Arrhythmias such as asystole or bradycardia are more likely in children, in contrast to ventricular fibrillation or tachycardia as seen in adults. Additional causes of sudden unexplained cardiac arrest in children include hypertrophic cardiomyopathy and coronary artery abnormalities. In childhood hypertrophic cardiomyopathy, previous adverse cardiac events, non-sustained ventricular tachycardia, syncope, and left ventricular hypertrophy have been shown to predict sudden cardiac death. Other causes can include drugs, such as Cocaine intoxication, cocaine and methamphetamine, or overdose of medications, such as antidepressants. For management of pediatric cardiac arrest, CPR should be initiated if suspected. Guidelines provide algorithms for pediatric cardiac arrest management. Recommended medications during pediatric resuscitation include epinephrine, lidocaine, and amiodarone. However, the use of sodium bicarbonate or calcium is not recommended. The use of calcium in children has been associated with poor neurological function as well as decreased survival. Correct dosing of medications in children is dependent on weight, and to minimize time spent calculating medication doses, the use of a Broselow tape is recommended. Rates of survival in children with cardiac arrest are 3 to 16% in North America.

References

External links

The Center for Resuscitation Science at the Hospital of the University of Pennsylvania
{{DEFAULTSORT:Cardiac Arrest Cardiac arrhythmia Medical emergencies Causes of death Wikipedia medicine articles ready to translate Wikipedia emergency medicine articles ready to translate