High Vs. Low Initial Oxygen to Improve the Breathing Effort of Preterm Infants at Birth: Study Protocol for a Randomized Controlled Trial

Overview

Journal Front Pediatr

Specialty Pediatrics

Date 2019 May 29

PMID 31134170

Citations 3

Authors

Janneke Dekker

Stuart B Hooper

Martin Giera

Erin V McGillick

G Jeroen Hutten

W Onland

Anton H van Kaam

Arjan B Te Pas

Affiliations

Soon will be listed here.

Abstract

Although most preterm infants breathe at birth, their respiratory drive is weak and supplemental oxygen is often needed to overcome hypoxia. This could in turn lead to hyperoxia. To reduce the risk of hyperoxia, currently an initial low oxygen concentration (21-30%) is recommended during stabilization at birth, accepting the risk of a hypoxic period. However, hypoxia inhibits respiratory drive in preterm infants. Starting with a higher level of oxygen could lead to a shorter duration of hypoxia by stimulating breathing effort of preterm infants, and combined with subsequent titration based on oxygen saturation, prolonged hyperoxia might be prevented. This multi-center randomized controlled trial will include 50 infants with a gestational age between 24 and 30 weeks. Eligible infants will be randomized to stabilization with an initial FiO of either 1.0 or 0.3 at birth. Hereafter, FiO will be titrated based on the oxygen saturation target range. In both groups, all other interventions during stabilization and thereafter will be similar. The primary outcome is respiratory effort in the first 5 min after birth expressed as average minute volume/kg. Secondary outcomes include inspired tidal volumes/kg, rate of rise to maximum tidal volume/kg, percentage of recruitment breaths with tidal volumes above 8 mL/kg, duration of hypoxia and hyperoxia and plasma levels of markers of oxidative stress (8-iso-prostaglandin F2α). Current resuscitation guidelines recommend oxygen titration if infants fail to achieve the 25th percentile of the SpO reference ranges. It has become clear that, using this approach, most preterm infants are at risk for hypoxia in the first 5 min after birth, which could suppress the breathing effort. In addition, for compromised preterm infants who need respiratory support at birth, higher SpO reference ranges in the first minutes after birth might be needed to prevent prolonged hypoxia. Enhancing breathing effort by achieving an adequate level of oxygenation could potentially lead to a lower incidence of intubation and mechanical ventilation in the delivery room, contributing to a lower risk on lung injury in high-risk preterm infants. Measuring 8-iso-prostaglandin F2α could lead to a reflection of the true amount of oxygen exposure in both study groups.

Citing Articles

Optimising CPAP and oxygen levels to support spontaneous breathing in preterm rabbits.

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Initial Use of 100% but Not 60% or 30% Oxygen Achieved a Target Heart Rate of 100 bpm and Preductal Saturations of 80% Faster in a Bradycardic Preterm Model.

Bawa M, Gugino S, Helman J, Nielsen L, Bradley N, Mani S Children (Basel). 2022; 9(11).

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The Effect of Initial High vs. Low FiO on Breathing Effort in Preterm Infants at Birth: A Randomized Controlled Trial.

Dekker J, Martherus T, Lopriore E, Giera M, McGillick E, Hutten J Front Pediatr. 2020; 7:504.

PMID: 31921719 PMC: 6927294. DOI: 10.3389/fped.2019.00504.

Increasing Respiratory Effort With 100% Oxygen During Resuscitation of Preterm Rabbits at Birth.

Dekker J, Hooper S, Croughan M, Crossley K, Wallace M, McGillick E Front Pediatr. 2019; 7:427.

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