Publication

• Title: A Comparison of Repeated High Doses and Repeated Standard Doses of Epinephrine for Cardiac Arrest Outside the Hospital
• Acronym: None (European Epinephrine Study Group)
• Year: 1998
• Journal published in: The New England Journal of Medicine
• Citation: Gueugniaud PY, Mols P, Goldstein P, et al. A comparison of repeated high doses and repeated standard doses of epinephrine for cardiac arrest outside the hospital. N Engl J Med. 1998;339:1595-1601.

Context & Rationale

• Background

  • Epinephrine (adrenaline) was embedded in advanced life support algorithms, intended to increase aortic diastolic pressure and coronary perfusion pressure via α-adrenergic vasoconstriction, thereby improving defibrillation success and return of spontaneous circulation (ROSC).
  • Experimental studies and small clinical series suggested that higher doses might augment perfusion pressures and increase ROSC, particularly in prolonged arrests or refractory rhythms.
  • Earlier clinical trials of high-dose epinephrine reported higher initial resuscitation rates without consistent improvement in survival to discharge, and many regimens used only a single high dose rather than repeated dosing during ongoing resuscitation.
• Research Question/Hypothesis

  • In adult out-of-hospital cardiac arrest (OHCA) patients requiring epinephrine during advanced life support, repeated high-dose epinephrine (5 mg every 3 minutes) would improve successful resuscitation (ROSC and hospital admission) and translate into improved survival (and neurological outcome) compared with repeated standard-dose epinephrine (1 mg every 3 minutes).
• Why This Matters

  • OHCA carries very high mortality; even small absolute improvements in survival could yield substantial population benefit.
  • Clarifying whether dose escalation improves patient-centred outcomes (survival with good neurological function) helps avoid practice driven by surrogate endpoints (ROSC/admission) alone.
  • The trial tested a pragmatic “real-world” prehospital strategy in physician-led European emergency medical systems, directly informing resuscitation algorithms and subsequent trial design.

Design & Methods

• Research Question:
  • Among adults with OHCA who met rhythm-based criteria for epinephrine during advanced cardiac life support, does repeated high-dose epinephrine (5 mg per dose) improve outcomes compared with repeated standard-dose epinephrine (1 mg per dose)?
• Study Type:
  • Prospective, multicentre, randomised, double-blind, parallel-group trial.
  • Prehospital setting (out-of-hospital cardiac arrest) across 12 emergency medical systems in France and Belgium; September 1994 to September 1996.
• Population:
  • Adults (≥18 years) with non-traumatic OHCA treated by mobile emergency teams.
  • Eligibility triggered by initial rhythm and early response:
    • Asystole or pulseless electrical activity, or
    • Ventricular fibrillation persisting after three shocks.
  • Key exclusions:
    • Traumatic cardiac arrest.
    • Obvious irreversible death (e.g., decapitation, rigor mortis, extensive burns).
    • Epinephrine given before enrolment.
    • Age <18 years.
• Intervention:
  • High-dose epinephrine: 5 mg per dose in 5 mL ampoules; administered IV (peripheral or central) or endotracheally.
  • Dosing schedule: repeated every 3 minutes; maximum 15 doses per patient (maximum cumulative dose 75 mg).
• Comparison:
  • Standard-dose epinephrine: 1 mg per dose in identical 5 mL ampoules; administered via the same routes and at the same 3-minute intervals; maximum 15 doses.
  • Co-interventions (defibrillation, airway/ventilation strategy, other drugs) followed contemporaneous advanced life support practice within participating systems.
• Blinding:
  • Double-blind: identical ampoules and packaging; clinicians and receiving hospitals were unaware of assigned dose.
  • Implications: reduces risk of performance bias for decisions to continue resuscitation and for post-ROSC care intensity; early endpoints were largely objective.
• Statistics:
  • Power calculation: Not reported in the index manuscript.
  • Two-sided significance level: 0.05.
  • Effect reporting: differences in proportions with 95% confidence intervals for key outcomes.
  • Analysis approach: described “true intention-to-treat” analysis (all treated patients; N=3907) and a “final analysis” after exclusions (N=3327).
• Follow-Up Period:
  • Early: ROSC and hospital admission.
  • Later: survival assessed at 24 hours, 1 week, 1 month, and 1 year; neurological status assessed at discharge (and survival tracked to 1 year).

Key Results

This trial was not stopped early. It completed enrolment over September 1994 to September 1996.

• High-dose epinephrine increased ROSC (40.4% vs 36.4%; P=0.02) and admission to hospital (26.5% vs 23.6%; P=0.05), but did not improve survival to discharge (2.3% vs 2.8%; P=0.34) or survival at 1 year (2.1% vs 2.6%; P=0.32).
• Rhythm subgroup signals were discordant: in asystole, ROSC was 36.9% vs 32.2% (P=0.01) and admission 25.2% vs 20.3% (P=0.004), whereas in coarse ventricular fibrillation ROSC was numerically lower with high dose (55.9% vs 64.3%; P=0.19).
• Potential harm signals in early post-resuscitation course were reported: in-hospital mortality during the first 24 hours was 38.7% in the high-dose group vs 32.4% in the standard-dose group (P=0.06).

Internal Validity

• Randomisation and Allocation:
  • Central randomisation with prepackaged study boxes (15 identical ampoules); boxes distributed in sets of 10 (5 high-dose, 5 standard-dose) and used sequentially.
  • Allocation concealment during resuscitation was credible because ampoules were visually identical and teams/hospitals were blinded to dose.
• Drop out or exclusions (post randomisation):
  • 3946 study boxes were assigned; 39 were excluded because of incorrect use of the assigned package.
  • “True intention-to-treat” analysis included 3907 treated patients (standard-dose 1938; high-dose 1969).
  • Final analysis excluded 580 patients (345 traumatic arrests; 45 not meeting eligibility; 190 with essential data not available or lost to follow-up), leaving 3327 (standard-dose 1650; high-dose 1677).
  • The large post-randomisation exclusion fraction risks attrition bias relative to a strict ITT framework, particularly if exclusions were not independent of outcomes.
• Performance/Detection Bias:
  • Double-blinding reduced the risk that clinicians’ expectations influenced continuation of resuscitation or post-ROSC management.
  • Primary early outcomes (ROSC, admission, survival timepoints) were objective; neurological outcomes relied on clinical documentation (CPC at discharge), which may be less standardised.
• Protocol Adherence:
  • Drug separation was substantial: mean total epinephrine dose 29.0 ± 18.5 mg (high-dose) vs 6.1 ± 3.7 mg (standard-dose).
  • Mean number of epinephrine doses was similar (5.8 ± 3.7 vs 6.1 ± 3.7), consistent with comparable resuscitation duration/effort.
  • Route distribution was similar: peripheral IV 87.2% vs 87.0%; central IV 8.8% vs 9.1%; endotracheal 4.1% vs 3.9%.
• Baseline Characteristics:
  • Groups were broadly comparable for key arrest features (witnessed arrest 46.8% vs 47.8%; bystander CPR 10.3% vs 9.3%).
  • Initial rhythm distribution was similar: asystole 74.7% vs 74.6%; pulseless electrical activity 8.4% vs 8.4%; coarse ventricular fibrillation 8.5% vs 8.5%; fine/medium ventricular fibrillation 8.4% vs 8.5%.
  • Age differed statistically (64.5 ± 14.9 vs 66.7 ± 14.6 years), with unclear clinical relevance for these outcomes.
• Heterogeneity:
  • Trial spanned 12 centres across two countries; centre practice varied, including active compression–decompression CPR use (647/1677 vs 645/1650).
  • Because CPR modality was not randomised, centre-level practice differences may confound subgroup/interaction findings.
• Timing:
  • Epinephrine was administered late relative to collapse in both groups (20.6 ± 14.1 minutes vs 20.7 ± 12.9 minutes), which may constrain any achievable effect on neurological survival.
• Dose:
  • High-dose strategy used 5 mg every 3 minutes (up to 15 doses), creating large cumulative exposure compared with standard dosing; physiological plausibility exists for increasing ROSC, but the trial did not demonstrate improved survival to discharge or 1-year survival.
• Separation of the Variable of Interest:
  • ROSC: 40.4% (high-dose) vs 36.4% (standard-dose).
  • Admission: 26.5% vs 23.6%.
  • Discharge: 2.3% vs 2.8%.
• Outcome Assessment:
  • Endpoints were prespecified and largely objective; longer-term survival was tracked to 1 year.
  • Neurological outcome was summarised using CPC at discharge; among discharged survivors, CPC 1–2 occurred in 76.3% vs 71.7% (P=0.64).
• Statistical Rigor:
  • Two-sided α=0.05 and 95% confidence intervals for differences in proportions were reported for key outcomes.
  • No reported power calculation; the very low event rate for discharge survival (2–3%) limits precision for patient-centred endpoints.

Conclusion on Internal Validity: Overall, internal validity appears moderate: allocation concealment and blinding were strong and treatment separation was large, but substantial post-randomisation exclusions, centre-level heterogeneity (including non-randomised CPR modality), and late drug delivery complicate causal inference for survival and neurological outcomes.

External Validity

• Population Representativeness:
  • Adult OHCA population in France/Belgium, with a high proportion of asystole (~75%) and low bystander CPR (~10%), reflecting substantial delays to effective circulation/defibrillation in many cases.
  • Care was delivered by physician-led mobile emergency teams, which differs from paramedic-led systems in many countries.
• Applicability:
  • The tested regimen (5 mg every 3 minutes, up to 15 doses) is not contemporary standard practice; direct translation to current dosing is therefore limited.
  • Findings remain highly relevant for the conceptual question of dose escalation: improving ROSC/admission does not necessarily translate into improved survival or neurological outcome.
  • Systems with earlier high-quality bystander CPR and earlier defibrillation may have different rhythm distributions and therapeutic windows, potentially modifying the balance of benefit and harm from vasopressors.

Conclusion on External Validity: Generalisability is moderate for comparable European-style advanced prehospital systems, but limited for modern systems with earlier CPR/defibrillation and for current guideline dosing; the central message about surrogate versus patient-centred outcomes remains widely applicable.

Strengths & Limitations

• Strengths:
  • Large, multicentre, double-blind, pragmatic prehospital randomised trial in adult OHCA.
  • Clear separation of exposure: mean total epinephrine dose 29.0 ± 18.5 mg vs 6.1 ± 3.7 mg.
  • Objective early outcomes with longer follow-up, including survival to 1 year and neurological status at discharge.
• Limitations:
  • No reported power calculation; survival to discharge was very low (2–3%), limiting precision for patient-centred outcomes.
  • Substantial post-randomisation exclusions (580/3907) and missing data in the final analysis cohort may bias effect estimates.
  • Low bystander CPR rate and delayed epinephrine administration (~20 minutes) may reduce relevance to current systems prioritising early CPR/defibrillation.
  • Active compression–decompression CPR was used in a sizeable minority without randomisation, complicating interpretation of interaction analyses.

Interpretation & Why It Matters

• ROSC is not enough

  High-dose epinephrine improved ROSC (40.4% vs 36.4%) and admission (26.5% vs 23.6%) but did not improve survival to discharge (2.3% vs 2.8%) or 1-year survival (2.1% vs 2.6%), underscoring the risk of equating physiological success with meaningful recovery.
• Dose escalation is not a solution

  The strategy of repeated 5 mg dosing (mean total 29.0 mg) did not translate into better neurological outcomes among survivors (CPC 1–2: 76.3% vs 71.7%), supporting the view that escalation beyond standard dosing is unlikely to improve patient-centred outcomes in unselected OHCA populations.
• Trial design lessons for resuscitation research

  Very low discharge survival rates and late drug delivery (~20 minutes) highlight the importance of designing trials around early, system-level interventions (bystander CPR, defibrillation, minimising no-flow/low-flow time) and around patient-centred endpoints with adequate statistical power.

Controversies & Subsequent Evidence

• Adopting high-dose epinephrine based on improved intermediate endpoints (ROSC/admission) was challenged because survival to discharge was numerically lower with high dose (2.3% vs 2.8%), emphasising that surrogate endpoints can mislead when neurological survival is unchanged.¹
• Interaction findings were debated because CPR modality (standard versus active compression–decompression) reflected centre practice rather than randomisation, yet discharge survival appeared to “cross over” by CPR type (standard ACLS: 1.7% high-dose vs 3.6% standard-dose; ACD-ACLS: 3.1% vs 1.6%); these observations are hypothesis-generating rather than definitive.¹
• Subsequent placebo-controlled evidence for epinephrine (standard dosing) and subsequent syntheses consistently demonstrate increased ROSC and hospital admission, with only modest (or absent) improvement in longer-term, patient-centred survival outcomes, reinforcing that vasopressor strategies should be evaluated against meaningful survival and neurological recovery rather than ROSC alone.²³⁴
• Large observational datasets have reported time-dependent associations in which delayed prehospital epinephrine is linked to worse neurological outcomes, providing a plausible explanation for why late vasopressor administration may increase ROSC without improving discharge survival or long-term outcomes.⁵⁶
• Contemporary guidelines recommend standard-dose epinephrine (1 mg IV/IO every 3–5 minutes) and do not recommend routine high-dose epinephrine; the dose-escalation strategy tested in this European trial is therefore generally viewed as unsupported by patient-centred evidence.⁷⁸⁹¹⁰

Summary

• In a large, multicentre, double-blind prehospital trial (France/Belgium), repeated 5 mg epinephrine increased ROSC and hospital admission compared with repeated 1 mg dosing.
• There was no improvement in survival to discharge (2.3% vs 2.8%) or survival at 1 year (2.1% vs 2.6%).
• Neurological outcomes among survivors were similar (CPC 1–2: 76.3% vs 71.7%).
• Subgroup signals differed by rhythm (benefit for ROSC/admission in asystole, no benefit in ventricular fibrillation), but interaction inferences were limited by centre-level practice heterogeneity.
• The trial helped shift emphasis from surrogate resuscitation endpoints to meaningful survival and neurological recovery when evaluating vasopressor strategies.

Further Reading

Other Trials

• 1992Stiell IG, Hebert PC, Weitzman BN, et al. High-dose epinephrine in adult cardiac arrest. N Engl J Med. 1992;327:1045-1050.
• 1992Brown CG, Martin DR, Pepe PE, et al. A comparison of standard-dose and high-dose epinephrine in cardiac arrest outside the hospital. N Engl J Med. 1992;327:1051-1055.
• 1995Choux C, Gueugniaud PY, Barbieux A, et al. Standard doses versus repeated high doses of epinephrine in cardiac arrest outside the hospital. Resuscitation. 1995;29(1):3-9.
• 2011Jacobs IG, Finn JC, Jelinek GA, et al. Effect of adrenaline on survival in out-of-hospital cardiac arrest: a randomised double-blind placebo-controlled trial. Resuscitation. 2011;82(9):1138-1143.
• 2018Perkins GD, Ji C, Deakin CD, et al. A randomized trial of epinephrine in out-of-hospital cardiac arrest. N Engl J Med. 2018;379(8):711-721.

Systematic Review & Meta Analysis

• 2019Kempton H, Vlok R, Thang C, Melhuish T, White L. Standard dose epinephrine versus placebo in out-of-hospital cardiac arrest: a systematic review and meta-analysis. Am J Emerg Med. 2019;37(3):511-517.
• 2019Vargas M, Servillo G, et al. Epinephrine for out-of-hospital cardiac arrest: a systematic review and meta-analysis. Resuscitation. 2019.
• 2019Holmberg MJ, Issa MS, Moskowitz A, et al. Vasopressors in adult cardiac arrest: a systematic review and meta-analysis. Resuscitation. 2019.
• 2020Aves T, Allan KS, Sandroni C, et al. Vasopressors for adult cardiac arrest: a systematic review and meta-analysis. Crit Care Med. 2020.
• 2023Fernando SM, Qureshi D, Rochwerg B, et al. Epinephrine in out-of-hospital cardiac arrest: a network meta-analysis and subgroup analyses of shockable and nonshockable rhythms. Chest. 2023.

Observational Studies

• 2012Hagihara A, Hasegawa M, Abe T, Nagata T, Wakata Y, Miyazaki S. Prehospital epinephrine use and survival among patients with out-of-hospital cardiac arrest. JAMA. 2012;307(11):1161-1168.
• 2013Nakahara S, Tomio J, Takahashi H, et al. Association between prehospital epinephrine administration and survival among patients with out-of-hospital cardiac arrest. BMJ. 2013;347:f6829.
• 2014Dumas F, Bougouin W, et al. Epinephrine use during cardiac arrest and outcomes in resuscitated patients. J Am Coll Cardiol. 2014.
• 2014Donnino MW, et al. Time to epinephrine administration and survival after in-hospital cardiac arrest with nonshockable rhythms. JAMA. 2014.
• 2019Fothergill RT, et al. Repeated adrenaline doses and survival from an out-of-hospital cardiac arrest. Resuscitation. 2019.

Guidelines

• 2020Panchal AR, Bartos JA, Cabañas JG, et al. Part 3: Adult Basic and Advanced Life Support: 2020 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation. 2020;142(16_suppl_2):S366-S468.
• 2021Soar J, Böttiger BW, Carli P, et al. European Resuscitation Council Guidelines 2021: Adult advanced life support. Resuscitation. 2021;161:115-151.
• 2025Soar J, et al. European Resuscitation Council Guidelines 2025: Adult advanced life support. Resuscitation. 2025;215(Suppl 1):110769.
• 2025Greif R, et al. European Resuscitation Council Guidelines 2025: Executive summary. Resuscitation. 2025;215(Suppl 1):110770.
• 2025Semeraro F, Monsieurs KG, Perkins GD, et al. International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science with Treatment Recommendations: Advanced Life Support. Resuscitation. 2025;215(Suppl 2):110806.

Notes

• Key Results table reports the “final analysis” cohort (standard-dose n=1650; high-dose n=1677) unless otherwise stated; the index manuscript also presented an earlier “true intention-to-treat” analysis (n=3907) with similar qualitative conclusions for survival to discharge.

Overall Takeaway

This European Epinephrine Study was a landmark, double-blind, multicentre prehospital trial that rigorously tested whether escalating epinephrine dose during adult OHCA improves outcomes. It showed that repeated 5 mg dosing increases physiological “success” (ROSC and admission) but does not improve meaningful survival or neurological recovery, reinforcing modern resuscitation’s focus on early CPR/defibrillation and patient-centred endpoints rather than drug-driven surrogate outcomes.

Bibliography

• 1Bakker J, Rommes H, Martens PR, et al. Epinephrine for out-of-hospital cardiac arrest. N Engl J Med. 1999;340:1763-1765.
• 2Jacobs IG, Finn JC, Jelinek GA, et al. Effect of adrenaline on survival in out-of-hospital cardiac arrest: a randomised double-blind placebo-controlled trial. Resuscitation. 2011;82(9):1138-1143.
• 3Perkins GD, Ji C, Deakin CD, et al. A randomized trial of epinephrine in out-of-hospital cardiac arrest. N Engl J Med. 2018;379(8):711-721.
• 4Kempton H, Vlok R, Thang C, Melhuish T, White L. Standard dose epinephrine versus placebo in out-of-hospital cardiac arrest: a systematic review and meta-analysis. Am J Emerg Med. 2019;37(3):511-517.
• 5Hagihara A, Hasegawa M, Abe T, Nagata T, Wakata Y, Miyazaki S. Prehospital epinephrine use and survival among patients with out-of-hospital cardiac arrest. JAMA. 2012;307(11):1161-1168.
• 6Nakahara S, Tomio J, Takahashi H, et al. Association between prehospital epinephrine administration and survival among patients with out-of-hospital cardiac arrest. BMJ. 2013;347:f6829.
• 7Panchal AR, Bartos JA, Cabañas JG, et al. Part 3: Adult Basic and Advanced Life Support: 2020 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care. Circulation. 2020;142(16_suppl_2):S366-S468.
• 8Soar J, Böttiger BW, Carli P, et al. European Resuscitation Council Guidelines 2021: Adult advanced life support. Resuscitation. 2021;161:115-151.
• 9Soar J, et al. European Resuscitation Council Guidelines 2025: Adult advanced life support. Resuscitation. 2025;215(Suppl 1):110769.
• 10Semeraro F, Monsieurs KG, Perkins GD, et al. International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science with Treatment Recommendations: Advanced Life Support. Resuscitation. 2025;215(Suppl 2):110806.