Helmet Continuous Positive Airway Pressure in COVID-19 Related Acute Respiratory Distress Syndrome in Respiratory Intermediate Care Unit

Research Article

Austin J Infect Dis. 2021; 8(4): 1061.

Helmet Continuous Positive Airway Pressure in COVID-19 Related Acute Respiratory Distress Syndrome in Respiratory Intermediate Care Unit

Piluso M¹*, Scarpazza P¹, Oggionni E¹, Celeste A¹, Bencini S¹, Bernareggi M¹, Bonacina C¹, Cattaneo R¹, Melacini C¹, Raschi S¹, Usai P¹, Sioli P², Bellini R³, Salandini MC³, Iozzia M¹, Di Franco G¹ and D’Arcangelo F¹

¹Division of Respiratory Diseases with Intermediate Respiratory Intensive Care Unit, Vimercate Hospital, Vimercate, Monza e Brianza, Italy

²Department of Cadiopulmonary and Neuromotor Rehabilitation, Seregno Hospital, Seregno, Monza e Brianza, Italy

³Department of Surgery, General Surgery Division, Vimercate Hospital, Vimercate, Monza e Brianza, Italy

*Corresponding author: Piluso M, Respiratory Diseases and Respiratory Intermediate Care Unit, Vimercate Hospital, via SS. Cosma e Damiano 10, 20871 Vimercate (MB), Italy

Received: September 20, 2021; Accepted: October 27, 2021; Published: November 03, 2021

Abstract

Background: The SARS-CoV-2 outbreak spread in Lombardy Region (Italy) rapidly saturating intensive care unit beds, forcing the application of noninvasive respiratory support in RICU.

Objectives: We aimed to analyze the effects of helmet CPAP in COVID19- related ARDS in RICU. The primary outcome was CPAP failure, defined as the occurrence of either intubation or death due to any cause during RICU stay; the secondary one was the identification of factors related to patients’ prognosis.

Methods: 150 consecutive patients with ARDS due to COVID-19 and referred to Vimercate Hospital (MB) between March and May 2020 were enrolled. All patients were treated with helmet CPAP. Demographics, clinical and laboratory tests and blood gas analysis were collected.

Results: Patients had a mean (SD) age of 62 (±11) years. The worst PaO2/ FiO2 ratio during continuous positive airway pressure stratified the subjects in mild (26/150), moderate (39/150) and severe (85/150) ARDS. Most of patients were treated with systemic corticosteroids (79%). 93 patients (62%) were successfully treated while 57 (38%) failed; of the latter, 32 patients were transferred in the intensive care unit to receive invasive mechanical ventilation. Dimer test and ferritin at admission, use of steroids, P/F in oxygen at admission and age were independently associated with CPAP failure. The severity of ARDS and the use of steroids strongly correlate with clinical outcomes. Mortality rate in our cohort of patients was 28%.

Conclusions: The application of helmet CPAP in RICU and the administration of corticosteroids in COVID19-related ARDS are associated with satisfactory clinical outcomes.

Keywords: Helmet CPAP (Continuous Positive Airway Pressure); COVID-19; ARDS (Acute Distress Respiratory Syndrome); RICU (Respiratory Intermediate Care Unit); Corticosteroid

Abbreviations

CPAP: Continuous Positive Airway Pressure; COVID-19: Coronavirus Disease-19; ARDS: Acute Distress Respiratory Syndrome; RICU: Respiratory Intermediate Care Unit; P/F: PaO2/ FiO2 ratio; PaO2: Arterial Oxygen Tension; FiO2: Inspiratory Oxygen Fraction; WHO: World Health Organization; ICU: Intensive Care Unit; NIV: Non-Invasive Ventilation; IMV: Invasive Mechanical Ventilation; HFNC: High Flow Nasal Cannula; PEEP: Positive End-Expiratory Pressure; BPM: Breaths Per Minute; DNI: Do-Not- Intubate; SD: Standard Deviations; IQR: Interquartile Ranges; CT: Computed Tomography; RCT: Randomized Controlled Trial; BMI: Body Mass Index; COPD: Chronic Obstructive Pulmonary Disease; APACHE: Acute Physiology and Chronic Health Evaluation; IL: Interleukin; HR: Hazard Ratio; CI: Confidence Interval

Introduction

In December 2019, a novel coronavirus–related pneumonia has been firstly reported in the city of Wuhan, China [1]. The World Health Organization (WHO) declared the outbreak of a pandemic on 11th March 2020 [2].

Although in most cases it causes very mild symptoms, approximately 20% of patients develops significant respiratory disease, with bilateral interstitial pneumonia [3]. Acute Respiratory Distress Syndrome (ARDS) is a major complication of COVID-19 that occurs in 20-41% of patients with severe disease [4].

It is well known that, despite advances in supportive care, mortality rates of ARDS in Intensive Care Unit (ICU) are still high (35-40%) and increase with the severity of hypoxemia (27% in mild, 32% in moderate, 45% in severe ARDS as defined by the Berlin definition) [5].

The frequent lack of ICU beds has pushed the authorities to create respiratory intermediate care units (RICU), in order to face the increasing number of patients with ARDS needing respiratory support and monitoring [6].

Non-Invasive Ventilation (NIV) is a reasonable initial approach in less severely ill patients with ARDS [7]; the beneficial role of Continuous Positive Airway Pressure (CPAP) in acute, non-hypercapnic respiratory insufficiency is well known in terms of improvement in oxygenation and reduction in endotracheal intubation rate as compared to oxygen therapy, even if no difference in outcomes is demonstrated [8,9].

One of the main issues in CPAP treatment failure is the interface, as technical problems and compliance often represent a major concern; in this perspective, the helmet has been proposed, as an alternative to the facemask and evidence of its superiority is reported [10].

In ARDS due to COVID-19 infection treated with invasive mechanical ventilation (IMV) in ICU, prognosis seems to be even worse than non COVID-19 related ARDS, as reported in numerous recent published data: a 28-day mortality exceeding 60% emerges in Wuhan City Hospital [11], at least 50% in Seattle region [12] and, from the experience in New York, 76.4% in the 18-to-65 and 97.2% in older than 65 groups respectively [13].

In Lombardy, northern Italy, the COVID-19 pandemic has led to a substantial increase in the number of patients admitted to hospital with ARDS, causing a stressful burden on the healthcare system, particularly on ICUs, with almost 10% of the hospitalized COVID-19 patients needing invasive respiratory assistance, rapidly saturating resources and the availability of ICU beds [6].

To avoid aqueous droplets dispersion during active disease, the use of high flow nasal cannula (HFNC) oxygen therapy and NIV is generally not recommended [14]. Nevertheless, in a recent overview of the indications for the healthcare workers’ protection from SARSCoV- 2 infection, Ferioli and co-workers showed how the helmet have negligible air dispersion with a tight air cushion around the neckhelmet interface [15].

The aims of our study were the evaluation of helmet CPAP efficacy in COVID19-related ARDS in our RICU and the identification of factors related to patients’ prognosis.

Bed’s quick filling and high mortality rate of these patients in ICU led to the need of treating this disease with a non-invasive ventilation approach in a proper specialized environment (RICU).

Materials and Methods

During COVID-19 pandemic, 230 patients were admitted in the Pulmonology Division at Vimercate Hospital, Lombardy, Italy, between March and May 2020 with a diagnosis of COVID-19 pneumonia, defined as the presence of interstitial pulmonary infiltrates and a positive SARS-CoV-2 nasal-pharyngeal swab. Of these, 150 were enrolled in our study, selected for having ARDS criteria satisfied during hospital-stay as defined by the Berlin definition (P/F ≤300 with PEEP ≥5cm H2O); all of the 150 patients were treated with helmet CPAP in RICU; patients aged more than 80 and those who never developed ARDS were excluded.

In our Hospital the ad hoc RICU dedicated to patients with COVID-19-related severe respiratory failure (implemented with 50 beds) was characterized by negative pressure rooms, continuous multiparametric monitors, access to high flow oxygen and air source with blender systems to obtain adequate values of delivered FiO2, onsite life support and intubation kit, a nurse: patient ratio between 1:6- 1:10 and active full day shift run by pulmonologists.

This is a monocentric observational study. The primary outcome was CPAP failure, defined as the occurrence of either intubation or death due to any cause during RICU stay; the secondary one was the identification of factors related to patients’ prognosis.

All patients included in the study were hemodynamically stable, had a normal Glasgow Coma Scale score, did not show multiorgan system failure, acidosis or hypercapnia [16], and were poor respondent to treatment with high flows oxygen therapy with Venturi mask or non-rebreathing oxygen mask (SpO2 < 92%, respiratory rate > 24 Breaths Per Minute (BPM), paCO2 <35mmHg, thoraco-abdominal dyssychrony).

Indications to intubation were a reduced level of consciousness, altered breathing mechanic, hypoxiemia and hemodynamic instability.

The Do-Not-Intubate (DNI) order was the decision to withhold intubation and to use CPAP as “ceiling” treatment considering patient’s characteristics and the reduced availability of ICU beds. “DNI” criteria was considered only in the cases needing intubation by intensivists, not at the admission.

Helmet CPAP was delivered with pressure between 7.5-15 cm H2O (mean pressure 13 ± 1.91) and FiO2 variable between 50 and 99% (mean FiO2 81% ± 12.37) with a target oxygen saturation of 92% or more. During helmet CPAP therapy patients were moved, when feasible, into prone position, which was maintained for a minimum duration of 2 hours. During each blood, gas control the PaO2/FiO2 ratio was re-calculated. The most critical patients were selected by pulmonologists and evaluated by intensivists to decide ICU transfer.

Qualitative and quantitative variables were summarized with frequencies (absolute and relative, percentage) and central tendency (means and medians) and variability (standard deviations, SD, and interquartile ranges, IQR) indicators, depending on their parametric distribution. A chi-squared or Fisher exact test was computed for qualitative variables; Student t test or Mann Whitney was used for quantitative variables with a parametric or non-parametric distribution, respectively. Survival analysis were performed with Kaplan – Meier method. A Cox proportional hazards regression analysis was carried out to assess the relationship between the composite primary outcome and independent variables. A twotailed p-value less than 0.05 was considered statistically significant. Statistical computations were performed with R Studio.

Results

Demographics and patients’ characteristics are summarized in Table 1.

Table 1: Baseline characteristics, hospital treatment and outcomes of the study population according to CPAP failure or success.





  

    
    
Total 

    
Success 

    
Failure 

    
p-value 

  

  

    
Number of patients 

    
150 

    
93 (62%) 

    
57 (38%) 

    
- 

  

  

    
Demographics 

  

  

    
Meanage 

    
62 ± 11 

    
60 ± 11 

    
65 ± 9 

    
0.005** 

  

  

    
Male sex 

    
123 (82%) 

    
75 (81%) 

    
48 (84%) 

    
0.739 

  

  

    
Neversmokers 

    
104 (69%) 

    
69 (74%) 

    
35 (61%) 

    
0.143 

  

  

    
BMI = 24.5 

    
48 (32%) 

    
33 (35%) 

    
15 (26%) 

    
0.323 

  

  

    
Comorbidities and prognostic    score 

  

  

    
Hypertension 

    
72 (48%) 

    
43 (46%) 

    
29 (51%) 

    
0.701 

  

  

    
Ischemiccardiacdisease 

    
15 (10%) 

    
6 (6%) 

    
9 (16%) 

    
0.116 

  

  

    
Cardiovasculardiseases 

    
21 (14%) 

    
9 (10%) 

    
12 (21%) 

    
0.088 

  

  

    
Hypercholesterolemia 

    
28 (19%) 

    
12 (13%) 

    
16 (28%) 

    
0.036* 

  

  

    
Diabetes 

    
11 (7%) 

    
6 (6%) 

    
5 (9%) 

    
0.749 

  

  

    
Tumors 

    
6 (4%) 

    
1 (1%) 

    
5 (9%) 

    
0.030* 

  

  

    
COPD/asthma 

    
14 (9%) 

    
5 (5%) 

    
9 (16%) 

    
0.044* 

  

  

    
Chronicrenalfailure 

    
1 (0.7%) 

    
0 

    
1 (1.8%) 

    
- 

  

  

    
APACHE II score 

    
8.6 (2.1) 

    
8.3 (2.2) 

    
9.1 (1.8) 

    
0.015* 

  

  

    
Pharmacological treatment    duringhospitalization 

  

  

    
Antivirals 

    
104 (69%) 

    
61 (66%) 

    
43 (75%) 

    
0.277 

  

  

    
Remdesivir 

    
4 (2.7%) 

    
2 (2.2%) 

    
2 (3.5%) 

    
0.635 

  

  

    
Azytromicin 

    
37 (25%) 

    
26 (28%) 

    
11 (19%) 

    
0.318 

  

  

    
Tocilizumab 

    
11 (7%) 

    
6 (6%) 

    
5 (9%) 

    
0.749 

  

  

    
Hydroxychloroquine 

    
145 (97%) 

    
91 (98%) 

    
54 (95%) 

    
0.369 

  

  

    
Steroids 

    
118 (79%) 

    
81 (87%) 

    
37 (65%) 

    
0.003** 

  

  

    
Heparin 

    
136 (91%) 

    
87 (94%) 

    
49 (86%) 

    
0.151 

  

  

    
Outcomes 

  

  

    
DNI order 

    
22 (15%) 

    
1 (1%) 

    
21 (37%) 

    
- 

  

  

    
Intubation 

    
32 (21%) 

    
0 (0%) 

    
32 (56%) 

    
- 

  

  

    
Survived 

    
108 (72%) 

    
93 (100%) 

    
15 (26%) 

    
- 

  

  

    
Blood tests 

  

  

    
Dimer test (admission) (ng/mL)

    
4365 ± 9423 

    
1617 ± 4685 

    
7113 ± 13699 

    
0.007** 

  

  

    
Dimer test (worst)(ng/mL)

    
8258 ± 12382 

    
3130 ± 6249 

    
13386 ± 16848 

    
- 

  

  

    
Ferritin (admission) (ng/mL) 

    
2193 ± 1943 

    
1378 ± 984 

    
3007 ± 2613 

    
<0.001*** 

  

  

    
Ferritin (worst)(ng/mL) 

    
2750 ± 3115 

    
1772 ± 1810 

    
4362 ± 4039 

    
- 

  

  

    
IL-6 (admission) (pg/mL) 

    
67 ± 83 

    
41 ± 55 

    
93 ± 103 

    
0.06 

  

  

    
IL-6 (worst)(pg/mL) 

    
362 950 ± 338.2 

    
111 ± 196 

    
613 ± 1366 

    
- 

  

  

    
CPAP treatment 

  

  

    
PEEP 

    
13 ± 1.91 

    
12 ± 1.90 

    
14 ± 1.65 

    
<0.001*** 

  

  

    
FiO2 

    
81 ± 12.37 

    
77 ± 12.6 

    
88 ± 8.66 

    
<0.001*** 

  

  

    
Days of CPAP 

    
8 ± 5.00 

    
9 ± 5.1 

    
6 ± 4.1 

    
- 

  

  

    
P/F (in oxygen) 

    
132 ± 64.4 

    
144 ± 68.2 

    
114 ± 53.3 

    
0.004** 

  

  

    
First P/F (in CPAP)

    
218 ± 105.8 

    
235 ± 109 

    
189 ± 95 

    
0.008** 

  

  

    
Worst P/F (in CPAP)

    
123 ± 73.8 

    
156 ± 74.9 

    
68 ± 16.6 

    
<0.001*** 

  

  

    
Number of pronedpts 

    
73 (49%) 

    
37 (40%) 

    
36 (63%) 

    
0.824 

  

  

    
P/F post-pronation (in CPAP)

    
242 ± 119.6 

    
271 ± 120 

    
184 ± 96.8 

    
<0.001*** 

  

  

    
Data    are presented as n (%), mean ± standard deviation, unless otherwise stated.    BMI: Body Mass Index; COPD: Chronic Obstructive Pulmonary Disease; APACHE:    Acute Physiology and Chronic Health Evaluation; DNI: Do-Not-Intubate; IL:    Interleukin; PEEP: Positive End-Expiratory Pressure; P/F: PaO2/FiO2    Ratio; PaO2: Arterial Oxygen Tension; FiO2: Inspiratory    Oxygen Fraction; CPAP: Continuous Positive Airway Pressure. Besides; *: Statistically    Significant p-Value < 0.05; **: Statistically Significant p-Value <    0.01; ***: Statistically Significant p-Value < 0.001. 

  










Table 1: Baseline characteristics, hospital treatment and outcomes of the study
population according to CPAP failure or success.

At admission, most patients presented an ARDS pattern: ARDS was mild in 50 (33%), moderate in 60 (40%) and severe in 15 (10%). There is a small number of patients enrolled (25/150, 17%) who did not fulfill ARDS criteria at admission but, as shown in Figure 4, all of them developed ARDS during hospital stay (we define this initial condition as “pre-ARDS”).

Most of the patients were treated with systemic corticosteroids (79%, receiving methylprednisolone at a dose of 1 mg/kg a day for 10 days than gradually reduced). Other drugs administered are summarised in Table 1.

Ninety-three patients (62%) were successfully discharged without need of invasive support, while in 57 subjects (38%) non-invasive treatment failed; of those, 25 died without intubation while 32 were transferred in ICU to receive IMV. Between the two groups (success vs failure), we found significant statistical difference in mean age (60 ± 11 vs. 65 ± 9 respectively, p-value 0.005).

Of the 26 patients who died in the RICU ward: 21 with a DNI order and 5 with sudden deaths (2 massive pulmonary thromboembolism, 1 sudden cardiac arrest, 1 acute cardiac ischemic attack, 1 cerebral stroke after ICU discharge).

Complications developed during RICU stay included: 4 supraventricular tachyarrhythmias, 5 Pulmonary Embolisms (PE) (2 fatal and 3 non-fatal), 5 thrombosis (1 fatal stroke, 1 cerebral transient ischemic attack, 1 popliteal thrombosis, 1 fatal cardiac ischemic attack, 1 thrombosis in descending aorta), 1 fatal diffuse intravascular coagulation, 1 acute renal failure, 2 bleedings treated with embolization, 2 pneumothoraxes (1 fatal and 1 non-fatal) and 2 episodes of pneumomediastinum (1 fatal and 1 non-fatal), 1 cardiac arrest with possible non demonstrated PE.

The PaO2/FiO2 ratio in CPAP at presentation is significantly different between the two groups, as lower P/F are associated with a worse prognosis (mean P/F 189 vs 235, p-value 0.008) and this is even more evident if we consider the worst P/F in CPAP during hospital staying (mean value of 68 vs 156, p-value < 0.001).

The severity of ARDS at admission strictly correlates with the clinical outcome (p-value 0.0047) (Figure 1).

Figure 1: Survival analysis according to ARDS class.

    

    
    

    

    Figure 1: Survival analysis according to ARDS class.

The most important inflammatory biomarkers collected at admission were higher in those patients who failed CPAP. We have defined 4 levels for ferritin (1: ≤1000 ng/mL; 2: 1000-1500; 3: 1500-2000; 4: >2000) and 3 for dimer-test values (1: ≤ 500 ng/mL; 2: 500-1000; 3: >1000) considering the two biomarkers as qualitative variables (Figure 2). We found a statistically significant difference between the surviving curves in both cases as shown in Figure 2.

Figure 2: Survival analysis according to ferritin and dimer-test classes.

    

    
    

    

    Figure 2: Survival analysis according to ferritin and dimer-test classes.

We finally searched for a correlation between the P/F ratio and the value of the two biomarkers recorded and we observed a prognostic relevance in dimer-test only: an increase in dimer-test class is associated to a lower P/F.

In our study 96 patients (almost 65%) were put in prone position during CPAP therapy (not applied only if not considered necessary; 58/96 patients were compliant to pronation). If we consider the P/F ratio after 1 hour of prone position, a positive prognostic role seems to emerge in treated patients (mean P/F 271 vs. 184) but this evidence is lacking in the multivariate analysis.

Another parameter analyzed was steroids use. Steroids were more frequently used in the “success” group (87% vs. 65%, p-value 0.003). The use of steroids strongly correlated with the clinical outcome (p < 0.0001) also stratifying for ARDS severity classes. The use of systemic steroids increased the probability of a positive outcome even compared to patients belonging to a better ARDS class but not receiving the drug (p-value: <0.0001) (Figure 3). According to the Cox model (Table 2), expressing the prognostic relevance of a number of variables in a multivariate analysis (Dimer test and ferritin at admission, use of steroids, P/F in oxygen at admission and age), a 0.24 coefficient emerges in the group treated with steroids, meaning that, maintaining consistent all other parameters, being treated with steroids reduces helmet CPAP failure risk of 76%. In addition, in patients failing the treatment, we observe an increase in the risk of failure of 4% for each additional year of age.

Table 2: Multivariate analysis of factor associated with helmet CPAP failure.





  

    
Factor 

    
p-Value 

    
Statistically significant

    
HR=exp(coef) 

    
95% CI 

  

  

    
Dimer test (admission) 

    
0.00230 

    
** 

    
1.000 

    
1.000;1.000 

  

  

    
Ferritin(admission) 

    
0.03973 

    
* 

    
1.000 

    
1.000;1.000 

  

  

    
Steroids 

    
0.00048 

    
*** 

    
0.24 

    
0.108;0.353 

  

  

    
P/F in oxygen at admission

    
0.00393 

    
** 

    
0.99 

    
0.984;0.997 

  

  

    
Age 

    
0.02558 

    
* 

    
1.04 

    
1.005;1.083 

  

  

    
HR: Hazard    Ratio; HR = 1 no effect, HR <1 reduction of risk, HR>1 increase of    risk, 95% CI = 95% Confidence Interval. 

  










Table 2: Multivariate analysis of factor associated with helmet CPAP failure.

Figure 3: Survival analysis according to steroid therapy.

    

    
    

    

    Figure 3: Survival analysis according to steroid therapy.

Discussion

The use of NIV in “de novo” ARDS has received a growing interest over the last decades in order to avoid complications related to IMV. Until the outbreak of COVID-19 pandemic, evidence suggested to limit this treatment to carefully selected patients with mild to moderate ARDS (failure in fact is higher than 50% in severe ARDS) and applied in experienced centers with close monitoring of blood gases and respiratory mechanics in order to avoid delayed intubation in case of failure [17,18].

It is well known that in ARDS the application of a positive end expiratory pressure (PEEP) recruits non aerated alveoli in dependent pulmonary regions, stabilizes the airways and reduces the inhomogeneity of lung volume distribution [16]. PEEP can be applied to spontaneous breathing patients in the form of CPAP [19] with an increase in functional residual capacity and improvement of oxygenation [8,20]. The benefits of prone position in non-COVID-19 related ARDS treated with IMV in terms of improved oxygenation and reduced mortality are well-know [21] and is due to improved ventilation–perfusion matching and recruitment of more gasexchange- efficient dorsal regions [22,23].

A large number of COVID-19 patients in early phase of the disease present bilateral ground glass opacities at Computed Tomography (CT) [24], with an atypical, recently termed “L-type” ARDS, characterized by severe hypoxemia and a relatively high compliance [25,26]; the greater part of the lung is still not affected, which explains the low pulmonary elastance, but in affected areas the vessels are maximally dilated with a postulated loss of hypoxic vasoconstriction and a secondary increase in shunt volume; due to the preserved lung compliance, however, the patient is able to increase ventilation, often not perceiving dyspnoea despite hypocapnia and simultaneous significant hypoxemia [27]. In this scenario, most patients successfully proceed with helmet CPAP. Gattinoni and coworkers stress the idea that, in this first stage of disease, improvement in oxygenation by application of PEEP or pronation is mainly not due to the recruitment mentioned above, but to the redistribution of perfusion in the lungs [25,26].

In many cases this is followed by a progressive worsening of hypoxemia, which perhaps corresponds to the “cytokine storm” typical of COVID-19 infection and characterized by elevated concentration of ferritin, interleukin-6 and D-dimers: a severe primarily local inflammation that can lead to widespread damage to the lung parenchyma towards a so called “H type” ARDS [25,26] with low compliance as a result of increasing oedema and atelectasis with high right to left shunt, and associated to an extensive densification on the CT, similar to those seen in typical ARDS.

A hypercoagulability state, with consequent pulmonary microvascular coagulation [28], is also well-know.

The RECOVERY TRIAL [29], a large multicenter Randomized Controlled Trial (RCT), demonstrated that patients receiving Dexamethasone 6 mg for 10 days had a death rate reduced by up to one-third with more prominent effect in-patient on mechanical ventilation. These results suggest that corticosteroids, acting as inflammatory attenuators, could slow down the transition from L- to H-ARDS pattern in COVID-19 pneumonia.

Our study shows good clinical outcomes in patients affected by COVID19-related ARDS treated with helmet CPAP in RICU and a significant improvement of prognosis in subjects who received corticosteroids. Dimer test and ferritin at admission, use of steroids, P/F in oxygen at admission and age all influence the overall outcome by expressing the entity of the cytokines storm on one side (the two biomarkers) and the severity of respiratory compromission on the other (P/F ratio). As previously mentioned, in patients failing the treatment, an increase in the risk of failure of 4% is observed for each additional year of age.

Many management models for non-invasive treatment of COVID-19 ARDS in RICU have been proposed in literature [14,33,34].

Aliberti and co-workers [30] have recently described, in a multicentric study, a group of patients with COVID-19 pneumonia in RICU; despite a lower level of disease severity (ARDS criteria were not needed) the study shows worse outcomes; we bring forth the hypothesis that a more diffuse use of steroids in our center (79% versus 46% of patients treated) could play a role in this regard.

The other two trials conducted on the application of helmet CPAP in COVID19 hypoxic pneumonia were carried out in different specialistic units in a multicentric study [35] and in general wards [36].

In detail, a multicentric observational study published by Franco and co-workers [35] sustained the feasibility of non-invasive respiratory support including HFNC, CPAP and NIV outside the ICU, describing favorable outcomes in a cohort of 670 patients. Considering the CPAP group only (n=330), the failure rate (IMV/ death) was 47.3% (vs. 38% in our study), although the percentage of patients treated with steroids was similar but mean age was higher (70.3 years).

Also in another, recent observational study conducted by Coppadoro and co-workers [36] in general ward, the risk of clinical failure (always defined as the occurrence of either intubation or death) in patients treated with helmet CPAP was 48%. Furthermore, 29% of patients had hypoxic pneumonia without ARDS.

We may therefore assume that the proper management in a specialistic intermediate care setting (RICU) affects the prognosis of patients with COVID-19 ARDS; a constant clinical and parametric monitoring during hospitalization by the pulmonologist in RICU is critical in promptly recognition and treatment of every possible worsening in clinical conditions, an event that can arise even later in the course of the disease (Figure 4d). In fact, the majority of patients move to a worse ARDS class during hospitalization (“V-shape” trend of hypoxemia in successful patients) (Fig. 4d). This explains why the APACHE II (“Acute Physiology and Chronic Health Evaluation II”) score, by definition an admission score, is not predictive of mortality in these patients.

Figure 4: Distribution of the study population according to ARDS severity at admission (a) and during disease evolution (b) focusing on shifts in ARDS classes (c). Pre-ARDS: P/F ratio >300; Mild: 200 < P/F ratio ≤ 300; Moderate: 100 < P/F ratio ≤ 200, Severe: P/F ratio ≤ 100.(d) Trend of P/F ratio in the success group over time of the disease (“V-shaped” trend). Note: Time 1: initial P/F ratio in CPAP; Time 2: worst P/F ratio in CPAP; Time 3: better P/F ratio in CPAP. P/F ratio was calculated as mean in success group. P/F: PaO2/FiO2Ratio; PaO2: Arterial Oxygen Tension; FiO2: Inspiratory Oxygen Fraction; CPAP: Continuous Positive Airway Pressure.

    

    
    

    

    Figure 4: Distribution of the study population according to ARDS severity at admission (a) and during disease evolution (b) focusing on shifts in ARDS classes (c).
Pre-ARDS: P/F ratio >300; Mild: 200 < P/F ratio ≤ 300; Moderate: 100 < P/F ratio ≤ 200, Severe: P/F ratio ≤ 100.(d) Trend of P/F ratio in the success group over
time of the disease (“V-shaped” trend).
Note: Time 1: initial P/F ratio in CPAP; Time 2: worst P/F ratio in CPAP; Time 3: better P/F ratio in CPAP. P/F ratio was calculated as mean in success group. P/F:
PaO2/FiO2Ratio; PaO2: Arterial Oxygen Tension; FiO2: Inspiratory Oxygen Fraction; CPAP: Continuous Positive Airway Pressure.

Prone position determined in all our patients a meaningful increase in P/F value, although this improvement does not represent a good prognostic factor in itself. As far as we have observed, this response provided a delay in the need of intubation and mechanical ventilation so giving the patient a chance to overcome the critical phase of ARDS.

We want to emphasize the fact that, despite the extremely low values of worst PaO2/FiO2 ratio recorded (26/150 mild ARDS; 39/150 moderate ARDS; 85/150 severe ARDS), 62% of our patients were finally discharged without need of IMV. If we divide the subjects in the different severity stages of ARDS we can appreciate that in mild patients we have a success of 100%, in moderate patients of 97% (only 1 patient failing, died in ICU with pneumomediastinum) and, in severe patients, of 34%. In addition, of the 56 patients in the “severe ARDS” group, 31 were transferred to ICU and, of these, 15 finally survived, with a mortality rate of 48%, in agreement with the mortality rate described for patients with severe ARDS in ICU (45%). We underline that, in our group of patients, mortality rates in mild and moderate ARDS are inferior to those reported in literature [5,17], considering the different features of patients admitted to ICUs (i.e. multiorgan failure).

Furthermore, our data seem to exclude a possible delay in intubation timing due to CPAP treatment and this is remarked by a mortality rate of almost 50% in patients finally admitted to ICU, substantially comparable with 55% of all Lombardy ICUs [31].

In addiction we must remember that, even if delayed intubation is associated with increased mortality in patients with acute respiratory failure [32], it is also true that premature intubation in patients in whom non-invasive respiratory support is adequate exposes patients to potentially unnecessary risks associated with IMV [10,37].

Our study has several limitations that can limit the generalizability of our results, among them the relatively small number of patients enrolled, the lack of control group and, at least, the peculiar setting of the study, characterized by an emergency pandemic situation with continuous changes in scientific evidence and ongoing shifts in clinical indications.

Conclusion

Our study suggests satisfactory clinical outcomes with helmet CPAP in COVID-19 ARDS in RICU. The proper management in a specialistic intermediate care setting (RICU) may affect the prognosis of these patients. We observed a significant improvement of prognosis in subjects who received corticosteroids. The severity of acute respiratory distress syndrome strongly correlates with clinical outcomes. Finally, dimer test and ferritin at admission and age all influence the overall outcome.

To our knowledge, till now this is the only study entirely carried out in RICU on patients with COVID-19 related ARDS treated with helmet CPAP.

Nevertheless, further multicentric and more numerous trials are needed in order to confirm these data.

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Citation: Piluso M, Scarpazza P, Oggionni E, Celeste A, Bencini S, Bernareggi M, et al. Helmet Continuous Positive Airway Pressure in COVID-19 Related Acute Respiratory Distress Syndrome in Respiratory Intermediate Care Unit. Austin J Infect Dis. 2021; 8(4): 1061.