After successful resuscitation from cardiac arrest, cooling the whole body is a well established treatment that improves the chances of the brain recovering. This however, has to be done within a certain time-frame from the arrest. The purpose of this study is to explore the best way of dosing the muscle relaxing medications that are given during the cooling process. Hypothesis: In the context of our institutional therapeutic hypothermia protocol, cisatracurium infusions lead to faster drops in core temperature when compared to cisatracurium prn boluses alone.
STUDY RATIONALE: A large proportion of comatose survivors of cardiac arrest presenting to our intensive care units at London Health Sciences Centre (LHSC) undergo therapeutic hypothermia. Current evidence suggests that timely achievement of target temperatures is desirable to improve outcomes. At LHSC, this intervention is protocolized with a defined set of preprinted orders that includes a dosing regimen for neuromuscular blocking agents (NMBA's). Our preprinted protocol has been in place since January of 2004. Cisatracurium infusions were part of the therapeutic hypothermia protocol until October 2011. Since that time, our protocol has changed to cisatracurium prn boluses for any observed shivering. In this study we will examine if there has been any change in the times to achieving target temperatures with the implementation of this change. It is important to note that no other change in our protocol has taken place since it was first implemented, making our before and after comparison valid and fair. Our hypothesis is that NMBA infusions lead to a faster drop in core temperatures when compared to NMBA prn boluses. If this were to stand true, we would expect cisatracurium IV infusions to result in faster reductions in core temperature when compared with cisatracurium prn boluses in the context of our therapeutic hypothermia protocol. Hypothermia has been known to cause a subclinical increase in muscle tone. This previously reported phenomenon has been named "microshivering". When attempting to reduce core temperatures, microshivering is likely a natural body response to try to restore body temperature back to normal. We therefore hypothesize that NMBA infusions are likely more effective at abolishing microshivering, which would be a desirable effect when trying to induce therapeutic hypothermia. Although current American Heart Association (AHA) guidelines suggest considering the administration of NMBA's to facilitate induced hypothermia and control shivering. Their recommendation is to minimize the duration of NMBA use or if possible, avoid them altogether. After the publication of these guidelines our institutional protocol changed to prn boluses instead of the previous infusion orders. We therefore believe it is important to examine the effects of this change on our cooling protocol and potentially add to the growing body of knowledge in this field.
Study Type
OBSERVATIONAL
Enrollment
400
This group will include postcardiac arrest patients that have received a cisatracurium infusion as part of their therapeutic hypothermia protocol. It will only include patients that had their infusion started within 2 hours from protocol initiation. Patients that received an infusion as a rescue measure (beyond the first 2 hours) or did not receive and infusion at all will not be included in this group. Most patients admitted to our ICU postcardiac arrest prior to October 2011, will likely belong to this group (the cisatracurium infusion group).
Patients that have not received a cisatracurium infusion within the first 2 hours from protocol initiation will be in this group. These are likely to be patients admitted to our ICU after October 2011 (when the protocol change happened).
University Hospital, London Health Sciences Centre, University of Western Ontario
London, Ontario, Canada
Victoria Hospital, London Health Sciences Centre, University of Western Ontario
London, Ontario, Canada
Time to attaining target temperature (hours).
The primary outcome will be a binary outcome that is: adequate cooling time versus inadequate cooling time based on the time needed to achieve target temperatures. We will define adequate cooling time as being ≤ 4 hours from initiation of protocol to reaching target temperature. Inadequate cooling time will be requiring \> 4 hours to achieve that goal. Target core body temperature range in our institutional protocol is 32 - 34ºC. The primary outcome will be assessed using a logistic regression model, constructed using covariates affecting speed of cooling as determined by expert opinion and current evidence apriori. The variables will be age, sex, weight, pre-protocol core body temperature, initial arrest rhythm and infusion versus boluses. The model will be used to determine whether the cisatracurium dosing regimen is an independent predictor of adequate patient cooling time or not.
Time frame: From initiation of hypothermia protocol to reaching a core body temperature of ≤34ºC, assessed up to 72 hours from protocol initiation.
Cerebral performance category score on hospital discharge.
Neurological outcome on discharge from hospital as defined by the cerebral performance category (CPC) scale. The CPC scale is a 5 point scale. The outcome measure will be dichotomized into good or bad. Good outcome will be equivalent to CPC scores of 1 \& 2 (where the patient is independent), and bad outcome will be equivalent to CPC scores of 3, 4 \& 5 (where the patient is either dependent or dead). We will examine whether the use of a neuromuscular blocking agent infusion correlates with good CPC scores on hospital discharge or not. CPC Scale: 1. Functioning normally and independent, possibly with a minor disability. 2. Moderately disabled, still independent. 3. Conscious but with a severe disability, dependent. 4. Unconscious (comatose or in a persistent vegetative state). 5. Brain dead or dead by traditional criteria.
Time frame: Upon discharge from hospital, assessed up to 36 months postcardiac arrest.
Hospital length of stay postcardiac arrest (days).
Hospital length of stay (LOS) post-cardiac arrest will be calculated from the day of the cardiac arrest to the day of hospital discharge. If prior to the arrest the patient was an inpatient, we will only count the days from the arrest to discharge. Days spent in hospital prior to the arrest will not be included.
Time frame: Days spent in hospital after successful resuscitation from cardiac arrest, assessed up to 36 months from the date of cardiac arrest
Intensive care unit length of stay postcardiac arrest (days).
The length of stay (LOS) in the intensive care unit (ICU) after successful resuscitation from cardiac arrest in days.
Time frame: Days spent in the intensive care unit after successful resuscitation from cardiac arrest, assessed up to 36 months from the date of cardiac arrest.
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