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Abstract

To date, the optimal cooling device for targeted temperature management (TTM) remains unclear. Water-circulating cooling blankets are broadly available and quickly applied but reveal inaccuracy during maintenance and rewarming period. Recently, esophageal heat exchangers (EHEs) have been shown to be easily inserted, revealed effective cooling rates (0.26–1.12°C/h), acceptable deviations from target core temperature (<0.5°C), and rewarming rates between 0.2 and 0.4°C/h. The aim of this study was to compare cooling rates, accuracy during maintenance, and rewarming period as well as side effects of EHEs with water-circulating cooling blankets in a porcine TTM model. Mean core temperature of domestic pigs (n = 16) weighing 83.2 ± 3.6 kg was decreased to a target core temperature of 33°C by either using EHEs or water-circulating cooling blankets. After 8 hours of maintenance, rewarming was started at a goal rate of 0.25°C/h. Mean cooling rates were 1.3 ± 0.1°C/h (EHE) and 3.2 ± 0.5°C/h (blanket, p < 0.0002). Mean difference to target core temperature during maintenance ranged between ±1°C. Mean rewarming rates were 0.21 ± 0.01°C/h (EHE) and 0.22 ± 0.02°C/h (blanket, n.s.). There were no differences with regard to side effects such as brady- or tachycardia, hypo- or hyperkalemia, hypo- or hyperglycemia, hypotension, shivering, or esophageal tissue damage. Target temperature can be achieved faster by water-circulating cooling blankets. EHEs and water-circulating cooling blankets were demonstrated to be reliable and safe cooling devices in a prolonged porcine TTM model with more variability in EHE group.

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References

Arrich

, Holzer

, Havel

, Mullner

, Herkner

. Hypothermia for neuroprotection in adults after cardiopulmonary resuscitation. Cochrane Database Syst Rev, 2016; 2:CD004128.

Bernard

, Gray

, Buist

, Jones

, Silvester

, Gutteridge

, et al. Treatment of comatose survivors of out-of-hospital cardiac arrest with induced hypothermia. N Engl J Med, 2002; 346:557–563.

Böttiger

, Semeraro

, Altemeyer

, Breckwoldt

, Kreimeier

, Rucker

, et al. KIDS SAVE LIVES: school children education in resuscitation for Europe and the world. Eur J Anaesthesiol, 2017; 34:792–796.

Buse

, Blancher

, Viglino

, Pasquier

, Maignan

, Bouzat

, et al. The impact of hypothermia on serum potassium concentration: a systematic review. Resuscitation, 2017; 118:35–42.

Che

, Li

, Kopil

, Liu

, Guo

, Neumar

. Impact of therapeutic hypothermia onset and duration on survival, neurologic function, and neurodegeneration after cardiac arrest. Crit Care Med, 2011; 39:1423–1430.

Desai

, Stecevic

, Chang

, Goldstein

, Badizadegan

, Furuta

. Association of eosinophilic inflammation with esophageal food impaction in adults. Gastrointest Endosc, 2005; 61:795–801.

Dingley

, Okano

, Planas

, Chakkarapani

. Feasibility of a miniature esophageal heat exchange device for rapid therapeutic cooling in newborns: preliminary investigations in a piglet model. Ther Hypothermia Tem Manag, 2018; 8:36–44.

El-Kattan

, Asbill

, Haidar

. Transdermal testing: practical aspects and methods. Pharm Sci Technol Today, 2000; 3:426–430.

Goury

, Poirson

, Chaput

, Voicu

, Garcon

, Beeken

, et al. Targeted temperature management using the “Esophageal Cooling Device” after cardiac arrest (the COOL study): a feasibility and safety study. Resuscitation, 2017; 121:54–61.

10.

Haugk

, Krizanac

, Stratil

, Grassberger

, Weihs

, Testori

, et al. Comparison of surface cooling and invasive cooling for rapid induction of mild therapeutic hypothermia in pigs—effectiveness of two different devices. Resuscitation, 2010; 81:1704–1708.

11.

Haugk

, Testori

, Sterz

, Uranitsch

, Holzer

, Behringer

, et al. Relationship between time to target temperature and outcome in patients treated with therapeutic hypothermia after cardiac arrest. Crit Care, 2011; 15:R101.

12.

Hegazy

, Lapierre

, Butler

, Martin

, Althenayan

. The esophageal cooling device: a new temperature control tool in the intensivist's arsenal. Heart Lung, 2017; 46:143–148.

13.

Hoedemaekers

, Ezzahti

, Gerritsen

, van der Hoeven

. Comparison of cooling methods to induce and maintain normo- and hypothermia in intensive care unit patients: a prospective intervention study. Crit Care, 2007; 11:R91.

14.

Kelley

, Curtis

, Marzan

, Karara

, Anderson

. Body surface area of female swine. J Animal Sci, 1973; 36:927–930.

15.

Khan

, Haymore

, Barnaba

, Armahizer

, Melinosky

, Bautista

, et al. Esophageal cooling device versus other temperature modulation devices for therapeutic normothermia in subarachnoid and intracranial hemorrhage. Ther Hypothermia Tem Manag, 2018; 8:53–58.

16.

Kilkenny

, Browne

, Cuthill

, Emerson

, Altman

. Improving bioscience research reporting: the ARRIVE guidelines for reporting animal research. PLoS Biol, 2010; 8:e1000412.

17.

Kim

, Shin

, Song

, Ro

, Kim

, Hong

, et al. Cooling methods of targeted temperature management and neurological recovery after out-of-hospital cardiac arrest: a nationwide multicenter multi-level analysis. Resuscitation, 2018; 125:56–65.

18.

Kulstad

, Metzger

, Courtney

, Rees

, Shanley

, Matsuura

, et al. Induction, maintenance, and reversal of therapeutic hypothermia with an esophageal heat transfer device. Resuscitation, 2013; 84:1619–1624.

19.

Kulstad

, Courtney

, Waller

. Induction of therapeutic hypothermia via the esophagus: a proof of concept study. World J Emerg Med, 2012; 3:118–122.

20.

Laptook

, Kilbride

, Shepherd

, McDonald

, Shankaran

, Truog

, et al. Temperature control during therapeutic hypothermia for newborn encephalopathy using different Blanketrol devices. Ther Hypothermia Temp Manag, 2014; 4:193–200.

21.

Lequerica

, Sanz

, Hornero

, Herrero

, Ruiz

, Burdio

, et al. Esophagus histological analysis after hyperthermia-induced injury: implications for cardiac ablation. Int J Hyperthermia, 2009; 25:150–159.

22.

Markota

, Fluher

, Kit

, Balazic

, Sinkovic

. The introduction of an esophageal heat transfer device into a therapeutic hypothermia protocol: a prospective evaluation. Am J Emerg Med, 2016; 34:741–745.

23.

Moulaert

, Verbunt

, van Heugten

, Wade

. Cognitive impairments in survivors of out-of-hospital cardiac arrest: a systematic review. Resuscitation, 2009; 80:297–305.

24.

Naiman

, Shanley

, Garrett

, Kulstad

. Evaluation of advanced cooling therapy's esophageal cooling device for core temperature control. Expert Rev Med Devices, 2016; 13:423–433.

25.

Nolan

, Soar

, Cariou

, Cronberg

, Moulaert

, Deakin

, et al. European Resuscitation Council and European Society of Intensive Care Medicine Guidelines for post-resuscitation care 2015: section 5 of the European Resuscitation Council Guidelines for Resuscitation 2015. Resuscitation, 2015; 95:202–222.

26.

Pehböck

, Dietrich

, Klima

, Paal

, Lindner

, Wenzel

. Anesthesia in swine: optimizing a laboratory model to optimize translational research. Anaesthesist, 2015; 64:65–70.

27.

Perman

, Ellenberg

, Grossestreuer

, Gaieski

, Leary

, Abella

, et al. Shorter time to target temperature is associated with poor neurologic outcome in post-arrest patients treated with targeted temperature management. Resuscitation, 2015; 88:114–119.

28.

Polderman

, Herold

. Therapeutic hypothermia and controlled normothermia in the intensive care unit: practical considerations, side effects, and cooling methods. Crit Care Med, 2009; 37:1101–1120.

29.

Schroeder

, Guschlbauer

, Maul

, Cremer

, Becker

, de la Puente Bethencourt

, et al. Oesophageal heat exchangers with a diameter of 11 mm or 14.7 mm are equally effective and safe for targeted temperature management. PLoS One, 2017; 12:e0173229.

30.

Schroeder

, Maul

, Guschlbauer

, Finke

, de la Puente Bethencourt

, Becker

, et al. Intravascular cooling device versus esophageal heat exchanger for mild therapeutic hypothermia in an experimental setting. Anesth Analg, 2018 [Epub ahead of print]; DOI: 10.1213/ANE.0000000000003922.

31.

Sessler

. Temperature monitoring and perioperative thermoregulation. Anesthesiology, 2008; 109:318–338.

32.

Sonder

, Janssens

, Beishuizen

, Henry

, Rittenberger

, Callaway

, et al. Efficacy of different cooling technologies for therapeutic temperature management: a prospective intervention study. Resuscitation, 2018; 124:14–20.

33.

Wang

, Moy

, Hiendlmayr

, Krainski

, Duvall

, Fernandez

. Intravascular cooling catheter-related venous thromboembolism after hypothermia: a case report and review of the literature. Ther Hypothermia Tem Manag, 2018; 8:117–120.

34.

Weihs

, Schratter

, Sterz

, Janata

, Hogler

, Holzer

, et al. The importance of surface area for the cooling efficacy of mild therapeutic hypothermia. Resuscitation, 2011; 82:74–78.

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Esophageal Heat Exchanger Versus Water-Circulating Cooling Blanket for Targeted Temperature Management

Abstract

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References

Supplementary Material