Newborn resuscitation: should we oxygenate or not?

Abstract

EDITORIAL FOCUSNewborn resuscitation: should we oxygenate or not?Ola Didrik SaugstadOla Didrik SaugstadPublished Online:01 Oct 2008https://doi.org/10.1152/ajpheart.00880.2008This is the final version - click for previous versionMoreSectionsPDF (39 KB)Download PDF ToolsExport citationAdd to favoritesGet permissionsTrack citations ShareShare onFacebookTwitterLinkedInWeChat how should we oxygenate newborn and infants suffering from hypoxia and ischemia? Is it harmful to use 100% O2? It may seem odd to question a practice that has been carried out for so long, seemingly without any adverse effects. The case is, however, that after the practice of routinely using 100% O2 for newborn resuscitation was examined, many serious potentially harmful effects have to date been described (for review, see Ref. 13).Fabian et al. (1) add new information to the topic of how asphyxiated newborns should be reoxygenated (1). By inducing unilateral brain ischemia and hypoxia in newborn (7 day) rats, they showed that cerebral blood flow in the ischemic cortex declined following resuscitation with 100% O2 but not with ambient air. These findings in hyperoxic animals were accompanied by a reduction in perivascular production of nitric oxide (NO). Intraperitoneal injection with tetrahydrobiopterin (BH4) increased cerebral blood flow during hyperoxic resuscitation. This was followed by increased perivascular NO and reduced perivascular O2−. The authors suggest that hyperoxia uncouples perivascular NO synthase (NOS), probably endothelial NOS, leading to a reduced NO and increased O2− production. An injection of apocyanin, which is an inhibitor of NADPH oxidase, also increased NO and reduced O2−, indicating that an oxidative burst may be of importance in neonatal hypoxic-ischemic brain injury.This study confirms that a hyperoxic resuscitation of newborns may reduce the restoration of cerebral blood flow and therefore may be detrimental. But it also indicates that BH4 and perhaps also apocyanin should be interesting agents to test out in similar models to prevent such potentially harmful effects.For many reasons one should be careful drawing firm conclusions from newborn rats to newborn human infants. One major difference between birth asphyxia and the present model is that in the former the partial carbon dioxide tension of arterial blood (PaCO2) is elevated. Restoration of cerebral blood flow during reoxygenation differs whether it starts out with a high or as in the present study a relatively low PaCO2 (16). In resuscitated newborns infants, we also know that the time of reoxygenation often does not last more than a few minutes. A reoxygenation time of 2 h as in the study of Fabian et al. (1) therefore may not be relevant for newborns. On the other hand, such a long exposure to hyperoxia is not rare in the intensive care of children outside the immediate newborn period. A recent study by Koch et al. (8) showed that postischemic and posthypoxic hyperoxic exposure may have shocking effects on the brain. These authors found a dramatic augmented cerebral injury in 2-wk-old mice exposed to unilateral carotid ligation and hypoxia already after 30 min of hyperoxic-reoxygenation compared with reoxygenation with ambient air.There are now numerous experimental studies showing that hyperoxic resuscitation of newborn animals leads to inflammation and necrosis/apoptosis in the brain as well as in other organs (10, 13). Clinical studies as well show that hyperoxic compared with normoxic reoxygenation of newborn infants leads to tissue injury, for instance, in the myocardium and kidney (19). Even a brief exposure of hyperoxia after birth seems to trigger long-term elevation—at least several weeks—of oxidative stress (18). The consequence of this for growth and development is not understood. And more importantly, a recent meta-analysis including more than 2,000 newborn infants shows a 30% reduction in neonatal mortality when resuscitation was carried out with 21% instead of 100% O2 (15). This is an important finding because 5% of all newborn infants are in need of some ventilatory stimulation after birth and 1% need more extensive respiratory and ventilatory support (6). This means that in the United States 200,000 newborn infants need some kind of resuscitation every year. A reduction of mortality from 3.9% to 1.2% in these children, as found in European data (15), indicates that thousands of lives can be saved in the United States alone by avoiding the use of 100% O2 for newborn resuscitation. Based on these findings, more and more countries are therefore changing their guidelines and practice, starting with a low instead of a high inspired O2 fraction when newborn infants are in need of resuscitation. The study by Fabian et al. (1), as well as the one of Koch et al. (8), strongly indicates that also in children outside the newborn period hyperoxic-reoxygenation should be avoided. However, in this age group, clinical studies are lacking and are absolutely needed.There is in my opinion strong reasons that the results of Fabian et al. (1) have clinical relevance. Already by the mid-1990s, Lundstrøm et al. (9) showed that preterm infants exposed to a brief period of hyperoxia after birth had cerebral vasoconstriction as long as 2 h later.The understanding that a brief exposure of hyperoxia at birth may be detrimental has slowly evolved during more than 50 years in two lines of research. In 1953, Gerschman et al. (3) formulated the hypothesis that O2 is toxic because it generates O2 free radicals. The seminal observation by McCord and Fridovich (11) 14 years later that the xanthine/xanthine oxidase system generates O2 radicals continued this line of research. The other line of evidence was accumulated in the 1960s when it was shown that purine metabolites accumulate in isolated hypoxic kidney and myocardium (5) and in the 1970s when we found that hypoxanthine, the precursor of xanthine, accumulates in the body fluids of hypoxic newborn babies (12). This is the background of so-called reoxygenation or reperfusion injury (4, 14).One consequence of this understanding has been to reduce the O2 supplementation when hypoxic tissues or organs are reoxygenated. In the newborn this seems to be a promising strategy, and the O2 load to newborn and premature infants has been dramatically lowered the last decade or so (13). It is surprising that this has not yet to any extent been tested out in older children or adults.A second consequence of this line of research has been to find antioxidants that may reduce the harm inflicted by hypoxia-reoxygenation injury. So far the magic bullet has in my opinion not yet been found. One major issue is that reactive O2 species seem to have important regulatory functions in the newborn period, so care should be exercised giving antioxidants (7). It still is not well understood as shown by Friel et al. (2) why there is increased oxidative stress the first months of life.The study by Fabian et al. (1) opens for new therapeutic revenues, suggesting a different approach of therapy, administrating BH4. BH4 is synthesized from GTP and is a naturally occurring essential cofactor of phenylalanine, tyrosine, and tryptophan hydroxylases and is also essential for synthesis of NO by NOS. The lack of BH4 therefore may affect both catecholamine and NOS. BH4 is both a growth factor and a general neuroprotective factor (17). BH4 is reduced during oxidative stress; replenishment of this factor may therefore reduce O2 radical production. Yamashiro et al. (20) have for instance shown that BH4 lessens ischemia-reperfusion injury in isolated perfused rat hearts.The study by Fabian et al. (1) not only confirms that hyperoxic-reoxygenation of newborn hypoxic animals is detrimental, it also points to a pharmacological approach that may more specifically reduce O2 free radical production in a stage when this may be deleterious. This study is an example how experimental studies may lead the way from the laboratory to the bedside.REFERENCES1 Fabian HR, Perez-Polo J, Kent TA. Perivascular nitric oxide and superoxide in neonatal cerebral hypoxia-ischemia. Am J Physiol Heart Circ Physiol (August 1, 2008). doi: 10.1152/ajpheart.00301.2007.Link | ISI | Google Scholar2 Friel JK, Friesen RW, Harding SV, Roberts LJ. Evidence of oxidative stress in full-term healthy infants. Pediatr Res 56: 878–882, 2004.Crossref | PubMed | ISI | Google Scholar3 Gerschman R, Gilbert DL, Nye SW, Dwyer P, Fenn WO. Oxygen poisoning and x-irradiation: a mechanism in common. Science 119: 623–626, 1954.Crossref | PubMed | ISI | Google Scholar4 Granger DN, Rutili G, McCord JM. Superoxide radicals in feline intestinal ischemia. Gastroenterology 81: 22–29, 1981.Crossref | PubMed | ISI | Google Scholar5 Imai S, Riley AL, Berne RM. Effect of ischemia on adenine nucleotides in cardiac and skeletal muscles. Circ Res 15: 443–450, 1964.Crossref | PubMed | ISI | Google Scholar6 International Liaison Committee on Resuscitation. The International Liaison Committee on Resuscitation (ILCOR) consensus on science with treatment recommendations for pediatric and neonatal patients: neonatal resuscitation. Pediatrics 117: e978–e988, 2006.Crossref | PubMed | ISI | Google Scholar7 Jankov RP, Negus A, Tanswell AK. Antioxidants as therapy in the newborn: some words of caution. Pediatr Res 50: 681–687, 2001.Crossref | PubMed | ISI | Google Scholar8 Koch JD, Miles DK, Gilley JA, Yang CP, Kernie SG. Brief exposure to hyperoxia depletes the glial progenitor pool and impairs functional recovery after hypoxic-ischemic brain injury. J Cereb Blood Flow Metab 28: 1294–1306, 2008.Crossref | PubMed | ISI | Google Scholar9 Lundstrøm KE, Pryds O, Greisen G. Oxygen at birth and prolonged cerebral vasoconstriction in preterm infants. Arch Dis Child Fetal Neonatal Ed 73: F81–F86, 1995.Crossref | PubMed | ISI | Google Scholar10 Markus T, Hansson S, Amer-Wåhlin I, Hellström-Westas L, Saugstad OD, Ley D. Cerebral inflammatory response after fetal asphyxia and hyperoxic resuscitation in newborn sheep. Pediatr Res 62: 71–77, 2007.Crossref | PubMed | ISI | Google Scholar11 McCord JM, Fridovich I. The reduction of cytochrome c by milk xanthine oxidase. J Biol Chem 243: 5753–5760, 1968.Crossref | PubMed | ISI | Google Scholar12 Saugstad OD. Hypoxanthine as a measurement of hypoxia. Pediatr Res 9: 158–161, 1975.Crossref | PubMed | ISI | Google Scholar13 Saugstad OD. Optimal oxygenation at birth and in the neonatal period. Neonatology 91: 319–322, 2007.Crossref | PubMed | ISI | Google Scholar14 Saugstad OD, Aasen AO. Plasma hypoxanthine concentrations in pigs. A prognostic aid in hypoxia. Eur Surg Res 12: 123–129, 1980.Crossref | PubMed | ISI | Google Scholar15 Saugstad OD, Ramji S, Soll RF, Vento M. Resuscitation of newborn infants with 21% or 100% oxygen: an updated systematic review and meta-analysis. Neonatology 94: 176–182, 2008.Crossref | PubMed | ISI | Google Scholar16 Solås AB, Kalous P, Saugstad OD. Reoxygenation with 100 or 21% oxygen after cerebral hypoxemia-ischemia-hypercapnia in newborn piglets. Biol Neonate 85: 105–111, 2004.Crossref | PubMed | Google Scholar17 Thöny B, Auerbach G, Blau N. Tetrahydrobiopterin biosynthesis, regeneration and functions. Biochem J 347: 1–14, 2000.Crossref | PubMed | ISI | Google Scholar18 Vento M, Asensi M, Sastre J, García-Sala F, Pallardó FV, Viña J. Resuscitation with room air instead of 100% oxygen prevents oxidative stress in moderately asphyxiated term neonates. Pediatrics 107: 642–647, 2001.Crossref | PubMed | ISI | Google Scholar19 Vento M, Sastre J, Asensi MA, Viña J. Room-air resuscitation causes less damage to heart and kidney than 100% oxygen. Am J Respir Crit Care Med 172: 1393–1398, 2005.Crossref | PubMed | ISI | Google Scholar20 Yamashiro S, Noguchi K, Matsuzaki T, Miyagi K, Nakasone J, Sakanashi M, Koja K, Sakanshi M. Beneficial effect of tetrahydrobiopterin on ischemia-reperfusion injury in isolated perfused rat hearts. J Thorac Cardiovasc Surg 124: 775–784, 2002.Crossref | PubMed | ISI | Google ScholarAUTHOR NOTESAddress for reprint requests and other correspondence: O. D. Saugstad, Dept. of Pediatric Research, Rikshospitalet, 0027 Oslo, Norway (e-mail: [email protected]) Download PDF Back to Top Next FiguresReferencesRelatedInformation Cited ByAdditional Clinical Aspects of Developmental Physiology and Clinical Care2 February 2018Pulse Oximetry in Very Low Birth Weight InfantsClinics in Perinatology, Vol. 41, No. 4Reevaluating Reference Ranges of Oxygen Saturation for Healthy Full-term Neonates Using Pulse OximetryPediatrics & Neonatology, Vol. 55, No. 6Additional Clinical Aspects of Developmental Physiology31 July 2013Oxygen in Health and Disease: Regulation of Oxygen Homeostasis-Clinical ImplicationsPediatric Research, Vol. 65, No. 3 More from this issue > Volume 295Issue 4October 2008Pages H1371-H1372 Copyright & PermissionsCopyright © 2008 by the American Physiological Societyhttps://doi.org/10.1152/ajpheart.00880.2008PubMed18708440History Published online 1 October 2008 Published in print 1 October 2008 Metrics