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7 - The pharmacology of hypothermia

from Section 2 - Clinical neural rescue

Published online by Cambridge University Press:  05 March 2013

By
Alistair J. Gunn  and
Paul P. Drury
Edited by
A. David Edwards ,
Denis V. Azzopardi  and
Alistair J. Gunn
A. David Edwards
Affiliation:
Institute of Reproductive and Developmental Biology, Imperial College, London
Denis V. Azzopardi
Affiliation:
Institute of Reproductive and Developmental Biology, Imperial College, London
Alistair J. Gunn
Affiliation:
School of Medical Sciences, University of Auckland
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Summary

Introduction

The possibility that hypothermia might prevent or lessen asphyxial brain injury is a “dream revisited”, first proposed more than 300 years ago by Floyer [1]. Early experimental studies, mainly in precocial animals such as rat pups and kittens, demonstrated that hypothermia during severe hypoxia/asphyxia greatly extended the “time to last gasp” and improved functional recovery [2]. These encouraging data led to uncontrolled studies in the 1950s and 1960s, in which infants who were not breathing spontaneously at 5 minutes after birth were immersed in cold water until respiration resumed and then allowed to slowly spontaneously rewarm [3]. Outcomes after cooling at birth were reported to be better than for historical controls. Although these studies preceded the development of active resuscitation, immersion cooling was able to be combined with positive pressure resuscitation [4]. These provocative studies were not followed up because of the recognition that mild hypothermia was associated with increased oxygen requirements and greater mortality in premature newborns (<1500 g) [5] and disappointing outcomes from a small cohort of children resuscitated from near-drowning [6].

In retrospect, a key conceptual limitation of the early preclinical studies was that they tested cooling during severe hypoxia [2], in contrast with the clinical setting where cooling was induced many hours after resuscitation [7]. This chapter reviews the key empirical developments that helped to delineate the experimental parameters that determine whether post-resuscitation cooling is or is not successful and then relates the parameters to potential mechanisms of hypothermic neuroprotection.

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Type
Chapter
Information
Neonatal Neural Rescue
A Clinical Guide
 , pp. 73 - 84
Publisher: Cambridge University Press
Print publication year: 2013

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