Effect of High-Flow Nasal Cannula Therapy vs Continuous Positive Airway Pressure Following Extubation on Liberation From Respiratory Support in Critically Ill Children: A Randomized Clinical Trial.
Journal
JAMA
ISSN: 1538-3598
Titre abrégé: JAMA
Pays: United States
ID NLM: 7501160
Informations de publication
Date de publication:
26 04 2022
26 04 2022
Historique:
pubmed:
8
4
2022
medline:
29
4
2022
entrez:
7
4
2022
Statut:
ppublish
Résumé
The optimal first-line mode of noninvasive respiratory support following extubation of critically ill children is not known. To evaluate the noninferiority of high-flow nasal cannula (HFNC) therapy as the first-line mode of noninvasive respiratory support following extubation, compared with continuous positive airway pressure (CPAP), on time to liberation from respiratory support. This was a pragmatic, multicenter, randomized, noninferiority trial conducted at 22 pediatric intensive care units in the United Kingdom. Six hundred children aged 0 to 15 years clinically assessed to require noninvasive respiratory support within 72 hours of extubation were recruited between August 8, 2019, and May 18, 2020, with last follow-up completed on November 22, 2020. Patients were randomized 1:1 to start either HFNC at a flow rate based on patient weight (n = 299) or CPAP of 7 to 8 cm H2O (n = 301). The primary outcome was time from randomization to liberation from respiratory support, defined as the start of a 48-hour period during which the child was free from all forms of respiratory support (invasive or noninvasive), assessed against a noninferiority margin of an adjusted hazard ratio (HR) of 0.75. There were 6 secondary outcomes, including mortality at day 180 and reintubation within 48 hours. Of the 600 children who were randomized, 553 children (HFNC, 281; CPAP, 272) were included in the primary analysis (median age, 3 months; 241 girls [44%]). HFNC failed to meet noninferiority, with a median time to liberation of 50.5 hours (95% CI, 43.0-67.9) vs 42.9 hours (95% CI, 30.5-48.2) for CPAP (adjusted HR, 0.83; 1-sided 97.5% CI, 0.70-∞). Similar results were seen across prespecified subgroups. Of the 6 prespecified secondary outcomes, 5 showed no significant difference, including the rate of reintubation within 48 hours (13.3% for HFNC vs 11.5 % for CPAP). Mortality at day 180 was significantly higher for HFNC (5.6% vs 2.4% for CPAP; adjusted odds ratio, 3.07 [95% CI, 1.1-8.8]). The most common adverse events were abdominal distension (HFNC: 8/281 [2.8%] vs CPAP: 7/272 [2.6%]) and nasal/facial trauma (HFNC: 14/281 [5.0%] vs CPAP: 15/272 [5.5%]). Among critically ill children requiring noninvasive respiratory support following extubation, HFNC compared with CPAP following extubation failed to meet the criterion for noninferiority for time to liberation from respiratory support. isrctn.org Identifier: ISRCTN60048867.
Identifiants
pubmed: 35390113
pii: 2791014
doi: 10.1001/jama.2022.3367
pmc: PMC8990361
doi:
Banques de données
ISRCTN
['ISRCTN60048867']
Types de publication
Comparative Study
Journal Article
Multicenter Study
Pragmatic Clinical Trial
Randomized Controlled Trial
Langues
eng
Sous-ensembles de citation
IM
Pagination
1555-1565Investigateurs
Nazima Pathan
(N)
Esther Daubney
(E)
Deborah White
(D)
Nayan Shetty
(N)
Dawn Jones
(D)
Laura Rad
(L)
Laura O'Malley
(L)
Kevin Morris
(K)
Sarah Fox
(S)
Carly Tooke
(C)
Afeda Mohamed Ali
(A)
Peter Davis
(P)
Helen Marley
(H)
Rebecca Lean
(R)
Laura Dodge
(L)
Angela Aramburo
(A)
Laura Alcantara
(L)
Laura Tos
(L)
Helena Sampaio
(H)
Siva Oruganti
(S)
Susan Bowes
(S)
Awen Hughes
(A)
Mark J Peters
(MJ)
Lauran O'Neill
(L)
Holly Belfield
(H)
Samiran Ray
(S)
Rohit Saxena
(R)
Helen Vander Johnson
(H)
Tara McHugh
(T)
Gareth Jones
(G)
David Armstrong
(D)
Laura Fraser
(L)
Margrethe Van Dijke
(M)
Ian Piper
(I)
Jon Lillie
(J)
Paul A Wellman
(PA)
Aleksandra Williams
(A)
Tabitha Craen
(T)
Joanne Perkins
(J)
Christine Mackerness
(C)
Aravind Kashyap
(A)
Lindsay Cooper
(L)
Angela Lawton
(A)
Lynda Verhulst
(L)
Akash Deep
(A)
Ivan C Caro
(IC)
Eniola Nsirim
(E)
Samira N Vahid
(SN)
Bedangshu Saikia
(B)
Rekha Patel
(R)
Graham Mason
(G)
Claire Jennings
(C)
Rebecca Marshall
(R)
Danielle Pask
(D)
Avishay Sarfatti
(A)
Zoe Oliver
(Z)
Katie Wingfield
(K)
Sophie Herrington
(S)
Caterina Silvestre
(C)
Laura Anderson
(L)
Maria Saxton
(M)
Helen Fazackerley
(H)
Naomi Edmonds
(N)
Natasha Thorn
(N)
Nosheen Khalid
(N)
Hafiza Khatun
(H)
Anton Mayer
(A)
Alex Howlett
(A)
Jade Bryant
(J)
Ahmed Osman
(A)
Amber Cook
(A)
Lorena Caruana
(L)
Phillipa C Thomas
(PC)
Nicholas J Prince
(NJ)
Joana G de Queiroz
(JG)
Elena Maccarcari
(E)
Montserrat R Foguet
(MR)
Rebecca Mitting
(R)
Sarah Darnell
(S)
David Inwald
(D)
Sam Peters
(S)
Lorna Miller
(L)
Stefan Sprinckmoller
(S)
Abby Koelewyn
(A)
Roger Parslow
(R)
Commentaires et corrections
Type : CommentIn
Type : CommentIn
Références
Am J Nurs. 2005 Jan;105(1):33-6
pubmed: 15659992
JAMA. 2018 Nov 13;320(18):1881-1888
pubmed: 30347090
BMC Pediatr. 2010 May 05;10:29
pubmed: 20444256
Intensive Care Med. 2015 Apr;41(4):623-32
pubmed: 25691263
Intensive Care Med. 2017 Feb;43(2):209-216
pubmed: 28124736
JAMA. 2015 Jun 16;313(23):2331-9
pubmed: 25980660
JAMA Pediatr. 2017 Feb 1;171(2):165-174
pubmed: 27918754
Arch Dis Child. 2019 Nov;104(11):1077-1082
pubmed: 31175125
Crit Care Med. 2019 Oct;47(10):1324-1331
pubmed: 31356474
Crit Care Med. 2020 Nov;48(11):e1129-e1136
pubmed: 32947472
Pediatr Crit Care Med. 2020 Dec;21(12):e1069-e1075
pubmed: 32804740
J Matern Fetal Neonatal Med. 2021 Jan;34(2):259-266
pubmed: 30966839
N Engl J Med. 2014 Jan 23;370(4):385-6
pubmed: 24450905
BMJ Open. 2020 Aug 4;10(8):e038002
pubmed: 32753452
N Engl J Med. 2016 Sep 22;375(12):1142-51
pubmed: 27653564
Trials. 2020 Oct 31;21(1):903
pubmed: 33129360
JAMA. 2016 Oct 18;316(15):1565-1574
pubmed: 27706464
BMJ Open. 2015 Sep 18;5(9):e008522
pubmed: 26384724
JAMA. 2015 Jun 16;313(23):2371-2
pubmed: 26080342
Respir Care. 2017 Aug;62(8):1023-1029
pubmed: 28588119
Matern Child Nurs J. 1989 Fall;18(3):187-98
pubmed: 2491508
JAMA. 2018 Nov 13;320(18):1865-1867
pubmed: 30347040
Lancet. 2017 Mar 4;389(10072):886-887
pubmed: 28161017
Intensive Care Med. 2017 Dec;43(12):1764-1780
pubmed: 28936698
Pediatr Crit Care Med. 2020 May;21(5):e228-e235
pubmed: 32106187
Am J Respir Crit Care Med. 2014 Aug 1;190(3):258-65
pubmed: 25003705
N Engl J Med. 2018 Mar 22;378(12):1121-1131
pubmed: 29562151
Intensive Care Med. 2017 Feb;43(2):246-249
pubmed: 28124737
Am J Respir Crit Care Med. 2015 Dec 1;192(11):1306-13
pubmed: 26192398
Pediatr Crit Care Med. 2019 Mar;20(3):223-232
pubmed: 30395107
Crit Care. 2018 Jun 4;22(1):144
pubmed: 29866165
Pediatrics. 2015 Nov;136(5):e1316-22
pubmed: 26438711
JAMA. 2021 Aug 3;326(5):401-410
pubmed: 34342620
Intensive Care Med. 2022 Feb;48(2):137-147
pubmed: 34825256