ABSTRACT
Extremely preterm infants often develop chronic lung disease (CLD) characterized by
heterogeneous aeration; poorly supported, floppy airways; and air trapping. High-frequency
jet ventilation (HFJV) with high end-expiratory pressure (optimal lung volume strategy
[OLVS]) may improve airway patency, lead to better gas distribution, improve gas exchange,
and facilitate extubation. In a pilot trial, this study sought to explore the effect
of HFJV on oxygenation, ventilation, and ease of extubation in preterm infants with
evolving CLD and refractory respiratory failure (RRF). From September 2002 to October
2004, 12 episodes of RRF developed in 10 ventilated extremely immature infants with
evolving CLD (10 on conventional and two on high-frequency oscillation). Chorioamnionitis
was confirmed in all infants, patent ductus arteriosus was ligated in five patients,
and Ureaplasma urealyticum was cultured from trachea in four patients. HFJV with OLVS was initiated when oxygenation
index (OI) > 10 or exhaled tidal volume (Vte) ≥ 7 mL/kg were required to maintain partial pressure of carbon dioxide, arterial
(Paco
2) < 60 mm Hg. Inspiratory time (0.02/s) and frequency (310 to 420/min) were set initially
with adjustment of pressure amplitude to keep Paco
2 between 45 and 55 mm Hg. Ventilatory stabilization and weaning from mechanical ventilation
with extubation to nasal continuous positive airway pressure (CPAP) were the goals
of this approach. Gas exchange data were analyzed by Analysis of variance for repeated
measures. Ten patients on 11 occasions of RRF were extubated to nasal CPAP successfully
in a median of 15.5 days. Nine of 10 patients survived (one died of pentalogy of Cantrell),
all required supplemental O2 at 36 weeks. Paco
2 decreased within 1 hour after the initiation of HFJV, and OI decreased by 24 hours.
Both remained significantly lower until successful extubation (p < 0.02). Compared with conventional ventilation or high-frequency oscillatory ventilation,
HFJV used with OLVS appears to improve gas exchange and may facilitate weaning from
mechanical ventilation (MV) in extremely immature infants with evolving CLD. These
encouraging pilot data need to be confirmed in a larger clinical trial.
KEYWORDS
Chronic lung disease - high-frequency jet ventilation - gas exchange
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Richard PlavkaM.D. Ph.D.
Department of Obstetrics and Gynecology, Division of Neonatology General Faculty Hospital
in Prague, Charles University
18 Apolinarska Street, 128 08 Prague 2, Czech Republic
