key: cord-0705375-8pnruk8p
authors: Coppola, Silvia; Santus, Pierachille; Sotgiu, Giovanni; Mondoni, Michele; Gandola, Alessia; Saad, Marina; Sferrazza Papa, Giuseppe Francesco; Centanni, Stefano; Saderi, Laura; Chiumello, Davide Alberto; Radovanovic, Dejan
title: Feasibility and Clinical Outcomes of a Step Up Noninvasive Respiratory Support Strategy in Patients with Severe COVID-19 Pneumonia
date: 2021-11-22
journal: J Clin Med
DOI: 10.3390/jcm10225444
sha: eaf2da9bb0fbddb84bbcc66090d3ab5ba648743d
doc_id: 705375
cord_uid: 8pnruk8p

The best noninvasive respiratory strategy in patients with Coronavirus Disease 2019 (COVID-19) pneumonia is still discussed. We aimed at assessing the rate of endotracheal intubation (ETI) in patients treated with continuous positive airway pressure (CPAP) and noninvasive ventilation (NIV) if CPAP failed. Secondary outcomes were in-hospital mortality and in-hospital length of stay (LOS). A retrospective, observational, multicenter study was conducted in intermediate-high dependency respiratory units of two Italian university hospitals. Consecutive patients with COVID-19 treated with CPAP were enrolled. Thoraco-abdominal asynchrony or hemodynamic instability led to ETI. Patients showing SpO(2) ≤ 94%, respiratory rate ≥ 30 bpm or accessory muscle activation on CPAP received NIV. Respiratory distress and desaturation despite NIV eventually led to ETI. 156 patients were included. The overall rate of ETI was 30%, mortality 18% and median LOS 24 (17–32) days. Among patients that failed CPAP (n = 63), 28% were intubated, while the remaining 72% received NIV, of which 65% were intubated. Patients intubated after CPAP showed lower baseline PaO(2)/FiO(2), lower lymphocyte counts and higher D-dimer values compared with patients intubated after CPAP + NIV. Mortality was 22% with CPAP + ETI, and 20% with CPAP + NIV + ETI. In the case of CPAP failure, a NIV trial appears feasible, does not deteriorate respiratory status and may reduce the need for ETI in COVID-19 patients.

Coronavirus disease 2019 (COVID- 19) is an infectious disease caused by a new pathogen named severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Acute respiratory failure and acute respiratory distress syndrome (ARDS) caused by bilateral

Adults (>18 years) with acute respiratory failure caused by COVID-19 pneumonia, laboratory-confirmed SARS-CoV-2 infection, with ground glass bilateral opacities at chest X-ray or lung CT were consecutively enrolled. They were admitted to the intermediate-high dependency respiratory units of two University Hospitals in Milano (Italy) between March and May 2020.

They were included if eligible for CPAP [21, 30] . As suggested by previous reports [21, 30] , inclusion criteria were: PaO 2 /FiO 2 ratio <300 and/or dyspnea, tachypnea (respiratory rate > 30 bpm) or activation of respiratory accessory muscles while on Venturi or Reservoir mask delivering up to 12 L/min (FiO 2 of at least 0.5). Exclusion criteria were: the need for immediate endotracheal intubation (ETI), unstable hemodynamics, delirium, Glasgow coma scale < 15 and respiratory acidosis. Only a very limited percentage of patients with COVID-19 pneumonia present with hypercapnia at admission [21] . Decompensated hypercapnic respiratory failure at admission, if eligible, was considered a criterion for direct intubation, while patients with a history of nocturnal hypoventilation or obstructive sleep apnea with chronic hypercapnia were not excluded from the study. Patients receiving a "do not intubate" (DNI) order, thus not eligible to ETI and with noninvasive respiratory support as the ceiling treatment, were excluded from the study. A DNI order was determined after a multidisciplinary discussion among the high dependency respiratory unit and critical care unit staff and shared with the patient and the family, and was based upon survival chances, comorbidities, clinical status, frailty and, when possible, the patient's decision. The study was approved by the local ethical committee (Comitato Etico Milano Area I; 17263/2020-2020/ST/095).

CPAP was delivered through a high flow generator (VitalSigns Inc., Totowa, NJ, USA; 90-140 L/min; Myo 3133 A, Pulmodyne, Indianapolis, IN, USA), using a helmet (Starmed, Teramo, Italy) with a mechanical PEEP valve. The PEEP levels ranged between 7.5 and 10 cm H 2 O and FiO 2 was titrated to maintain a SpO 2 > 94%. CPAP failure was defined by the presence of tachypnea (respiratory rate > 30 bpm), accessory muscle activation, oxygenation worsening, poor tolerability to the device despite adequate sedation or if the patient developed respiratory acidosis or alkalosis. In the case of CPAP failure, a NIV trial was implemented, with the only exception of patients with severe respiratory distress (i.e., activation of neck, pectoralis, abdomen, transverse and intercostal muscles, respiratory asynchrony with/without agitation or delirium) where ETI was performed and IMV started. NIV was delivered by a mechanical ventilator (MONNAL T60, Air Liquide Medical Systems, Antony, France) with a facial or oro-nasal mask (Armstrong Medical, Coleraine, UK). The level of PSV during NIV was set between 10-12 cm H 2 O and subsequently adjusted to achieve an acceptable tolerability profile and a comfortable respiratory rate. PEEP and FiO 2 were titrated as well as during CPAP. In the case of NIV failure patients were intubated and started on IMV. Criteria for ETI during NIV were the same adopted for CPAP failure.

Demographics, comorbidities and chronic therapies were recorded at admission. Respiratory rate, gas exchange-related variables, laboratory parameters and ventilatory settings were collected at the emergency department and at the time of CPAP or NIV failure. Blood gas analysis, vital signs, respiratory mechanics and occurrence of respiratory distress were evaluated day by day. Patients' data were recorded daily up to CPAP or NIV failure or until weaning from CPAP or NIV was started. Weaning criteria were: PaO 2 /FiO 2 > 200 mmHg, respiratory rate < 20-22/min and PaCO 2 > 35 mmHg and "weaned" condition achieved when the noninvasive respiratory support was not administered for >24 h.

The primary outcome was the failure rate of noninvasive respiratory support (need for ETI), whereas the secondary outcomes were the in-hospital length of stay and mortality.

Qualitative variables were described with absolute and relative (percentage) frequencies. Quantitative variables were summarized with means (standard deviations, SD) or medians (interquartile ranges, IQR) depending on their parametric or non-parametric distribution, respectively. A chi-squared or Fisher exact test was used to statistically compare qualitative variables. Student's t or Mann-Whitney test was used to assess statistically significant differences related to parametric and non-parametric variables, respectively. Kaplan Meier curves were plotted to assess differences in terms of main outcomes (e.g., mortality) between groups that were intubated after CPAP and patients that underwent a NIV trial; a long-rank test was used to evaluate the statistical significance.

A two-tailed p-value less than 0.05 was considered statistically significant. The statistical software STATA version 16 (StataCorp LLC, College Station, TX, USA) was used to perform all statistical computations.

A total of 199 patients were evaluated and 156 were recruited ( Figure 1 ). The median (IQR) age of the cohort was 61 (55-69) years, with 76% males, 37% with hypertension, 11% with ischemic heart disease and 16% with diabetes (Table 1) . During the admission median (IQR) PaO 2 /FiO 2 ratio, respiratory rate and arterial carbon dioxide (PaCO 2 ) were 269 (168-310), 24 (22) (23) (24) (25) (26) (27) bpm, and 33 (30) (31) (32) (33) (34) (35) (36) (37) (38) mmHg, respectively. The median (IQR) length of hospital stay was 24 (17) (18) (19) (20) (21) (22) (23) (24) (25) (26) (27) (28) (29) (30) (31) (32) days. Data are reported as means (standard deviation) or medians (interquartile range), as appropriate. Statistically significant comparisons are marked in bold. ACE = angiotensin converting enzyme; Hb = hemoglobin; PaO2 = partial pressure of oxygen; PaCO2 = partial pressure of carbon dioxide; FiO2 = Inspired oxy-gen fraction.

Forty-seven (30%) patients showed a noninvasive respiratory support (both CPAP and CPAP + NIV) failure and were intubated with an overall in-hospital mortality of 18%. No patient died after being weaned from CPAP or CPAP-NIV ( Figure 1 ). 

In patients exposed to helmet CPAP (n = 156) CPAP was prescribed for a median (IQR) time of 4 (2-7) days, with a median PEEP of 10 (10-10) cm H2O. Ninety-three (60%) patients with CPAP were successfully treated (CPAP success group) without any other respiratory support, and 63 (40%) failed (CPAP failure group) ( Figure 1 ).

In the CPAP failure group, 18 patients (28%) were intubated (CPAP + ETI group) and 45 (72%) received NIV (CPAP + NIV group). Mortality was 22% (14/63) after CPAP + ETI and 20% (13/63) after CPAP + NIV ( Figure 2 Data are reported as means (standard deviation) or medians (interquartile range), as appropriate. Statistically significant comparisons are marked in bold. ACE = angiotensin converting enzyme; Hb = hemoglobin; PaO 2 = partial pressure of oxygen; PaCO 2 = partial pressure of carbon dioxide; FiO 2 = Inspired oxy-gen fraction.

Forty-seven (30%) patients showed a noninvasive respiratory support (both CPAP and CPAP + NIV) failure and were intubated with an overall in-hospital mortality of 18%. No patient died after being weaned from CPAP or CPAP-NIV ( Figure 1 ).

In patients exposed to helmet CPAP (n = 156) CPAP was prescribed for a median (IQR) time of 4 (2-7) days, with a median PEEP of 10 (10-10) cm H 2 O. Ninety-three (60%) patients with CPAP were successfully treated (CPAP success group) without any other respiratory support, and 63 (40%) failed (CPAP failure group) (Figure 1 ).

In the CPAP failure group, 18 patients (28%) were intubated (CPAP + ETI group) and 45 (72%) received NIV (CPAP + NIV group). Mortality was 22% (14/63) after CPAP + ETI and 20% (13/63) after CPAP + NIV (Figure 2 ). Patients who failed CPAP had a shorter median (IQR) CPAP duration (2 (1-4) vs. 6 (4-9) days; p-value < 0.0001) and a higher in-hospital mortality (42.9%, 27/63, vs. 0.0%, 0/93, p-value < 0.001), whereas the median (IQR) length of hospital stay was comparable 23 (17) (18) (19) (20) (21) (22) (23) (24) (25) (26) (27) (28) (29) (30) vs. 25 days; p-value = 0.41) ( Table 1) .

Considering the CPAP failure group, at the hospital admission the 18 patients directly intubated after CPAP failure (CPAP + ETI group) compared with the 45 patients treated with NIV (CPAP + NIV group) had lower median (IQR) PaO2/FiO2 ratio (151 (91-267) vs. 281 (209-321) mmHg; p-value = 0.005) and higher median (IQR) PaCO2 (35 (33) (34) (35) (36) (37) (38) (39) (40) vs. 32 (29) (30) (31) (32) (33) (34) (35) mmHg; p-value = 0.002), with a similar median (IQR) respiratory rate (25 (24-30) vs. 24 (22) (23) (24) (25) (26) (27) (28) bpm; p-value = 0.674). The CPAP + ETI group showed lower lymphocyte counts, neutrophil percentage, higher values of INR, LDH, D-dimer and bilirubin when compared with patients treated with CPAP + NIV (Table 2) . (Table 1) .

Patients who failed CPAP had a shorter median (IQR) CPAP duration (2 (1-4) vs. 6 (4-9) days; p-value < 0.0001) and a higher in-hospital mortality (42.9%, 27/63, vs. 0.0%, 0/93, p-value < 0.001), whereas the median (IQR) length of hospital stay was comparable 23 (17) (18) (19) (20) (21) (22) (23) (24) (25) (26) (27) (28) (29) (30) vs. 25 days; p-value = 0.41) ( Table 1) .

Considering the CPAP failure group, at the hospital admission the 18 patients directly intubated after CPAP failure (CPAP + ETI group) compared with the 45 patients treated with NIV (CPAP + NIV group) had lower median (IQR) PaO 2 /FiO 2 ratio (151 (91-267) vs. 281 (209-321) mmHg; p-value = 0.005) and higher median (IQR) PaCO 2 (35 (33-40) vs. 32 (29) (30) (31) (32) (33) (34) (35) mmHg; p-value = 0.002), with a similar median (IQR) respiratory rate (25 (24-30) vs. 24 (22) (23) (24) (25) (26) (27) (28) bpm; p-value = 0.674). The CPAP + ETI group showed lower lymphocyte counts, neutrophil percentage, higher values of INR, LDH, D-dimer and bilirubin when compared with patients treated with CPAP + NIV (Table 2) .

At time of CPAP failure, the median (IQR) PaO 2 /FiO 2 ratio of the CPAP + ETI group was significantly lower (99 (82-112) vs. 143 (121-190) mmHg; p-value < 0.001) and mean (SD) respiratory rate was significantly higher (35 (9) vs. 25 (6.5) bpm; p-value < 0.0001) when compared with the CPAP + NIV group.

The median (IQR) duration of CPAP tended to be higher in the CPAP + ETI group (2.5 (2-7) vs. 2 (1-3) days; p-value = 0.05) with equal median (IQR) PEEP levels (10 (10-10) vs. 10 (10-10) mmHg; p-value = 0.682) ( Table 2 ) compared with the CPAP + NIV group. 

Length of hospital stay, days 19 (15) (16) (17) (18) (19) (20) (21) (22) (23) (24) 29 0.05

In-hospital mortality, n (%) 14 (77.8) 13 (28.9) 0.001

Data are reported as means (standard deviation) or medians (interquartile range), as appropriate. Statistically significant comparisons are marked in bold. ACE = angiotensin converting enzyme; Hb = hemoglobin; PaO 2 = partial pressure of oxygen; PaCO 2 = partial pressure of carbon dioxide; FiO 2 = inspired oxygen fraction.

Among the 45 patients treated with CPAP + NIV, 29 (64%) failed NIV and were intubated (CPAP + NIV + ETI), whereas 16 (36%) were not intubated.

When admitted to hospital PaO 2 /FiO 2 , respiratory rate and PaCO 2 were not different. The median (IQR) duration of CPAP before NIV was not different (2 (1.0-3.5) in CPAP + NIV vs. 2 (1-3) days in CPAP + NIV + ETI), whereas median (IQR) NIV duration was significantly lower in patients that were intubated (1 (1-2) vs. 5 (2.5-5) days).

A similar median (IQR) hospital length of stay was recorded (28.5 (24.5-36.5) vs. 29 (17-39) days), whereas in-hospital mortality was significantly higher in patients who failed NIV (45% (13/29) vs. 0% (0/16)) ( Table 3) . Table 3 . Clinical characteristics and outcomes of patients that failed CPAP + NIV treatment and were intubated vs. patients that succeed CPAP + NIV at time of hospital admission and at the time of failure.

Males, n (%) 12 

The overall mortality of intubated patients both after CPAP and after CPAP + NIV failure was 57% (27/47).

Comparing intubated patients that failed CPAP (n = 18) and CPAP + NIV (n = 29), the mortality was higher in the CPAP + ETI group (77% (14/18) vs. 45% (13/29)). The median (IQR) time spent on CPAP compared with the total time spent on CPAP + NIV was not different (2.5 (2-5) vs. 4 (3-5) days). At the admission, the CPAP + ETI group showed a lower PaO 2 /FiO 2 , lower lymphocyte counts and higher values of INR, LDH, D-dimer and bilirubin, whereas, at the time of intubation, PaO 2 /FiO 2 , respiratory rate and PaCO 2 were similar (Table 4 ). Data are reported as means (standard deviation) or medians (interquartile range), as appropriate. Statistically significant comparisons are marked in bold. ACE = angiotensin converting enzyme; Hb = hemoglobin; PaO 2 = partial pressure of oxygen; PaCO 2 = partial pressure of carbon dioxide; FiO 2 = inspired oxygen fraction.

The main findings of the present retrospective study on COVID-19 patients treated with CPAP as first choice or with NIV after the failure of CPAP can be summarized as follows: (1) the overall intubation rate was 30%, 28% of patients that failed CPAP and 64% of patients that failed both CPAP and the subsequent NIV trial, (2) NIV avoided intubation in 35% of patients that failed CPAP; (3) overall in-hospital mortality was 18%: in patients that failed CPAP and were intubated mortality was 22%, while it was 20% in those treated with a NIV trial, and (4) length of hospital stay was similar in patients that succeeded or failed CPAP or NIV.

Hospitalized patients with COVID-19 pneumonia show acute hypoxemic respiratory failure caused by a diffuse alveolar/vascular damage and dyspnea. Oxygen therapy is the first therapeutic approach, with a target of arterial saturation between 92-96% [17] .

However, in the case of persistent hypoxemia, increased respiratory rate and dyspnea, a noninvasive respiratory support should be prescribed. The easiest noninvasive respiratory support is CPAP with mask or helmet [31] . The CPAP, by applying a PEEP, should increase the alveolar recruitment, reduce the work of breathing, and improve oxygenation 6. The helmet and face mask reduce the inspiratory effort during continuous flow CPAP [32] . However, the helmet CPAP is usually better tolerated, and should be chosen in the case of long-term exposure [31] . In non-COVID-19 acute respiratory failure, CPAP improves oxygenation, reduces the need of intubation and the risk of intensive care [33, 34] . A recent systematic review showed that helmet CPAP was superior to face mask in reducing the rate of ETI and mortality [35] . In COVID-19 patients with acute respiratory failure, several European consensus documents recommend CPAP, administered by helmet both due to the higher number of patients treated in non-intensive care settings and to reduce the risk of environmental spread of aerosols. The helmet requires only a high flow oxygen-air source without necessitating electricity and allowing the patients to be fed and hydrated orally [6] . Recent studies showed the effective prolonged prescription of noninvasive respiratory supports in intensive and non-intensive care settings [1] [2] [3] [4] [5] [13] [14] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] .

However, a protracted use of a noninvasive respiratory support not associated with a clinical recovery can increase the risk of mortality compared with an early adoption of IMV [28] . Thus, a decisional and monitoring algorithm for noninvasive respiratory support should reduce the number of failed patients [30] . An Italian study on noninvasive respiratory support outside the intensive care found that 85% were treated with CPAP with 68% using the helmet. The rate of failure in terms of intubation rate was 37% [19] . Aliberti et al. found a failure rate of 44% [21] .

The comparison was difficult due to heterogeneous settings, patients and protocols for noninvasive respiratory support; the ETI rate was slightly lower (30%) in our population. Our results are in line with the multicenter observational study by Franco et al., who found failure rates of 29% and 25% for CPAP and NIV, respectively [20] .

The mortality rate of previous studies ranged from 25% to 30% [19] [20] [21] 26] . The overall mortality was low (18%) in our study, with the highest chance of survival for patients that continued to be exposed to a noninvasive respiratory support in comparison with those that failed after CPAP or after CPAP + NIV and were intubated. Similarly, Grasselli et al. found that patients treated noninvasively and subsequently intubated had a significantly lower survival compared with those who continued to receive noninvasive support [2] . When NIV is successful it might significantly decrease mortality [12] .

Following our noninvasive respiratory strategy, 40% of patients failed CPAP and 72% of them continued the noninvasive ventilatory support with NIV (i.e., CPAP + NIV group). Patients directly intubated after CPAP had a more severe disease when admitted to hospital, with lower PaO 2 /FiO 2 , higher PaCO 2 , lower lymphocyte counts and higher levels of D-Dimer when compared with the CPAP + NIV group [36] . Accordingly, at the time of failure, after two days of CPAP treatment, intubated patients had a significantly lower PaO 2 /FiO 2 and higher respiratory rate. Severity of pneumonia according to American Thoracic Society and Infectious Diseases Society of America (ATS/IDSA) criteria [37] , higher values of IL-6 and lower platelet counts are risk factors for noninvasive support failure [19, 21] .

Our clinical strategy was designed to provide a NIV trial to the subgroup of patients showing initial signs of recruitment of the accessory respiratory muscles while on CPAP and were not directly intubated. So far, NIV has been prescribed to treat acute hypoxemic respiratory failure through oro-nasal, full face and helmet devices [30] . NIV could decrease the inspiratory effort and dyspnea better than CPAP, avoiding intubation [30] . However, by applying a pressure support during inspiration, NIV could increase the transpulmonary pressure and tidal volume (i.e., promote the PSILI) and delay the initiation of mechanical ventilation [27, 28] . To the best of our knowledge, this is the first study that proposed a step-up strategy in terms of noninvasive respiratory support (i.e., from oxygen supplementation to CPAP and NIV), integrating respiratory failure parameters and clinical criteria to determine the timing of escalation.

In our cohort, 35% who received NIV avoided intubation. Overall, patients received the NIV support for a median of 5 days, but patients that failed were treated for a shorter period in comparison with those who were weaned from NIV. Furthermore, the mortality of intubated patients was significantly higher after CPAP failure than after CPAP + NIV failure (77% vs. 45%), potentially caused by a more severe disease at hospital admission, characterized by lower lymphocytes and neutrophil percentage, higher values of INR, LDH, D-dimer and bilirubin. Indeed, maintaining patients on spontaneous breathing during NIV did not increase the mortality if compared with an early initiation of invasive mechanical ventilation, although it could increase the risk of self-inflicted lung injury. This is in accordance with the results of a recent systematic review, that included more than 8000 patients critically ill patients with COVID-19 pneumonia and demonstrated that timing of intubation may have no effect on in-hospital mortality, suggesting the possibility for a positive role of a "wait and see" approach [38] . Of note is that none of the patients receiving CPAP or CPAP + NIV were intubated in severe distress or hemodynamic instability after failure.

Several study limitations can be found. This is a retrospective study, which did not objectively assess the inspiratory effort using an esophageal catheter or by ultrasound. Data on prone position were not collected and thus the possible effect on clinical outcomes could not be assessed. Furthermore, the small sample size can affect the inference of the findings, although the study sample in terms of age and male prevalence was comparable with previous reports, both including patients admitted in the ICU [39] and in high dependency respiratory units [21] .

In conclusion, the majority of COVID-19 patients with acute hypoxemic respiratory failure can be managed with noninvasive respiratory support without the need for immediate ETI. A noninvasive respiratory support strategy is also feasible outside ICU, provided strict daily monitoring. For the first time we demonstrated that in the case of CPAP failure, a NIV trial can avoid intubation and does not seem to increase mortality and deteriorate patients' respiratory status. However, a subset of patients who needed direct intubation after CPAP failure for severe respiratory distress is characterized by worse clinical outcomes probably due to faster and severe evolution of disease.

The present noninvasive respiratory strategy needs further validation in larger prospective studies. Institutional Review Board Statement: The study was conducted according to the guidelines of the Declaration of Helsinki, and approved by the Ethics Committee "Comitato Etico Milano Area I" (17263/2020-2020/ST/095).

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement: D.C. had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis and had final responsibility for the decision to submit for publication. The anonymized datasets used and analyzed during the current study are available from the corresponding author on reasonable request.

The authors declare no conflict of interest.

Clinical Characteristics of 138 Hospitalized Patients With 2019 Novel Coronavirus-Infected Pneumonia in

Risk Factors Associated With Mortality Among Patients With COVID-19 in Intensive Care Units in

Guideline for the management of COVID-19 patients during hospital admission in a non-intensive care setting

Clinical features of patients infected with 2019 novel coronavirus in

Covid-19 in Critically Ill Patients in the Seattle Region-Case Series

Severe hypoxemia: Which strategy to choose

Pulmonary post-mortem findings in a series of COVID-19 cases from northern Italy: A two-centre descriptive study

Complexity and unanswered questions in the pathophysiology of COVID-19 ARDS

Physiological and quantitative CT-scan characterization of COVID-19 and typical ARDS: A matched cohort study

Mechanical Ventilation to Minimize Progression of Lung Injury in Acute Respiratory Failure

Spontaneous Effort During Mechanical Ventilation

Benefits and risks of success or failure of noninvasive ventilation

Early consensus management for non-ICU acute respiratory failure SARS-CoV-2 emergency in Italy: From ward to trenches

Respiratory support in patients with COVID-19 (outside intensive care unit). A position paper of the Respiratory Support and Chronic Care Group of the French Society of Respiratory Diseases

Balancing evidence and frontline experience in the early phases of the COVID-19 pandemic: Current position of the Italian Society of Anti-infective Therapy (SITA) and the Italian Society of Pulmonology (SIP)

Managing the Respiratory Care of Patients with COVID-19

Surviving Sepsis Campaign: Guidelines on the management of critically ill adults with Coronavirus Disease 2019 (COVID-19)

Noninvasive respiratory support in acute hypoxemic respiratory failure associated with COVID-19 and other viral infections

Noninvasive Ventilatory Support of Patients with COVID-19 outside the Intensive Care Units

Feasibility and clinical impact of out-of-ICU noninvasive respiratory support in patients with COVID-19-related pneumonia

Helmet CPAP treatment in patients with COVID-19 pneumonia: A multicentre cohort study

Continuous positive airway pressure to avoid intubation in SARS-CoV-2 pneumonia: A two-period retrospective case-control study

Continuous positive airway pressure in COVID-19 patients with moderate-to-severe respiratory failure

Noninvasive ventilation for acute hypoxemic respiratory failure in patients with COVID-19

Outcomes of COVID-19 patients treated with continuous positive airway pressure outside the intensive care unit

Helmet CPAP revisited in COVID-19 pneumonia: A case series

Official ERS/ATS clinical practice guidelines: Noninvasive ventilation for acute respiratory failure

Noninvasive Ventilation of Patients with Acute Respiratory Distress Syndrome. Insights from the LUNG SAFE Study

Spontaneous breathing, transpulmonary pressure and mathematical trickery

Helmet CPAP to Treat Acute Hypoxemic Respiratory Failure in Patients with COVID-19: A Management Strategy Proposal

A systematic technical review of the systems for the continuous positive airway pressure

Noninvasive positive pressure ventilation delivered by helmet vs. standard face mask

Helmet CPAP vs. oxygen therapy in severe hypoxemic respiratory failure due to pneumonia

Helmet Continuous Positive Airway Pressure vs Oxygen Therapy To Improve Oxygenation in Community-Acquired Pneumonia

Association of Noninvasive Oxygenation Strategies With All-Cause Mortality in Adults With Acute Hypoxemic Respiratory Failure

Lymphopenia in severe coronavirus disease-2019 (COVID-19): Systematic review and meta-analysis

Diagnosis and treatment of adults with community-acquired pneumonia. An official clinical practice guideline of the american thoracic society and infectious diseases society of America

Siempos, I.I. Effect of timing of intubation on clinical outcomes of critically ill patients with COVID-19: A systematic review and meta-analysis of non-randomized cohort studies

COVID-19 Lombardy ICU Network. Baseline Characteristics and Outcomes of 1591 Patients Infected With SARS-CoV-2 Admitted to ICUs of the Lombardy Region