Effectiveness of Nasal Continuous Positive Airway Pressure vs Nasal Intermittent Positive Pressure Ventilation vs Noninvasive High-Frequency Oscillatory Ventilation as Support After Extubation of Neonates Born Extremely Preterm or With More Severe Respiratory Failure: A Secondary Analysis of a Randomized Clinical Trial.
Journal
JAMA network open
ISSN: 2574-3805
Titre abrégé: JAMA Netw Open
Pays: United States
ID NLM: 101729235
Informations de publication
Date de publication:
03 07 2023
03 07 2023
Historique:
medline:
5
7
2023
pubmed:
3
7
2023
entrez:
3
7
2023
Statut:
epublish
Résumé
The NASONE (Nasal Oscillation Post-Extubation) trial showed that noninvasive high-frequency oscillatory ventilation (NHFOV) slightly reduces the duration of invasive mechanical ventilation (IMV) in preterm infants, whereas NHFOV and noninvasive intermittent positive pressure ventilation (NIPPV) result in fewer reintubations than nasal continuous positive airway pressure (NCPAP). It is unknown whether NHFOV is similarly effective in extremely preterm neonates or in those with more severe respiratory failure (based on the duration of previous ventilation and CO2 levels). To clarify whether NHFOV is better than NIPPV and NCPAP in reducing the duration of IMV in extremely preterm neonates or those with severe respiratory failure. This study is a predefined secondary analyses of a multicenter randomized clinical trial that was performed at tertiary academic neonatal intensive care units (NICUs) in China. Participants included neonates enrolled in the NASONE trial between December 2017 and May 2021 and belonging to 3 predefined subgroups: (1) born at less than or equal to 28 weeks' (plus 6 days) gestation, (2) invasively ventilated for more than 1 week from birth, and (3) with CO2 greater than 50 mm Hg before or in the 24 hours after extubation. Data analysis was performed in August 2022. NCPAP, NIPPV, or NHFOV since the first extubation and until NICU discharge, with airway pressure higher in NHFOV than in NIPPV and than in NCPAP. The co-primary outcomes were total duration of IMV during the NICU stay, need for reintubation, and ventilator-free days calculated as per the original trial protocol. Outcomes were analyzed on an intention-to-treat basis as for the whole trial, and subgroup analyses followed the original statistical plan. Among 1137 preterm infants, 455 (279 boys [61.3%]) were born at 28 weeks' gestation or less, 375 (218 boys [58.1%]) underwent IMV for more than 1 week from birth, and 307 (183 boys [59.6%]) had CO2 greater than 50 mm Hg before or in the 24 hours after extubation. Both NIPPV and NHFOV were associated with significantly fewer reintubations (risk difference range, -28% [95% CI, -39% to -17%] to -15% [95% CI, -25% to -4%]; number needed to treat, 3-7 infants) and early reintubations (risk difference range, -24% [95% CI, -35% to -14%] to -20% [95% CI, -30% to -10%]) than NCPAP, and these reintubations were less frequently due to refractory hypoxemia. IMV was shorter in the NIPPV and NHFOV groups (mean difference range, -5.0 days [95% CI, -6.8 to -3.1 days] to -2.3 days [95% CI, -4.1 to -0.4 days]) than in the NCPAP group. Co-primary outcomes were not different between NIPPV and NHFOV; there was no significant interaction effect. Infants in the NHFOV group showed significantly less moderate-to-severe bronchopulmonary dysplasia than infants in the NCPAP group (range, -12% to -10%; number needed to treat, 8-9 infants) and better postextubation gas exchange in all subgroups. The 3 interventions were provided at different mean airway pressure and were equally safe. The subgroup analyses of extremely preterm or more ill infants confirm the results obtained in the whole population: NIPPV and NHFOV appeared equally effective in reducing duration of IMV compared with NCPAP. ClinicalTrials.gov Identifier: NCT03181958.
Identifiants
pubmed: 37399009
pii: 2806831
doi: 10.1001/jamanetworkopen.2023.21644
pmc: PMC10318479
doi:
Substances chimiques
Carbon Dioxide
142M471B3J
Banques de données
ClinicalTrials.gov
['NCT03181958']
Types de publication
Randomized Controlled Trial
Multicenter Study
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
e2321644Investigateurs
Xiaoyun Zhong
(X)
Sijie Song
(S)
Lan Zhang
(L)
Li Li
(L)
Huiqiang Liu
(H)
Xiaomei Tong
(X)
Xiaojing Xu
(X)
LiFeng Cui
(L)
Ming Yi
(M)
Zhoujie Peng
(Z)
Jie Li
(J)
Dongmei Chen
(D)
Weifeng Zhang
(W)
Xinzhu Lin
(X)
Bin Wang
(B)
Weimin Huang
(W)
Guangliang Bi
(G)
Shaoru He
(S)
Yumei Liu
(Y)
Jie Yang
(J)
Weiwei Gao
(W)
Wuhua Liang
(W)
Yaoxun Wu
(Y)
Xinnian Pan
(X)
Qiufen Wei
(Q)
Yujun Chen
(Y)
Bingmei Wei
(B)
Ling Liu
(L)
Xinghui Zheng
(X)
Ding Xu
(D)
Fan Wang
(F)
Bin Yi
(B)
Jingyun Shi
(J)
Yuning Li
(Y)
Li Jiang
(L)
Chunming Jiang
(C)
Chenghe Tang
(C)
Hong Xiong
(H)
Huiqing Sun
(H)
Wenqing Kang
(W)
Dapeng Liu
(D)
Falin Xu
(F)
Kaihui Xing
(K)
Ning Yang
(N)
Fang Liu
(F)
Shaoguang Lv
(S)
Hanchu Liu
(H)
Wenchao Yuan
(W)
Rui Cheng
(R)
Xian Shen
(X)
Hui Wu
(H)
Laishuan Wang
(L)
Zhenying Yang
(Z)
Xiao Zhang
(X)
Jiang Xue
(J)
Zhankui Li
(Z)
Rong Ju
(R)
Jin Wang
(J)
Wenbin Dong
(W)
Xiaoxiu Ye
(X)
Benqing Wu
(B)
Jun Zheng
(J)
Xiuying Tian
(X)
Mingxia Li
(M)
Yanping Zhu
(Y)
Nuerya Rejiafu
(N)
Long Li
(L)
Yangfang Li
(Y)
Canlin He
(C)
Hongying Mi
(H)
Kun Liang
(K)
Hong Cao
(H)
Linlin Xia
(L)
Chuanfeng Li
(C)
Zhaoqing Yin
(Z)
Le Su
(L)
Yanxiang Chen
(Y)
Liping Shi
(L)
Chenhong Wang
(C)
Jiajun Zhu
(J)
Xuefeng Zhang
(X)
Xirong Gao
(X)
Bo Lv
(B)
Chongde Liu
(C)
Xiaorong Wang
(X)
Liping Chen
(L)
Lin Li
(L)
Chunli Zhang
(C)
Jia Chen
(J)
Qiyu Li
(Q)
Qin Lv
(Q)
Yanhong Li
(Y)
Yong Ji
(Y)
Yanjiang Chen
(Y)
Jianhua Sun
(J)
Jun Bu
(J)
Danni Zhong
(D)
Zongyan Cao
(Z)
Shuping Han
(S)
Xiaohui Chen
(X)
Caiyun Gao
(C)
Hongbin Zhu
(H)
Zhenguang Li
(Z)
Hongwei Wu
(H)
Xiuyong Cheng
(X)
Juhua Li
(J)
Long Chen
(L)
Huanhuan Li
(H)
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