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Return of spontaneous circulation

Return of spontaneous circulation (ROSC) is the restoration of a sustained and effective blood flow following , achieved through recovery of native cardiac function without reliance on mechanical circulatory support such as . This event marks the immediate goal of (CPR) efforts, indicating the transition from active resuscitation to post-arrest care. ROSC is a critical intermediate outcome in the of both in-hospital and out-of-hospital , with its achievement serving as a prerequisite for potential survival and neurological recovery. In large registries, ROSC rates vary by setting; for in-hospital , they typically range from 60% to 72% among patients receiving CPR, influenced by factors such as location, initial rhythm, CPR quality, and time to or epinephrine administration, while out-of-hospital rates are lower, typically 20% to 40%. For instance, data from over 348,000 in-hospital adult cases (2000-2021) show that approximately 66.9% achieve ROSC, though only about 22.6% survive to discharge. Post-ROSC care is essential to optimize outcomes and focuses on hemodynamic stability, , and identifying reversible causes of arrest. Guidelines recommend maintaining above 65 mm Hg, avoiding , and performing immediate 12-lead ECG to evaluate for coronary intervention. Sustained ROSC, defined as lasting at least 20 minutes or until arrival, is associated with higher rates of favorable neurological recovery compared to transient episodes. Despite advances, challenges persist, including rearrest risk and long-term morbidity, underscoring the need for multidisciplinary post-arrest protocols.

Definition and Physiology

Definition

Return of spontaneous circulation (ROSC) is defined as the return of effective , evidenced by a palpable pulse or measurable , following , achieved through recovery of intrinsic cardiac function without the need for mechanical circulatory support such as (ECMO). This resumption indicates the restoration of autonomous, perfusing heart rhythm that sustains adequate circulation to vital organs. The term ROSC was formalized in the early 1990s as part of the Utstein-style guidelines for uniform reporting of outcomes, developed by an international task force including the and European Resuscitation Council to standardize data collection and facilitate comparative research. These guidelines established ROSC as a key intermediate outcome metric in protocols. ROSC is distinguished from transient or partial circulation recovery, where a brief return of pulses (lasting approximately 30 seconds or more but less than 20 minutes) may occur but fails to persist without ongoing intervention, often leading to re-arrest. Sustained ROSC, by contrast, requires maintenance for at least 20 minutes or until transfer to advanced care, ensuring stability beyond immediate efforts. As a critical link in the chain of survival for patients, achieving ROSC markedly improves prospects for neurological recovery and long-term survival.

Physiological Mechanisms

Return of spontaneous circulation (ROSC) involves the restoration of effective following a period of , primarily through the reversal of ischemia-induced metabolic and electrophysiological derangements. During , myocardial ischemia leads to rapid depletion of (ATP), accumulation of metabolic byproducts, and disruption of ion homeostasis, impairing contractility. With adequate coronary perfusion pressure () generated during (CPR)—defined as the difference between diastolic aortic and right atrial pressures—myocardial blood flow is partially maintained, delivering oxygen and substrates necessary for ATP replenishment and cellular recovery. Studies in animal models demonstrate that CPP exceeding 20 mm Hg correlates with successful ROSC by enabling sufficient myocardial oxygenation to support and spontaneous electrical and mechanical activity. Upon ROSC, ATP levels begin to recover as aerobic resumes, with short durations of effective CPR preventing further depletion during ; for instance, 2 minutes of CPR can maintain myocardial ATP near baseline levels (approximately 5.3 nmol/mg protein) compared to progressive decline without intervention. This replenishment reactivates ATP-dependent ion pumps, such as Na⁺/K⁺-ATPase and Ca²⁺-ATPase, facilitating recovery and normalization of transmembrane potentials disrupted by ischemia-induced and calcium overload. Reversal of these changes restores calcium handling and myofilament sensitivity, alleviating global characterized by reduced (often dropping to 20-30% post-ROSC) and elevated end-diastolic pressure. In models, this contractile dysfunction is transient, with systolic and diastolic function recovering to baseline within 24-48 hours as ischemia is reversed. Systemically, ROSC initiates reperfusion of vital organs, resolving hypoxia-induced cellular damage by restoring oxygen delivery and mitigating oxidative stress from reactive oxygen species generated during the transition from anaerobiosis. This process clears accumulated and corrects , with arterial normalizing through restored ventilation and , typically achieving normocarbia (PaCO₂ 40-45 mm Hg) to support acid-base balance. Endothelial activation and microcirculatory dysfunction may persist initially, but overall, reperfusion reduces the oxygen debt accrued during , preventing progression to multi-organ failure and enabling resolution of hypoxia-related in the , kidneys, and other tissues over hours to days.

Clinical Achievement

Role in Cardiac Arrest Management

Return of spontaneous circulation (ROSC) serves as a critical milestone in management, marking the successful restoration of palpable pulses and effective after a period of circulatory arrest. This achievement shifts the focus from immediate resuscitation to post-arrest stabilization, preventing further organ damage and improving chances for neurological recovery. In the American Heart Association's framework, ROSC bridges the initial links of early recognition, high-quality (CPR), and with advanced interventions and integrated post-resuscitation care, emphasizing a seamless continuum from community response to hospital-based recovery. ROSC rates differ markedly by cardiac arrest location, influencing overall management strategies. For out-of-hospital cardiac arrest (OHCA), recent large-scale studies report ROSC in approximately 31% of cases treated by , reflecting challenges like delayed bystander and transport logistics. In contrast, in-hospital cardiac arrest (IHCA) yields higher ROSC rates of about 72%, attributed to immediate access to advanced monitoring and team responses. Monitoring for ROSC during ongoing is essential to confirm success without excessive interruptions to CPR. Key clinical signs include of a central , such as at the , and electrocardiographic (ECG) evidence of an organized rhythm rather than or . Additionally, a abrupt increase in end-tidal (ETCO₂) to greater than 10 mmHg, detected via waveform capnography, provides a reliable, non-invasive indicator of restored circulation, as it reflects improved and pulmonary .

Interventions to Achieve ROSC

High-quality (CPR) forms the cornerstone of interventions aimed at achieving return of spontaneous circulation (ROSC) during . According to the 2025 () guidelines, effective CPR involves delivering chest compressions with a depth of at least 5 cm (2 inches) but not exceeding 6 cm to optimize coronary and cerebral without causing injury, at a rate of 100-120 compressions per minute to maintain adequate , and minimizing interruptions to achieve a chest compression fraction of greater than 80% (Class of Recommendation [COR] 1, Level of Evidence [LOE] B-NR). These parameters, supported by observational studies linking them to improved rates, emphasize full chest recoil between compressions and avoiding excessive to prevent hyperventilation-related complications. Defibrillation is a critical intervention for shockable rhythms such as (VF) or pulseless (VT), where early delivery significantly enhances ROSC chances. The 2025 guidelines recommend immediate for witnessed arrests with a defibrillator readily available, followed by resumption of CPR without pausing for rhythm analysis to limit perishock pauses (COR 1, LOE B-R). For biphasic defibrillators, initial energy levels of 120-200 J are standard for VF/VT, escalating if needed based on device manufacturer recommendations, as this range balances efficacy in terminating arrhythmias with safety (COR 1, LOE B-NR). If the initial shock fails, CPR should continue for 2 minutes before reassessment, integrating attempts into the rhythm check cycle. Pharmacological agents serve as adjuncts when CPR and defibrillation alone do not achieve ROSC. Epinephrine, administered at 1 mg intravenously or intraosseously every 3-5 minutes, is recommended to increase coronary and cerebral pressures, improving rates of ROSC and short-term , though without clear benefits for long-term neurological outcomes (COR 1, LOE B-R). For VF or VT after multiple shocks, (300 mg initial dose, followed by 150 mg if needed) may be considered to stabilize membranes and facilitate success, with evidence showing improved hospital admission rates but not discharge (COR IIb, LOE B-R). Dosing should align with protocols to avoid delays in core interventions. Advanced techniques complement standard measures in select scenarios. Airway management, such as supraglottic devices or endotracheal , is an adjunct to ensure oxygenation and while minimizing CPR interruptions, particularly in prolonged arrests, though bag-mask remains first-line for most (COR 1, LOE C-LD). Mechanical CPR devices, which provide automated compressions, may be used in challenging environments like or when occurs, but routine deployment is not recommended due to limited evidence of survival benefit over high-quality CPR (COR IIb, LOE C-LD). These tools should integrate seamlessly to sustain until ROSC or advanced care arrives.

Predictors

Pre-Arrest and Patient Factors

Pre-arrest patient factors, including demographics and comorbidities, significantly influence the likelihood of achieving return of spontaneous circulation (ROSC) during . Younger age is consistently associated with higher ROSC rates, as physiological reserve and fewer accumulated comorbidities enhance resuscitation success. For instance, patients under 50 years exhibit substantially higher ROSC rates compared to those over 80 years, with a progressive decline in success with advancing age due to reduced cardiac and vascular resilience. Sex differences in ROSC show variability across studies, with some evidence of a slight advantage for males, potentially linked to higher prevalence of shockable rhythms and earlier intervention in male patients. However, other analyses report no significant sex-based disparity in ROSC achievement, emphasizing that and characteristics often overshadow effects. Comorbidities compromise baseline cardiac reserve and are inversely associated with ROSC probability. Diabetes mellitus, whether with or without complications, correlates with lower ROSC rates by promoting microvascular disease and impaired myocardial function. Prior reduces ROSC likelihood through scar tissue formation and diminished ventricular compliance, while renal failure exacerbates outcomes via electrolyte imbalances and fluid overload that hinder effective . Increasing comorbidity burden overall decreases ROSC odds, with renal disease and emerging as particularly detrimental in large cohorts. Arrest circumstances such as witnessed status and bystander-initiated CPR represent modifiable pre-arrest factors that markedly improve ROSC chances. Witnessed arrests double to quadruple the odds of ROSC compared to unwitnessed events, as immediate recognition allows for prompt CPR initiation and minimizes ischemic time. Bystander CPR further enhances ROSC rates, with meta-analyses reporting 2- to 3-fold increased odds (e.g., OR 2.44, 95% CI 1.69-3.19) by sustaining until professional help arrives. These factors underscore their role in planning, where early community response can substantially boost immediate recovery prospects.

Intra-Arrest and Procedural Factors

The initial cardiac rhythm at the onset of arrest is a critical intra-arrest predictor of ROSC, with shockable rhythms such as (VF) and pulseless (VT) associated with substantially higher success rates compared to non-shockable rhythms like and (PEA). In recent analyses, patients presenting with shockable rhythms achieve ROSC in up to 70-80% of cases under optimal conditions, such as rapid , whereas non-shockable rhythms yield ROSC rates of approximately 20-30%, reflecting poorer myocardial and reversibility. This disparity underscores the prognostic value of early rhythm assessment, as conversion from non-shockable to shockable rhythms during can improve outcomes, though persistent non-shockable states correlate with futility. The duration of cardiopulmonary resuscitation (CPR) exerts a profound influence on ROSC probability, with shorter intervals yielding the highest success rates due to minimized ischemic damage to vital organs. Evidence indicates an optimal window of less than 20 minutes from onset to ROSC for the best outcomes, as prolonged efforts beyond this threshold exponentially reduce ROSC likelihood, with cumulative downtime effects compounding metabolic derangements and . For instance, most ROSC events occur within the first 15-20 minutes of high-quality CPR, and extending beyond 25 minutes is linked to , particularly in non-shockable s. Real-time quality metrics during CPR, including end-tidal CO2 (ETCO2) trends and (CPP), serve as noninvasive and invasive indicators of efficacy and ROSC potential. ETCO2 values rising above 10-20 mmHg during ongoing compressions predict successful ROSC with high sensitivity, as increasing trends reflect improving and pulmonary blood flow, while persistent levels below 10 mmHg after 20 minutes signal low likelihood of recovery. Similarly, maintaining above 15 mmHg—calculated as the difference between diastolic aortic pressure and right atrial pressure—during CPR is an established threshold for myocardial viability, with values meeting or exceeding this level correlating directly with ROSC achievement in clinical studies. These metrics enable dynamic adjustments to CPR , such as compression depth and rate, to optimize . Location of the influences ROSC through variations in response time and , with in-hospital cardiac arrests (IHCA) generally showing higher ROSC rates than out-of-hospital (OHCA) due to immediate access to advanced interventions. As of 2024, data report IHCA ROSC rates approximately 50-60%, compared to 25-35% for OHCA, attributable to shorter mean response times (under 2 minutes versus 7-10 minutes for arrival in OHCA). These differences highlight how procedural delays in OHCA amplify downtime effects, interacting with patient-specific factors like age to further modulate outcomes.

Post-ROSC Management

Immediate Stabilization

Upon achieving return of spontaneous circulation (ROSC), immediate stabilization focuses on optimizing vital organ and preventing secondary injury through targeted interventions in , oxygenation, , glucose management, and cardiac evaluation. These steps are critical in the first minutes to hours post-ROSC to support and reduce morbidity. Hemodynamic support is prioritized to ensure adequate cerebral and coronary . The 2025 (AHA) guidelines recommend maintaining a minimum (MAP) of at least 65 mm Hg to avoid , which can exacerbate ischemic damage. Continuous invasive arterial monitoring is advised for precise assessment. If persists despite adequate fluid , vasopressors are recommended, though no specific agent is preferred due to insufficient evidence, titrated to achieve the MAP target while monitoring for arrhythmias or tissue hypoperfusion. Airway management and ventilation are essential to prevent hypoxia and hyperoxia, both of which can worsen neurological outcomes. After ROSC, supplemental oxygen should initially be administered at 100% fraction of inspired oxygen (FiO2) until pulse oximetry or arterial blood gas can reliably measure saturation, then titrated to maintain peripheral oxygen saturation (SpO2) between 90% and 98% (corresponding to partial pressure of arterial oxygen [PaO2] 60–105 mm Hg) to avoid hyperoxemia-induced oxidative stress. For intubated patients, mechanical ventilation should use low tidal volumes of 6–8 mL/kg of predicted body weight, with respiratory rate adjusted to target partial pressure of arterial carbon dioxide (PaCO2) of 35–45 mm Hg in the absence of severe acidosis, confirmed via arterial blood gas analysis. Waveform capnography is used to verify endotracheal tube placement and guide ventilation. Glucose control is managed to prevent metabolic derangements that could impair brain recovery. The 2025 guidelines emphasize avoiding (blood glucose <70 mg/dL) through frequent monitoring and insulin administration if necessary, as well as preventing hyperglycemia (>180 mg/dL), which is associated with increased mortality; every 1–4 hours is recommended during the initial stabilization phase. A 12-lead electrocardiogram (ECG) should be obtained as soon as possible after ROSC, ideally within 10 minutes, to evaluate for ST-segment elevation (STEMI) or other arrhythmias. If STEMI is identified, or in cases of persistent ST-elevation, , or recurrent ventricular arrhythmias, emergency coronary angiography with potential is indicated, regardless of coma status, to address underlying . This approach is supported by evidence showing improved survival in select post-arrest patients with acute coronary pathology.

Targeted Therapies

Following return of spontaneous circulation (ROSC), (TTM) is a cornerstone therapy for in comatose adult patients, involving controlled temperature maintenance to mitigate hypoxic-ischemic brain injury. According to the 2025 () guidelines, TTM targets a range of 32–37.5°C for at least 36 hours in patients remaining unresponsive to verbal commands after ROSC, with no single temperature proven superior across this spectrum. This approach, evolved from earlier protocols emphasizing stricter , prioritizes fever prevention alongside optional mild hypothermia, particularly in cases of out-of-hospital with shockable rhythms. To facilitate TTM and minimize patient discomfort, and analgesia protocols are essential, employing short-acting agents to achieve deep (Richmond Agitation-Sedation Scale ≤ -4) for the initial 40 hours post-ROSC. is commonly utilized at moderate-to-high doses (e.g., 100–150 mg/kg over 24 hours during cooling), showing associations with improved functional outcomes and survival in post-hoc analyses of trials like TTM2. serves as an alternative or adjunct, particularly for its reduced respiratory depression, though its use is less frequent (around 14% in good-outcome cohorts) and not independently linked to superior results. Long-acting benzodiazepines like are avoided due to risks of prolonged effects and potential exacerbation. Seizure management post-ROSC focuses on early detection and targeted to prevent secondary brain injury, with continuous or repeated (EEG) recommended for at least 24 hours in comatose patients not following commands. Prompt EEG is specifically advised for patients exhibiting after ROSC to identify electrographic correlates, as myoclonic jerks alone do not warrant without activity confirmation. A therapeutic trial of nonsedating antiseizure medications, such as or , is reasonable for EEG patterns on the ictal-interictal continuum, though routine prophylactic antiseizure therapy is not recommended due to lack of outcome benefits. Multidisciplinary care bundles integrate these therapies with advanced support options, emphasizing coordinated protocols to optimize recovery and address refractory complications like . Transfer to specialized centers is prioritized for patients requiring (ECMO), which may be considered in highly selected cases of persistent shock unresponsive to conventional measures. These bundles also facilitate equitable access and ongoing reassessment of patient selection criteria to enhance overall post-ROSC outcomes.

Prognosis and Complications

Survival and Neurological Outcomes

Return of spontaneous circulation (ROSC) marks a critical milestone in cardiac arrest management, but subsequent survival remains challenging. For out-of-hospital cardiac arrest (OHCA), approximately 25-30% of patients achieve ROSC, with survival to hospital discharge among those with ROSC ranging from 25% to 40%, reflecting an overall discharge rate of about 10.5% across all EMS-treated cases. In contrast, in-hospital cardiac arrest (IHCA) yields higher ROSC rates of 50-70%, and post-ROSC survival to discharge is typically 30-40%, contributing to an overall IHCA discharge rate of around 23.6%. These rates have shown modest improvements over time, with adjusted odds of post-ROSC survival to discharge increasing slightly from 30.3% in earlier cohorts to 31.4% in recent data. Short- and medium-term survival post-ROSC further declines beyond hospital discharge. Among OHCA patients achieving ROSC, 30-day survival hovers around 20-25%, while 1-year survival drops to 15-20%, with similar patterns observed in IHCA where 30-day rates reach 30-35% and 1-year rates 25-30%. These trends underscore the vulnerability of the post-ROSC phase, where early stabilization plays a pivotal role in preventing recurrent instability. Neurological outcomes are a primary concern following ROSC, often assessed using the Cerebral Performance Category (CPC) scale, where CPC 1-2 denotes good neurological recovery (conscious and independent in daily activities) and CPC 3-5 indicates poor outcomes (severe disability, coma, or death). Among hospital survivors post-ROSC, 70-80% achieve CPC 1-2, though this proportion is lower in OHCA (around 60-70%) compared to IHCA (80-90%) due to prolonged ischemia in out-of-hospital settings. A shorter time to ROSC, particularly under 20 minutes, strongly correlates with favorable CPC 1-2 recovery, as prolonged resuscitation exceeds the brain's tolerance for hypoxia, with outcomes deteriorating sharply beyond 15-20 minutes. Biomarkers aid in prognosticating neurological recovery post-ROSC. Elevated neuron-specific enolase (NSE) levels greater than 60 μg/L at 48 or 72 hours after ROSC are suggestive of poor neurological outcomes as part of prognostication, according to 2025 and European Council guidelines. Higher thresholds (e.g., >80-100 μg/L) may be used for greater specificity in predicting poor outcomes, reflecting neuronal damage from ischemia-reperfusion injury. This approach, established in recent studies and guidelines, supports prognostication when combined with clinical assessments, though values can vary with therapeutic interventions like temperature management.

Associated Complications

Following return of spontaneous circulation (ROSC), patients often develop (PCAS), a multifaceted condition characterized by interdependent pathophysiological processes. The primary components include hypoxic-ischemic , resulting from prolonged cerebral hypoperfusion and subsequent neuronal damage; , which manifests as transient left ventricular dysfunction despite restored circulation; and systemic ischemia-reperfusion , involving widespread , inflammation, and that exacerbate organ damage. Multi-organ failure represents a major complication within PCAS, with (AKI) occurring in 30-50% of cases due to hypoperfusion, , and inflammatory mediators during resuscitation. This renal insult often requires and contributes to prolonged intensive care needs. Infections are prevalent, particularly early-onset in mechanically ventilated patients, affecting up to 50% of survivors and driven by during , immune suppression, and invasive . Bleeding risks are heightened by anticoagulation therapies commonly initiated for underlying coronary pathology or during procedures like , compounded by CPR-induced trauma, hypothermia-induced , and systemic inflammation, leading to hemorrhagic events in a significant subset of patients. In 2025 updates to guidelines, there is increased emphasis on bundled care protocols to prevent rearrest and mitigate these complications, including integrated hemodynamic monitoring, early , and management within comprehensive post-ROSC systems of care. Targeted post-ROSC therapies, such as and hemodynamic optimization, have been shown to reduce the incidence of these adverse events by addressing underlying ischemia-reperfusion mechanisms.

References

  1. [1]
    Part 1: Executive Summary: 2025 American Heart Association ...
    Oct 22, 2025 · When return of spontaneous circulation is due to recovery of cardiac function without mechanical intervention, the term ROSC is used. Utstein ...
  2. [2]
    Risk‐Standardizing Rates of Return of Spontaneous Circulation for ...
    Mar 21, 2020 · Sustained return of spontaneous circulation (ROSC) is the most proximal and direct assessment of acute resuscitation quality in hospitals.
  3. [3]
    Duration of cardiopulmonary resuscitation and outcomes for adults ...
    Feb 7, 2024 · Achieving return of spontaneous circulation is the first step toward long term survival and favorable functional recovery. However, for nearly ...
  4. [4]
    Trends in Return of Spontaneous Circulation and Survival ... - PubMed
    Of the 114,371 ICU cardiac arrests, 70,610 (61.7%) achieved ROSC, and 21,747 (19.0%) survived until hospital discharge. The rate of ROSC improved from 2006 to ...
  5. [5]
    Association between duration of return of spontaneous circulation ...
    Return of spontaneous circulation is a core outcome element of CPR. It should be defined as sustained for at least 20 minutes or until arrival at the emergency ...
  6. [6]
    Abstract Sa902: Re-arrest Immediately after Return of Spontaneous ...
    Nov 11, 2024 · ROSC was defined as an organized ECG rhythm compatible with a pulse, accompanied by the absence of chest compressions for at least one minute.
  7. [7]
    https://www.ahajournals.org/doi/10.1161/circ.150.suppl_1.Sa902
  8. [8]
    the Utstein Style. A statement for health professionals from ... - PubMed
    Recommended guidelines for uniform reporting of data from out-of-hospital cardiac arrest: the Utstein Style.Missing: formalized | Show results with:formalized
  9. [9]
    Update of the Utstein Resuscitation Registry Templates for Out-of ...
    Nov 11, 2014 · The term “Utstein style” is synonymous with consensus reporting guidelines for resuscitation. It originated from an international ...
  10. [10]
    Post–Cardiac Arrest Syndrome | Circulation
    For example, depending on whether ROSC is defined as a brief (approximately >30 seconds) return of pulses or spontaneous circulation sustained for >20 minutes, ...
  11. [11]
    improving cardiac resuscitation outcomes both inside and outside ...
    Jun 25, 2013 · ROSC after CPR is dependent on adequate myocardial oxygen delivery and myocardial blood flow during CPR. Coronary perfusion pressure (CPP, the ...
  12. [12]
    Coronary perfusion pressure and return of spontaneous circulation ...
    One limited clinical study reported that a threshold of 15 mmHg was necessary for return of spontaneous circulation (ROSC), and that CPP was predictive of ROSC.
  13. [13]
    https://pubmed.ncbi.nlm.nih.gov/19947871/
  14. [14]
    Myocardial dysfunction after resuscitation from cardiac arrest
    This study investigated the effect of prolonged cardiac arrest and subsequent cardiopulmonary resuscitation on left ventricular systolic and diastolic function.Missing: ROSC | Show results with:ROSC
  15. [15]
    Part 6: Advanced Cardiovascular Life Support | Circulation
    Adequate alveolar ventilation is central for control of acid-base balance during cardiac arrest and the postarrest period. Hyperventilation corrects respiratory ...
  16. [16]
    Advanced Airway Practice Patterns and Out-of-Hospital Cardiac ...
    Sep 17, 2025 · ROSC occurred in 30.8% of patients; 10.4% survived to hospital discharge, and 8.3% survived with good neurologic recovery. ROSC, survival to ...
  17. [17]
    Part 9: Adult Advanced Life Support: 2025 American Heart ...
    Oct 22, 2025 · Data indicates that about 72.2% of these patients achieve return of spontaneous circulation (ROSC), with survival to hospital discharge rates ...
  18. [18]
    Part 7: Adult Basic Life Support: 2025 American Heart Association ...
    Oct 22, 2025 · The routine use of mechanical CPR devices is not recommended for adults in cardiac arrest. 7. For adult patients who are not breathing normally ...
  19. [19]
    Defibrillation - StatPearls - NCBI Bookshelf - NIH
    Mar 23, 2025 · If VF or pulseless VT persists, CPR is immediately resumed, and the patient may be shocked again. The manufacturer recommended dose (120-200 ...Introduction · Anatomy and Physiology · Preparation · Technique or Treatment
  20. [20]
    [PDF] Age-related differences in the prehospital management of 2,500 ...
    Nov 5, 2020 · Survival among older patients with OHCA is worse than in younger subjects, which results from lower efficacy of resuscitation and more frequent ...<|separator|>
  21. [21]
    Sex differences in survival after out-of-hospital cardiac arrest: a meta ...
    Oct 19, 2020 · The meta-analysis included 1,268,664 patients. Compared with males, females were older (69.7 years vs. 65.4 years, p < 0.05) and more frequently ...
  22. [22]
    The effect of sex and age on return of spontaneous circulation and ...
    Both younger females and younger males have higher odds of survival to hospital discharge compared to older females and males.
  23. [23]
    Comorbidity and survival in out-of-hospital cardiac arrest
    The most frequent comorbidities were a history of congestive heart failure (CHF) (29%), myocardial infarction (MI) (24%), and diabetes without complications (23 ...
  24. [24]
    Comorbidity and survival in out-of-hospital cardiac arrest - PubMed
    Oct 10, 2018 · The most common comorbidities were a history of congestive heart failure (29%), myocardial infarction (24%), and diabetes without complications ...
  25. [25]
    Effect of end-stage kidney disease on the return of spontaneous ...
    May 16, 2023 · This study hypothesizes that OHCA patients with ESKD undergoing maintenance hemodialysis have (1) higher rates of return of spontaneous circulation (ROSC) ...
  26. [26]
    Predictors of Survival From Out-of-Hospital Cardiac Arrest | Circulation
    Nov 10, 2009 · In this meta-analysis, we evaluated the strength of associations between OHCA and key factors (event witnessed by a bystander or emergency ...
  27. [27]
    Understanding the Importance of the Lay Responder Experience in ...
    Mar 21, 2022 · In a meta-analysis of 19 studies involving 232 703 patients, the provision of bystander CPR approximately doubles an individual's odds of ...
  28. [28]
    Comparison of return of spontaneous circulation prediction scores in ...
    Jul 1, 2025 · Prehospital-ROSC score was the most accurate predictor of ROSC in patients experiencing cardiac arrest during ambulance transport.
  29. [29]
    The link between initial cardiac rhythm and survival outcomes in in ...
    Apr 1, 2024 · ASY and PEA are non-shockable rhythms, while VF and PVT are shockable. The two factors that have been shown to be most strongly associated with ...
  30. [30]
    Prognostic Impact of Heart Rhythm Shockability Trajectory in Out-of ...
    May 17, 2024 · Shockable rhythms, including ventricular fibrillation and pulseless ventricular tachycardia, have a better prognosis than nonshockable rhythms, ...What The Study Adds · Study Setting · Statistical Analysis
  31. [31]
    Association Between Duration of Resuscitation and Favorable ...
    Oct 3, 2016 · Conventional resuscitation is most effective within the first 20 minutes, by which time 90% of patients with favorable neurological recovery had ...
  32. [32]
    Duration of in-hospital cardiopulmonary resuscitation and its effect ...
    Sep 19, 2019 · Our study shows that CPR duration is inversely associated with the establishment rates of ROSC. Most of the benefits of CPR can be achieved in the first 15 min.
  33. [33]
    Optimal cardiopulmonary resuscitation duration for favorable ...
    Jan 15, 2022 · Conclusions. The optimal cut-off for total CPR duration to achieve favorable neurological outcomes was 21–25 min. Thereafter, the effect of ...
  34. [34]
    Temporal Trends in End-Tidal Capnography and Outcomes in Out-of ...
    Jul 5, 2024 · In ROSC cases, median EtCO2 increased from 30.5 (IQR, 22.4-54.2) mm Hg to 51.0 (IQR, 37.6-64.1) mm Hg over resuscitation (P for trend = .001).
  35. [35]
    Utility of end-tidal carbon dioxide to guide resuscitation termination ...
    Patients with an ETCO2 ≥ 10 mmHg at any time point were more likely to achieve return of spontaneous circulation (ROSC), while patients below this value at 20 ...<|separator|>
  36. [36]
    Coronary Perfusion Pressure - StatPearls - NCBI Bookshelf
    Jan 22, 2025 · A value of at least 15 mm Hg predicts the return of spontaneous circulation. Physiology. The difference between ADP and LVEDP determines CPP ...
  37. [37]
    Coronary Perfusion Pressure and Return of Spontaneous ...
    One limited clinical study reported that a threshold of 15 mmHg was necessary for return of spontaneous circulation (ROSC), and that CPP was predictive of ROSC.
  38. [38]
    https://www.tandfonline.com/doi/abs/10.3109/10903120903349796
  39. [39]
    Variation in Out-of-Hospital Cardiac Arrest Survival Across ...
    Jun 14, 2022 · At the patient level, the mean EMS response time was 10.1±14.3 minutes, and sustained ROSC was achieved in 30.6% of patients. Overall, 70 752 ( ...<|control11|><|separator|>
  40. [40]
    Assessment of Emergency Medical Service (EMS) response times ...
    Shorter EMS response times were significantly associated with higher ROSC rates, with a mean response time of 7.92 min for ROSC cases (SD = 4.86) versus 8.29 ...
  41. [41]
    Part 11: Post–Cardiac Arrest Care: 2025 American Heart ...
    Oct 22, 2025 · ... ROSC, return of spontaneous circulation. Document Review and Approval. These guidelines were submitted for blinded peer review to 5 subject ...<|control11|><|separator|>
  42. [42]
    [PDF] Adult Post–Cardiac Arrest Care Algorithm
    Treat arrest etiologies and complications. Consider emergency coronary angiography and/or mechanical circulatory support. Initial stabilization after ROSC.<|control11|><|separator|>
  43. [43]
    Sedation and analgesia in post-cardiac arrest care - NIH
    Jun 17, 2025 · TTM and fever management are recommended to mitigate hypoxic-ischemic brain injury and improve functional outcomes, with sedation and analgesia ...
  44. [44]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC12175406/
  45. [45]
    Trends in Return of Spontaneous Circulation and Survival to ...
    May 5, 2022 · We sought to examine outcomes of in-ICU cardiac arrests, evaluating both achievement of return of spontaneous circulation (ROSC) and ...
  46. [46]
    Long-term survival and health-related quality of life after in-hospital ...
    Of these patients 394 (55.3%) achieved ROSC, 231 (32.4%) survived to hospital discharge and 198 (27.8%, 95 %CI 23.9%–30.5%) survived one year after cardiac ...
  47. [47]
    Predicting survival and neurological outcome in out-of-hospital ...
    Feb 9, 2023 · Given the discrepancy between rates of return of spontaneous circulation (ROSC) and 30-days survival – which may differ up to 10-fold – it is ...
  48. [48]
    Duration of resuscitation and long-term outcome after in-hospital ...
    Among 30-day survivors, survival without anoxic brain damage or nursing home admission within one-year post-arrest was highest for group A (80.4%; 78.2–82.6%), ...
  49. [49]
    Predicting Survival with Good Neurological Outcome Within 24 ...
    Patients with CPC 1 or 2 were considered to have a good neurologic outcome while those with CPC 3, 4 or 5 were considered to have a bad neurologic outcome.
  50. [50]
    Duration of Resuscitation Efforts and Functional Outcome After Out ...
    Nov 17, 2013 · Our findings suggest that conventional resuscitation strategies are most effective within the first 10 to 15 minutes, by which time >75% of ...
  51. [51]
    Association between Cardiac Arrest Time and Favorable ... - NIH
    Patients who achieve a return of spontaneous circulation (ROSC) with prolonged cardiac arrest have been recognized to have a poor prognosis.
  52. [52]
    Neuron-specific enolase & neurological outcome OHCA
    Results from early studies on patients resulted in guidelines suggesting NSE > 33 μg/L within three days after cardiac arrest predicted poor outcome with no ...
  53. [53]
    Time Course of Serum Neuron-Specific Enolase | Stroke
    The maximum NSE level measured within 72 hours after ROSC was also significantly higher in patients with a bad neurological outcome (45.2±57.3 versus 16.5±7.2 ...
  54. [54]
    Mild therapeutic hypothermia alters neuron specific enolase as an ...
    In the large Prognosis in Postanoxic Coma Study Group (PROPAC) all patients with NSE levels >33 μg/l at any time had an unfavourable outcome [6].Missing: biomarker | Show results with:biomarker
  55. [55]
    Post Cardiac Arrest Syndrome | Circulation
    Apr 5, 2011 · This syndrome, called the post cardiac arrest syndrome, comprises anoxic brain injury, post cardiac arrest myocardial dysfunction, systemic ischemia/ ...
  56. [56]
    Acute kidney injury after out-of-hospital cardiac arrest - Critical Care
    May 18, 2024 · Acute kidney injury (AKI) is a serious complication occurring in around 40% of patients resuscitated after out-of-hospital cardiac arrest ...
  57. [57]
    Acute kidney injury after cardiac arrest - PMC - PubMed Central
    AKI occurred in more than 40% of patients after CA. These patients had more severe hemodynamic impairment and needed more aggressive ICU therapy.Missing: complications | Show results with:complications
  58. [58]
    Early-Onset Pneumonia after Cardiac Arrest - ATS Journals
    Feb 23, 2011 · We found that early-onset pneumonia was a common complication in survivors of out-of-hospital cardiac arrest and that therapeutic hypothermia represented an ...
  59. [59]
    Infectious complications in survivors of cardiac arrest admitted to the ...
    New infections developed in 46%. The most common infection was pneumonia (65%) and the most common pathogen Staphylococcus aureus (31%). Blood cultures were ...
  60. [60]
    Bleeding and Thrombosis in Patients With Out‐of‐Hospital ...
    May 3, 2024 · The heightened risk of bleeding is thought to be related to trauma from prolonged CPR, hypothermia, and coagulopathy associated with postcardiac ...
  61. [61]
    Balancing thrombosis and bleeding after out-of-hospital cardiac ...
    Patients who are resuscitated after out-of-hospital cardiac arrest related to myocardial infarction are at an even higher risk of bleeding and thrombosis.
  62. [62]
    Rationale and development of a prehospital goal‐directed bundle of ...
    This care bundle includes guidance for prehospital personnel on recognition of impending rearrest, hemodynamic optimization, ventilatory strategies, airway ...
  63. [63]
    Post-Cardiac Arrest: Mechanisms, Management, and Future ...
    Dec 29, 2022 · In this review, we will discuss physiopathology, etiologies, and post-resuscitation care, emphasizing targeted temperature management, early coronary ...Missing: replenishment | Show results with:replenishment