High-Frequency Jet Ventilation in Pediatric Acute Respiratory Failure

Andrew G Miller; Kaitlyn E Haynes; Rachel M Gates; Karan R Kumar; Ira M Cheifetz; Alexandre T Rotta

doi:10.4187/respcare.08241

High-Frequency Jet Ventilation in Pediatric Acute Respiratory Failure

Respir Care. 2021 Feb;66(2):191-198. doi: 10.4187/respcare.08241. Epub 2020 Oct 2.

Authors

Andrew G Miller¹, Kaitlyn E Haynes², Rachel M Gates², Karan R Kumar³, Ira M Cheifetz⁴, Alexandre T Rotta³

Affiliations

¹ Respiratory Care Services, Duke University Medical Center, Durham, North Carolina. andrew.g.miller@duke.edu.
² Respiratory Care Services, Duke University Medical Center, Durham, North Carolina.
³ Division of Pediatric Critical Care Medicine, Duke Children's Hospital, Durham, North Carolina.
⁴ Division of Pediatric Critical Care Medicine, Duke Children's Hospital, Durham, North Carolina. He is currently affiliated with Rainbow Babies and Children's Hospital, Cleveland, Ohio.

PMID: 33008841
DOI: 10.4187/respcare.08241

Abstract

Background: High-frequency jet ventilation (HFJV) is primarily used in premature neonates; however, its use in pediatric patients with acute respiratory failure has been reported. The objective of this study was to evaluate HFJV use in the pediatric critical care setting. We hypothesized that HFJV would be associated with improvements in oxygenation and ventilation.

Methods: Medical records of all patients who received HFJV in the pediatric ICU of a quaternary care center between 2014 and 2018 were retrospectively reviewed. Premature infants who had not been discharged home were excluded, as were those in whom HFJV was started while on extracorporeal membrane oxygenation. Data on demographics, pulmonary mechanics, gas exchange, and outcomes were extracted and analyzed using chi-square testing for categorical variables, nonparametric testing for continuous variables, and a linear effects model to evaluate gas exchange over time.

Results: A total of 35 subjects (median age = 2.9 months, median weight = 5.2 kg) were included. Prior to HFJV initiation, median (interquartile range) oxygenation index (OI) was 11.3 (7.2-16.9), [Formula: see text] = 133 (91.3-190.0), pH = 7.18 (7.11-7.27), [Formula: see text] = 64 (52-87) mm Hg, and [Formula: see text] = 74 (64-125) mm Hg. For subjects still on HFJV (n = 25), there was no significant change in OI, [Formula: see text], or [Formula: see text] at 4-6 h after initiation, whereas pH increased (P = .001) and [Formula: see text] decreased (P = .001). For those remaining on HFJV for > 72 h (n = 12), the linear effects model revealed no differences over 72 h for OI, [Formula: see text], [Formula: see text], or mean airway pressure, but there was a decrease in [Formula: see text] while pH and [Formula: see text] increased. There were 9 (26%) subjects who did not survive, and nonsurvivors had higher Pediatric Index of Mortality 2 scores (P = .01), were more likely to be immunocompromised (P = .01), were less likely to have a documented infection (P = .02), and had lower airway resistance (P = .02).

Conclusions: HFJV was associated with improved ventilation among subjects able to remain on HFJV but had no significant effect on oxygenation.

Keywords: children; gas exchange; high-frequency ventilation; jet ventilation; mechanical ventilation; oxygenation; pediatric ARDS; pediatric respiratory failure; ventilation.

MeSH terms

Child
Child, Preschool
High-Frequency Jet Ventilation*
Humans
Infant
Infant, Newborn
Infant, Premature
Respiration, Artificial
Respiratory Distress Syndrome*
Respiratory Insufficiency* / therapy
Retrospective Studies