Pulseless electrical activity (PEA) is a life-threatening form of cardiac arrest in which the heart exhibits organized electrical activity detectable on electrocardiogram (ECG) but fails to generate a palpable pulse due to inadequate mechanical contraction of the ventricles; it can be true PEA (absent mechanical activity) or pseudo-PEA (minimal mechanical activity not producing a detectable pulse).[1] This condition, also known as electromechanical dissociation, represents approximately 20% of out-of-hospital sudden cardiac deaths and 30-38% of in-hospital cardiac arrests, often progressing rapidly without immediate intervention.[1]PEA is classified into primary (directly related to cardiac issues, such as myocardial ischemia or energy depletion) and secondary (due to extracardiac causes) forms, with the latter commonly remembered by the mnemonic "Hs and Ts" for reversible etiologies.[1] The "Hs" include hypovolemia, hypoxia, hydrogen ion (acidosis), hypo-/hyperkalemia, and hypothermia, while the "Ts" encompass tension pneumothorax, tamponade (cardiac), toxins, thrombosis (pulmonary or coronary), and trauma.[1] Pathophysiologically, PEA arises from disruptions in the electromechanical coupling, often triggered by metabolic derangements, ischemia, or mechanical obstructions that impair ventricular output despite preserved electrical impulses.[2] Risk factors include advanced age (over 70), female sex, and comorbidities such as pulmonary disease or prior syncope.[2]Diagnosis relies on clinical assessment confirming unresponsiveness and absent pulses alongside ECG evidence of organized rhythm (e.g., sinus or other non-shockable patterns, excluding asystole or ventricular fibrillation).[1] Immediate management follows advanced cardiovascular life support (ACLS) protocols, prioritizing high-quality cardiopulmonary resuscitation (CPR) at a rate of 100-120 compressions per minute, intravenous epinephrine (1 mg every 3-5 minutes), and rapid identification and correction of underlying causes—such as fluid resuscitation for hypovolemia or needle decompression for tension pneumothorax.[1] Unlike shockable rhythms, PEA does not respond to defibrillation, emphasizing the need for etiology-focused interventions to restore perfusion.[2]Prognosis remains poor, with survival to hospital discharge around 11% in reported cohorts, though outcomes improve with prompt CPR and reversible cause treatment; it is part of the natural dying process in some cases but can be survivable if addressed aggressively.[1] Ongoing research highlights needs for better PEA classification, biomarkers, and novel therapies like targeted temperature management or mechanical circulatory support to enhance survival rates.[2]
Overview
Definition
Pulseless electrical activity (PEA) is a clinical condition characterized by the presence of organized electrical activity on electrocardiography (ECG) in the absence of detectable mechanical cardiac output or a palpable pulse, resulting in cardiac arrest. PEA can be subclassified as "true" PEA (no mechanical activity) or "pseudo-PEA" (minimal cardiac motion detectable by ultrasound but no palpable pulse), with the latter showing better prognosis.[3] This disconnect between electrical depolarization and mechanicalcontraction distinguishes PEA as a form of non-shockable rhythm where the heart fails to generate sufficient blood flow despite apparent organized rhythms such as sinus, junctional, or idioventricular patterns.[1][4]Historically, PEA was first described in the 1980s under the term electromechanical dissociation (EMD), referring to the same phenomenon of electrical activity without synchronous myocardial contraction, based on early studies of prehospital and in-hospital cardiac arrests. The term evolved in the early 1990s when the international resuscitation community, including the American Heart Association (AHA), adopted "pulseless electrical activity" in advanced cardiovascular life support (ACLS) guidelines to encompass a broader spectrum of underlying etiologies and to better reflect clinical observations from diagnostic tools like echocardiography.[5][6]PEA must be differentiated from asystole, which shows no electrical activity on ECG (a flatline), and from ventricular fibrillation (VF), a chaotic, disorganized rhythm without coordinated electrical waves. In contrast, PEA exhibits discernible QRS complexes or other organized waveforms that would typically produce a pulse, but mechanical failure prevents effective circulation.[4][7]Clinically, PEA signifies a potentially reversible form of cardiac arrest, as restoring mechanical output is often possible by promptly identifying and treating underlying causes such as hypovolemia or tension pneumothorax, rather than relying solely on electrical interventions.[1][2]
Epidemiology
Pulseless electrical activity (PEA) accounts for approximately 20% of out-of-hospital cardiac arrests (OHCA) and 30-38% of in-hospital cardiac arrests (IHCA) as the initial rhythm, based on data from major registries as of 2023.[1][8] These figures reflect PEA's prominence among non-shockable rhythms, which constitute the majority of cardiac arrest presentations in both settings.[9]Recent trends indicate increasing recognition of PEA due to advancements in cardiac monitoring and resuscitation protocols, with the overall proportion of sudden cardiac arrests presenting as PEA rising in recent years.[10] The pseudo-PEA subtype has emerged in 10-35% of PEA cases according to studies from 2022-2023.[3]Demographically, PEA is more prevalent in elderly patients over 65 years, particularly those exceeding 70 years, and is associated with comorbidities such as coronary artery disease, heart failure, and chronic kidney disease.[1][11] While cardiac arrests overall occur more frequently in males, PEA specifically shows a higher incidence in females and individuals with prior hospitalizations or multiple chronic conditions.[12] In-hospital cases are notably elevated in intensive care unit (ICU) settings, where patient acuity and monitoring contribute to earlier detection.[13]Globally, IHCA rates of PEA are higher in developed countries with advanced monitoring capabilities, such as the United States, where it comprises around 30-38% of cases based on registry data as of 2023.[1] This variation underscores the role of healthcare infrastructure in identifying PEA, often linked to reversible causes like hypovolemia or tensionpneumothorax.[1]
Pathophysiology
Underlying Mechanisms
Pulseless electrical activity (PEA) arises when organized electrical depolarization of the myocardium fails to produce adequate mechanical contraction, resulting in insufficient cardiac output despite detectable electrical signals on electrocardiography. This core mechanism stems from impaired hemodynamics or cellular dysfunction that disrupts the translation of electrical impulses into forceful ventricular systole. In particular, severe pump failure occurs due to mismatches in preload or afterload, where diminished venous return or excessive systemic vascular resistance prevents effective ejection, leading to a rapid drop in blood pressure and perfusion.[1][2]At the cellular level, electromechanical uncoupling manifests through defects in calcium handling, where altered intracellular calcium dynamics impair excitation-contraction coupling in cardiomyocytes. Myocardial stunning, characterized by transient contractile dysfunction following ischemia, further exacerbates this by reducing the heart's ability to generate pressure, often in the context of underlying heart failure or acute insults. Metabolic derangements, such as acidosis, compound these issues by depressing myocardial contractility and promoting rhythm instability. For instance, reversible causes like hypovolemia can initiate this cascade by severely limiting preload, though the underlying failure lies in the myocardium's inability to compensate.[1][14][2]If untreated, PEA progresses rapidly to asystole as ongoing ischemia and metabolic stress deplete cellular energy stores, leading to complete cessation of electrical activity. Studies since 2021, including those using echocardiographic and animal models, highlight hypoxia-mediated ATP depletion as a primary uncoupler, where oxygen deprivation halts aerobic metabolism, causing progressive myocardial weakening and a continuum from pseudo-PEA to true arrest. Additionally, hyperkalemia induces conduction blocks by altering membrane potentials, which disrupts synchronized depolarization and contributes to electromechanical dissociation in vulnerable patients. These insights underscore the role of acute ischemia on dysfunctional substrates in driving PEA's lethality.[14][15][16]
True vs. Pseudo-PEA
Pulseless electrical activity (PEA) is classified into true PEA and pseudo-PEA based on the presence or absence of mechanical cardiac activity. True PEA represents a complete absence of cardiac output, where organized electrical activity on electrocardiography is not accompanied by any ventricular motion, as confirmed by point-of-care ultrasound (POCUS) showing cardiac standstill.[17] This subtype carries a poor prognosis, with low rates of return of spontaneous circulation (ROSC) and survival, necessitating rapid intervention to address underlying causes.[1]In contrast, pseudo-PEA involves low-output mechanical activity, such as weak ventricular contractions visible on echocardiography, despite the pulse being undetectable by manualpalpation.[17] This form often reflects profound shock rather than true arrest and is associated with improved outcomes, including higher ROSC rates and better neurological recovery when targeted therapies, such as fluid resuscitation for hypovolemia, are applied promptly.[17] For example, patients with pseudo-PEA may respond favorably to volume expansion if preload is inadequate.[1]The distinction between true and pseudo-PEA gained prominence in the medical literature during the 2010s, driven by increased use of POCUS during resuscitation, which allows real-time identification of subtle cardiac motion.[18] Recent studies indicate that pseudo-PEA may account for 42% to 86% of apparent PEA cases, highlighting its underrecognition in earlier protocols.[17] The 2025 American Heart Association guidelines recommend the use of point-of-care ultrasound (POCUS) by experienced professionals during cardiac arrest to diagnose reversible causes if it can be done without interrupting chest compressions.[19]This differentiation has critical implications for management, shifting focus toward reversible causes in pseudo-PEA cases while underscoring the urgency of comprehensive evaluation in true PEA.[17]Ultrasound integration is essential for accurate subtype identification, potentially improving survival by guiding etiology-specific interventions.[19]
Pulseless electrical activity (PEA) presents primarily with unresponsiveness and the absence of palpable carotid or femoral pulses, indicating a failure of cardiac output despite organized electrical activity in the heart.[1] Patients typically exhibit apnea or agonal respirations, reflecting inadequate oxygenation and ventilation due to circulatory collapse.[20]Associated manifestations include cyanosis from poor tissue perfusion, diaphoresis as a sign of sympathetic activation prior to arrest, and cool extremities signaling hypoperfusion.[1] These may be accompanied by indicators of underlying causes, such as hypotension and tachycardia preceding arrest in cases of hypovolemia.[2]The onset of PEA is often sudden in out-of-hospital cardiac arrest (OHCA), leading to abrupt collapse, whereas in in-hospital cardiac arrest (IHCA), it may develop more gradually with observable deterioration due to continuous monitoring.[21] It can also occur following the conversion of shockable rhythms, such as ventricular fibrillation, to non-shockable ones during resuscitation efforts.[2]Patients experience complete loss of consciousness with no awareness of the event. Family witnesses or bystanders often report sudden collapse without preceding symptoms like chest pain, highlighting the unpredictable nature of the condition.
Initial Assessment
The initial assessment of pulseless electrical activity (PEA) begins with the ABC approach to rapidly evaluate and stabilize the patient in cardiac arrest. Airway patency must be ensured immediately, often using basic maneuvers such as head-tilt chin-lift or jaw thrust, while assessing for spontaneous breathing; in PEA, patients typically exhibit no spontaneous breaths due to absent effective circulation despite organized electrical activity on ECG. Breathing support follows with bag-mask ventilation at a rate of 10 breaths per minute if an advanced airway is not yet placed, prioritizing oxygenation to address potential hypoxia as a reversible cause. Circulation is then checked by initiating high-quality chest compressions without delay, confirming the absence of a central pulse (e.g., carotid or femoral) in the presence of ECG rhythm, which distinguishes PEA from other arrest types.[1][22][19]Pulse verification is a critical step performed simultaneously with ECG monitoring to confirm PEA, involving manual palpation of central pulses for no more than 10 seconds to minimize interruptions in CPR. Over-reliance on peripheral pulses, such as radial or brachial, should be avoided, as they may be unreliable in low-output states; instead, central pulse checks provide higher accuracy for detecting the lack of mechanical cardiac output. If an arterial line is available, waveform analysis can corroborate the absence of pulsatile flow, further supporting the PEA diagnosis.[1][22][19]Team roles are essential for efficient assessment, with bystanders or lay rescuers initiating CPR immediately upon recognizing unresponsiveness and absent breathing or pulse, as per the 2025 American Heart Association (AHA) guidelines, which update the 2020 recommendations to emphasize early activation of emergency response systems. In healthcare settings, a rapid response or code team should be activated without delay, comprising designated roles such as a team leader for oversight, compressors for uninterrupted CPR, and airway managers, all trained through simulation to ensure coordinated action. This structured approach enhances the speed and quality of the initial evaluation.[19][23]The entire assessment must occur within 10 seconds to differentiate PEA from shockable rhythms or other arrests, allowing prompt integration of the H's and T's mnemonic to screen for reversible causes like hypovolemia or tension pneumothorax during ongoing resuscitation. This time-sensitive process underscores the need for minimal CPR interruptions, as delays beyond 10 seconds significantly reduce survival chances.[19][22][1]
Etiology
Reversible Causes
Pulseless electrical activity (PEA) is frequently attributable to potentially reversible underlying conditions, often categorized using the mnemonic of the "H's and T's" to guide systematic evaluation during resuscitation. Identifying and addressing these causes promptly is critical, as PEA survival rates are low unless a treatable etiology is corrected rapidly.[1][7]The "H's" represent key metabolic and environmental factors:
Hypovolemia: Caused by significant fluid loss from hemorrhage, dehydration, or third-spacing, leading to inadequate preload and cardiac output; addressed through aggressive fluid resuscitation with crystalloids or blood products.[1]
Hypoxia: Resulting from respiratory failure, airway obstruction, or ventilation-perfusion mismatch, this is one of the most common reversible causes, accounting for approximately 40-50% of PEA cases; managed by optimizing oxygenation and ventilation, including 100% oxygen delivery and advanced airway support if needed.[1][7]
Hydrogen ion (acidosis): Severe metabolic or respiratory acidosis impairs myocardial contractility; in cases of profound acidosis (pH <7.1), sodium bicarbonate may be administered to facilitate reversal.[1]
Hypo/hyperkalemia: Electrolyte imbalances disrupt cardiac membrane potentials; hypokalemia or hyperkalemia is corrected with targeted therapies such as potassium supplementation or insulin-glucose for hyperkalemia, alongside calcium stabilization.[1]
Hypothermia: Core temperature below 35°C reduces metabolic demand but impairs cardiac function; rewarming techniques, such as active external or invasive methods, are employed to restore normothermia.[1]
The "T's" encompass mechanical and obstructive issues:
Tamponade (cardiac): Pericardial effusion compresses the heart, preventing diastolic filling; pericardiocentesis is the definitive reversal method.[1]
Tension pneumothorax: Air accumulation in the pleural space causes mediastinal shift and reduced venous return; needle decompression followed by chest tube insertion reverses the obstruction.[1]
Thrombosis: Includes coronary thrombosis (acute myocardial infarction) and pulmonary thrombosis (massive pulmonary embolism), both obstructing blood flow; coronary cases may require thrombolysis or percutaneous coronary intervention, while pulmonary embolism benefits from anticoagulation or embolectomy if unstable.[1][24]
Toxins: Overdoses or exposures (e.g., opioids, beta-blockers, calcium channel blockers) depress cardiac activity; specific antidotes like naloxone for opioids or high-dose insulin for beta-blockers are used.[1]
Trauma: Includes hypovolemic shock from bleeding or direct cardiac injury; hemorrhage control via direct pressure, tourniquets, or surgical intervention is essential.[1]
Evaluation for these causes should occur during brief pauses in cardiopulmonary resuscitation (CPR), using point-of-care ultrasound and clinical assessment to avoid prolonging interruptions. Hypovolemia and hypoxia are among the most frequent etiologies, alongside thrombosis in certain populations. The American Heart Association's 2025 guidelines stress that rapid identification and reversal of these causes can substantially enhance return of spontaneous circulation (ROSC) rates, potentially increasing success by several-fold in responsive cases.[19][1]
Other Contributing Factors
In addition to acute reversible causes, pulseless electrical activity (PEA) can arise from chronic or non-reversible conditions that impair cardiac output or systemic perfusion over time, often serving as predisposing or precipitating factors in vulnerable patients.[1] These factors typically involve underlying structural heart disease, systemic inflammatory states, or iatrogenic insults that reduce myocardial contractility or vascular resistance without immediate correctable interventions.[7]Cardiac conditions represent a major category of such factors. Acute myocardial infarction, particularly due to coronary occlusion without progression to full infarction, can lead to transient ischemia and hypotension, precipitating PEA by diminishing ventricular filling and output.[1]Cardiomyopathy, whether dilated, hypertrophic, or restrictive, chronically weakens myocardial contractility, increasing susceptibility to electromechanical dissociation during stress or decompensation.[7] Valvular rupture, such as acute mitral or aortic regurgitation from endocarditis or post-infarction complications, causes severe hemodynamic instability by disrupting forward flow and elevating left atrial pressures, often culminating in PEA.[25]Systemic disorders also contribute significantly by inducing widespread circulatory collapse. Sepsis, through vasodilatory shock and cytokine-mediated myocardial depression, reduces systemic vascular resistance and cardiac preload, fostering PEA in critically ill patients.[1]Anaphylaxis triggers profound vasodilation and bronchospasm, leading to hypoxia and distributive shock that can rapidly evolve into PEA without prompt reversal.[7] Massive pulmonary embolism, even in the absence of acute thrombosis (such as from tumor emboli or fat), obstructs right ventricular outflow, causing acute cor pulmonale and diminished left ventricular preload.[1]Iatrogenic factors often stem from therapeutic interventions or medication errors that exacerbate underlying vulnerabilities. Overdose of beta-blockers or calcium channel blockers impairs atrioventricular conduction and myocardial inotropy, resulting in bradycardia and reduced cardiac output that manifests as PEA.[7] Procedural complications, such as those following cardiac surgery (e.g., graft failure or pericardial effusion), can precipitate PEA through mechanical obstruction or inflammatory responses.[1]Rare contributing factors include adrenal crisis, where acute cortisol deficiency in Addison's disease leads to refractory hypotension and electrolyte imbalances that trigger PEA.[26] Pulmonary embolism in the context of chronic thromboembolic pulmonary hypertension progressively burdens the right ventricle, predisposing to PEA during acute decompensation. Such rare etiologies underscore their underrecognized role in non-traumatic arrests.[7]
Diagnosis
Electrocardiographic Findings
Pulseless electrical activity (PEA) is characterized on electrocardiography by the presence of organized electrical activity in the absence of a detectable pulse, distinguishing it from asystole or ventricular fibrillation.[1] The ECG typically shows coordinated QRS complexes that would normally generate mechanical output, but in PEA, this fails due to underlying circulatory collapse.[2]Rhythms in PEA can be narrow-complex, such as sinus, junctional, or accelerated idioventricular, or wide-complex, including those with bundle branch block or ventricular escape beats.[1] The heart rate is often in the bradycardic range (e.g., median around 50 beats per minute), though it may present as bradycardia or, less commonly, tachycardia.[27] Key features include the absence of a PEA-specific waveform, with organized QRS complexes that may be mimicked by motion artifacts during resuscitation efforts.[1]During cardiac arrest, PEA rhythms may evolve into asystole if untreated, reflecting progressive myocardial dysfunction.[1]Myocardial infarction, often indicated by ST-segment changes suggestive of ischemia, is linked to approximately 30% of PEA cases of cardiac origin as an underlying cause.[15] Continuous three-lead ECG monitoring is essential throughout resuscitation to identify rhythm changes, and PEA is classified as non-shockable, precluding defibrillation attempts.[28]
Confirmatory Tests
Confirmatory tests for pulseless electrical activity (PEA) are essential to verify the absence of a palpable pulse despite organized electrical activity on electrocardiography and to identify potential underlying reversible causes during resuscitation. The primary initial step involves a brief pause in cardiopulmonary resuscitation (CPR) to perform a central pulse check, typically via manual palpation of the carotid artery, which should last no longer than 10 seconds to minimize interruptions in chest compressions. This method confirms pulselessness but has limitations in accuracy, particularly in low-flow states, where it may miss subtle cardiac output. To enhance detection, Doppler ultrasound of the carotid or femoral artery is recommended, as it identifies minimal blood flow with higher sensitivity than palpation alone, achieving detection rates up to 95% in cardiac arrest scenarios.Bedside point-of-care ultrasound (POCUS), integrated into advanced cardiac life support protocols, provides rapid visualization of cardiac function and is particularly valuable in distinguishing true PEA—characterized by no ventricular wall motion on subxiphoid or parasternal views—from pseudo-PEA, where minimal organized activity persists. In true PEA, the subxiphoid view reveals an empty, non-contracting heart chamber, while pseudo-PEA may show faint contractions or organized motion, guiding adjustments in resuscitation efforts. POCUS also detects reversible etiologies, such as pericardial effusion leading to tamponade, allowing for immediate interventions like pericardiocentesis during arrest. The 2025 European Resuscitation Council guidelines recommend the use of POCUS by skilled operators during cardiac arrest to identify reversible causes, without causing additional interruptions in chest compressions.[29]Laboratory evaluations support confirmatory diagnosis by identifying metabolic or ischemic contributors to PEA. Arterial blood gas analysis assesses for severe acidosis or hypoxia, which can precipitate or exacerbate PEA, while serum electrolyte panels detect imbalances like hyperkalemia or hypocalcemia that impair cardiac output. Elevated troponin levels indicate possible myocardial infarction as an underlying cause, prompting targeted therapies once return of spontaneous circulation is achieved.For patients stabilized post-resuscitation, advanced imaging refines the diagnosis; echocardiography evaluates detailed wall motion abnormalities, and computed tomography (CT) angiography identifies pulmonary embolism or other vascular issues if clinically suspected.
Management
Resuscitation Protocol
The resuscitation protocol for pulseless electrical activity (PEA) follows the American Heart Association's (AHA) Advanced Cardiovascular Life Support (ACLS) guidelines, emphasizing immediate initiation of high-quality cardiopulmonary resuscitation (CPR) upon confirmation of the rhythm and absence of a pulse.[30] High-quality CPR involves delivering compressions at a rate of 100-120 per minute, with a depth of at least 2 inches (5 cm) in adults, allowing full chest recoil between compressions, and minimizing interruptions to less than 10 seconds.[19] The compressor should be rotated every 2 minutes or sooner if fatigue is evident to maintain effectiveness.[30]Airway management begins with bag-mask ventilation using supplemental oxygen, employing a compression-to-ventilation ratio of 30:2 if no advanced airway is in place.[19] Once an advanced airway (such as endotracheal intubation or supraglottic device) is established, ventilation should occur asynchronously at a rate of 10 breaths per minute, with continuous chest compressions; waveform capnography is recommended to confirm placement and monitor CPR quality, targeting an end-tidal CO2 of 10-20 mm Hg.[30]Hyperventilation must be avoided to prevent complications such as increased intrathoracic pressure.[19]PEA is a non-shockable rhythm, so defibrillation is not indicated; instead, epinephrine is administered intravenously or intraosseously at a dose of 1 mg as soon as possible, with repeat doses every 3-5 minutes.[30] Early epinephrine administration is associated with improved rates of return of spontaneous circulation (ROSC).[19]Rhythm and pulse checks are performed approximately every 2 minutes, ideally during brief pauses in CPR, to assess for ROSC or rhythm changes while limiting interruptions.[30]Resuscitation continues with these interventions until ROSC is achieved or termination criteria are met, such as in out-of-hospital settings where the arrest was not witnessed by emergency medical services, no shocks were delivered, and no ROSC occurred.[23] Throughout, providers should consider screening for reversible causes, as detailed in the etiology section.[19]
Targeted Interventions
Targeted interventions for pulseless electrical activity (PEA) focus on rapidly identifying and correcting underlying reversible causes, often using the "Hs and Ts" mnemonic to guide therapy during ongoing resuscitation efforts. These cause-specific treatments are integrated with standard advanced cardiac life support (ACLS) protocols to improve the likelihood of return of spontaneous circulation (ROSC). Prompt intervention is critical, as PEA outcomes depend heavily on addressing the etiology within minutes of arrestrecognition.[19]For hypovolemia, the primary approach involves aggressive volume resuscitation with intravenous isotonic crystalloid solutions, such as normal saline or lactated Ringer's, administered in boluses of 500 to 1000 mL to restore circulating volume and improve cardiac output. In cases of hemorrhagic hypovolemia, blood product transfusion, including packed red blood cells, is prioritized to address ongoing blood loss while monitoring for signs of fluid overload via point-of-care ultrasound (POCUS).[1][19]Hypoxia is managed by ensuring adequate oxygenation through high-flow supplemental oxygen delivered via bag-valve-mask ventilation or advanced airway management, targeting a saturation of 94% to 99% once ROSC is achieved, while avoiding hyperoxia. Acidosis, often metabolic from prolonged arrest or hypoxia, is corrected primarily through effective ventilation to eliminate CO2; however, if arterial pH falls below 7.2 despite ventilation, sodium bicarbonate is administered at a dose of 1 mEq/kg intravenously to buffer severe acidosis and support hemodynamic stability.[1][31]Electrolyte imbalances, particularly potassium disturbances, require immediate correction to stabilize cardiac membranes and rhythm. Hyperkalemia is treated with intravenous calcium gluconate (10 mL of 10% solution) to antagonize cardiac toxicity, followed by insulin (10 units regular) with glucose (25 g dextrose) to shift potassium intracellularly; additional therapies like sodium bicarbonate or beta-agonists may be used per established protocols. Hypokalemia is addressed by potassium chloride supplementation (10-20 mEq intravenously over 1 hour) to maintain serum levels above 3.5 mEq/L, preventing arrhythmogenic effects. These interventions follow updated guidelines emphasizing rapid laboratory confirmation when feasible during resuscitation.[1][31]Mechanical causes demand urgent procedural interventions to relieve obstructions. Tension pneumothorax is decompressed via needle thoracostomy (14- to 16-gauge needle inserted at the second intercostal space, midclavicular line) to equalize intrathoracic pressure and restore venous return, often confirmed by POCUS or clinical signs like tracheal deviation. Cardiac tamponade requires pericardiocentesis (needle aspiration under ultrasound guidance) to drain pericardial effusion and alleviate right ventricular compression, with surgical repair considered if unstable.[19][1]In refractory PEA cases unresponsive to initial therapies, extracorporeal membrane oxygenation (ECMO) via extracorporeal cardiopulmonary resuscitation (ECPR) may be considered in specialized centers to provide mechanical circulatory support, particularly for reversible causes like severe hypovolemia or tamponade, with reported survival benefits in select in-hospital arrests.[32][19]
Prognosis
Survival Outcomes
Pulseless electrical activity (PEA) during cardiac arrest is associated with low survival rates, particularly in out-of-hospital cardiac arrest (OHCA) settings. For OHCA cases, return of spontaneous circulation (ROSC) occurs in approximately 10-20% of patients, while survival to hospital discharge ranges from 2-5%, as reported in analyses of large registries and studies.[33] These rates are notably lower than those for ventricular fibrillation (VF), where survival to discharge approaches 25% in witnessed OHCA.In contrast, in-hospital cardiac arrest (IHCA) involving PEA yields better outcomes due to immediate monitoring and rapid response capabilities. ROSC rates reach 25-35%, with survival to discharge estimated at 10-15%, based on data from the American Heart Association's Get With The Guidelines-Resuscitation registry and recent analyses.[34][35] For instance, a 2023 study of over 147,000 IHCA events found a 19.1% survival to discharge for PEA rhythms.[34]Recent trends indicate modest improvements in OHCA survival for PEA, with discharge rates around 8% in some reports.[36] Additionally, pseudo-PEA—characterized by organized cardiac activity visible on ultrasound despite absent palpable pulses—has a more favorable prognosis than true PEA, with meta-analyses showing substantially higher odds of ROSC and survival (odds ratios exceeding 4 in some cases).[37]Certain contextual factors influence these aggregate outcomes. Witnessed arrests increase ROSC likelihood in PEA cases due to minimized downtime.[38] Conversely, delays in CPR initiation lead to exponential reductions in survival, with each additional minute decreasing ROSC and discharge probabilities sharply.[5][39]
Prognostic Factors
Several factors influence the prognosis in pulseless electrical activity (PEA), with early intervention playing a critical role in improving outcomes. The initiation of bystander cardiopulmonary resuscitation (CPR) significantly enhances survival rates compared to cases without bystander CPR.[7] Identification and rapid correction of reversible causes, such as hypovolemia, substantially improve return of spontaneous circulation (ROSC) rates when addressed promptly during resuscitation.[7] Additionally, the pseudo-PEA subtype—characterized by organized electrical activity with detectable myocardial motion on ultrasound despite no palpable pulse—carries a more favorable prognosis than true PEA, with higher ROSC and survival to discharge rates due to its association with low-output states rather than complete cardiac standstill.[40]Negative prognostic indicators include prolonged downtime, where durations exceeding 10 minutes are linked to markedly reduced survival probabilities owing to cumulative ischemic damage.[41] Non-witnessed arrests further worsen outcomes, with survival rates substantially lower than in witnessed events due to delayed recognition and initiation of resuscitation efforts.[42] Advanced age over 80 years correlates with poorer survival, reflecting diminished physiologic reserve and higher comorbidity burden.[15] Comorbidities such as chronic kidney disease (CKD) independently predict poor neurological recovery, increasing mortality risk regardless of renal replacement therapy status.[43]Biomarkers provide additional prognostic insight during resuscitation. Elevated serum lactate levels greater than 10 mmol/L signal severe tissue hypoperfusion and are strongly associated with adverse outcomes, including low ROSC and high mortality.[44] Similarly, end-tidal carbon dioxide (ETCO2) values below 10 mmHg during CPR indicate inadequate cardiac output and pulmonary blood flow, serving as a marker of futility with minimal chance of successful resuscitation.[45]In the long term, out-of-hospital cardiac arrest (OHCA) presenting with PEA yields neurologic intact survival rates below 10%, highlighting the challenge of preserving brain function amid prolonged hypoxia.[15] Among survivors, approximately 70% require rehabilitation due to persistent neurologic deficits, as noted in 2022 analyses emphasizing the need for multidisciplinary post-arrest care.[15] The 2025 American Heart Association guidelines note potential benefits of sodium bicarbonate in select PEA cases, which may influence future prognostic considerations.[19]