Background Cardiac arrest with widespread cerebral ischemiafrequently leads to severe neurologic impairment. We studiedwhether mild systemic hypothermia increases the rate of neurologicrecovery after resuscitation from cardiac arrest due to ventricularfibrillation.
Conclusions In patients who have been successfully resuscitatedafter cardiac arrest due to ventricular fibrillation, therapeuticmild hypothermia increased the rate of a favorable neurologicoutcome and reduced mortality.
An estimated 375,000 people in Europe undergo sudden cardiacarrest yearly.1 Recovery without residual neurologic damageafter cardiac arrest with global cerebral ischemia is rare.After cardiac arrest with no blood flow for more than five minutes,the generation of free radicals, together with other mediators,during reperfusion creates chemical cascades that result incerebral injury.2 Until recently, there was no therapy withdocumented efficacy in preventing brain damage after cardiacarrest.
Several studies have shown that moderate systemic hypothermia(30°C)3 or mild hypothermia (34°C)4,5,6,7,8 markedlymitigates brain damage after cardiac arrest in dogs. The exact mechanism for this cerebral resuscitative effect is not clear.A reduction in cerebral oxygen consumption9,10 and other multifactorialchemical and physical mechanisms during and after ischemia havebeen postulated.11,12,13,14,15,16 These include retardationof destructive enzymatic reactions, suppression of free-radicalreactions, protection of the fluidity of lipoprotein membranes,reduction of the oxygen demand in low-flow regions, reductionof intracellular acidosis, and inhibition of the biosynthesis,release, and uptake of excitatory neurotransmitters.
Preliminary clinical studies have shown that patients treatedwith mild hypothermia after cardiac arrest have an improvedneurologic outcome, without important side effects, as comparedwith the outcome in historical controls.17,18,19,20
We compared mild hypothermia with standard normothermia in patientswho had had cardiac arrest due to ventricular fibrillation.The primary end point was a favorable neurologic outcome withinsix months after cardiac arrest.21,22,23 Secondary end pointswere mortality at six months and the incidence of complicationsduring the first seven days. Nine centers in five European countriesparticipated in the study.
Methods
Patients
Patients seen consecutively in the emergency department in whomspontaneous circulation had been restored after cardiac arrestwere eligible for the study. The criteria for inclusion werea witnessed cardiac arrest, ventricular fibrillation or nonperfusingventricular tachycardia as the initial cardiac rhythm, a presumedcardiac origin of the arrest, an age of 18 to 75 years, an estimatedinterval of 5 to 15 minutes from the patient's collapse to thefirst attempt at resuscitation by emergency medical personnel,and an interval of no more than 60 minutes from collapse torestoration of spontaneous circulation.
Patients were excluded if they met any of the following criteria:a tympanic-membrane temperature below 30°C on admission,a comatose state before the cardiac arrest due to the administrationof drugs that depress the central nervous system, pregnancy,response to verbal commands after the return of spontaneouscirculation and before randomization, evidence of hypotension(mean arterial pressure, less than 60 mm Hg) for more than 30minutes after the return of spontaneous circulation and beforerandomization, evidence of hypoxemia (arterial oxygen saturation,less than 85 percent) for more than 15 minutes after the returnof spontaneous circulation and before randomization, a terminalillness that preceded the arrest, factors that made participationin follow-up unlikely, enrollment in another study, the occurrenceof cardiac arrest after the arrival of emergency medical personnel,or a known preexisting coagulopathy.
Study Design
The study was designed as a randomized, controlled trial withblinded assessment of the outcome. The protocol and consentprocedure were approved by the institutional review board ofeach participating center. For all patients, the requirementof informed consent was waived in accordance with the ethicalstandards of the local institutional review board and the guidelinesfor good clinical practice of the European Agency for the Evaluationof Medicinal Products.24 The patient's family was informed aboutthe trial, and the protocol specified that if there were anyobjections, the patient would be withdrawn from the study. However,there were no objections.
Treatment assignments were randomly generated by computer inblocks of 10, with stratification according to center. Sealedenvelopes containing the treatment assignments were providedby the biostatistics center. Immediately after a patient hadbeen enrolled, an envelope was opened, and the patient was assignedto the specified group.
Personnel involved in the care of patients during the first48 hours after cardiac arrest could not be blinded with respectto treatment assignments. However, the physicians responsiblefor assessing the neurologic outcome within the first six monthsafter the arrest were unaware of the treatment assignments.
Treatment
All patients received standard intensive care according to adetailed protocol. Sedation was induced by the intravenous administrationof midazolam (0.125 mg per kilogram of body weight per hourinitially) and fentanyl (0.002 mg per kilogram per hour initially),and the doses were adjusted as needed for 32 hours for the managementof mechanical ventilation. To prevent shivering, paralysis wasinduced by the intravenous administration of pancuronium (0.1mg per kilogram) every 2 hours for a total of 32 hours. Intracranialpressure was not monitored.
The temperature on admission was measured with an infrared tympanicthermometer (Ototemp LighTouch, Exergen, Watertown, Mass.).Further temperature measurements were made with a bladder-temperatureprobe (Foley catheter). Patients randomly assigned to the normothermiagroup were placed on a conventional hospital bed, and normothermiawas maintained. Those randomly assigned to the hypothermia groupwere cooled to a target temperature of 32°C to 34°Cwith the use of an external cooling device (TheraKool, KineticConcepts, Wareham, United Kingdom). This device consists ofa mattress with a cover that delivers cold air over the entirebody. The goal was to reach the target bladder temperature withinfour hours after the return of spontaneous circulation. If thisgoal was not achieved, ice packs were applied. The temperaturewas maintained at 32°C to 34°C for 24 hours from thestart of cooling, followed by passive rewarming, which we expectedwould occur over a period of 8 hours.
Data Collection
Data on cardiac arrest for individual patients were recordedin the Utstein style.25 Laboratory tests were performed at baseline, 12 and 48 hours after cardiac arrest, and as clinicallyindicated. Risk factors for an unfavorable outcome (hypotensionor a nonfatal cardiac arrest after resuscitation) were documented.
Outcome
The primary outcome was a favorable neurologic outcome withinsix months, defined as a Pittsburgh cerebral-performance categoryof 1 (good recovery) or 2 (moderate disability) on a five-categoryscale; the other categories were 3 (severe disability), 4 (avegetative state), and 5 (death).21,22,23 The neurologic outcomewas determined without knowledge of the patient's treatmentassignment. Patients with good recovery or moderate disabilityhad sufficient cerebral function to live independently and workat least part-time.
Secondary end points were overall mortality at six months andthe rate of complications during the first seven days aftercardiac arrest. Bleeding of any severity, pneumonia, sepsis,pancreatitis, renal failure, pulmonary edema, seizures, arrhythmias,and pressure sores were recorded. Since an individual patientmight have more than one complication at a time, the occurrenceof at least one complication of any kind per patient was alsodocumented.
Statistical Analysis
Continuous variables, which were not normally distributed, arereported as medians and interquartile ranges. Categorical variablesare reported as counts and percentages. Primary and secondaryoutcomes were binary, and the chi-square test or Fisher's exacttest, as appropriate, was used to compare outcomes in the hypothermiaand normothermia groups. Trends across subgroups were measuredwith an extension of the Wilcoxon rank-sum test.26 The differencein risk between the two groups, with the corresponding 95 percentconfidence interval, was calculated as a measure of the absoluterisk, which was then used to calculate the number needed totreat. Risk ratios are reported as a measure of relative risk.
We used a multivariate logistic-regression model to determinewhether the association between the intervention and the primaryand secondary outcomes (neurologic recovery and mortality) wasconfounded by base-line differences between the study groups.All the covariables listed in Table 1 were entered into themodel, except for the dose of epinephrine, which was excludedbecause of collinearity with the interval from the patient'scollapse to the restoration of spontaneous circulation. We convertedodds ratios to risk ratios using the following formula:
Table 1. Base-Line Characteristics of the Patients.
risk ratio = odds ratio ÷ ([1 – incidence in normothermiagroup] + incidence in normothermia group x odds ratio).27
Confounding can be assumed if the crude risk ratio differs fromthe adjusted risk ratio. Goodness of fit was assessed with theHosmer–Lemeshow chi-square test. A reasonable fit canbe assumed if the result is not significant at the 5 percentlevel. Analysis was carried out according to the intention-to-treatprinciple. Stata software (version 7, Stata, College Station,Tex.) was used to analyze the data.
Results
The study was carried out between March 1996 and January 2001.Since the enrollment rate was lower than expected and fundinghad ended by July 2000, enrollment was stopped at this date.
A total of 3551 patients were assessed for eligibility; 3246of these patients did not meet the inclusion criteria, and 30were not included because of logistic problems. Thus, 275 patientswere enrolled, with 137 patients randomly assigned to the hypothermiagroup and 138 to the normothermia group (i.e., the group thatreceived standard care after resuscitation). Hypothermia wasdiscontinued early in 14 patients for the following reasons:death (6 patients), arrhythmia and hemodynamic instability (3),technical problems with the cooling device (2), liver rupture(1), previous random assignment to the hypothermia group (1),and an error in the duration of cooling (1). All randomizedpatients were included in the analysis of mortality. One patientin each group was lost to follow-up for neurologic status.
At base line, the patients in the two groups were generallysimilar, although the patients in the normothermia group weremore likely to have a history of diabetes mellitus or coronaryheart disease and to have received basic life support from abystander than were those in the hypothermia group. These differencesappear to have been due to random variation (Table 1).
Cooling
In patients randomly assigned to the hypothermia group, themedian interval between the restoration of spontaneous circulationand the initiation of cooling was 105 minutes (interquartilerange, 61 to 192). The median interval between the restorationof spontaneous circulation and the attainment of a temperaturebetween 32°C and 34°C was 8 hours (interquartile range,4 to 16). In 19 patients, the target temperature could not bereached. Ice packs were required for 93 of the 132 patientsfor whom data were available (70 percent). The median durationof cooling was 24 hours (interquartile range, 24 to 25), andamong patients in whom the target temperature was reached, itwas maintained for a median of 24 hours (interquartile range,12 to 29). Passive rewarming to a temperature above 36°Clasted for a median of 8 hours (interquartile range, 8 to 12).The temperature curves for the normothermia and hypothermiagroups are shown in Figure 1.
Figure 1. Bladder Temperature in the Normothermia and Hypothermia Groups.
The T bars indicate the 75th percentile in the normothermia group and the 25th percentile in the hypothermia group. The target temperature in the hypothermia group was 32°C to 34°C, and the duration of cooling was 24 hours. Only patients with recorded temperatures were included in the analysis.
Outcome at Six Months
A total of 75 of the 136 patients (55 percent) in the hypothermiagroup had a favorable neurologic outcome, as compared with 54of the 137 (39 percent) in the normothermia group (risk ratio,1.40; 95 percent confidence interval, 1.08 to 1.81) (Table 2).To prevent one unfavorable neurologic outcome, 6 patients wouldneed to be treated with hypothermia (95 percent confidence interval,4 to 25 patients). After adjustment for a history of diabetesmellitus, a history of coronary heart disease, and receipt ofbasic life support from a bystander, the risk ratio changedonly marginally (data not shown). After adjustment for all thebase-line variables shown in Table 1, the risk ratio increasedslightly, to 1.47 (95 percent confidence interval, 1.09 to 1.82).
Table 2. Neurologic Outcome and Mortality at Six Months.
The rate of death six months after cardiac arrest was 14 percentagepoints lower in the hypothermia group than in the normothermiagroup (risk ratio for the hypothermia group, 0.74 [95 percentconfidence interval, 0.58 to 0.95]) (Table 2 and Figure 2).On the basis of the difference in the risk of death betweenthe two groups, 7 patients would need to be treated with hypothermia(95 percent confidence interval, 4 to 33 patients) to prevent1 death. After adjustment for base-line differences in the proportionsof patients with a history of diabetes mellitus, a history ofcoronary heart disease, and receipt of basic life support froma bystander, the risk ratio changed only minimally (data notshown). After adjustment for all the base-line variables shownin Table 1, the effect of hypothermia on mortality was slightlystronger (risk ratio, 0.62; 95 percent confidence interval,0.36 to 0.95).
Figure 2. Cumulative Survival in the Normothermia and Hypothermia Groups.
Censored data are indicated by tick marks.
Most of the patients with unfavorable neurologic outcomes diedwithin six months after discharge from the hospital. In thissubgroup of patients, mortality after discharge did not differsignificantly according to the assigned treatment (Table 3).
Table 3. Deaths before Discharge and Deaths after Discharge According to the Cerebral-Performance Category.
Complications
The proportion of patients with any complication did not differsignificantly between the two groups (93 of 132 patients inthe normothermia group [70 percent] and 98 of 135 in the hypothermiagroup [73 percent], P=0.70). Sepsis was more likely to developin the patients with hypothermia than in those with normothermia,although this difference was not statistically significant (Table 4).The total number of complications was not significantlyhigher in the hypothermia group than in the normothermia group(P=0.09).
Table 4. Complications during the First Seven Days after Cardiac Arrest.
Discussion
Our results show that among patients in whom spontaneous circulationhad been restored after cardiac arrest due to ventricular fibrillation,systemic cooling to a bladder temperature between 32°C and34°C for 24 hours increased the chance of survival and ofa favorable neurologic outcome (a cerebral-performance categoryof 1 or 2), as compared with standard normothermic life support.
The use of moderate hypothermia after cardiac arrest was initiallyreported in the late 1950s and early 1960s.28,29,30 Althoughthe target temperature was lower in these studies than in oursand the method and duration of cooling also differed from thosein our study, the results were similar. However, the findingswere inconclusive, and the rate of complications was higherthan that observed with the mild hypothermia used in our study.There were no further investigations of hypothermia as a resuscitativemeasure until the 1990s, when laboratory studies demonstratedthe benefit of mild hypothermia.4,5,6,7,8,16 These studies ledto preliminary clinical studies of mild hypothermia.
In the study by Bernard et al.,17 cooling was induced more rapidly(with ice packs) and for a shorter period than in our study.Nevertheless, the results were similar to ours. The neurologicoutcome has also been consistently favorable in studies of mildhypothermia in animals.31,32,33,34 In the pilot studies by Yanagawaet al.18 and Nagao et al.,19 the frequency of a favorable neurologicoutcome was similar to that in our study, although the methodand duration of cooling in these studies differed from thosein our study. In contrast to these encouraging findings, a studyof hypothermia in patients with traumatic brain injury35 showedno improvement in the neurologic outcome. The reasons for thisdiscrepancy are thought to include the different pathogenesisof direct central nervous system injury, as well as the lateinitiation of cooling in some of the patients and variationsin intensive care and life support among participating hospitals.35,36
Although the proportions of patients with any complication didnot differ significantly between the two treatment groups inour study, a detailed analysis of the complications and an analysisof the total number of complications revealed a trend towarda higher rate of infectious problems in the hypothermia group.Nevertheless, the benefit of hypothermia exceeded its possibleadverse effects.
One limitation of our study was the fact that the attendingphysicians could not be blinded to the treatment assignments.The relative risk may be slightly exaggerated in studies thatare not double blind.37 Although the outcome was assessed withoutknowledge of the treatment assignments, we did not verify thatthe blinding was successful. Even if it was not successful ina few cases, we do not believe that any bias that might havebeen introduced would have been strong enough to invalidateour findings.
The study population was restricted to a group of patients witha high risk of brain damage because of the specified intervalbetween the patient's collapse and the first attempt at resuscitationby emergency medical personnel, as well as other factors, soonly 8 percent of the patients assessed for eligibility wereincluded in the trial. Further studies are warranted to determinewhether our findings apply to patients at lower risk for braindamage and to those with cardiac arrest due to causes otherthan ventricular fibrillation.
Treatment with hypothermia may be of value in terms of publichealth. Each year, cardiac arrest occurs in approximately 375,000people in Europe,1 about 30,000 of whom would meet our inclusioncriteria. We can be 95 percent confident that treatment withhypothermia would prevent an unfavorable neurologic outcomein 1200 to 7500 of these patients.
Supported by grants from the Biomedicine and Health Programme(BIOMED 2) implemented under the Fourth RTD Framework Programme1994–1998 of the European Union (BMH4-CD-96-0667), theAustrian Ministry of Science and Transport (GZ 5.550/12-Pr/4/95and GZ 650.0251/2-IV/6/96), and the Austrian Science Foundation(P11405-MED).
K. Heaton and R. Meier (Kinetic Concepts, Wareham, United Kingdom)provided technical support and the TheraKool cooling device.
We are indebted to the nurses and staff of the participatingcenters for their enthusiastic cooperation, to Elaine Ward foreditorial assistance, and to the patients in the study for theirtrust and support.
* The investigators who participated in the Hypothermia afterCardiac Arrest Study Group are listed in the Appendix.
Source Information
Michael Holzer, M.D., Universitätsklinik für Notfallmedizin, Vienna, Austria, assumes overall responsibility for the integrity of the report.
Address reprint requests to Dr. Fritz Sterz, Universitätsklinik für Notfallmedizin, Allgemeines Krankenhaus der Stadt Wien, Währinger Gürtel 18–20/6D, 1090 Vienna, Austria or at fritz.sterz{at}akh-wien.ac.at.
References
de Vreede-Swagemakers JJ, Gorgels AP, Dubois-Arbouw WI, et al. Out-of-hospital cardiac arrest in the 1990's: a population-based study in the Maastricht area on incidence, characteristics and survival. J Am Coll Cardiol 1997;30:1500-1505. [Abstract]
Leonov Y, Sterz F, Safar P, Radovsky A. Moderate hypothermia after cardiac arrest of 17 minutes in dogs: effect on cerebral and cardiac outcome. Stroke 1990;21:1600-1606. [Free Full Text]
Leonov Y, Sterz F, Safar P, et al. Mild cerebral hypothermia during and after cardiac arrest improves neurologic outcome in dogs. J Cereb Blood Flow Metab 1990;10:57-70. [Web of Science][Medline]
Sterz F, Safar P, Tisherman S, Radovsky A, Kuboyama K, Oku K. Mild hypothermic cardiopulmonary resuscitation improves outcome after prolonged cardiac arrest in dogs. Crit Care Med 1991;19:379-389. [Web of Science][Medline]
Weinrauch V, Safar P, Tisherman S, Kuboyama K, Radovsky A. Beneficial effect of mild hypothermia and detrimental effect of deep hypothermia after cardiac arrest in dogs. Stroke 1992;23:1454-1462. [Free Full Text]
Kuboyama K, Safar P, Radovsky A, Tisherman SA, Stezoski SW, Alexander H. Delay in cooling negates the beneficial effect of mild resuscitative cerebral hypothermia after cardiac arrest in dogs: a prospective, randomized study. Crit Care Med 1993;21:1348-1358. [Web of Science][Medline]
Safar P, Xiao F, Radovsky A, et al. Improved cerebral resuscitation from cardiac arrest in dogs with mild hypothermia plus blood flow promotion. Stroke 1996;27:105-113. [Free Full Text]
Hegnauer AH, D'Amato HE. Oxygen consumption and cardiac output in the hypothermic dog. Am J Physiol 1954;178:138-142.
Mezrow CK, Sadeghi AM, Gandsas A, et al. Cerebral blood flow and metabolism in hypothermic circulatory arrest. Ann Thorac Surg 1992;54:609-615. [Abstract]
Chopp M, Knight R, Tidwell CD, Helpern JA, Brown E, Welch KM. The metabolic effects of mild hypothermia on global cerebral ischemia and recirculation in the cat: comparison to normothermia and hyperthermia. J Cereb Blood Flow Metab 1989;9:141-148. [Web of Science][Medline]
Dempsey RJ, Combs DJ, Maley ME, Cowen DE, Roy MW, Donaldson DL. Moderate hypothermia reduces postischemic edema development and leukotriene production. Neurosurgery 1987;21:177-181. [Web of Science][Medline]
Kramer RS, Sanders AP, Lesage AM, Woodhall B, Sealy WC. The effect of profound hypothermia on preservation of cerebral ATP content during circulatory arrest. J Thorac Cardiovasc Surg 1968;56:699-709. [Web of Science][Medline]
Natale JA, D'Alecy LG. Protection from cerebral ischemia by brain cooling without reduced lactate accumulation in dogs. Stroke 1989;20:770-777. [Free Full Text]
Sterz F, Leonov Y, Safar P, et al. Multifocal cerebral blood flow by Xe-CT and global cerebral metabolism after prolonged cardiac arrest in dogs: reperfusion with open-chest CPR or cardiopulmonary bypass. Resuscitation 1992;24:27-47. [CrossRef][Web of Science][Medline]
Busto R, Globus MY, Dietrich WD, Martinez E, Valdes I, Ginsberg MD. Effect of mild hypothermia on ischemia-induced release of neurotransmitters and free fatty acids in rat brain. Stroke 1989;20:904-910. [Free Full Text]
Bernard SA, Jones BM, Horne MK. Clinical trial of induced hypothermia in comatose survivors of out-of-hospital cardiac arrest. Ann Emerg Med 1997;30:146-153. [CrossRef][Web of Science][Medline]
Yanagawa Y, Ishihara S, Norio H, et al. Preliminary clinical outcome study of mild resuscitative hypothermia after out-of-hospital cardiopulmonary arrest. Resuscitation 1998;39:61-66. [CrossRef][Web of Science][Medline]
Nagao K, Hayashi N, Kanmatsuse K, et al. Cardiopulmonary cerebral resuscitation using emergency cardiopulmonary bypass, coronary reperfusion therapy and mild hypothermia in patients with cardiac arrest outside the hospital. J Am Coll Cardiol 2000;36:776-783. [Free Full Text]
Zeiner A, Holzer M, Sterz F, et al. Mild resuscitative hypothermia to improve neurological outcome after cardiac arrest: a clinical feasibility trial. Stroke 2000;31:86-94. [Free Full Text]
Jennett B, Bond M. Assessment of outcome after severe brain damage. Lancet 1975;1:480-484. [Web of Science][Medline]
Brain Resuscitation Clinical Trial II Study Group. A randomized clinical study of a calcium-entry blocker (lidoflazine) in the treatment of comatose survivors of cardiac arrest. N Engl J Med 1991;324:1225-1231. [Abstract]
Safar P, Bircher NG. Cardiopulmonary cerebral resuscitation: basic and advanced cardiac and trauma life support: an introduction to resuscitation medicine. 3rd ed. London: W.B. Saunders, 1988:267.
Human Medicines Evaluation Unit. Note for guidance on good clinical practice (clinical practice medicinal products [CPMP]/International Conference of Harmonization [ICH]/135/95). Guidelines for good clinical practice. ICH topic E6. London: European Agency for the Evaluation of Medicinal Products, 1995:1-58. (Also available at http://www.eudra.org/emea.html.)
Cummins RO, Chamberlain DA, Abramson NS, et al. Recommended guidelines for uniform reporting of data from out-of-hospital cardiac arrest: the Utstein Style: a statement for health professionals from a task force of the American Heart Association, the European Resuscitation Council, the Heart and Stroke Foundation of Canada, and the Australian Resuscitation Council. Circulation 1991;84:960-975. [Free Full Text]
Zhang J, Yu KF. What's the relative risk? A method of correcting the odds ratio in cohort studies of common outcomes. JAMA 1998;280:1690-1691. [Free Full Text]
Benson DW, Williams GR Jr, Spencer FC, Yates AJ. The use of hypothermia after cardiac arrest. Anesth Analg 1958;38:423-428.
Williams GR Jr, Spencer FC. The clinical use of hypothermia following cardiac arrest. Ann Surg 1959;148:462-468.
Ravitch MM, Lane R, Safar P, Steichen FM, Knowles P. Lightning stroke: report of a case with recovery after cardiac massage and prolonged artificial respiration. N Engl J Med 1961;264:36-38. [Web of Science][Medline]
Markarian GZ, Lee JH, Stein DJ, Hong SC. Mild hypothermia: therapeutic window after experimental cerebral ischemia. Neurosurgery 1996;38:542-550. [CrossRef][Web of Science][Medline]
Coimbra C, Wieloch T. Hypothermia ameliorates neuronal survival when induced 2 hours after ischaemia in the rat. Acta Physiol Scand 1992;146:543-544. [Medline]
Colbourne F, Li H, Buchan AM. Indefatigable CA1 sector neuroprotection with mild hypothermia induced 6 hours after severe forebrain ischemia in rats. J Cereb Blood Flow Metab 1999;19:742-749. [CrossRef][Web of Science][Medline]
Hickey RW, Ferimer H, Alexander HL, et al. Delayed, spontaneous hypothermia reduces neuronal damage after asphyxial cardiac arrest in rats. Crit Care Med 2000;28:3511-3516. [CrossRef][Medline]
Clifton GL, Miller ER, Choi SC, et al. Lack of effect of induction of hypothermia after acute brain injury. N Engl J Med 2001;344:556-563. [Free Full Text]
Safar P, Kochanek PM. Lack of effect of induction of hypothermia after acute brain injury. N Engl J Med 2001;345:66-66. [Free Full Text]
Schulz KF, Chalmers I, Hayes RJ, Altman DG. Empirical evidence of bias: dimensions of methodological quality associated with estimates of treatment effects in controlled trials. JAMA 1995;273:408-412. [Free Full Text]
Appendix
The following investigators participated in the Hypothermiaafter Cardiac Arrest Study Group (the number of patients enrolledat each center is shown): Chair, Central Coordinating Office—M. Holzer (Universitätsklinik für Notfallmedizin,Vienna, Austria); Steering Committee — E. Cerchiari (OspedaleNiguarda Ca'Granda, Milan, Italy), P. Martens (A.Z. Sint Jan,Bruges, Belgium), R. Roine (Helsinki University Hospital, Helsinki,Finland), F. Sterz (Universitätsklinik für Notfallmedizin,Vienna, Austria); Central Coordinating Office — P. Eisenburger,C. Havel, J. Kofler, E. Oschatz, K. Rohrbach, W. Scheinecker,W. Schörkhuber; hospital investigators — W. Behringer,A. Zeiner (Universitätsklinik für Notfallmedizin,Vienna, Austria; 88 patients); A. Valentin (Krankenhaus Rudolfstiftung,Vienna, Austria; 2 patients); M. De Meyer (A.Z. Sint Jan, Bruges,Belgium; 35 patients); O. Takunen, M. Tiainen (Helsingin YliopistollisenKeskussairaalan, Helsinki, Finland; 71 patients); S. Hachimi-Idrissi,L. Huyghens (Academisch Ziekenhuis van de Vrije UniversiteitBrussel, Brussels, Belgium; 25 patients); M. Fischer, P. Walger(Medizinische Fakultat der Rheinischen Friedrich-Wilhems-UniversitatBonn, Bonn, Germany; 15 patients); A. Bartsch, M. Foedisch (EvangelischesWaldkrankenhaus Bonn, Bonn, Germany; 15 patients); E. Cerchiari(Ospedale Niguarda Ca'Granda, Milan, Italy; 12 patients); M.Bonizzoli, E. Pagni (Azienda Ospedalieria Careggi, Florence,Italy; 12 patients); Monitoring Committee — A.N. Laggner(Universitätsklinik für Notfallmedizin, Vienna, Austria),A. Kaff (Rettungs- und Krankenbeförderungsdienst der StadtWien, Vienna, Austria), B. Schneider (randomization procedure)(Institut für Medizinische Statistik, UniversitätWien, Vienna, Austria); Data Analysis — M. Müllner(Universitätsklinik für Notfallmedizin, Vienna, Austria).
Therapeutic Hypothermia after Cardiac Arrest
Darby J. M., Padosch S. A., Kern K. B., Böttiger B. W., Polderman K. H., Girbes A. R.J., Holzer M., the Hypothermia after Cardiac Arrest Study Group , Bernard S. A., Buist M. D., Safar P., Kochanek P. M.
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N Engl J Med 2002;
347:63-65, Jul 4, 2002.
Correspondence
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(2009). A Qualitative Study to Identify Barriers to Local Implementation of Prehospital Termination of Resuscitation Protocols. Circ Cardiovasc Qual Outcomes
2: 361-368
[Abstract][Full Text]
Masamune, T., Sato, H., Okuyama, K., Imai, Y., Iwashita, H., Ishiyama, T., Oguchi, T., Sessler, D. I., Matsukawa, T.
(2009). The Shivering Threshold in Rabbits with JM-1232(-), a New Benzodiazepine Receptor Agonist. Anesth. Analg.
109: 96-100
[Abstract][Full Text]
Abend, N. S., Topjian, A., Ichord, R., Herman, S. T., Helfaer, M., Donnelly, M., Nadkarni, V., Dlugos, D. J., Clancy, R. R.
(2009). Electroencephalographic monitoring during hypothermia after pediatric cardiac arrest. Neurology
72: 1931-1940
[Abstract][Full Text]
Binda, M.M., Koninckx, P.R.
(2009). Prevention of adhesion formation in a laparoscopic mouse model should combine local treatment with peritoneal cavity conditioning. Hum Reprod
24: 1473-1479
[Abstract][Full Text]
Meloni, B. P., Campbell, K., Zhu, H., Knuckey, N. W.
(2009). In Search of Clinical Neuroprotection After Brain Ischemia: The Case for Mild Hypothermia (35{degrees}C) and Magnesium. Stroke
40: 2236-2240
[Abstract][Full Text]
Reynolds, J. C., Callaway, C. W., El Khoudary, S. R., Moore, C. G., Alvarez, R. J., Rittenberger, J. C.
(2009). Review of A Large Clinical Series: Coronary Angiography Predicts Improved Outcome Following Cardiac Arrest: Propensity-adjusted Analysis. J Intensive Care Med
24: 179-186
[Abstract]
Richter, S., Ehrlich, J. R., Fassbender, S., Fichtlscherer, S.
(2009). Malignant Osborn waves during therapeutic hypothermia. Europace
11: 668-669
[Full Text]
Kollmar, R., Schellinger, P. D., Steigleder, T., Kohrmann, M., Schwab, S.
(2009). Ice-Cold Saline for the Induction of Mild Hypothermia in Patients With Acute Ischemic Stroke: A Pilot Study. Stroke
40: 1907-1909
[Abstract][Full Text]
KOCHANEK, P. M.
(2009). Bakken Lecture: The brain, the heart, and therapeutic hypothermia. Cleveland Clinic Journal of Medicine
76: S8-S12
[Abstract][Full Text]
Doherty, D. R., Parshuram, C. S., Gaboury, I., Hoskote, A., Lacroix, J., Tucci, M., Joffe, A., Choong, K., Farrell, R., Bohn, D. J., Hutchison, J. S., on Behalf of the Canadian Critical Care Trials Gro,
(2009). Hypothermia Therapy After Pediatric Cardiac Arrest. Circulation
119: 1492-1500
[Abstract][Full Text]
Haslam, G. M., Thomas, M. C, Laver, S. R
(2009). Delayed therapeutic hypothermia following cardiac arrest secondary to chloroquine toxicity. BMJ Case Reports
2009: bcr0820080824-bcr0820080824
[Abstract][Full Text]
Dichtwald, S., Matot, I., Einav, S.
(2009). Improving the Outcome of In-Hospital Cardiac Arrest: The Importance of Being EARNEST. SEMIN CARDIOTHORAC VASC ANESTH
13: 19-30
[Abstract]
Husselbee, N., Davies, R. P., Perkins, G. D.
(2009). Advanced life support update. Br Med Bull
89: 79-91
[Abstract][Full Text]
Schneider, A., Bottiger, B. W., Popp, E.
(2009). Cerebral Resuscitation After Cardiocirculatory Arrest. Anesth. Analg.
108: 971-979
[Abstract][Full Text]
Mayer, S. A., Davis, S. M., Skolnick, B. E., Brun, N. C., Begtrup, K., Broderick, J. P., Diringer, M. N., Steiner, T.
(2009). Can a Subset of Intracerebral Hemorrhage Patients Benefit From Hemostatic Therapy With Recombinant Activated Factor VII?. Stroke
40: 833-840
[Abstract][Full Text]
Savitz, S. I.
(2009). Cosmic Implications of NXY-059. Stroke
40: S115-S118
[Full Text]
Eisenberg, M. S., Psaty, B. M.
(2009). Defining and Improving Survival Rates From Cardiac Arrest in US Communities. JAMA
301: 860-862
[Full Text]
Ewy, G. A., Kern, K. B.
(2009). Recent advances in cardiopulmonary resuscitation: cardiocerebral resuscitation.. J Am Coll Cardiol
53: 149-157
[Abstract][Full Text]
Trujillo, M. H., Bellorin-Font, E., Fragachan, C. F., Perret-Gentil, R.
(2009). Multiple Organ Failure Following Near-fatal Exertional Heat Stroke. J Intensive Care Med
24: 72-78
[Abstract]
Alberts, M. J., Felberg, R. A., Guterman, L. R., Levine, S. R., for Writing Group 4,
(2008). Atherosclerotic Peripheral Vascular Disease Symposium II: Stroke Intervention: State of the Art. Circulation
118: 2845-2851
[Full Text]
Zed, P. J., Abu-Laban, R. B., Shuster, M., Green, R. S., Slavik, R. S., Travers, A. H.
(2008). Update on cardiopulmonary resuscitation and emergency cardiovascular care guidelines. Am J Health Syst Pharm
65: 2337-2346
[Abstract][Full Text]
Neumar, R. W., Nolan, J. P., Adrie, C., Aibiki, M., Berg, R. A., Bottiger, B. W., Callaway, C., Clark, R. S.B., Geocadin, R. G., Jauch, E. C., Kern, K. B., Laurent, I., Longstreth, W.T. Jr, Merchant, R. M., Morley, P., Morrison, L. J., Nadkarni, V., Peberdy, M. A., Rivers, E. P., Rodriguez-Nunez, A., Sellke, F. W., Spaulding, C., Sunde, K., Vanden Hoek, T.
(2008). Post-Cardiac Arrest Syndrome: Epidemiology, Pathophysiology, Treatment, and Prognostication A Consensus Statement From the International Liaison Committee on Resuscitation (American Heart Association, Australian and New Zealand Council on Resuscitation, European Resuscitation Council, Heart and Stroke Foundation of Canada, InterAmerican Heart Foundation, Resuscitation Council of Asia, and the Resuscitation Council of Southern Africa); the American Heart Association Emergency Cardiovascular Care Committee; the Council on Cardiovascular Surgery and Anesthesia; the Council on Cardiopulmonary, Perioperative, and Critical Care; the Council on Clinical Cardiology; and the Stroke Council. Circulation
118: 2452-2483
[Full Text]
Badjatia, N., Strongilis, E., Gordon, E., Prescutti, M., Fernandez, L., Fernandez, A., Buitrago, M., Schmidt, J. M., Ostapkovich, N. D., Mayer, S. A.
(2008). Metabolic Impact of Shivering During Therapeutic Temperature Modulation: The Bedside Shivering Assessment Scale. Stroke
39: 3242-3247
[Abstract][Full Text]
Al Thenayan, E., Savard, M., Sharpe, M., Norton, L., Young, B.
(2008). Predictors of poor neurologic outcome after induced mild hypothermia following cardiac arrest. Neurology
71: 1535-1537
[Abstract][Full Text]
Topjian, A. A., Berg, R. A., Nadkarni, V. M.
(2008). Pediatric Cardiopulmonary Resuscitation: Advances in Science, Techniques, and Outcomes. Pediatrics
122: 1086-1098
[Abstract][Full Text]
Weisfeldt, M. L., Ornato, J. P.
(2008). Closed-Chest Cardiac Massage: Progress Measured by the Exceptions. JAMA
300: 1582-1584
[Full Text]
Shankaran, S., Pappas, A., Laptook, A. R., McDonald, S. A., Ehrenkranz, R. A., Tyson, J. E., Walsh, M., Goldberg, R. N., Higgins, R. D., Das, A., for the NICHD Neonatal Research Network,
(2008). Outcomes of Safety and Effectiveness in a Multicenter Randomized, Controlled Trial of Whole-Body Hypothermia for Neonatal Hypoxic-Ischemic Encephalopathy. Pediatrics
122: e791-e798
[Abstract][Full Text]
Yenari, M., Kitagawa, K., Lyden, P., Perez-Pinzon, M.
(2008). Metabolic Downregulation: A Key to Successful Neuroprotection?. Stroke
39: 2910-2917
[Abstract][Full Text]
Nichol, G., Thomas, E., Callaway, C. W., Hedges, J., Powell, J. L., Aufderheide, T. P., Rea, T., Lowe, R., Brown, T., Dreyer, J., Davis, D., Idris, A., Stiell, I.
(2008). Regional Variation in Out-of-Hospital Cardiac Arrest Incidence and Outcome. JAMA
300: 1423-1431
[Abstract][Full Text]
Meloni, B. P., Mastaglia, F. L., Knuckey, N. W.
(2008). Review: Therapeutic applications of hypothermia in cerebral ischaemia. Therapeutic Advances in Neurological Disorders
1: 75-98
[Abstract]
Hollenberg, J., Herlitz, J., Lindqvist, J., Riva, G., Bohm, K., Rosenqvist, M., Svensson, L.
(2008). Improved Survival After Out-of-Hospital Cardiac Arrest Is Associated With an Increase in Proportion of Emergency Crew-Witnessed Cases and Bystander Cardiopulmonary Resuscitation. Circulation
118: 389-396
[Abstract][Full Text]
Gueugniaud, P.-Y., David, J.-S., Chanzy, E., Hubert, H., Dubien, P.-Y., Mauriaucourt, P., Braganca, C., Billeres, X., Clotteau-Lambert, M.-P., Fuster, P., Thiercelin, D., Debaty, G., Ricard-Hibon, A., Roux, P., Espesson, C., Querellou, E., Ducros, L., Ecollan, P., Halbout, L., Savary, D., Guillaumee, F., Maupoint, R., Capelle, P., Bracq, C., Dreyfus, P., Nouguier, P., Gache, A., Meurisse, C., Boulanger, B., Lae, C., Metzger, J., Raphael, V., Beruben, A., Wenzel, V., Guinhouya, C., Vilhelm, C., Marret, E.
(2008). Vasopressin and Epinephrine vs. Epinephrine Alone in Cardiopulmonary Resuscitation. NEJM
359: 21-30
[Abstract][Full Text]
Papadimitriou, D, Xanthos, T, Dontas, I, Lelovas, P, Perrea, D
(2008). The use of mice and rats as animal models for cardiopulmonary resuscitation research. Lab Anim
42: 265-276
[Abstract][Full Text]
Hutchens, M. P., Dunlap, J., Hurn, P. D., Jarnberg, P. O.
(2008). Renal Ischemia: Does Sex Matter?. Anesth. Analg.
107: 239-249
[Abstract][Full Text]
Hutchison, J. S., Ward, R. E., Lacroix, J., Hebert, P. C., Barnes, M. A., Bohn, D. J., Dirks, P. B., Doucette, S., Fergusson, D., Gottesman, R., Joffe, A. R., Kirpalani, H. M., Meyer, P. G., Morris, K. P., Moher, D., Singh, R. N., Skippen, P. W., the Hypothermia Pediatric Head Injury Trial Invest,
(2008). Hypothermia Therapy after Traumatic Brain Injury in Children. NEJM
358: 2447-2456
[Abstract][Full Text]
Tsai, M.-S., Barbut, D., Tang, W., Wang, H., Guan, J., Wang, T., Sun, S., Inderbitzen, B., Weil, M. H.
(2008). Rapid Head Cooling Initiated Coincident With Cardiopulmonary Resuscitation Improves Success of Defibrillation and Post-Resuscitation Myocardial Function in a Porcine Model of Prolonged Cardiac Arrest. J Am Coll Cardiol
51: 1988-1990
[Full Text]
Binnema, R, van der Wal, A, Visser, C, Schepp, R, Jekel, L, Schroder, P
(2008). Treatment of accidental hypothermia with cardiopulmonary bypass: a case report. Perfusion
23: 193-196
[Abstract]
Varon, J., Acosta, P.
(2008). Therapeutic Hypothermia: Past, Present, and Future. Chest
133: 1267-1274
[Abstract][Full Text]
Hovland, A, Bjornstad, H, Hallstensen, R F, Hugaas, K A, Westlie, J A, Elden, T, Andersen, K
(2008). Massive pulmonary embolism with cardiac arrest treated with continuous thrombolysis and concomitant hypothermia. Emerg. Med. J.
25: 310-311
[Abstract][Full Text]
Bouch, D. C., Thompson, J. P., Damian, M. S.
(2008). Post-cardiac arrest management: more than global cooling?. Br J Anaesth
100: 591-594
[Full Text]
Nichol, G., Rumsfeld, J., Eigel, B., Abella, B. S., Labarthe, D., Hong, Y., O'Connor, R. E., Mosesso, V. N., Berg, R. A., Leeper, B. B., Weisfeldt, M. L.
(2008). Essential Features of Designating Out-of-Hospital Cardiac Arrest as a Reportable Event: A Scientific Statement From the American Heart Association Emergency Cardiovascular Care Committee; Council on Cardiopulmonary, Perioperative, and Critical Care; Council on Cardiovascular Nursing; Council on Clinical Cardiology; and Quality of Care and Outcomes Research Interdisciplinary Working Group. Circulation
117: 2299-2308
[Abstract][Full Text]
Rauen, C. A., Chulay, M., Bridges, E., Vollman, K. M., Arbour, R.
(2008). Seven Evidence-Based Practice Habits: Putting Some Sacred Cows Out to Pasture. Crit Care Nurse
28: 98-123
[Full Text]
Harada, M., Honjo, H., Yamazaki, M., Nakagawa, H., Ishiguro, Y. S., Okuno, Y., Ashihara, T., Sakuma, I., Kamiya, K., Kodama, I.
(2008). Moderate hypothermia increases the chance of spiral wave collision in favor of self-termination of ventricular tachycardia/fibrillation. Am. J. Physiol. Heart Circ. Physiol.
294: H1896-H1905
[Abstract][Full Text]
Rincon, F.
(2008). Therapeutic Hypothermia after Cardiac Arrest. ANN INTERN MED
148: 485-486
[Full Text]
Zafari, A. M., Ali, B.
(2008). Therapeutic Hypothermia after Cardiac Arrest. ANN INTERN MED
148: 486-486
[Full Text]
Gunn, A. J., Hoehn, T., Hansmann, G., Buhrer, C., Simbruner, G., Yager, J., Levene, M., Hamrick, S. E. G., Shankaran, S., Thoresen, M.
(2008). Hypothermia: An Evolving Treatment for Neonatal Hypoxic Ischemic Encephalopathy. Pediatrics
121: 648-649
[Full Text]
O'Donnell, C. P F, Kamlin, C O. F, Davis, P. G, Morley, C. J
(2008). Ethical and legal aspects of video recording neonatal resuscitation. Arch. Dis. Child. Fetal Neonatal Ed.
93: F82-F84
[Full Text]
Statler, K. D.
(2008). Hypothermia to Treat Neonatal Hypoxic Ischemic Encephalopathy. AAP Grand Rounds
19: 3-4
[Full Text]
Pretre, R., Turina, M. I.
(2008). Deep Hypothermic Circulatory Arrest. Card Surg Adult
3: 431-442
[Full Text]
Anstadt, M. P., Lowe, J. E.
(2008). Cardiopulmonary Resuscitation. Card Surg Adult
3: 487-506
[Full Text]
Boodhwani, M., Rubens, F., Wozny, D., Rodriguez, R., Nathan, H. J.
(2007). Effects of sustained mild hypothermia on neurocognitive function after coronary artery bypass surgery: A randomized, double-blind study.. J. Thorac. Cardiovasc. Surg.
134: 1443-1452.e1
[Abstract][Full Text]
van der Worp, H. B., Sena, E. S., Donnan, G. A., Howells, D. W., Macleod, M. R.
(2007). Hypothermia in animal models of acute ischaemic stroke: a systematic review and meta-analysis. Brain
130: 3063-3074
[Abstract][Full Text]
Bader, M. K., Rovzar, M., Baumgartner, L., Winokur, R., Cline, J., Schiffman, G.
(2007). Keeping Cool: A Case for Hypothermia After Cardiopulmonary Resuscitation. Am J Crit Care
16: 636-640
[Abstract][Full Text]
Hemmen, T. M., Lyden, P. D.
(2007). Response to Letter by den Hertog et al. Stroke
38: e132-e132
[Full Text]
Bardutzky, J., Schwab, S.
(2007). Antiedema Therapy in Ischemic Stroke. Stroke
38: 3084-3094
[Abstract][Full Text]
Kozik, T. M.
(2007). Induced Hypothermia for Patients With Cardiac Arrest: Role of a Clinical Nurse Specialist. Crit Care Nurse
27: 36-42
[Full Text]
Anderson, R.
(2007). Ask the Experts. Crit Care Nurse
27: 61-62
[Full Text]
Golbin, J. M., Gajic, O.
(2007). A UNIQUE CAUSE OF HYPOXEMIA: COMPRESSION ATELECTASIS INDUCED BY HYPOTHERMIC COOLING AFTER CARDIAC ARREST. Chest Meeting
132: 731-731
[Abstract]
Shah, P. S., Ohlsson, A., Perlman, M.
(2007). Hypothermia to Treat Neonatal Hypoxic Ischemic Encephalopathy: Systematic Review. Arch Pediatr Adolesc Med
161: 951-958
[Abstract][Full Text]
Sanders, R. D., Maze, M.
(2007). Translational Research: Addressing Problems Facing the Anesthesiologist. Anesth. Analg.
105: 899-901
[Full Text]
Ibrahim, W. H
(2007). Recent advances and controversies in adult cardiopulmonary resuscitation. Postgrad. Med. J.
83: 649-654
[Abstract][Full Text]
Yellon, D. M., Hausenloy, D. J.
(2007). Myocardial Reperfusion Injury. NEJM
357: 1121-1135
[Full Text]
Soar, J., Nolan, J. P
(2007). Mild hypothermia for post cardiac arrest syndrome. BMJ
335: 459-460
[Full Text]
van der Worp, H. B., van Gijn, J.
(2007). Acute Ischemic Stroke. NEJM
357: 572-579
[Full Text]
Thompson, K. M., Gerlach, S. Y., Jorn, H. K. S., Larson, J. M., Brott, T. G., Files, J. A.
(2007). Advances in the Care of Patients With Intracerebral Hemorrhage. Mayo Clin Proc.
82: 987-990
[Abstract][Full Text]
Tiainen, M., Poutiainen, E., Kovala, T., Takkunen, O., Happola, O., Roine, R. O.
(2007). Cognitive and Neurophysiological Outcome of Cardiac Arrest Survivors Treated With Therapeutic Hypothermia. Stroke
38: 2303-2308
[Abstract][Full Text]
Rossetti, A. O., Logroscino, G., Liaudet, L., Ruffieux, C., Ribordy, V., Schaller, M. D., Despland, P. A., Oddo, M.
(2007). Status epilepticus: An independent outcome predictor after cerebral anoxia. Neurology
69: 255-260
[Abstract][Full Text]
Fukuda, S., Warner, D. S.
(2007). Cerebral protection. Br J Anaesth
99: 10-17
[Abstract][Full Text]
Kollmar, R., Schwab, S.
(2007). Ischaemic stroke: acute management, intensive care, and future perspectives. Br J Anaesth
99: 95-101
[Abstract][Full Text]
Barrett, K. M., Freeman, W. D., Weindling, S. M., Brott, T. G., Broderick, D. F., Heckman, M. G., Crook, J. E., Divertie, G. D., Meschia, J. F.
(2007). Brain Injury After Cardiopulmonary Arrest and Its Assessment With Diffusion-Weighted Magnetic Resonance Imaging. Mayo Clin Proc.
82: 828-835
[Abstract][Full Text]
Kim, F., Olsufka, M., Longstreth, W.T. Jr, Maynard, C., Carlbom, D., Deem, S., Kudenchuk, P., Copass, M. K., Cobb, L. A.
(2007). Pilot Randomized Clinical Trial of Prehospital Induction of Mild Hypothermia in Out-of-Hospital Cardiac Arrest Patients With a Rapid Infusion of 4{degrees}C Normal Saline. Circulation
115: 3064-3070
[Abstract][Full Text]
Varon, J., Marik, P. E.
(2007). Cardiopulmonary Resuscitation in Patients With Cancer. AM J HOSP PALLIAT CARE
24: 224-229
[Abstract]
Rubens, F. D., Nathan, H.
(2007). Lessons learned on the path to a healthier brain: dispelling the myths and challenging the hypotheses. Perfusion
22: 153-160
[Abstract]
Nathan, H. J., Rodriguez, R., Wozny, D., Dupuis, J.-Y., Rubens, F. D., Bryson, G. L., Wells, G.
(2007). Neuroprotective effect of mild hypothermia in patients undergoing coronary artery surgery with cardiopulmonary bypass: Five-year follow-up of a randomized trial. J. Thorac. Cardiovasc. Surg.
133: 1206-1211
[Abstract][Full Text]
Chin, J.-Y., Koh, Y., Joung Kim, M., Seong Kim, H., Kim, W.-S., Kim, D.-S., Kim, W.-D., Lim, C.-M.
(2007). The Effects of Hypothermia on Endotoxin-Primed Lung. Anesth. Analg.
104: 1171-1178
[Abstract][Full Text]
Ouyang, Y.-B., Voloboueva, L. A., Xu, L.-J., Giffard, R. G.
(2007). Selective Dysfunction of Hippocampal CA1 Astrocytes Contributes to Delayed Neuronal Damage after Transient Forebrain Ischemia. J. Neurosci.
27: 4253-4260
[Abstract][Full Text]
Stier, G. R., Verde, E. W.
(2007). The postoperative care of adult patients exposed to deep hypothermic circulatory arrest.. SEMIN CARDIOTHORAC VASC ANESTH
11: 77-85
[Abstract]
Lew, W. Y.W.
(2007). A Cool Heart Protected From Infarction: Clinical Translation of Breathing Chilled Liquids. J Am Coll Cardiol
49: 606-607
[Full Text]
Hemmen, T. M., Lyden, P. D.
(2007). Induced Hypothermia for Acute Stroke. Stroke
38: 794-799
[Abstract][Full Text]
A correction has been published: N Engl J Med 2002;346(22):1756.
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