Seasonal variability and influence of outdoor temperature on body temperature of cardiac arrest victims
Peter StratilChristian WallmuellerAndreas SchoberM. StoecklDavid HoerburgerChristoph WeiserChristoph TestoriDanica KrizanacAlexander O. SpielThomas UrayFritz SterzMoritz Haugk
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Core temperature
Targeted temperature management
Human body temperature
In experimental models of ischemic-anoxic brain injury, changes in body temperature after the insult have a profound influence on neurologic outcome. Specifically, hypothermia ameliorates whereas hyperthermia exacerbates neurologic injury. Accordingly, we sought to determine the temperature changes occurring in children after resuscitation from cardiac arrest.The clinical records of 13 children resuscitated from cardiac arrest were analyzed. Patients were identified through the emergency department and pediatric intensive care unit arrest logs. Only patients surviving for > or =12 hours after resuscitation were considered for analysis. Charts were reviewed for body temperatures, warming or cooling interventions, antipyretic and antimicrobial administration, and evidence of infection.Seven patients had a minimum temperature (T min) of < or =35 degrees C and 11 had a maximum temperature (T max) of > or =38.1 degrees C. Hypothermia often preceded hyperthermia. All 7 patients with T min < or =35 degrees C were actively warmed with heating lamps and 5 of 7 responded to warming with a rebound of body temperatures > or =38.1 degrees C. None of the 6 patients with T min >35 degrees C were actively warmed but all developed T max > or =38.1 degrees C. Six patients received antipyretics and 11 received antibiotics. Fever was not associated with a positive culture in any case. Conclusion. Spontaneous hypothermia followed by hyperthermia is common after resuscitation from cardiac arrest. Temperature should be closely monitored after cardiac arrest and fever should be managed expectantly.
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Although targeted temperature management (TTM) has been widely implemented among comatose survivors after cardiac arrest (CA), there are still several unanswered issues, including the optimal time to initiate cooling. Experimental studies have showed that early cooling after return of spontaneous circulation (ROSC) provides better neurological protection than normothermia, while clinical studies failed to show any significant benefits of this strategy [1]. Importantly, several experimental data suggested that hypothermia initiated during cardiopulmonary resuscitation (CPR) – that is, so-called intra-arrest hypothermia (IAHT) – increased the effectiveness of resuscitation attempts and defibrillation when compared with normothermia [2,3]. In a recent systematic review, Scolletta and colleagues identified 23 animal studies and five human studies which evaluated the effects of IAHT in this setting [4]. In particular, animal studies showed that IAHT improved survival and neurological outcomes when compared with normothermia and/or hypothermia after ROSC. IAHT was also associated with improved ROSC rates and with improved cardiac function, including better left ventricular function and reduced myocardial infarct size, when compared with normothermia.
Unfortunately, clinical data on the efficacy of IAHT remain limited. In a retrospective study, Garrett and colleagues compared the outcome for 208 out-of-hospital CA patients treated with intra-arrest cold intravenous fluids with historical controls ( n= 334) [5]. The use of IAHT was associated with an increased ROSC rate, while it could not improve overall survival to hospital admission or to discharge. Nevertheless, less than 10% of patients admitted to the hospital were eventually treated with in-hospital TTM, which negatively influenced the effects of early cooling on patients’ outcome. In a recent randomized clinical trial, Debaty and colleagues evaluated the effects of intra-arrest cold fluids when compared with TTM started after hospital admission on out-of-hospital CA patients, irrespective of their initial rhythm [6]. Of the 245 patients included (n = 123 in the IAHT group; n = 122 in the control group), IAHT significantly reduced the time to reach body temperature below 34°C by 75 minutes; however, the proportion of patients admitted alive to hospital was not different between groups (33% vs. 30%; P = 0.51). Levels of neuron-specific enolase, a biomarker of brain injury, which was considered the primary outcome of the study, were not different between groups and no difference in survival and 1-month neurological recovery was found. Importantly, intra-arrest cold fluids are potentially associated with important adverse events, such as a reduced coronary perfusion pressure, a longer duration of CPR and the development of lung edema, which may have blunted their beneficial effects [7].
In another randomized clinical trial using intra-arrest transnasal evaporative cooling [8], out-of-hospital CA patients were randomized, irrespective of their rhythm, to receive IAHT (n = 96) or standard of care ( n= 104, including in-hospital TTM) during CPR [8]. Overall survival rates were similar in the two groups (15% vs. 13%). Among patients admitted to the hospital, overall survival was increased, although not significantly, from 31 to 44% using IAHT (P = 0.16). Also, IAHT increased, although not significantly (P = 0.14), the intact neurological outcome rate from 21% to 34% when compared with controls; these beneficial effects were more pronounced in patients with short time to CPR (that is, <10 minutes; 43% vs. 17%, P= 0.03). An ongoing randomized clinical trial will include nearly 800 patients to confirm these promising preliminary results using intra-arrest transnasal evaporative cooling in out-of-hospital CA.
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Out-of-hospital cardiac arrest remains a major cause of mortality and morbidity despite progress in resuscitative practices. The number of survivors with severe neurological impairment at hospital discharge is similarly dismal. Recently, much attention has been directed toward the use of mild therapeutic hypothermia in the care of comatose survivors with postcardiac arrest syndrome. Recent research suggests mild hypothermia lowers mortality and improves neurological outcome after successful treatment of cardiac arrest. The current 2005 updated guidelines of International Liaison Committee on Resuscitation and European Resuscitation Council recommend the utilization of mild induced hypothermia in postresuscitation treatment. Hypothermia induction in order to avoid the pathophysiological mechanisms of euthermia and hyperthermia and subsequent complications are briefly discussed. Cooling methods, potential side effects and questions regarding implementation of therapeutic hypothermia recommendations in every day clinical practice and future investigation are also addressed.
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