Cardiac Arrest

ByShira A. Schlesinger, MD, MPH, Harbor-UCLA Medical Center
Reviewed/Revised Apr 2023
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Cardiac arrest is the cessation of cardiac mechanical activity resulting in the absence of circulating blood flow. Cardiac arrest stops blood from flowing to vital organs, depriving them of oxygen, and, if left untreated, results in death. Sudden cardiac arrest is the unexpected cessation of circulation within a short period of symptom onset (often without warning).

Sudden cardiac arrest occurs outside the hospital in more than 400,000 people/year in the United States, including an estimated 5000 infants and children, with a > 90% mortality rate.

Respiratory arrest and cardiac arrest are distinct, but without treatment, one inevitably leads to the other. (See also respiratory failure, dyspnea, and hypoxia.)

(See also the American Heart Association [AHA] 2023 update of heart disease and stroke statistics for out-of-hospital and in-hospital cardiac arrest.)

Etiology of Cardiac Arrest

In adults, sudden cardiac arrest results primarily from cardiac disease (of all types, with more than 15% of sudden cardiac arrest attributable to acute coronary syndromes, and a large majority associated with underlying cardiovascular disease). In a significant percentage of patients, sudden cardiac arrest is the first manifestation of heart disease. Other causes include circulatory shock due to noncardiac disorders (especially pulmonary embolism, gastrointestinal hemorrhage, or trauma), ventilatory failure, and metabolic disturbance (including drug overdose).

In infants and children, cardiac causes of cardiac arrest are less common than in adults. The predominant cause of cardiac arrest in infants and children is respiratory failure due to various respiratory disorders (eg, airway obstruction, drowning, infection, sudden infant death syndrome [SIDS], smoke inhalation). However, sudden cardiac arrest (the unexpected cessation of circulation without warning) in children and adolescents is most commonly due to arrhythmia resulting from a channelopathy or underlying structural cardiac abnormality (1, 2, 3, 4).

Etiology references

  1. 1. Atkins DL, Everson-Stewart S, Sears GK, et al; Resuscitation Outcomes Consortium Investigators: Epidemiology and outcomes from out-of-hospital cardiac arrest in children: the Resuscitation Outcomes Consortium Epistry-Cardiac Arrest. Circulation 119(11):1484–1491, 2009. doi: 10.1161/CIRCULATIONAHA.108.802678

  2. 2. Meert KL, Telford R, Holubkov R, et al; Therapeutic Hypothermia after Pediatric Cardiac Arrest (THAPCA) Trial Investigators: Pediatric out-of-hospital cardiac arrest characteristics and their association with survival and neurobehavioral outcome. Pediatr Crit Care Med 17(12):e543–e550, 2016. doi: 10.1097/PCC.0000000000000969

  3. 3. Scheller RL, Johnson L, Lorts A, Ryan TD: Sudden cardiac arrest in pediatrics. Pediatr Emerg Care 32(9):630–636, 2016. doi: 10.1097/PEC.0000000000000895

  4. 4. Tsao CW, Aday AW, Almarzooq ZI, et al: Heart Disease and Stroke Statistics-2023 Update: A Report From the American Heart Association [published correction appears in Circulation 147(8):e622, 2023]. Circulation 147(8):e93-e621, 2023. doi:10.1161/CIR.0000000000001123

Pathophysiology of Cardiac Arrest

Cardiac arrest causes global ischemia with consequences at the cellular level that adversely affect organ function even after resuscitation and restoration of perfusion. The main consequences involve direct cellular damage and edema formation. Edema is particularly harmful in the brain, which has minimal room to expand, and often results in increased intracranial pressure and corresponding decreased cerebral perfusion postresuscitation. A significant proportion of successfully resuscitated patients have short-term or long-term cerebral dysfunction manifested by altered alertness (from mild confusion to coma), seizures, or both.

Decreased adenosine triphosphate (ATP) production leads to loss of membrane integrity with efflux of potassium and influx of sodium and calcium. Excess intracellular sodium is one of the initial causes of cellular edema. Excess calcium damages mitochondria (depressing ATP production), increases nitric oxide production (leading to formation of damaging free radicals), and, in certain circumstances, activates proteases that further damage cells.

Abnormal ion flux also results in depolarization of neurons, releasing neurotransmitters, some of which are damaging (eg, glutamate activates a specific calcium channel, worsening intracellular calcium overload).

Inflammatory mediators (eg, interleukin-1B, tumor necrosis factor-alpha) are elaborated; some of them may cause microvascular thrombosis and loss of vascular integrity with further edema formation. Some mediators trigger apoptosis, resulting in accelerated cell death.

Symptoms and Signs of Cardiac Arrest

In critically or terminally ill patients, cardiac arrest is often preceded by a period of clinical deterioration with rapid, shallow breathing, arterial hypotension, and a progressive decrease in mental alertness. In sudden cardiac arrest, collapse occurs without warning, occasionally accompanied by brief myoclonic jerks or other seizure-like activity.

Diagnosis of Cardiac Arrest

  • Clinical evaluation

  • Cardiac monitoring and electrocardiography (ECG)

  • Sometimes testing for cause (eg, echocardiography, chest imaging [x-ray, ultrasonography], electrolyte testing)

Diagnosis of cardiac arrest is by clinical findings of apnea, pulselessness, and unconsciousness. Arterial pressure is not measurable. Pupils dilate and become unreactive to light after several minutes.

A cardiac monitor should be applied; it may indicate ventricular fibrillation (VF), ventricular tachycardia (VT), or asystole. Sometimes a perfusing rhythm (eg, extreme bradycardia) is present; this rhythm may represent true pulseless electrical activity (previously termed electromechanical dissociation) or extreme hypotension with failure to detect a pulse.

The patient is evaluated for potentially treatable causes; a useful memory aid is "Hs and Ts":

  • H:Hypoxia, hypovolemia, acidosis (hydrogen ion), hyperkalemia or hypokalemia, hypothermia

  • T:Tablet or toxin ingestion, cardiac tamponade, tension pneumothorax, thrombosis (pulmonary or coronary)

In pediatric cardiac arrest, hypoglycemia is another potentially treatable cause.

Unfortunately, the cause of cardiac arrest often cannot be identified during cardiopulmonary resuscitation (CPR). Clinical examination, chest ultrasonography during CPR, and chest x-rays taken after return of spontaneous circulation following needle thoracostomy can detect pneumothorax, which suggests tension pneumothorax as the cause of the arrest.

Cardiac ultrasonography can detect cardiac contractions and recognize cardiac tamponade, extreme hypovolemia (empty heart), right ventricular overload suggesting pulmonary embolism, and focal wall motion abnormalities suggesting myocardial infarction (MI). However, transthoracic cardiac ultrasonography should not be done if it requires significant interruption in CPR.

Rapid bedside blood tests can detect abnormal levels of potassium, helping to confirm suspicion that cardiac arrest was caused by an arrhythmia secondary to hyperkalemia.

History given by family or rescue personnel may suggest overdose.

Treatment of Cardiac Arrest

Rapid intervention is essential.

(See also the 2020 American Heart Association [AHA] guidelines for CPR and emergency cardiovascular care and 2022 AHA Interim Guidance to Health Care Providers for Basic and Advanced Cardiac Life Support in Adults, Children, and Neonates With Suspected or Confirmed COVID-19.)

Cardiopulmonary resuscitation (CPR

In children, who most often have asphyxial causes of cardiac arrest, the presenting rhythm is typically a bradyarrhythmia followed by asystole. However, about 15 to 20% of children (particularly when cardiac arrest has not been preceded by respiratory symptoms) present with VT or VF and thus also require prompt defibrillation. The incidence of VF as the initial recorded rhythm increases in children > 12 years.

1, 2

After return of pulses, postresuscitative care focuses on determination and treatment of cause, stabilization and prevention of rearrest, and optimization of neurologic outcome. In addition to treatment of cause, postresuscitative care may include methods to optimize oxygenation and ventilation and rapid coronary angiography in patients who have a ST-segment elevation (STEMI). The 2020 AHA guidelines suggest delayed coronary angiography should also be considered for patients without STEMI. Current recommendations are for targeted temperature management to therapeutic normothermia < 37.5° C, although AHA 2020 guidelines still recommend a lower temperature range. Research is ongoing to determine whether targeted temperature management with controlled hypothermia (32° C to 34° C) benefit select cardiac arrest survivors (3).

Treatment references

  1. 1. Okubo M, Komukai S, Callaway CW, Izawa J: Association of Timing of Epinephrine Administration With Outcomes in Adults With Out-of-Hospital Cardiac Arrest. JAMA Netw Open 2021;4(8):e2120176. Published 2021 Aug 2. doi:10.1001/jamanetworkopen.2021.20176

  2. 2. Perkins GD, Ji C, Deakin CD, et al: A Randomized Trial of Epinephrine in Out-of-Hospital Cardiac Arrest. N Engl J Med 379(8):711-721, 2018. doi:10.1056/NEJMoa1806842

  3. 3. Wyckoff MH, Greif R, Morley PT, et al: 2022 International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science With Treatment Recommendations: Summary From the Basic Life Support; Advanced Life Support; Pediatric Life Support; Neonatal Life Support; Education, Implementation, and Teams; and First Aid Task Forces. Circulation 2022;146(25):e483–e557, 2022. doi:10.1161/CIR.0000000000001095

Prognosis for Cardiac Arrest

Survival to hospital discharge, particularly neurologically intact survival, is a more meaningful outcome than simply return of spontaneous circulation.

Survival rates vary significantly; favorable factors include

  • Early and effective bystander-initiated CPR

  • Witnessed arrest

  • In-hospital location (particularly a monitored unit)

  • Initial rhythm of ventricular fibrillation (VF) or ventricular tachycardia (VT)

  • Early defibrillation of VF or VT

  • Postresuscitative care, including circulatory support and access to cardiac catheterization

  • In adults, targeted temperature management (body temperature of 32 to 36° C for ≥ 24 hours) and avoidance of hyperthermia

While the American Heart Association 2020 Advanced Cardiac Life Support (ACLS) guidelines recommend cooling to a temperature range between 32° C and 36° C, more recent recommendations from the International Liaison Committee on Resuscitation Advanced Life Support (ALS) suggest actively preventing fever with a target temperature of ≤ 37.5° C rather than active cooling. It is still unclear whether certain groups of patients with cardiac arrest will have improved neurologically intact survival with targeted hypothermia management rather than with maintaining normothermia (1, 2, 3, 4, 5).

If many factors are favorable (eg, VF is witnessed in an intensive care unit or emergency department), 50% of adults with inpatient cardiac arrest may survive to hospital discharge. Overall, survival to hospital discharge in patients experiencing in-hospital arrest varies from 25 to 50%.

When factors are uniformly unfavorable (eg, patient in asystole after unwitnessed, out-of-hospital arrest), survival is unlikely. Overall, reported survival after out-of-hospital arrest is about 12%.

Only about 10% of all cardiac arrest survivors have good neurologic function, defined as minimal to moderate cerebral disability with ability to perform the majority of activities of daily living independently, at hospital discharge.

Prognosis references

  1. 1. Bernard SA, Gray TW, Buist MD, et al: Treatment of comatose survivors of out-of-hospital cardiac arrest with induced hypothermia. N Engl J Med 346:557–563, 2002. doi 10.1056/NEJMoa003289

  2. 2. Granfeldt A, Holmberg MJ, Nolan JP, Soar J, Andersen LW; International Liaison Committee on Resuscitation (ILCOR) Advanced Life Support Task Force: Targeted temperature management in adult cardiac arrest: Systematic review and meta-analysis. Resuscitation 167:160–172, 2021. doi:10.1016/j.resuscitation.2021.08.040

  3. 3. Merchant RM, Topjian AA, Panchal AR, et al: Part 1: Executive Summary: 2020 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation. 2020;142(16_suppl_2):S337-S357. doi:10.1161/CIR.0000000000000918

  4. 4. Nielsen N, Wetterslev J, Cronberg T, et al: Targeted temperature management at 33°C versus 36°C after cardiac arrest. N Engl J Med 369:2197–2206, 2013. doi: 10.1056/NEJMoa1310519

  5. 5. Wyckoff MH, Greif R, Morley PT, et al: 2022 International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science With Treatment Recommendations: Summary From the Basic Life Support; Advanced Life Support; Pediatric Life Support; Neonatal Life Support; Education, Implementation, and Teams; and First Aid Task Forces. Circulation 146(25):e483–e557, 2022. doi:10.1161/CIR.0000000000001095

More Information

The following English-language resources may be useful. Please note that THE MANUAL is not responsible for the content of these resources.

  1. American Heart Association 2020 Guidelines: These guidelines for cardiopulmonary resuscitation (CPR) and emergency cardiovascular care (ECC) are based on the most recent review of resuscitation science, protocols, and education.

  2. Wyckoff MH, Greif R, Morley PT, et al: 2022 International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science With Treatment Recommendations: Summary From the Basic Life Support; Advanced Life Support; Pediatric Life Support; Neonatal Life Support; Education, Implementation, and Teams; and First Aid Task Forces. Circulation 2022;146(25):e483–e557, 2022. doi:10.1161/CIR.0000000000001095

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