Literature DB >> 35581612

Early short course of neuromuscular blocking agents in patients with COVID-19 ARDS: a propensity score analysis.

Gianluigi Li Bassi^1,2,3,4,5,6, Kristen Gibbons⁷, Jacky Y Suen^8,9, Heidi J Dalton¹⁰, Nicole White¹¹, Amanda Corley^8,9, Sally Shrapnel^9,12, Samuel Hinton⁹, Simon Forsyth⁹, John G Laffey¹³, Eddy Fan¹⁴, Jonathon P Fanning^8,9,15,16, Mauro Panigada¹⁷, Robert Bartlett¹⁸, Daniel Brodie¹⁹, Aidan Burrell²⁰, Davide Chiumello^21,22, Alyaa Elhazmi²³, Mariano Esperatti²⁴, Giacomo Grasselli^14,22, Carol Hodgson²⁰, Shingo Ichiba²⁵, Carlos Luna²⁶, Eva Marwali²⁷, Laura Merson²⁸, Srinivas Murthy^29,30, Alistair Nichol^20,31,32, Mark Ogino³³, Paolo Pelosi^34,35, Antoni Torres^36,37, Pauline Yeung Ng³⁸, John F Fraser^{8,9,36,11,15,16}.

Abstract

BACKGROUND: The role of neuromuscular blocking agents (NMBAs) in coronavirus disease 2019 (COVID-19) acute respiratory distress syndrome (ARDS) is not fully elucidated. Therefore, we aimed to investigate in COVID-19 patients with moderate-to-severe ARDS the impact of early use of NMBAs on 90-day mortality, through propensity score (PS) matching analysis.
METHODS: We analyzed a convenience sample of patients with COVID-19 and moderate-to-severe ARDS, admitted to 244 intensive care units within the COVID-19 Critical Care Consortium, from February 1, 2020, through October 31, 2021. Patients undergoing at least 2 days and up to 3 consecutive days of NMBAs (NMBA treatment), within 48 h from commencement of IMV were compared with subjects who did not receive NMBAs or only upon commencement of IMV (control). The primary objective in the PS-matched cohort was comparison between groups in 90-day in-hospital mortality, assessed through Cox proportional hazard modeling. Secondary objectives were comparisons in the numbers of ventilator-free days (VFD) between day 1 and day 28 and between day 1 and 90 through competing risk regression.
RESULTS: Data from 1953 patients were included. After propensity score matching, 210 cases from each group were well matched. In the PS-matched cohort, mean (± SD) age was 60.3 ± 13.2 years and 296 (70.5%) were male and the most common comorbidities were hypertension (56.9%), obesity (41.1%), and diabetes (30.0%). The unadjusted hazard ratio (HR) for death at 90 days in the NMBA treatment vs control group was 1.12 (95% CI 0.79, 1.59, p = 0.534). After adjustment for smoking habit and critical therapeutic covariates, the HR was 1.07 (95% CI 0.72, 1.61, p = 0.729). At 28 days, VFD were 16 (IQR 0-25) and 25 (IQR 7-26) in the NMBA treatment and control groups, respectively (sub-hazard ratio 0.82, 95% CI 0.67, 1.00, p = 0.055). At 90 days, VFD were 77 (IQR 0-87) and 87 (IQR 0-88) (sub-hazard ratio 0.86 (95% CI 0.69, 1.07; p = 0.177).
CONCLUSIONS: In patients with COVID-19 and moderate-to-severe ARDS, short course of NMBA treatment, applied early, did not significantly improve 90-day mortality and VFD. In the absence of definitive data from clinical trials, NMBAs should be indicated cautiously in this setting.

Entities: Chemical

Keywords: COVID-19; Intensive care unit; Mechanical ventilation; Neuromuscular blocking agent; SARS-CoV-2

Mesh：

Substances：

Year: 2022 PMID： 35581612 PMCID： PMC9112652 DOI： 10.1186/s13054-022-03983-5

Source DB: PubMed Journal: Crit Care ISSN： 1364-8535 Impact factor: 19.334

Background

Since early 2020, SARS-CoV-2 infections have placed tremendous burden on patients and international healthcare services [1]. A high proportion of diseased patients require hospitalization, and a small subset with severe coronavirus disease 2019 (COVID-19) become critically ill and require invasive mechanical ventilation (IMV) for life-threatening respiratory failure [2-5]. High mortality has been reported in this subpopulation [4, 6–9], irrespective of survival benefits from established treatments, such as corticosteroids and IL-6 receptor antagonists [10, 11]. Neuromuscular blocking agents (NMBAs) have been commonly used for acute respiratory distress syndrome (ARDS) [12, 13] to reduce patient–ventilator asynchrony and—in the context of severely damaged and poorly compliant lungs—to improve oxygenation, while minimizing the work of breathing and risks of barotrauma. International studies have confirmed the use of NMBAs in up to 26% of ARDS patients [14]. Yet, conflicting results were provided by large randomized clinical trials, such as the ACURASYS [15] and ROSE trials [16], and indication, efficacy, and safety on the use of NMBAs in such patients remain uncertain. The severe respiratory failure associated with COVID-19 has been described as a form of ARDS, and the potential benefits of supportive treatments have largely been extrapolated from evidence in non-COVID-19-related ARDS. Thus, many COVID-19 patients have been treated with NMBAs [17, 18], and in some areas even shortage of these medications has been reported [19], especially during the early phase of the pandemic. To the best of our knowledge, no international studies have clearly elucidated the effects of NMBAs on mortality in COVID-19 patients. Interestingly, in a multicenter observational study, Courcelle et al. [20] reported that the duration of NMBA treatment in this population was often longer than 48 h and not associated with shorter duration of IMV. To further delineate the role of NMBA in ventilated COVID-19 patients, data extracted from the multicenter registry of the international COVID-19 Critical Care Consortium incorporating the ExtraCorporeal Membrane Oxygenation for 2019 novel Coronavirus Acute Respiratory Disease (COVID-19–CCC/ECMOCARD) were examined. Our hypothesis was that in patients with microbiologically confirmed COVID-19 and moderate-to-severe ARDS, no significant difference in 90-day hospital mortality was to be found between populations who received or not early NMBAs. Thus, the primary goal of this study was to identify difference in 90-day mortality, through propensity score (PS)-adjusted analysis, between patients who received or not a short course of NMBAs, within 48 h from commencement of IMV.

Methods

Study design

This was a comparative study in which mechanically ventilated COVID-19 patients with moderate-to-severe ARDS, who received an early short course of NMBAs, were compared with patients who did not receive NMBA or underwent NMBA treatment only on the day of commencement of IMV to explore the impact on in-hospital mortality during a follow-up period up to 90 days. Of note, the STROBE (Strengthening the Reporting of Observational Studies in Epidemiology) guidelines were used to ensure the reporting of this observational study [21].

Study population and settings

Inclusion criteria

We studied a convenience sampling of patients (≥ 16 years old) with microbiologically confirmed SARS-CoV-2 infection, via rapid nucleic acid amplification test (NAAT) or antigen tests, who were admitted to an intensive care unit (ICU) from February 1, 2020, through October, 31, 2021, at any of the COVID-19 Critical Care Consortiums participating hospitals. In addition, patients were selected if they presented with moderate-to-severe ARDS, defined by a ratio of the partial pressure of arterial oxygen to the fraction of inspired oxygen of < 150 mm Hg [16], within 48 h from commencement of IMV.

Exclusion criteria

We excluded patients with unrecorded date of commencement of IMV or who were transferred from other institutions, after commencement of IMV. In addition, we excluded from the primary analysis all patients with continuous use of NMBA for periods longer than 3 days, and intermittent use of NMBA within a 3-day period of treatment.

Variables, data sources, and measurements

Data on demographics, comorbidities, clinical symptoms, and laboratory results were collected by clinical and research staff of the participating ICUs in an electronic case report form [22]. Details of respiratory and hemodynamic support, physiological variables, and laboratory results were collected daily, with worst daily values recorded preferentially. Duration of IMV, length of ICU and hospital stays, and hospital mortality were also recorded.

Study groups

In line with previous therapeutic protocols applied in patients with moderate-to-severe ARDS [15, 16], we aimed to appraise a short course of NMBAs, applied early during the course of IMV. Thus, patients were assigned to the following study groups.

NMBA treatment

Use of NMBA treatment for at least 48 h and up to 3 consecutive days, initiated early, within 48 h from commencement of IMV.

Control

No use of NMBAs or administration only on the day IMV was commenced. Of note, the time of first NMBAs administration was not recorded on the case report form; thus, the treatment group was designed to include up to 3 consecutive days of NMBAs exposure to ensure that at least 2 days of full treatment were achieved in most of the patients, even if treatment commenced during the night or a single NMBA dose was given upon endotracheal intubation. In addition, patients who were tracheally intubated and transferred from institutions not collaborating with the COVID-19-CCC/ECMOCARD were excluded from the analysis to avoid enrolment of subjects who might have received NMBA prior to study monitoring. Recording of NMBA use was censored at 28 days from ICU admission, or upon discharge from the ICU or death, whichever occurred first.

Outcomes

The primary objective was comparison between groups in 90-day in-hospital mortality, through PS matching analysis. Secondary objectives were the numbers of ventilator-free days (days since successful weaning from mechanical ventilation) between day 1 and day 28 and between day 1 and day 90 in the PS-matched population. VFD was calculated as follows: VFDs = 0 if subject died in hospital within 28 or 90 days of mechanical ventilation; VFDs = 28 or 90 − x if successfully liberated from ventilation x days after initiation; VFDs = 0 if the subject was mechanically ventilated for more than 28 or 90 days.

Data source

We analyzed the COVID-19-CCC/ECMOCARD study dataset. COVID-19-CCC/ECMOCARD is an international, multicenter, observational cohort study ongoing in 354 hospitals across 54 countries (Additional file 1: Appendix). The full study protocol has been published elsewhere [22]. The COVID-19-CCC/ECMOCARD observational study was reviewed under the National Mutual Acceptance scheme by the Alfred Health Human Research Ethics Committee on February 27, 2020. The ethics committee certified that the study protocol met the requirements of the National Statement on Ethical Conduct in Human Research (2007), granting approval on March 2, 2020. In addition, in accordance with the Office of the Health Services Commissioners Statutory Guidelines on Research issued for the purposes of Health Privacy Principles, the Alfred Health Human Research Ethics Committee granted a waiver of consent for the collection, use, and disclosure of participants health and personal information. Subsequently, the protocol was approved by all international participating hospitals prior to data collection and waiver of consent was granted in all centers.

Data management and quality

The COVID-19 Consortium collaborates with the International Severe Acute Respiratory and Emerging Infection Consortium (ISARIC) group [23] and their Short PeRiod IncideNce sTudy of Severe Acute Respiratory Infection (SPRINT-SARI) [24] project. De-identified patient data are recorded by data collectors at each collaborating site via the REDCap (Vanderbilt/NIH/NCATS UL1 TR000445 v.10.0.23) electronic data capture tool, using instances hosted at the University of Oxford (UK), University College Dublin (Ireland), Monash University (Australia), and The University of Queensland (Australia). A detailed data dictionary was provided to all sites to assist in data collection. In addition, biweekly drop-in data sessions were scheduled to assist with all queries that data collectors might have. Importantly, the database quality audits of the COVID-19 Consortium dataset are a continuing and intensive process encompassing (1) data cleaning rules; (2) checks for outliers; (3) filtering rules setup during the initial development of the case report form, which was periodically monitored/adjusted; and (4) data completeness checks. Finally, in the case any issue was detected during monitoring of data quality, or statistical analysis, these matters were pursued to address any data collection/process limitation in a timely manner, often including follow-up with the site that entered the data for value verification and correction where appropriate.

Statistical analyses

Categorical data are presented as frequency and percentage, while continuous data as mean and standard deviation (SD; normally distributed) and median and interquartile range (IQR; non-normally distributed). Normality of continuous data was reviewed via visual inspection of histograms. Bivariate comparisons between patients receiving NMBA treatment and controls were compared using Fishers exact test, Students unpaired t test, or the Mann–Whitney U test for categorical, normally, and non-normally distributed continuous variables, respectively. Analyses were performed to examine the relationship between the primary outcome—mortality censored at 90 days post-commencement of IMV—and NMBA treatment. Patients entered the study analysis once they commenced IMV. As an imbalance in several characteristics at ICU admission between the study groups was noted, propensity score (PS) matching analysis was undertaken to balance these patient characteristics. Matching was undertaken, in preference to other techniques involving propensity scores, to best mimic the results of a randomized controlled trial. Baseline features considered potential variables for inclusion in the PS calculation were demographic and clinical characteristics with either a documented relationship with mortality or a baseline imbalance. Variables with more than 5% missing data were not considered. Based on the available literature on risk factors associated with mortality in severe COVID-19, the following covariates were included during PS modeling: age, sex, region (reference group: North America), time from symptom onset to hospital admission and baseline comorbidities (PaO2/FiO2 within 48 h from commencement of IMV, hypertension, chronic cardiac disease, chronic kidney disease, obesity). Matched cohorts were constructed based on the logit of the PS using nearest-neighbor matching with a caliper width of 0.2 and replacement to promote better balance, and accounting for the estimation of the standard errors. Rubins B [25] (a summation measure of bias with value < 25% indicating adequate balance) and Rubins R (0.5–2.0 indicating appropriate balancing) statistics were initially calculated to assess the success of the matching (i.e., if the resulting matched cohort had balanced characteristics). Standardized mean differences for all covariates, before and after matching, were then estimated, with an absolute difference of 10% or greater considered indicative of imbalance [26, 27]. Following PS matching, survival curves were generated for the matched sample to compare patients undergoing NMBA treatment against control. Finally, multivariable Cox regression models were constructed to assess the effect of NMBA treatment on outcome—incorporating robust estimators of variance to account for matched observations—as well as investigating effect modification on the association between mortality and NMBA by concomitant use of corticosteroids and respiratory failure severity. Covariates considered for inclusion in the multivariable Cox regression were laboratory results upon admission, treatments received and ventilator settings; covariates with known relationship with mortality in COVID-19 patients available in this dataset with less than 5% missing data were included in the final model. Where potential covariates were correlated, the most relevant clinical variable was chosen for inclusion in the model to avoid multicollinearity and the violation of model assumptions. Continuous covariates were standardized by subtracting the mean and dividing by the standard deviation to facilitate meaningful interpretation of the hazard ratios. Multiple imputation was not undertaken, and complete case analysis was performed [28]. Assumptions of the Cox regression model, particularly the proportional hazards assumption, were evaluated using test of the Schoenfeld residuals, as well as graphical exploration of the log–log plot; the proportional hazards assumption was met. Competing risk regression was performed to assess the secondary outcomes of VFDs at 28 and 90 days post-starting of IMV [29].

Sensitivity analyses

Considering the observational nature of our report and potential limitations related to PS matching, we also balanced baseline patient characteristics by weighting each individual in the analysis, by the inverse probability of receiving exposure to NMBAs (inverse probability of treatment weighting [IPTW]) [30]. In addition, as the dataset did not report exact NMBA administration practice, the following sensitivity analyses were conducted to confirm the results of the primary analysis: (1) in patients with clinically suspected and microbiologically confirmed COVID-19, with the treatment group defined as per the primary analysis; and in the treatment group only including patients who received NMBAs (2) continuously for 2 days; (3) continuously for 3 days; and (4) continuously for more than 3 days. Of note, a post hoc power calculation was undertaken, as a convenience sample was being used. In the unmatched cohort, assuming type I error of 0.05, as well as the rate of primary outcome and study group size as reported in the results, the analysis had 98% power, adequate to undertake and report on the analyses of interest. Data were analyzed using StataSE version 17.0 (StataCorp Pty Ltd., College Station, Texas). Any two-tailed p value less than 0.05 was considered significant. No correction was made for multiple comparisons.

Results

Study population

There were 11,873 patients with microbiologically confirmed, or suspected, COVID-19 admitted to 244 hospitals between February 1, 2020, and October 31, 2021. After excluding 3244 patients because of lack of microbiological confirmation of SARS-CoV-2 infection and 1844 patients who were transferred from non-collaborating centers, or transferred out while still on mechanical ventilation, 4616 patients who were on IMV were included in the primary analysis (Fig. 1). Figure 2 shows enrolment rate of those mechanically ventilated patients by date of ICU admission. A matched cohort based on propensity scores was generated, with 210 patients who underwent NMBA treatment and 210 patients as control group. Overall, baseline characteristics were balanced in the propensity score-matched cohort. The mean age was 60.3 years (standard deviation [SD] 13.2 years) (Table 1) and 296 (70.5%) were male. The mean acute physiology and chronic health evaluation (APACHE) II score was 19.5 (SD 11.6; N = 117). In the NMBA treatment and control group, respiratory system compliance was 32.5 mL/cmH2O (SD 12.6) and 33.9 (SD 12.2), respectively, and driving pressure was 22.7 cmH2O (SD 7.5) and 22.4 (SD 8.6). The most common comorbidities among patients in the PS-matched cohort were hypertension (239, 56.9%), obesity (172, 41.1%), and diabetes (125, 30.0%).

Fig. 1

Flow of patient enrolment by the censor date of October 31, 2021. MV, mechanical ventilation; NMBA, neuromuscular blocking agents

Fig. 2

Number of patients per week of intensive care unit (ICU) admission is depicted

Table 1

Demographic and clinical characteristics upon intensive care unit admission of patients who received or did not receive NMBA treatment

	Unmatched cohort(N = 1953)			Propensity score-matched cohort(N = 420)
Parameter	Control (N = 1711)		NMBA treatment(N = 242)	Control (N = 210)	NMBA treatment(N = 210)
Age (years) mean (SD)	61.8 (12.3)		58.9 (12.2)	61.2 (14.2)	59.4 (12.1)
Age (years) n (%)
< 50	268 (15.7%)		50 (20.7%)	42 (20.0%)	40 (19.0%)
50–59	366 (21.4%)		66 (27.3%)	45 (21.4%)	56 (26.7%)
60–69	578 (33.8%)		80 (33.1%)	57 (27.1%)	73 (34.8%)
70–79	448 (26.2%)		43 (17.8%)	59 (28.1%)	39 (18.6%)
≥ 80	51 (3.0%)		3 (1.2%)	7 (3.3%)	2 (1.0%)
Male n (%)	1,196 (70.0%)		175 (72.3%)	144 (68.6%)	152 (72.4%)
Duration of symptom onset to hospital admission (days) median (IQR)	6.0 (4.0–9.0)		7.0 (4.0–9.0)	6.0 (4.0–9.0)	7.0 (3.0–9.0)
Duration of symptom onset to ICU admission (days) median (IQR)	11.0 (8.0–15.0)		10.0 (7.0–13.0)	10.0 (8.0–15.0)	10.0 (7.0–13.0)
Duration of symptom onset to first use of mechanical ventilation (days) median (IQR)	11.0 (8.0–15.0)		10.0 (7.0–13.0)	10.0 (8.0–15.0)	10.0 (7.0–13.0)
Ethnicity
Aboriginal	5 (0.3%)		0 (0.0%)	3 (1.4%)	0 (0%)
Arab	59 (3.4%)		6 (2.5%)	8 (3.8%)	4 (1.9%)
Black	53 (3.1%)		21 (8.7%)	11 (5.2%)	20 (9.5%)
East Asian	18 (1.1%)		5 (2.1%)	7 (3.3%)	5 (2.4%)
Latin American	108 (6.3%)		31 (12.8%)	25 (11.9%)	27 (12.9%)
South Asian	75 (4.4%)		9 (3.7%)	8 (3.8%)	9 (4.3%)
West Asian	5 (0.3%)		1 (0.4%)	1 (0.5%)	1 (0.5%)
White	163 (9.5%)		54 (22.3%)	18 (8.6%)	48 (22.9%)
Mixed	11 (0.6%)		8 (3.3%)	4 (1.9%)	5 (2.4%)
Other	22 (1.3%)		10 (4.1%)	1 (0.5%)	10 (4.8%)
Missing	1192 (69.7%)		97 (40.1%)	124 (59.0%)	81 (38.6%)
Continent
Africa n (%)	19 (1.1%)		18 (7.4%)	14 (6.7%)	14 (6.7%)
Asia n (%)	148 (8.6%)		19 (7.9%)	12 (5.7%)	18 (8.6%)
Europe n (%)	1237 (72.3%)		135 (55.8%)	121 (57.6%)	114 (54.3%)
North America n (%)	175 (10.2%)		43 (17.8%)	42 (20.0%)	43 (20.5%)
Oceania n (%)	30 (1.8%)		7 (2.9%)	3 (1.4%)	5 (2.4%)
South/Central America n (%)	102 (6.0%)		20 (8.3%)	18 (8.6%)	16 (7.6%)
Healthcare or laboratory worker n (%)	42 (2.6%)		10 (4.5%)	8 (4.0%)	9 (4.7%)
Comorbidities
Smoking n (%)	525 (31.0%)		76 (32.1%)	62 (29.5%)	65 (31.4%)
Obesity* n (%)	622 (36.7%)		97 (40.8%)	88 (41.9%)	84 (40.2%)
Hypertension n (%)	916 (53.9%)		125 (52.7%)	123 (58.6%)	116 (55.2%)
Chronic cardiac disease n (%)	227 (13.4%)		21 (8.9%)	17 (8.1%)	19 (9.0%)
Diabetes n (%)	502 (29.8%)		65 (27.9%)	65 (31.0%)	60 (29.1%)
Malignant neoplasm n (%)	66 (3.9%)		8 (3.4%)	9 (4.3%)	8 (3.8%)
Chronic pulmonary disease n (%)	171 (10.1%)		30 (12.6%)	32 (15.2%)	27 (12.9%)
Severe liver disease n (%)	30 (1.8%)		6 (2.5%)	4 (1.9%)	6 (2.9%)
Chronic kidney disease n (%)	152 (9.0%)		12 (5.0%)	12 (5.7%)	12 (5.7%)
BMI mean (SD)	30.2 (6.4)		30.9 (6.8)	30.3 (6.2)	30.6 (6.6)
Severity of illness
APACHE II mean (SD)	18.5 (10.5)		17.8 (11.0)	21.2 (12.3)	18.3 (11.0)
SOFA mean (SD)	6.0 (3.9)		5.3 (3.5)	6.1 (4.7)	5.4 (3.6)
Laboratory results upon ICU admission
WBC count (10*3/µL) median (IQR)		9.6 (6.1–13.0)	8.8 (7.1–11.7)	10.0 (6.4–14.1)	8.7 (7.1–11.4)
Lymphocyte count (10*3/µL) median (IQR)		0.7 (0.5–1.1)	0.8 (0.5–1.0)	0.8 (0.5–1.2)	0.8 (0.5–1.0)
Neutrophils/lymphocyte ratio median (IQR)		9.9 (5.8–17.9)	10.6 (6.2–15.8)	9.8 (5.5–17.8)	10.4 (6.0–15.2)
Temperature (°C) mean (SD)		37.3 (1.1)	37.4 (1.1)	37.2 (1.0)	37.4 (1.0)
Creatinine (mg/dL) median (IQR)		0.9 (0.7–1.2)	0.8 (0.7–1.1)	1.0 (0.7–1.4)	0.8 (0.7–1.1)
C-reactive protein level (mg/dL) median (IQR)		104.8 (30.0–192.0)	86.3 (22.6–185.4)	126.3 (40.9–228.6)	82.8 (20.8–172.1)
D-dimer (mcg/mL) median (IQR)		0.9 (0.5–2.2)	1.0 (0.5–2.3)	1.0 (0.6–2.9)	1.1 (0.5–2.3)
Lactate (mmol/L) median (IQR)		1.5 (1.1–2.1)	1.6 (1.1–2.1)	1.6 (1.1–2.0)	1.5 (1.1–2.1)
Ferritin (ng/mL) median (IQR)		2.9 (1.4–4.8)	2.8 (1.7–5.6)	3.4 (1.7–5.9)	3.2 (1.7–5.6)
IL-6 (ng/L) median (IQR)		124.7 (51.2–268.0)	79.4 (28.9–108.2)	83.0 (47.8–173.3)	75.9 (26.3–100.1)

Demographic and clinical characteristics upon intensive care unit admission of patients who received or did not receive neuromuscular blocking agents (NMBA). NMBA treatment was defined as at least 2 days of continuous use of NMBAs or up to 3 days, within 48 h from commencement of IMV

IMV, invasive mechanical ventilation; BMI, body mass index; APACHE II, acute physiology and chronic health evaluation; SOFA, sequential organ failure assessment; WBC, white blood cells; IL, interleukin

Flow of patient enrolment by the censor date of October 31, 2021. MV, mechanical ventilation; NMBA, neuromuscular blocking agents Number of patients per week of intensive care unit (ICU) admission is depicted Demographic and clinical characteristics upon intensive care unit admission of patients who received or did not receive NMBA treatment Demographic and clinical characteristics upon intensive care unit admission of patients who received or did not receive neuromuscular blocking agents (NMBA). NMBA treatment was defined as at least 2 days of continuous use of NMBAs or up to 3 days, within 48 h from commencement of IMV IMV, invasive mechanical ventilation; BMI, body mass index; APACHE II, acute physiology and chronic health evaluation; SOFA, sequential organ failure assessment; WBC, white blood cells; IL, interleukin

NMBA therapy

In the full unmatched cohort, 180 (74.4%) patients received NMBAs for 48 h and 62 (25.6%) for 3 days, while in the control group, 1151 (67.3%) patients received NMBAs only on the day IMV started, and 560 (32.7%) never received NMBAs. In the PS-matched cohort, NMBA treatment was noted in 210 patients. Early use of NMBAs for 48 h was reported in 160 (76.2%) of the patients, while 50 (23.8%) patients received NMBAs for 3 days. In the matched control group, patients never received NMBAs, not even upon the day IMV started. NMBA was provided on average 1 day after ICU admission (N = 207; IQR 0–2 days). The median length from commencement of IMV to initiation of NMBA therapy was 0 days (IQR 0–0 days).

ICU management

In the PS-matched cohort, as summarized in Table 2, PaO2/FiO2 was 88.6 (SD 29.7) vs 86.0 (SD 30.7), in NMBA treatment and control group, respectively. Upon IMV commencement, patients who received NMBA treatment presented PaCO2 of 51.0 mmHg (SD 13.7) vs 48.0 mmHg (SD 15.5) in those who did not. Positive end-expiratory pressure in those undergoing NMBA treatment or not was 12.8 cmH2O (SD 3.3) vs 11.9 cmH2O (SD 3.1), respectively. As for adjunctive therapies, extracorporeal membrane oxygenation, renal replacement therapy, and recruitment maneuvers were provided more frequently to patients who received NMBA treatment (Table 3). Pneumothorax occurred in 21 (10.4%) and 19 (9.6%) of the patients undergoing NMBA treatment or not, respectively.

Table 2

Gas exchange and level of ventilatory support within 24 h of commencement of IMV in patients who received or did not receive neuromuscular blocking agents (NMBAs)

	Unmatched cohort(N = 1953)		Propensity score-matched cohort (N = 420)
Parameter	Control(N = 1711)	NMBA treatment(N = 242)	Control(N = 210)	NMBA treatment(N = 210)
pH mean (SD)	7.4 (0.1)	7.3 (0.1)	7.3 (0.1)	7.3 (0.1)
FiO₂ (mmHg) mean (SD)	76.1 (21.9)	77.3 (21.9)	81.0 (20.8)	77.5 (22.0)
PaO₂/FiO₂ (mmHg) mean (SD)	98.1 (31.1)	88.5 (29.3)	86.0 (30.7)	88.6 (29.7)
PaCO₂ (mmHg) mean (SD)	48.7 (13.5)	50.9 (13.9)	48.0 (15.5)	51.0 (13.7)
Tidal volume (ml/PBW) mean (SD)	7.1 (1.4)	6.9 (1.4)	7.4 (1.6)	6.8 (1.4)
Respiratory system compliance (mL/cmH₂O) mean (SD)	33.8 (11.9)	32.9 (12.7)	33.9 (12.2)	32.5 (12.6)
Plateau pressure (cmH₂O) mean (SD)	25.4 (5.7)	26.1 (5.1)	25.0 (5.9)	26.2 (5.0)
Driving pressure (cmH₂O) mean (SD)	22.8 (7.4)	22.1 (7.6)	22.4 (8.6)	22.7 (7.5)
Respiratory rate (breaths/min) mean (SD)	23.8 (7.0)	24.5 (7.1)	24.7 (7.4)	24.8 (7.3)
PEEP level (cmH₂O) mean (SD)	12.0 (3.0)	12.8 (3.3)	11.9 (3.1)	12.8 (3.3)
Heart rate (beats/min) mean (SD)	89.1 (27.4)	93.9 (29.0)	90.9 (30.5)	95.5 (28.4)
Mean arterial pressure (mmHg) mean (SD)	80.9 (19.8)	77.3 (21.6)	80.2 (20.2)	76.7 (21.7)

NMBA treatment was defined as at least 2 days of continuous use of NMBAs or up to 3 days, within 48 h from commencement of IMV

IMV, invasive mechanical ventilation; FiO2, inspiratory fraction of oxygen; PaO2/FiO2, ratio between arterial partial pressure of oxygen and inspiratory fraction of oxygen; PaCO2, arterial partial pressure of carbon dioxide; PBW, predicted body weight; PEEP, positive end-expiratory pressure

Table 3

Intensive care unit clinical management in patients who received or did not receive neuromuscular blocking agents (NMBAs)

	Unmatched cohort(N = 1953)		Propensity score-matched cohort(N = 420)
Parameter	Control(N = 1711)	NMBA treatment(N = 242)	Control(N = 210)	NMBA treatment(N = 210)
Vasopressor/Inotropic support n (%)	1556 (90.9%)	197 (81.4%)	180 (85.7%)	175 (83.3%)
Antibiotics n (%)	1629 (97.4%)	219 (96.5%)	194 (94.2%)	192 (96.5%)
Any antiviral n (%)	1399 (82.8%)	160 (70.5%)	154 (73.7%)	142 (71.7%)
Remdesivir n (%)	270 (16.1%)	38 (16.2%)	39 (18.8%)	34 (16.6%)
Use of corticosteroids (%)	364 (21.3%)	48 (19.8%)	48 (22.9%)	40 (19.0%)
Continuous renal replacement therapy n (%)	16 (0.9%)	11 (4.5%)	1 (0.5%)	10 (4.8%)
Vasoactive drugs n (%)	1483 (89.6%)	185 (81.1%)	178 (86.8%)	163 (81.5%)
Cardiac-assist devices n (%)	1 (0.1%)	4 (1.7%)	0 (0.0%)	3 (1.4%)
ECMO n (%)	132 (7.7%)	36 (14.9%)	14 (6.7%)	35 (16.7%)
Prone positioning n (%)	148 (8.6%)	52 (21.5%)	22 (10.5%)	46 (21.9%)
Use of iNO n (%)	2 (0.1%)	4 (1.7%)	1 (0.5%)	4 (1.9%)
Use of recruitment maneuvers n (%)	11 (0.6%)	20 (8.3%)	3 (1.4%)	19 (9.0%)
Pneumothorax n (%)	208 (12.4%)	22 (9.6%)	19 (9.6%)	21 (10.4%)
Duration of mechanical ventilation (days) median (IQR)	2 (2–4)	4 (3–13)	2 (2–10)	4 (3–13)
Duration of ICU stay (days) median (IQR)*	19 (10–34)	16 (8–27)	16 (8–29)	16 (8–27)
Time from ICU admission to death (days) median (IQR)	12 (6–23)	11 (5–18)	8 (2–22)	11 (4–19)
Time from commencement of MV to death (days) median (IQR)	9 (4–20)	10 (2–16)	5 (1–17)	9 (2–18)

NMBA treatment was defined as at least 2 days of continuous use of NMBAs or up to 3 days, within 48 h from commencement of IMV

IMV, invasive mechanical ventilation; ECMO, extracorporeal membrane oxygenation; iNO, inhaled nitric oxide

Gas exchange and level of ventilatory support within 24 h of commencement of IMV in patients who received or did not receive neuromuscular blocking agents (NMBAs) NMBA treatment was defined as at least 2 days of continuous use of NMBAs or up to 3 days, within 48 h from commencement of IMV IMV, invasive mechanical ventilation; FiO2, inspiratory fraction of oxygen; PaO2/FiO2, ratio between arterial partial pressure of oxygen and inspiratory fraction of oxygen; PaCO2, arterial partial pressure of carbon dioxide; PBW, predicted body weight; PEEP, positive end-expiratory pressure Intensive care unit clinical management in patients who received or did not receive neuromuscular blocking agents (NMBAs) NMBA treatment was defined as at least 2 days of continuous use of NMBAs or up to 3 days, within 48 h from commencement of IMV IMV, invasive mechanical ventilation; ECMO, extracorporeal membrane oxygenation; iNO, inhaled nitric oxide

Primary outcome: 90-day in-hospital mortality

The Kaplan–Meier (Fig. 3A) (log rank test p < 0.001) and the Cox regression model (unadjusted HR 1.78; 95% CI 1.38, 2.30; p < 0.001) confirmed that NMBA treatment was associated with increased mortality risk. The PS-matched cohort analysis comprised 210 patients in the NMBA treatment group vs 210 controls (using replacements). The summaries of balance for unmatched and matched critical parameters are depicted in Fig. 4. Kaplan–Meier curves (Fig. 3B) (log rank p = 0.537) showed no effect of NMBA treatment on mortality, which was also corroborated by the Cox regression model (unadjusted HR = 1.12, 95% CI 0.79, 1.59, p = 0.534). The lack of association with 90-day mortality was consistent after adjusting for smoking habit and critical therapeutic covariates (adjusted HR 1.07; 95% CI 0.72, 1.61, p = 0.729) (Table 4). In subgroup analyses, PaO2/FiO2 and the concomitant use of corticosteroids did not alter negative NMBA association with mortality.

Fig. 3

Fig. 4

Standard mean difference of key parameters before and after propensity score matching. *Compared with North America

Table 4

90-day mortality in patients with coronavirus disease 2019 identified by Cox proportional hazards regression model, considering neuromuscular blocking agents (NMBAs) treatment as at least 2 days of continuous use of NMBAs and up to 3 days, within 48 h from commencement of IMV

	Propensity score-matched cohort^a(N = 420)
Variable	Adjusted hazard ratio for 90-day mortality^	95% CI	p value
NMBA treatment	1.07	0.72, 1.61	0.729
NMBA treatment and corticosteroids	1.09	0.39, 3.05	0.872
NMBA treatment per PaO₂/FiO₂ Strata within 24 h from Commencement of IMV
< 100	0.70	0.28, 1.74	0.445
100–149	(Reference)	–	–

aPost-propensity score matching, also adjusting for smoking, use of antibiotics, antivirals, corticosteroids, renal replacement therapy, ECMO, and prone positioning. N = 420, due to equally sized cohorts post-propensity score matching

IMV, invasive mechanical ventilation; NMBA, neuromuscular blocking agents; PaO2/FiO2, ratio between arterial partial pressure of oxygen and inspiratory fraction of oxygen

Unadjusted Kaplan–Meier event curves for in-hospital mortality from commencment of invasive mechanical ventilation to 90 days. A Before propensity score matching, 90-day ICU Kaplan-Meier curves differed between patients undergoing up to three-day NMBA therapy, within 48 hours from commencement of IMV, in comparison with those who did not (N = 1953, p < 0.001). B After propensity score matching, no difference in survival between patients undergoing NMBA therapy in comparison with those who did not was found (N = 420, due to equally sized cohorts post propensity score matching, P = 0.537). NMBA neuromuscular blocking agent, ICU intensive care unit Standard mean difference of key parameters before and after propensity score matching. *Compared with North America 90-day mortality in patients with coronavirus disease 2019 identified by Cox proportional hazards regression model, considering neuromuscular blocking agents (NMBAs) treatment as at least 2 days of continuous use of NMBAs and up to 3 days, within 48 h from commencement of IMV aPost-propensity score matching, also adjusting for smoking, use of antibiotics, antivirals, corticosteroids, renal replacement therapy, ECMO, and prone positioning. N = 420, due to equally sized cohorts post-propensity score matching IMV, invasive mechanical ventilation; NMBA, neuromuscular blocking agents; PaO2/FiO2, ratio between arterial partial pressure of oxygen and inspiratory fraction of oxygen Sensitivity analyses confirmed the lack of association between NMBA treatment and 90-day mortality, when inverse probability weighting analysis was applied (adjusted HR 1.28; 95% CI 0.89, 1.84; p = 0.187) and in the analysis of the cohort of patients with clinically suspected and microbiologically confirmed COVID-19 (adjusted HR 1.44; 95% CI 0.99, 2.09, p = 0.055) (Table 5). In addition, when analyses were restricted to only 2 days (Table 6) or 3 days of NMBA treatment (Table 7), similar insignificant effect on 90-day mortality was found. Conversely, sensitivity analysis exploring continuous NMBA treatment beyond 3 days (Table 8) showed increased risk of 90-day mortality (adjusted HR 1.73, 95% CI 1.22, 2.37, p = 0.001). In this context, the reported median duration of NMBA treatment was 6 days (IQR 5–10).

Table 5

NMBA treatment versus controls in patients with clinically suspected and microbiologically confirmed COVID-19 on 90-day in-hospital mortality

	Propensity score-matched cohort(N = 792)
90-day mortality from ICU admission	Control(N = 396)	NMBA treatment(N = 396)	Total(N = 792)
Survived	334 (84.3%)	314 (79.3%)	648 (81.8%)
Died	62 (15.7%)	82 (20.7%)	144 (18.2%)
Total	396	396	792

Prior to propensity score matching, neuromuscular blocking agent (NMBA) treatment, defined as at least 2 days of continuous use of NMBAs or up to 3 days, within 48 h from commencement of invasive mechanical ventilation, was associated with mortality (unadjusted Cox regression; HR 1.33, 95% CI 1.06, 1.66, p = 0.015). After propensity score matching, 396 patients who received NMBA treatment were matched with 396 controls (using replacement). Using the propensity score-matched cohort and adjusting for covariates listed in Table 4, NMBA therapy was not associated with 90-day mortality (adjusted HR 1.44, 95% CI 0.99, 2.09, p = 0.055)

Table 6

Impact of NMBA treatment (defined by 2 days of continuous use of NMBAs within 48 h from commencement of mechanical ventilation) vs controls on 90-day in-hospital mortality

	Propensity score-matched cohort(N = 320)
90-day mortality from ICU admission	Control(N = 160)	NMBA treatment(N = 160)	Total(N = 320)
Survived	117 (73.1%)	112 (70.0%)	229 (72.6%)
Died	43 (26.9%)	48 (30.0%)	91 (28.4%)
Total	160	160	320

Prior to propensity score matching, neuromuscular blocking agent (NMBA) treatment, defined as 2 days of continuous use of NMBAs, within 48 h from commencement of invasive mechanical ventilation, was associated with 90-day mortality (unadjusted Cox regression; HR 1.65, 95% CI 1.22, 2.23, p = 0.001). After propensity score matching, 160 patients who received NMBA treatment were matched with 160 controls (using replacement). Using the propensity score-matched cohort and adjusting for covariates as per Table 4, NMBA therapy was not associated with 90-day mortality (adjusted HR 1.15, 95% CI 0.74, 1.78, p = 0.524)

Table 7

Prior to propensity score matching, neuromuscular blocking agent (NMBA) treatment, defined as 3 days of continuous use of NMBAs, within 48 h from commencement of invasive mechanical ventilation, was associated with 90-day mortality (unadjusted Cox regression; HR 2.13, 95% CI 1.40, 3.24, P < 0.001). After propensity-score matching, 50 patients who received NMBA treatment were matched with 50 controls (using replacement). Using the propensity score-matched cohort (and adjusting for covariates as per Table 4, NMBA therapy was not associated with 90-day mortality (adjusted HR 1.56 95% CI 0.55, 4.32, P = 0.392)

	Propensity score-matched cohort(N = 100)
90-day mortality from ICU admission	Control(N = 50)	NMBA treatment(N = 50)	Total(N = 100)
Survived	38 (76%)	33 (66%)	71 (71%)
Died	12 (24%)	17 (34%)	29 (29%)
Total	50	50	100

Table 8

NMBA treatment (defined by > 3 days within 48 h from commencement of mechanical ventilation) vs controls on 90-day in-hospital mortality

	Propensity score-matched cohort(N = 324)
90-day mortality from ICU admission	Control(N = 162)	NMBA treatment(N = 162)	Total(N = 362)
Survived	130 (80.3%)	81 (50.0%)	211 (65.1%)
Died	32 (19.8%)	81 (50.0%)	113 (34.9%)
Total	162	162	324

Prior to propensity score matching, neuromuscular blocking agent (NMBA) treatment, defined as more than 3 days of continuous use of NMBAs, within 48 h from commencement of invasive mechanical ventilation, was associated with 90-day mortality (unadjusted Cox regression; HR 2.57, 95% CI 2.02, 2.71, p < 0.001). After propensity score matching, 372 patients who received NMBA treatment were matched with 372 controls (using replacement). Using the propensity score-matched cohort and adjusting for covariates as per Table 4, NMBA therapy was associated with 90-day mortality (adjusted HR 1.73, 95% CI 1.27, 2.37, p = 0.001)

NMBA treatment versus controls in patients with clinically suspected and microbiologically confirmed COVID-19 on 90-day in-hospital mortality Prior to propensity score matching, neuromuscular blocking agent (NMBA) treatment, defined as at least 2 days of continuous use of NMBAs or up to 3 days, within 48 h from commencement of invasive mechanical ventilation, was associated with mortality (unadjusted Cox regression; HR 1.33, 95% CI 1.06, 1.66, p = 0.015). After propensity score matching, 396 patients who received NMBA treatment were matched with 396 controls (using replacement). Using the propensity score-matched cohort and adjusting for covariates listed in Table 4, NMBA therapy was not associated with 90-day mortality (adjusted HR 1.44, 95% CI 0.99, 2.09, p = 0.055) Impact of NMBA treatment (defined by 2 days of continuous use of NMBAs within 48 h from commencement of mechanical ventilation) vs controls on 90-day in-hospital mortality Prior to propensity score matching, neuromuscular blocking agent (NMBA) treatment, defined as 2 days of continuous use of NMBAs, within 48 h from commencement of invasive mechanical ventilation, was associated with 90-day mortality (unadjusted Cox regression; HR 1.65, 95% CI 1.22, 2.23, p = 0.001). After propensity score matching, 160 patients who received NMBA treatment were matched with 160 controls (using replacement). Using the propensity score-matched cohort and adjusting for covariates as per Table 4, NMBA therapy was not associated with 90-day mortality (adjusted HR 1.15, 95% CI 0.74, 1.78, p = 0.524) Prior to propensity score matching, neuromuscular blocking agent (NMBA) treatment, defined as 3 days of continuous use of NMBAs, within 48 h from commencement of invasive mechanical ventilation, was associated with 90-day mortality (unadjusted Cox regression; HR 2.13, 95% CI 1.40, 3.24, P < 0.001). After propensity-score matching, 50 patients who received NMBA treatment were matched with 50 controls (using replacement). Using the propensity score-matched cohort (and adjusting for covariates as per Table 4, NMBA therapy was not associated with 90-day mortality (adjusted HR 1.56 95% CI 0.55, 4.32, P = 0.392) NMBA treatment (defined by > 3 days within 48 h from commencement of mechanical ventilation) vs controls on 90-day in-hospital mortality Prior to propensity score matching, neuromuscular blocking agent (NMBA) treatment, defined as more than 3 days of continuous use of NMBAs, within 48 h from commencement of invasive mechanical ventilation, was associated with 90-day mortality (unadjusted Cox regression; HR 2.57, 95% CI 2.02, 2.71, p < 0.001). After propensity score matching, 372 patients who received NMBA treatment were matched with 372 controls (using replacement). Using the propensity score-matched cohort and adjusting for covariates as per Table 4, NMBA therapy was associated with 90-day mortality (adjusted HR 1.73, 95% CI 1.27, 2.37, p = 0.001)

Secondary outcome: ventilator-free days

In the PS-matched cohort at 28 days after commencement of IMV, VFD were 16 (IQR 0–25) in patients undergoing NMBA treatment and 25 (IQR 7–26) in the control group, and the sub-hazard ratio is 0.82 (95% CI 0.67, 1.00, p = 0.055). However, at 90 days after commencement of IMV, VFD were 77 (IQR 0–87) in patients undergoing NMBA treatment and 87 (IQR 0–88) in the control group; HR 0.86 (95% CI 0.69, 1.07; p = 0.177).

Discussion

To the best of our knowledge, this is the largest, international observational study of patients with COVID-19 requiring mechanical ventilation to assess the impact of short-course NMBA treatment, commenced early during IMV, on 90-day in-hospital mortality. We found that NMBA use was common, specifically at European sites, and frequently applied in patients who presented hypercapnic and required higher levels of PEEP upon commencement of IMV. PS-matching analysis confirmed that early NMBA treatment did not result in lower mortality, while post hoc sensitivity analysis found increased mortality risk when NMBAs use was extended beyond 3 days. In addition, at 28 and 90 days, there were no between-group differences in days free of mechanical ventilation. NMBAs are commonly used in critically ill patients who require IMV, but this practice has considerably changed throughout the years. In the 1980s, a survey from Great Britain reported NMBA administered in 90% of the patients on IMV [13], while in 2005 data from an international large cohort of mechanically ventilated patients reported NMBAs use merely in 13% of the patients [31]. The most recent clinical practice guidelines by the Society of Critical Care Medicine specified various indications for the use of NMBA in critically ill adult patients [32], among those patients with ARDS and PaO2/FiO2 < 150. In line with the original findings by Gainnier et al. demonstrating consistent oxygenation improvement in ARDS patients undergoing a 48-h course of NMBA [33], the confirmatory ACURASYS trial found that early administration of continuous cisatracurium for 48 h improved 90-day survival [15] and reduced risk of barotrauma. However, subsequent results from the Reevaluation of Systemic Early Neuromuscular Blockade (ROSE) trial failed to show reductions in mortality [16]. Meta-analyses emphasized potential limitations of those previous trials, i.e., heterogeneity in the use of sedation and prone positioning, selection bias, and crossover between treatment groups. Thus, to date, available evidence supports the use of NMBAs to reduce risks of barotrauma and to improve oxygenation [34-36], but without clear advantage in survival rate. ARDS caused by COVID-19 has broad similarities with historic ARDS caused by other etiologies [18, 37–39], although pulmonary blood flow derangement and resulting pulmonary shunt seem to play a primary role in COVID-19 ARDS [40]. As a result, various interventions previously employed for ARDS, such as prone position [41], ECMO [42], and NMBAs [20], were extensively applied in the COVID-19 population. In the current study, we describe COVID-19 patients who required mechanical ventilation and who presented with moderate-to-severe hypoxemia. Various small case reports have demonstrated substantial ventilatory asynchrony in these patients [43-45] and adverse sequelae, such as pneumothorax or pneumomediastinum [46-48]. Patients receiving NMBA also frequently required adjunctive therapies for ARDS, suggesting that the severity of disease was a main driver in the use of these drugs. The COVID-19 population subset investigated in our analyses provides further value to our study; indeed, we identified patients with moderate-to-severe ARDS who received, early, a short course of NMBAs. This is in line with protocols applied in previous large randomized trials [15, 16]. Furthermore, in comparison with the ACURASYS and ROSE trials, we found that the COVID-19 population presented similar baseline impairment in respiratory function, and as in the ROSE trial, low tidal volume and high PEEP were applied and resulted in comparable airway plateau pressure. However, prone position was used much more frequently in the COVID-19 population and the improvements associated with its use [49, 50] might have offset any additional benefit related to NMBAs. Courcelle and collaborators specifically investigated the effects of NMBAs in COVID-19 patients enrolled in French/Belgian ICUs. After PS matching, they did not find a significant difference in 28-day mortality [20]. Similar to these preliminary findings, our international, larger multicenter investigation also found no improvement in 90-day mortality in patients receiving a short course of NMBAs. Moreover, Courcelle found a median duration of NMBA use of 5 days; conversely, our study appraised only patients who received continuous NMBAs up to 3 days, and interestingly, we found higher hazard ratio of 90-day mortality when the use of NMBAs was extended more than 3 days. This finding provides further evidence on the risks associated with NMBAs in COVID-19 patients. Relative to Courcelles PS-matched cohort, our matched population was similar in age, gender proportion, and BMI and initial ventilatory settings. Yet, in the French/Belgian study, prone positioning was applied in over 90% and ECMO in 15% of the patients, in line with French expert consensus guidelines recommendations [51] and evidence in favor of the aforementioned interventions in COVID-19 patients [42, 50, 52]. Conversely, our dataset encompassed a global population of critically ill COVID-19 patients, including ICU centers both with and without access to modalities such as prone position and ECMO, which were applied in up to 69.6% and 16.7%, respectively. In the early waves of the pandemic, centers with the highest patient numbers acknowledged that treatments, such as prone positioning, could sometimes not be accomplished, due to staffing limitations and patient safety concerns [11]. Similarly, NMBA use at centers with overwhelming ICU surge may also be greater than in less resource-constrained environments. Non-depolarizing NMBAs inhibit the acetylcholine (Ach) receptor on the motor endplate and are available as aminosteroid or benzylisoquinolinium compound, the latter being the first choice for ARDS patients [53]. Renal and hepatic disease can drastically prolong the clearance of aminosteroid NMBAs, and in these conditions benzylisoquinolinium agents are preferred, since they undergo spontaneous degradation via Hofmann elimination. The NMBA class used was not recorded in our dataset, but severe liver and chronic kidney diseases were present in only 2.9 and 5.7% of the patients treated with NMBAs, respectively. Of note, COVID-19 can cause a broad variety of neurological symptoms and sequelae [54] and has been associated with the development of anti-Ach receptors antibodies [55] and myasthenia gravis [56]. Hence, comprehensive research is needed in this field to elucidate whether underlying neurological mechanisms associated with COVID-19 lead to an increased risk of death when NMBA are administered, and caution should be applied.

Strengths and limitations

To date, this is the first international report of a large group of mechanically ventilated COVID-19 patients with severe disease to investigate the effects of NMBA. Employing comprehensive PS matching analysis, we demonstrated no improvement in mortality with NMBA use. These findings were consistently corroborated in sensitivity analysis applying inverse probability of treatment weighting. In addition, we provided inferences not limited by clinical practice specific to single-country studies. Nonetheless, certain limitations must be highlighted. First, although we conducted a comprehensive comparative PS-matched analysis that resulted in significant homogeneity in the evaluated sub-cohorts, the observational nature of our study and risks of drawing causal inferences should be highlighted. While immortal time bias could be considered as a potential limitation of this study design, given the short duration between cohort entry and exposure to NMBA therapy, the magnitude of the bias is expected to be limited [57]. In addition, similar times from ICU admission to death were found in both groups. Yet, the risk of immortal time bias should also be considered for several interventions potentially associated with survival—such as prone positioning, ECMO, and corticosteroids—since only patients who survived long enough to receive these interventions were analyzed. Second, the analyzed dataset did not provide any information on the type of NMBA, doses, or adequacy of the block achieved; hence, we were unable to extrapolate the appropriateness of their clinical use. In addition, the time of commencement of NMBA treatment was not recorded; thus, although we included patients who received NMBAs up to 3 days, and we explored different treatment regimens in sensitivity analyses, potential discrepancy in the clinically indicated 2-day full course of NMBA treatment [15, 16] should be considered when interpreting the results. Third, a proportion of the studied population was admitted to the ICU early during the pandemic. Consequently, potential logistical limitations related to managing critically ill patients treated in newly developed and understaffed ICUs, due to shortages in ICU beds or healthcare providers, must be considered. Fourth, as shown in Fig. 4, residual discrepancy for Asia likely persisted post-matching. Further assessment on the potential reasons for this divergence suggested possible increased mortality in control patients from Asia. This could be related to the specific regional differences in ventilatory practice or application of adjunctive therapies, which should be further explored in future studies. Irrespective, potential random effect related to heterogenous practice among collaborating hospitals should be considered while interpreting our results. Fifth, the voluntary nature of site participation in the study must be emphasized, especially during a pandemic, as data may be skewed toward centers with enough resources to enter data. Lastly, as our observational study acquired data from routine clinical records, missing data could have biased our estimates.

Conclusions

Our results derived by PS-matching analysis suggest that among patients with COVID-19 and moderate-to-severe ARDS, early administration of a short course of NMBAs did not result in improved 90-day in-hospital mortality. In addition, NMBA treatment did not impact ventilator-free days. Thus, the use of NMBAs should be cautiously assessed in this population, pending further studies that could elucidate specific indications for NMBAs in COVID-19. Additional file 1. Appendix.

50 in total

1. The Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) statement: guidelines for reporting observational studies.

Authors: Erik von Elm; Douglas G Altman; Matthias Egger; Stuart J Pocock; Peter C Gøtzsche; Jan P Vandenbroucke
Journal: Lancet Date: 2007-10-20 Impact factor: 79.321

2. Effect of Hydrocortisone on Mortality and Organ Support in Patients With Severe COVID-19: The REMAP-CAP COVID-19 Corticosteroid Domain Randomized Clinical Trial.

Authors: Derek C Angus; Lennie Derde; Farah Al-Beidh; Djillali Annane; Yaseen Arabi; Abigail Beane; Wilma van Bentum-Puijk; Lindsay Berry; Zahra Bhimani; Marc Bonten; Charlotte Bradbury; Frank Brunkhorst; Meredith Buxton; Adrian Buzgau; Allen C Cheng; Menno de Jong; Michelle Detry; Lise Estcourt; Mark Fitzgerald; Herman Goossens; Cameron Green; Rashan Haniffa; Alisa M Higgins; Christopher Horvat; Sebastiaan J Hullegie; Peter Kruger; Francois Lamontagne; Patrick R Lawler; Kelsey Linstrum; Edward Litton; Elizabeth Lorenzi; John Marshall; Daniel McAuley; Anna McGlothin; Shay McGuinness; Bryan McVerry; Stephanie Montgomery; Paul Mouncey; Srinivas Murthy; Alistair Nichol; Rachael Parke; Jane Parker; Kathryn Rowan; Ashish Sanil; Marlene Santos; Christina Saunders; Christopher Seymour; Anne Turner; Frank van de Veerdonk; Balasubramanian Venkatesh; Ryan Zarychanski; Scott Berry; Roger J Lewis; Colin McArthur; Steven A Webb; Anthony C Gordon; Farah Al-Beidh; Derek Angus; Djillali Annane; Yaseen Arabi; Wilma van Bentum-Puijk; Scott Berry; Abigail Beane; Zahra Bhimani; Marc Bonten; Charlotte Bradbury; Frank Brunkhorst; Meredith Buxton; Allen Cheng; Menno De Jong; Lennie Derde; Lise Estcourt; Herman Goossens; Anthony Gordon; Cameron Green; Rashan Haniffa; Francois Lamontagne; Patrick Lawler; Edward Litton; John Marshall; Daniel McAuley; Shay McGuinness; Bryan McVerry; Stephanie Montgomery; Paul Mouncey; Srinivas Murthy; Alistair Nichol; Rachael Parke; Kathryn Rowan; Christopher Seymour; Anne Turner; Frank van de Veerdonk; Steve Webb; Ryan Zarychanski; Lewis Campbell; Andrew Forbes; David Gattas; Stephane Heritier; Lisa Higgins; Peter Kruger; Sandra Peake; Jeffrey Presneill; Ian Seppelt; Tony Trapani; Paul Young; Sean Bagshaw; Nick Daneman; Niall Ferguson; Cheryl Misak; Marlene Santos; Sebastiaan Hullegie; Mathias Pletz; Gernot Rohde; Kathy Rowan; Brian Alexander; Kim Basile; Timothy Girard; Christopher Horvat; David Huang; Kelsey Linstrum; Jennifer Vates; Richard Beasley; Robert Fowler; Steve McGloughlin; Susan Morpeth; David Paterson; Bala Venkatesh; Tim Uyeki; Kenneth Baillie; Eamon Duffy; Rob Fowler; Thomas Hills; Katrina Orr; Asad Patanwala; Steve Tong; Mihai Netea; Shilesh Bihari; Marc Carrier; Dean Fergusson; Ewan Goligher; Ghady Haidar; Beverley Hunt; Anand Kumar; Mike Laffan; Patrick Lawless; Sylvain Lother; Peter McCallum; Saskia Middeldopr; Zoe McQuilten; Matthew Neal; John Pasi; Roger Schutgens; Simon Stanworth; Alexis Turgeon; Alexandra Weissman; Neill Adhikari; Matthew Anstey; Emily Brant; Angelique de Man; Francois Lamonagne; Marie-Helene Masse; Andrew Udy; Donald Arnold; Phillipe Begin; Richard Charlewood; Michael Chasse; Mark Coyne; Jamie Cooper; James Daly; Iain Gosbell; Heli Harvala-Simmonds; Tom Hills; Sheila MacLennan; David Menon; John McDyer; Nicole Pridee; David Roberts; Manu Shankar-Hari; Helen Thomas; Alan Tinmouth; Darrell Triulzi; Tim Walsh; Erica Wood; Carolyn Calfee; Cecilia O’Kane; Murali Shyamsundar; Pratik Sinha; Taylor Thompson; Ian Young; Shailesh Bihari; Carol Hodgson; John Laffey; Danny McAuley; Neil Orford; Ary Neto; Michelle Detry; Mark Fitzgerald; Roger Lewis; Anna McGlothlin; Ashish Sanil; Christina Saunders; Lindsay Berry; Elizabeth Lorenzi; Eliza Miller; Vanessa Singh; Claire Zammit; Wilma van Bentum Puijk; Wietske Bouwman; Yara Mangindaan; Lorraine Parker; Svenja Peters; Ilse Rietveld; Kik Raymakers; Radhika Ganpat; Nicole Brillinger; Rene Markgraf; Kate Ainscough; Kathy Brickell; Aisha Anjum; Janis-Best Lane; Alvin Richards-Belle; Michelle Saull; Daisy Wiley; Julian Bion; Jason Connor; Simon Gates; Victoria Manax; Tom van der Poll; John Reynolds; Marloes van Beurden; Evelien Effelaar; Joost Schotsman; Craig Boyd; Cain Harland; Audrey Shearer; Jess Wren; Giles Clermont; William Garrard; Kyle Kalchthaler; Andrew King; Daniel Ricketts; Salim Malakoutis; Oscar Marroquin; Edvin Music; Kevin Quinn; Heidi Cate; Karen Pearson; Joanne Collins; Jane Hanson; Penny Williams; Shane Jackson; Adeeba Asghar; Sarah Dyas; Mihaela Sutu; Sheenagh Murphy; Dawn Williamson; Nhlanhla Mguni; Alison Potter; David Porter; Jayne Goodwin; Clare Rook; Susie Harrison; Hannah Williams; Hilary Campbell; Kaatje Lomme; James Williamson; Jonathan Sheffield; Willian van’t Hoff; Phobe McCracken; Meredith Young; Jasmin Board; Emma Mart; Cameron Knott; Julie Smith; Catherine Boschert; Julia Affleck; Mahesh Ramanan; Ramsy D’Souza; Kelsey Pateman; Arif Shakih; Winston Cheung; Mark Kol; Helen Wong; Asim Shah; Atul Wagh; Joanne Simpson; Graeme Duke; Peter Chan; Brittney Cartner; Stephanie Hunter; Russell Laver; Tapaswi Shrestha; Adrian Regli; Annamaria Pellicano; James McCullough; Mandy Tallott; Nikhil Kumar; Rakshit Panwar; Gail Brinkerhoff; Cassandra Koppen; Federica Cazzola; Matthew Brain; Sarah Mineall; Roy Fischer; Vishwanath Biradar; Natalie Soar; Hayden White; Kristen Estensen; Lynette Morrison; Joanne Smith; Melanie Cooper; Monash Health; Yahya Shehabi; Wisam Al-Bassam; Amanda Hulley; Christina Whitehead; Julie Lowrey; Rebecca Gresha; James Walsham; Jason Meyer; Meg Harward; Ellen Venz; Patricia Williams; Catherine Kurenda; Kirsy Smith; Margaret Smith; Rebecca Garcia; Deborah Barge; Deborah Byrne; Kathleen Byrne; Alana Driscoll; Louise Fortune; Pierre Janin; Elizabeth Yarad; Naomi Hammond; Frances Bass; Angela Ashelford; Sharon Waterson; Steve Wedd; Robert McNamara; Heidi Buhr; Jennifer Coles; Sacha Schweikert; Bradley Wibrow; Rashmi Rauniyar; Erina Myers; Ed Fysh; Ashlish Dawda; Bhaumik Mevavala; Ed Litton; Janet Ferrier; Priya Nair; Hergen Buscher; Claire Reynolds; John Santamaria; Leanne Barbazza; Jennifer Homes; Roger Smith; Lauren Murray; Jane Brailsford; Loretta Forbes; Teena Maguire; Vasanth Mariappa; Judith Smith; Scott Simpson; Matthew Maiden; Allsion Bone; Michelle Horton; Tania Salerno; Martin Sterba; Wenli Geng; Pieter Depuydt; Jan De Waele; Liesbet De Bus; Jan Fierens; Stephanie Bracke; Brenda Reeve; William Dechert; Michaël Chassé; François Martin Carrier; Dounia Boumahni; Fatna Benettaib; Ali Ghamraoui; David Bellemare; Ève Cloutier; Charles Francoeur; François Lamontagne; Frédérick D’Aragon; Elaine Carbonneau; Julie Leblond; Gloria Vazquez-Grande; Nicole Marten; Martin Albert; Karim Serri; Alexandros Cavayas; Mathilde Duplaix; Virginie Williams; Bram Rochwerg; Tim Karachi; Simon Oczkowski; John Centofanti; Tina Millen; Erick Duan; Jennifer Tsang; Lisa Patterson; Shane English; Irene Watpool; Rebecca Porteous; Sydney Miezitis; Lauralyn McIntyre; Laurent Brochard; Karen Burns; Gyan Sandhu; Imrana Khalid; Alexandra Binnie; Elizabeth Powell; Alexandra McMillan; Tracy Luk; Noah Aref; Zdravko Andric; Sabina Cviljevic; Renata Đimoti; Marija Zapalac; Gordan Mirković; Bruno Baršić; Marko Kutleša; Viktor Kotarski; Ana Vujaklija Brajković; Jakša Babel; Helena Sever; Lidija Dragija; Ira Kušan; Suvi Vaara; Leena Pettilä; Jonna Heinonen; Anne Kuitunen; Sari Karlsson; Annukka Vahtera; Heikki Kiiski; Sanna Ristimäki; Amine Azaiz; Cyril Charron; Mathieu Godement; Guillaume Geri; Antoine Vieillard-Baron; Franck Pourcine; Mehran Monchi; David Luis; Romain Mercier; Anne Sagnier; Nathalie Verrier; Cecile Caplin; Shidasp Siami; Christelle Aparicio; Sarah Vautier; Asma Jeblaoui; Muriel Fartoukh; Laura Courtin; Vincent Labbe; Cécile Leparco; Grégoire Muller; Mai-Anh Nay; Toufik Kamel; Dalila Benzekri; Sophie Jacquier; Emmanuelle Mercier; Delphine Chartier; Charlotte Salmon; PierreFrançois Dequin; Francis Schneider; Guillaume Morel; Sylvie L’Hotellier; Julio Badie; Fernando Daniel Berdaguer; Sylvain Malfroy; Chaouki Mezher; Charlotte Bourgoin; Bruno Megarbane; Nicolas Deye; Isabelle Malissin; Laetitia Sutterlin; Christophe Guitton; Cédric Darreau; Mickaël Landais; Nicolas Chudeau; Alain Robert; Pierre Moine; Nicholas Heming; Virginie Maxime; Isabelle Bossard; Tiphaine Barbarin Nicholier; Gwenhael Colin; Vanessa Zinzoni; Natacham Maquigneau; André Finn; Gabriele Kreß; Uwe Hoff; Carl Friedrich Hinrichs; Jens Nee; Mathias Pletz; Stefan Hagel; Juliane Ankert; Steffi Kolanos; Frank Bloos; Sirak Petros; Bastian Pasieka; Kevin Kunz; Peter Appelt; Bianka Schütze; Stefan Kluge; Axel Nierhaus; Dominik Jarczak; Kevin Roedl; Dirk Weismann; Anna Frey; Vivantes Klinikum Neukölln; Lorenz Reill; Michael Distler; Astrid Maselli; János Bélteczki; István Magyar; Ágnes Fazekas; Sándor Kovács; Viktória Szőke; Gábor Szigligeti; János Leszkoven; Daniel Collins; Patrick Breen; Stephen Frohlich; Ruth Whelan; Bairbre McNicholas; Michael Scully; Siobhan Casey; Maeve Kernan; Peter Doran; Michael O’Dywer; Michelle Smyth; Leanne Hayes; Oscar Hoiting; Marco Peters; Els Rengers; Mirjam Evers; Anton Prinssen; Jeroen Bosch Ziekenhuis; Koen Simons; Wim Rozendaal; F Polderman; P de Jager; M Moviat; A Paling; A Salet; Emma Rademaker; Anna Linda Peters; E de Jonge; J Wigbers; E Guilder; M Butler; Keri-Anne Cowdrey; Lynette Newby; Yan Chen; Catherine Simmonds; Rachael McConnochie; Jay Ritzema Carter; Seton Henderson; Kym Van Der Heyden; Jan Mehrtens; Tony Williams; Alex Kazemi; Rima Song; Vivian Lai; Dinu Girijadevi; Robert Everitt; Robert Russell; Danielle Hacking; Ulrike Buehner; Erin Williams; Troy Browne; Kate Grimwade; Jennifer Goodson; Owen Keet; Owen Callender; Robert Martynoga; Kara Trask; Amelia Butler; Livia Schischka; Chelsea Young; Eden Lesona; Shaanti Olatunji; Yvonne Robertson; Nuno José; Teodoro Amaro dos Santos Catorze; Tiago Nuno Alfaro de Lima Pereira; Lucilia Maria Neves Pessoa; Ricardo Manuel Castro Ferreira; Joana Margarida Pereira Sousa Bastos; Simin Aysel Florescu; Delia Stanciu; Miahela Florentina Zaharia; Alma Gabriela Kosa; Daniel Codreanu; Yaseen Marabi; Eman Al Qasim; Mohamned Moneer Hagazy; Lolowa Al Swaidan; Hatim Arishi; Rosana Muñoz-Bermúdez; Judith Marin-Corral; Anna Salazar Degracia; Francisco Parrilla Gómez; Maria Isabel Mateo López; Jorge Rodriguez Fernandez; Sheila Cárcel Fernández; Rosario Carmona Flores; Rafael León López; Carmen de la Fuente Martos; Angela Allan; Petra Polgarova; Neda Farahi; Stephen McWilliam; Daniel Hawcutt; Laura Rad; Laura O’Malley; Jennifer Whitbread; Olivia Kelsall; Laura Wild; Jessica Thrush; Hannah Wood; Karen Austin; Adrian Donnelly; Martin Kelly; Sinéad O’Kane; Declan McClintock; Majella Warnock; Paul Johnston; Linda Jude Gallagher; Clare Mc Goldrick; Moyra Mc Master; Anna Strzelecka; Rajeev Jha; Michael Kalogirou; Christine Ellis; Vinodh Krishnamurthy; Vashish Deelchand; Jon Silversides; Peter McGuigan; Kathryn Ward; Aisling O’Neill; Stephanie Finn; Barbara Phillips; Dee Mullan; Laura Oritz-Ruiz de Gordoa; Matthew Thomas; Katie Sweet; Lisa Grimmer; Rebekah Johnson; Jez Pinnell; Matt Robinson; Lisa Gledhill; Tracy Wood; Matt Morgan; Jade Cole; Helen Hill; Michelle Davies; David Antcliffe; Maie Templeton; Roceld Rojo; Phoebe Coghlan; Joanna Smee; Euan Mackay; Jon Cort; Amanda Whileman; Thomas Spencer; Nick Spittle; Vidya Kasipandian; Amit Patel; Suzanne Allibone; Roman Mary Genetu; Mohamed Ramali; Alison Ghosh; Peter Bamford; Emily London; Kathryn Cawley; Maria Faulkner; Helen Jeffrey; Tim Smith; Chris Brewer; Jane Gregory; James Limb; Amanda Cowton; Julie O’Brien; Nikitas Nikitas; Colin Wells; Liana Lankester; Mark Pulletz; Patricia Williams; Jenny Birch; Sophie Wiseman; Sarah Horton; Ana Alegria; Salah Turki; Tarek Elsefi; Nikki Crisp; Louise Allen; Iain McCullagh; Philip Robinson; Carole Hays; Maite Babio-Galan; Hannah Stevenson; Divya Khare; Meredith Pinder; Selvin Selvamoni; Amitha Gopinath; Richard Pugh; Daniel Menzies; Callum Mackay; Elizabeth Allan; Gwyneth Davies; Kathryn Puxty; Claire McCue; Susanne Cathcart; Naomi Hickey; Jane Ireland; Hakeem Yusuff; Graziella Isgro; Chris Brightling; Michelle Bourne; Michelle Craner; Malcolm Watters; Rachel Prout; Louisa Davies; Suzannah Pegler; Lynsey Kyeremeh; Gill Arbane; Karen Wilson; Linda Gomm; Federica Francia; Stephen Brett; Sonia Sousa Arias; Rebecca Elin Hall; Joanna Budd; Charlotte Small; Janine Birch; Emma Collins; Jeremy Henning; Stephen Bonner; Keith Hugill; Emanuel Cirstea; Dean Wilkinson; Michal Karlikowski; Helen Sutherland; Elva Wilhelmsen; Jane Woods; Julie North; Dhinesh Sundaran; Laszlo Hollos; Susan Coburn; Joanne Walsh; Margaret Turns; Phil Hopkins; John Smith; Harriet Noble; Maria Theresa Depante; Emma Clarey; Shondipon Laha; Mark Verlander; Alexandra Williams; Abby Huckle; Andrew Hall; Jill Cooke; Caroline Gardiner-Hill; Carolyn Maloney; Hafiz Qureshi; Neil Flint; Sarah Nicholson; Sara Southin; Andrew Nicholson; Barbara Borgatta; Ian Turner-Bone; Amie Reddy; Laura Wilding; Loku Chamara Warnapura; Ronan Agno Sathianathan; David Golden; Ciaran Hart; Jo Jones; Jonathan Bannard-Smith; Joanne Henry; Katie Birchall; Fiona Pomeroy; Rachael Quayle; Arystarch Makowski; Beata Misztal; Iram Ahmed; Thyra KyereDiabour; Kevin Naiker; Richard Stewart; Esther Mwaura; Louise Mew; Lynn Wren; Felicity Willams; Richard Innes; Patricia Doble; Joanne Hutter; Charmaine Shovelton; Benjamin Plumb; Tamas Szakmany; Vincent Hamlyn; Nancy Hawkins; Sarah Lewis; Amanda Dell; Shameer Gopal; Saibal Ganguly; Andrew Smallwood; Nichola Harris; Stella Metherell; Juan Martin Lazaro; Tabitha Newman; Simon Fletcher; Jurgens Nortje; Deirdre Fottrell-Gould; Georgina Randell; Mohsin Zaman; Einas Elmahi; Andrea Jones; Kathryn Hall; Gary Mills; Kim Ryalls; Helen Bowler; Jas Sall; Richard Bourne; Zoe Borrill; Tracey Duncan; Thomas Lamb; Joanne Shaw; Claire Fox; Jeronimo Moreno Cuesta; Kugan Xavier; Dharam Purohit; Munzir Elhassan; Dhanalakshmi Bakthavatsalam; Matthew Rowland; Paula Hutton; Archana Bashyal; Neil Davidson; Clare Hird; Manish Chhablani; Gunjan Phalod; Amy Kirkby; Simon Archer; Kimberley Netherton; Henrik Reschreiter; Julie Camsooksai; Sarah Patch; Sarah Jenkins; David Pogson; Steve Rose; Zoe Daly; Lutece Brimfield; Helen Claridge; Dhruv Parekh; Colin Bergin; Michelle Bates; Joanne Dasgin; Christopher McGhee; Malcolm Sim; Sophie Kennedy Hay; Steven Henderson; Mandeep-Kaur Phull; Abbas Zaidi; Tatiana Pogreban; Lace Paulyn Rosaroso; Daniel Harvey; Benjamin Lowe; Megan Meredith; Lucy Ryan; Anil Hormis; Rachel Walker; Dawn Collier; Sarah Kimpton; Susan Oakley; Kevin Rooney; Natalie Rodden; Emma Hughes; Nicola Thomson; Deborah McGlynn; Andrew Walden; Nicola Jacques; Holly Coles; Emma Tilney; Emma Vowell; Martin Schuster-Bruce; Sally Pitts; Rebecca Miln; Laura Purandare; Luke Vamplew; Michael Spivey; Sarah Bean; Karen Burt; Lorraine Moore; Christopher Day; Charly Gibson; Elizabeth Gordon; Letizia Zitter; Samantha Keenan; Evelyn Baker; Shiney Cherian; Sean Cutler; Anna Roynon-Reed; Kate Harrington; Ajay Raithatha; Kris Bauchmuller; Norfaizan Ahmad; Irina Grecu; Dawn Trodd; Jane Martin; Caroline Wrey Brown; Ana-Marie Arias; Thomas Craven; David Hope; Jo Singleton; Sarah Clark; Nicola Rae; Ingeborg Welters; David Oliver Hamilton; Karen Williams; Victoria Waugh; David Shaw; Zudin Puthucheary; Timothy Martin; Filipa Santos; Ruzena Uddin; Alastair Somerville; Kate Colette Tatham; Shaman Jhanji; Ethel Black; Arnold Dela Rosa; Ryan Howle; Redmond Tully; Andrew Drummond; Joy Dearden; Jennifer Philbin; Sheila Munt; Alain Vuylsteke; Charles Chan; Saji Victor; Ramprasad Matsa; Minerva Gellamucho; Ben Creagh-Brown; Joe Tooley; Laura Montague; Fiona De Beaux; Laetitia Bullman; Ian Kersiake; Carrie Demetriou; Sarah Mitchard; Lidia Ramos; Katie White; Phil Donnison; Maggie Johns; Ruth Casey; Lehentha Mattocks; Sarah Salisbury; Paul Dark; Andrew Claxton; Danielle McLachlan; Kathryn Slevin; Stephanie Lee; Jonathan Hulme; Sibet Joseph; Fiona Kinney; Ho Jan Senya; Aneta Oborska; Abdul Kayani; Bernard Hadebe; Rajalakshmi Orath Prabakaran; Lesley Nichols; Matt Thomas; Ruth Worner; Beverley Faulkner; Emma Gendall; Kati Hayes; Colin Hamilton-Davies; Carmen Chan; Celina Mfuko; Hakam Abbass; Vineela Mandadapu; Susannah Leaver; Daniel Forton; Kamal Patel; Elankumaran Paramasivam; Matthew Powell; Richard Gould; Elizabeth Wilby; Clare Howcroft; Dorota Banach; Ziortza Fernández de Pinedo Artaraz; Leilani Cabreros; Ian White; Maria Croft; Nicky Holland; Rita Pereira; Ahmed Zaki; David Johnson; Matthew Jackson; Hywel Garrard; Vera Juhaz; Alistair Roy; Anthony Rostron; Lindsey Woods; Sarah Cornell; Suresh Pillai; Rachel Harford; Tabitha Rees; Helen Ivatt; Ajay Sundara Raman; Miriam Davey; Kelvin Lee; Russell Barber; Manish Chablani; Farooq Brohi; Vijay Jagannathan; Michele Clark; Sarah Purvis; Bill Wetherill; Ahilanandan Dushianthan; Rebecca Cusack; Kim de Courcy-Golder; Simon Smith; Susan Jackson; Ben Attwood; Penny Parsons; Valerie Page; Xiao Bei Zhao; Deepali Oza; Jonathan Rhodes; Tom Anderson; Sheila Morris; Charlotte Xia Le Tai; Amy Thomas; Alexandra Keen; Stephen Digby; Nicholas Cowley; Laura Wild; David Southern; Harsha Reddy; Andy Campbell; Claire Watkins; Sara Smuts; Omar Touma; Nicky Barnes; Peter Alexander; Tim Felton; Susan Ferguson; Katharine Sellers; Joanne Bradley-Potts; David Yates; Isobel Birkinshaw; Kay Kell; Nicola Marshall; Lisa Carr-Knott; Charlotte Summers
Journal: JAMA Date: 2020-10-06 Impact factor: 56.272

3. Effect of neuromuscular blocking agents on gas exchange in patients presenting with acute respiratory distress syndrome.

Authors: Marc Gainnier; Antoine Roch; Jean-Marie Forel; Xavier Thirion; Jean-Michel Arnal; Stéphane Donati; Laurent Papazian
Journal: Crit Care Med Date: 2004-01 Impact factor: 7.598

4. Feasibility and physiological effects of prone positioning in non-intubated patients with acute respiratory failure due to COVID-19 (PRON-COVID): a prospective cohort study.

Authors: Anna Coppo; Giacomo Bellani; Dario Winterton; Michela Di Pierro; Alessandro Soria; Paola Faverio; Matteo Cairo; Silvia Mori; Grazia Messinesi; Ernesto Contro; Paolo Bonfanti; Annalisa Benini; Maria Grazia Valsecchi; Laura Antolini; Giuseppe Foti
Journal: Lancet Respir Med Date: 2020-06-19 Impact factor: 30.700

5. SARS-CoV-2 infection associated with diplopia and anti-acetylcholine receptor antibodies.

Authors: Á I Pérez Álvarez; C Suárez Cuervo; S Fernández Menéndez
Journal: Neurologia (Engl Ed) Date: 2020-04-18

Review 6. Reappraisal of Ventilator-Free Days in Critical Care Research.

Authors: Nadir Yehya; Michael O Harhay; Martha A Q Curley; David A Schoenfeld; Ron W Reeder
Journal: Am J Respir Crit Care Med Date: 2019-10-01 Impact factor: 21.405

7. Clinical features, ventilatory management, and outcome of ARDS caused by COVID-19 are similar to other causes of ARDS.

Authors: Carlos Ferrando; Fernando Suarez-Sipmann; Ricard Mellado-Artigas; María Hernández; Alfredo Gea; Egoitz Arruti; César Aldecoa; Graciela Martínez-Pallí; Miguel A Martínez-González; Arthur S Slutsky; Jesús Villar
Journal: Intensive Care Med Date: 2020-07-29 Impact factor: 41.787

8. Extracorporeal membrane oxygenation support in COVID-19: an international cohort study of the Extracorporeal Life Support Organization registry.

Authors: Ryan P Barbaro; Graeme MacLaren; Philip S Boonstra; Theodore J Iwashyna; Arthur S Slutsky; Eddy Fan; Robert H Bartlett; Joseph E Tonna; Robert Hyslop; Jeffrey J Fanning; Peter T Rycus; Steve J Hyer; Marc M Anders; Cara L Agerstrand; Katarzyna Hryniewicz; Rodrigo Diaz; Roberto Lorusso; Alain Combes; Daniel Brodie
Journal: Lancet Date: 2020-09-25 Impact factor: 79.321

9. Extracorporeal membrane oxygenation for severe acute respiratory distress syndrome associated with COVID-19: a retrospective cohort study.

Authors: Matthieu Schmidt; David Hajage; Guillaume Lebreton; Antoine Monsel; Guillaume Voiriot; David Levy; Elodie Baron; Alexandra Beurton; Juliette Chommeloux; Paris Meng; Safaa Nemlaghi; Pierre Bay; Pascal Leprince; Alexandre Demoule; Bertrand Guidet; Jean Michel Constantin; Muriel Fartoukh; Martin Dres; Alain Combes
Journal: Lancet Respir Med Date: 2020-08-13 Impact factor: 30.700