Acute Hypoxemic Respiratory Failure Clinical Trial
Official title:
High-Frequency Oscillatory Ventilation Associated With Inhaled Nitric Oxide in Children: Randomized, Crossover Study
Background/Objectives: Acute hypoxemic respiratory failure (AHRF) is a frequent cause of
pediatric ICU admission. Early treatment with inhaled nitric oxide (iNO) plus conventional
mechanical ventilation (CMV) improves oxygenation, responsiveness being significantly
influenced by alveolar recruitment level. High-frequency oscillatory ventilation (HFV) is
conceptually very attractive as constant mean airway pressure optimizes lung recruitment;
this could maximize iNO effects.
Aims: To analyze the effects of HFV on oxygenation indexes in AHRF children under CMV and
iNO.
Methods: Children with AHRF (oxygenation index ≥10) aged between one month and 14 years
under CMV with PEEP≥10cmH2O and 5ppm iNO for 1h were randomly assigned to CMV (CMVG, n=12)
or HFV (HFVG, n=12) in a crossover design. Children with chronic cardiac or pulmonary
diseases were excluded. Patients were kept under one of the two ventilation modes for 8h,
crossing to the other for 8h, and then back again to complete 24h observation. Blood gas
analysis, oxygenation indexes, and hemodynamic variables were recorded at enrollment (Tind),
1h after iNO start and then every 4h (T4h etc). The Mann-Whitney U test compared group ages
and PRISM scores, and the Fisher test genders. Moments and groups were compared by repeated
measure analysis for independent groups. Significance was considered at p<0.05.
Acute hypoxemic respiratory failure (AHRF) is a frequent cause of admission and complicates
evolution of critically ill children. Mortality rate is still high, mainly when acute
respiratory distress syndrome (ARDS) evolves.
Clinical management of AHRF is essentially supportive and includes control of underlying
infections, fluid balance and hemodynamic status, nutritional support, and optimized
protective mechanical ventilation4,5,6. Ventilatory strategies should be directed at
minimizing ventilator-induced lung injury (VILI), eliminating oxygen toxicity, and
controlling lung inflammation. Also, when hypoxemia persists, additional treatments may be
implemented, such as inhaled nitric oxide (iNO)and high-frequency oscillatory ventilation
(HFOV).
Recently, we have demonstrated that early treatment with iNO associated with protective
conventional mechanical ventilation (CMV) causes acute and sustained improvement in
oxygenation, with earlier reduction in ventilator settings that are associated with a high
risk of VILI and oxygen toxicity; this might contribute to reducing the mortality rate in
children with ARDS.
However, many studies have given no value to iNO therapy because of a lack of impact on
mortality rate. Despite this, it should be considered that the improvement in oxygenation
promoted by NO inhalation may be useful as rescue therapy. Also, it is known that
responsiveness to iNO can be significantly influenced by applying sufficient positive and
expiratory pressure (PEEP), as this seems to recruit additional alveoli for gas exchange. In
this sense, HFOV is very attractive as the application of a constant mean airway pressure
maintains an "open lung" and optimizes lung recruitment; this could maximize iNO effects.
Two experimental studies have shown increased iNO effects when the gas was used together
with HFOV. In ARDS adults, Authors studied this association and demonstrated improvement in
oxygenation with significant reduction in FiO2, probably due to the degree of alveolar
recruitment during HFOV which may increase the amount of alveolar/capillary interface
available for iNO to act upon.
In pediatrics, there is one study combining iNO and HFOV in newborn babies with severe
persistent pulmonary hypertension which concluded that the association is often more
successful than each treatment alone23. After neonatal period, a retrospective (post hoc)
data analysis from a multicenter, randomized controlled trial on the effects of iNO in the
treatment of AHRF concluded that the combination of HFOV with iNO causes greater improvement
in oxygenation than either treatment strategy alone.
Therefore, the question about the potential role of the association between iNO therapy and
HFOV in AHRF children is still open and remains to be defined. Our hypothesis is the
association between early iNO treatment and HFOV improves oxygenation more consistently and
for longer time than the association of the gas with protective conventional mechanical
ventilation.
The aim of this study was to analyze the effects of HFOV on oxygenation indexes in AHRF
children under CMV and iNO therapy.
;
Allocation: Randomized, Intervention Model: Crossover Assignment, Masking: Single Blind (Subject), Primary Purpose: Treatment
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