ORIGINAL ARTICLE


https://doi.org/10.5005/jp-journals-10071-24155
Indian Journal of Critical Care Medicine
Volume 26 | Issue 3 | Year 2022

Comparison of Effect of Non-invasive Ventilation Delivered by Helmet vs Face Mask in Patients with COVID-19 Infection: A Randomized Control Study

Anupriya Saxena1https://orcid.org/0000-0002-6203-3962, Nazia Nazir2https://orcid.org/0000-0001-6950-2111, Ruchi Pandey3https://orcid.org/0000-0002-4653-6738, Savita Gupta4https://orcid.org/0000-0002-3104-7368

1Anaesthesia, Government Institute of Medical Sciences, New Delhi, India

2Anesthesiology and Critical Care, Government Institute of Medical Sciences, Greater Noida, Uttar Pradesh, India

3Community Medicine, Government Institute of Medical Sciences, Greater Noida, Uttar Pradesh, India

4Department of Anaesthesia, Government Institute of Medical Sciences, Greater Noida, Uttar Pradesh, India

Corresponding Author: Anupriya Saxena, Anaesthesia, Government Institute of Medical Sciences, New Delhi, India, Phone: +91 9953090044, e-mail: anupriya.pmch@gmail.com

How to cite this article: Saxena A, Nazir N, Pandey R, Gupta S. Comparison of Effect of Non-invasive Ventilation Delivered by Helmet vs Face Mask in Patients with COVID-19 Infection: A Randomized Control Study. Indian J Crit Care Med 2022;26(3):282-287.

Source of support: Nil

Conflict of interest: None

ABSTRACT

Background and aims: We compared the effectiveness of non-invasive ventilation (NIV) provided by helmet mask vs face mask in patients with COVID-19.

Methods and materials: Between March and May 2021, a single-center, prospective, open-label randomized controlled research was undertaken. Sixty patients were randomly assigned to one of two groups based on the NIV delivery interface. In group I (n = 30) helmet mask was used and in group II (n = 30) face mask was used for delivery of NIV. The proportion of patients in each group who required endotracheal intubation was the primary outcome. The duration of NIV, length of stay in the intensive care unit (ICU), hospital mortality, ratio of partial pressure of oxygen to fraction of inspired oxygen (PaO2/FiO2), respiratory rate, patient comfort, and complications were all documented as secondary outcomes. Results: In both groups, demographics, clinical characteristics, and treatment received were comparable. Around 10% of patients in the helmet mask group were intubated, while 43.3% of patients in the face mask group were intubated (p = 0.004). The two groups demonstrated similar hemodynamic patterns. The use of a helmet mask, on the other hand, resulted in enhanced oxygenation (263.57 ± 31.562 vs 209.33 ± 20.531, p = 0.00), higher patient satisfaction (p = 0.001), a lower risk of complications, and a shorter NIV and ICU stay (p = 0.001) (4.53 ± 0.776 vs 7.60 ± 1.354, p = 0.00 and 6.37 ± 0.556 vs 11.57 ± 2.161, p = 0.00).

Conclusion: Helmet mask could be a reliable interface for delivery of NIV in COVID-19 and results in a lower rate of endotracheal intubation, better oxygenation with greater patient comfort and shorter ICU stay as compared to face mask used for NIV.

Keywords: COVID-19, Critical care unit, Face mask, Helmet continuous positive airway pressure, Hypoxia, Non-invasive ventilation.

INTRODUCTION

The coronavirus disease-2019 (COVID-19) outbreak has affected millions of people all over the world. Although the majority of patients have a favorable prognosis, infection can cause acute respiratory distress syndrome (ARDS), which has a high risk of morbidity and mortality. According to oxygenation criteria, the prevalence of ARDS in COVID-19 varies from 20 to 67% in hospitalized patients and is 100% in patients who get intubated.1

Non-invasive ventilation (NIV) may play a critical role in managing patients with respiratory failure secondary to COVID-19 infection. Studies have reported that NIV has effectively prevented the need for intubation in many of the patients treated.2 Hence in COVID-19 patients, many appeared to have shifted away from early intubation and toward NIV.

The helmet mask, major and evidence-based airway equipment, was first introduced utilizing hyperbaric oxygen treatment device modifications, and then utilized for NIV.3 Its use was also prompted by concerns about poor patient compliance and the risk of aerosolization from older forms of NIV. Although it is not intended to replace endotracheal intubation and mechanical ventilatory support in severely ill patients, research from Italy and China shows that COVID-19 patients managed with it may have a better outcome.4 However, these benefits have not yet been confirmed in a randomized control trial. As a result, this study was carried out to quantify the prospective benefits of a helmet mask over a face mask NIV in COVID-19 patients with ARDS.

When a helmet mask is utilized as an interface for providing NIV, we hypothesize that it can result in lesser rate of mechanical ventilation and better oxygenation than when a face mask is used as an interface for providing NIV.

METHODS AND MATERIALS

From March to May 2021, we conducted an open-label, single-center, randomized controlled research comprising consecutive patients hospitalized to our COVID ICU. The Helsinki Declaration of 1975 defined Ethical Principles for Medical Research with Human Subjects, which were followed in this clinical investigation (revised 2013).

The institutional ethics committee authorized the protocol, which was then registered on ctri.nic.in. Participants signed a written informed consent form. Patients between the age-group of 18-80 years who were conscious and alert, requiring NIV as a part of treatment of ARDS due to COVID-19 were eligible for enrolment.

Those requiring emergency intubation or cardiopulmonary resuscitation, respiratory arrest, hemodynamic instability, encephalopathy, respiratory failure due to neurologic disease or patients with any pre-existing pulmonary pathology, patients at risk of aspiration, history of claustrophobia, facial deformities, presence of tracheostomy, raised intracranial pressure, pregnancy, or those who had refused endotracheal intubation were excluded from the study.

Assuming the failure rate (proportion of patients undergoing intubation) in the Face mask group to be 61% and in the helmet mask group to be 18%,5 the power the of study to be 80%, 95% confidence interval and enrolment ratio of 1:1, the sample size calculated was 19 in each group. In order to account for dropouts or refusals to participate in the study, a total of 30 participants in each group were enrolled (Sample Size Calculator by Kane SP. https://clincalc.com/stats/samplesize.aspx ClinCalc: https://clincalc.com/stats/samplesize.aspx).

Sixty-four patients were approached for the study, four patients denied consent so 60 patients were enrolled and randomized into two groups. A computer-generated randomization list was used for the randomization. NIV was administered to group I via a helmet mask interface (n = 30). NIV was administered to group II using a face mask interface (n = 30).

In both groups, the patients received NIV via a ventilator with a double-limbed circuit in bilevel pressure support mode (PM CARE CV 200 ventilator system).

The helmet mask (Innaccel SAANS CPAP Helmet) was a transparent hood made of polyvinyl chloride (latex free), fixed in place by straps attached to the two sides of the helmet under the arms with buckles adjusted to secure the helmet. The circumference of the patient's neck was measured, and the neck seal in the helmet mask was cut to achieve a tight but comfortable seal, resulting in a breathing circuit that was sealed off from the outside environment.

After ensuring the patient is wearing earplugs and hair cap, the expiratory limb was connected to the output port. The inspiratory limbs were connected to the input ports on either side. The plunger of the anti-asphyxiation valve was pulled till the helmet mask was inflated.

In group II, the appropriate size NIV non-vented face mask (large, medium, or small) was applied as per the facial contour of the patient. The size of the mask was measured from the level of the eye to the lower part of the lip. The dual limb circuit having separate inspiratory and expiratory limbs with a built-in exhalation port/ filter for removal of CO2 was used. After attaching the tubing to the ventilator, the mask was put over the face of the patient held with hand for some time till the patient got adjusted to the experience of NIV. The straps were then secured to the back of the head and on either side of the mask and was checked for any air leak. In both the groups, to avoid carbon dioxide rebreathing, an inspiratory fresh gas flow rate was set at more than 60 L/min in the ventilator.

Both groups used the same NIV titration technique. First, expiratory positive airway pressure (EPAP) was steadily increased to achieve an oxygen saturation (SpO2) of more than 92% keeping the inspired oxygen concentration of less than 60%. Inspiratory positive airway pressure was adjusted gradually in a step by increase of 2-3 cm H2O to reach a target respiratory rate of less than 30/min and tidal volume of >6 mL/kg without the use of accessory muscles of respiration. The ratio of NIV and high flow nasal cannula (HFNC) was set at 4:1 hour duration and was continued till the patient’s condition improved or worsened.

The time of NIV was gradually lowered in patients who showed improvement in oxygenation, and the patient was weaned to either an HFNC or a non-rebreathing mask. The weaning criteria were same for both groups: patient’s conscious, oriented with stable vitals, and absence of any tachypnea with respiratory rate lower than 25 breaths/min and no use of accessory muscles; arterial blood gas analysis (ABG) showing pH ≥7.35; partial pressure of oxygen (PaO2) ≥80 mmHg, SpO2 ≥94% with FIO2 ≤0.40, and EPAP of 5 cm water. Weaned patients were those who did not require NIV for more than 12 hours per day for 48 hours.

The patients deteriorating on NIV were considered for intubation as per the decision of the treating physician. The intubation criteria were the same for both the groups which included worsening neurological/ hemodynamic status, worsening PO2/FiO2 ratio, SpO2 <85%, and respiratory rate >35/min with the use of abdominal muscles, and ongoing hypoxia (PaO2) <45 mmHg, persistent hypercapnea (PCO2) >60 mmHg (on NIV with FiO2 100%), and patient uncooperative to the face mask or helmet mask. Following intubation, ARDS protocol was followed with lung-protective ventilation.

All patients had round-the-clock monitoring of electrocardiography, heart rate, blood pressure, and oxygen saturation. Blood gases and oxygenation status (PaO2/FiO2) were monitored 6 hourly in both the groups. The patients in both the groups received similar medical treatment as clinically appropriate.

Adverse events were pre specified to each group. In group I, skin ulceration at the neck seal, claustrophobia, noise disturbance, eye irritation, and helmet deflation were noted. In group II, the presence of facial ulcers was noted.

The patient’s comfort was measured using a visual analog scale (VAS).6 The VAS to analyze the patient comfort is a 100 mm long horizontal line. There are two predefined criteria of comfort: at the beginning (no comfort) and finish (maximum comfort). The patient expressed his level of comfort by putting a visible mark on this line. The point marked by the patient was converted to the same decimal number as was the millimeter marked on the line. The decimal number varied from 0 to 10. “Are you comfortable with the mask you’re wearing?” was the precise question. The form recording the VAS had detailed instructions written on it to elaborate the method to express the VAS.

The primary outcome noted was the proportion of patients who were intubated. The secondary outcomes were duration of NIV, ICU length of stay, in hospital mortality, PaO2/FiO2 ratio, and patient comfort and complications.

The results of the study were entered into the SPSS version 23 programmed and checked for discrepancies and outliers. The Shapiro Wilk Test was used to ensure that the data were normal. The mean and standard deviation were used to express quantitative variables with a normal distribution. Proportions or percentages were used to express the categorical variables. The proportions were compared using Chi-square or Fisher’s exact test, and the mean among both the intervention groups was comparatively analyzed using independent t-test. Odd’s ratio was used to assess the relationship. The Kaplan-Meier plot was generated using SPSS for survival analysis, and other graphs were created using Microsoft Excel version 16. In a Kaplan-Meier plot, the groups were compared using the Log Rank Test. In our investigation, a p value of less than equal to 0.05 was accepted as statistically significant.

RESULTS

Sixty-four patients were approached for the study between March and May 2021; four patients declined to participate, therefore sixty patients were enrolled in the study and were consequently randomized (Flowchart 1). Thirty patients were randomized to group I, the helmet mask, and 30 to group II, the face mask group.

Flowchart 1: Consort flow diagram of the study

The two study groups were comparable in terms of demographics, clinical features, comorbidities, baseline ABG, hemodynamic parameters, and Simplified Acute Physiology Score (SAPS II) on admission (Table 1).

Table 1: Baseline patient characteristics
Parameters Helmet mask*(N = 30) Face mask*(N = 30) p value
Gender, male 18 15 0.43
Age (years) 53.23 ± 9.179 52.56 ± 9.807 0.787
BMI (median IQR£) 24.5 (22-27) 23.5 (21-26) 1.000
Heart rate 87.03 ± 3.567 87.87 ± 3.371 0.124
Mean arterial blood pressure 83.63 ± 1.159 83.33 ± 1.709 0.429
PAO2/FIO2 155.33 ± 3.836 155.33 ± 2.975 0.946
Respiratory rate 32.77 ± 1.165 32.37 ± 1.066 0.171
SpO2§ 84.47 ± 1.479 84.6 ± 1.221 0.355
SAPS II¥ 32 ± 9 31 ± 9 0.668
Comorbidities, n (%)
Diabetes 10 (33.3) 12 (40) 0.592
Hypertension 12 (40) 14 (46) 0.602
Coronary artery disease 3 (10) 5 (16.6) 0.451
Chronic kidney disease 2 (6.6) 3 (10) 0.642
Chronic liver disease 1 (3.3) 0 0.493
*Values are presented as mean ± SD.
p value less than 0.05 is considered significant.
PaO2/FiO2, ratio of partial pressure of oxygen and fraction of inspiratory oxygen concentration;
§SpO2, saturation of oxygen;
£IQR, interquartile range;
¥Simplified Acute Physiology Score (SAPS) II calculator scores ranges from 0 to 163, with higher scores reflecting greater disease severity

The rate of endotracheal intubation rate was significantly more in the face mask group in comparison to the helmet mask group (43.3 vs 10%, p = 0.004) (Table 2). The Kaplan-Meier plot for intubation as an event showed significant difference in duration and proportion of participants undergoing intubation in both the study groups of this study (Fig. 1).

Table 2: Primary and secondary outcomes
Parameters Helmet mask, numbers (%) Face mask, numbers (%) p value Odds ratio
Endotracheal intubation 3/30 (10%) 13/30 (43.3%) 0.004 1.707-27.752
In-hospital mortality 4 (13.3%) 12 (40%) 0.020 1.23-15.60
Complications 3/30 (10%) 13/30 (43.3%) 0.004 1.707-27.752
p value less than 0.05 is considered significant

Fig. 1: Survival analysis

During the detailed analysis of the secondary outcomes, the helmet mask group patients had decreased duration of NIV and spent lesser days in ICU as compared to the patients in the face mask group (4.53 ± 0.776 vs 7.60 ± 1.354, p = 0.00 and 6.37 ± 0.556 vs 11.57 ± 2.161, p = 0.00, respectively).

The use of the helmet mask significantly improved the PaO2/FiO2 ratio throughout the clinical course of patients as compared to the face mask group (263.57 ± 31.562 vs 209.33 ± 20.531, p = 0.00; Fig. 2). Respiratory rate in the helmet group (22.53 ± 1.697) was also significantly lower than in the face mask group (27.37 ± 1.159) (p = 0.00). The patient comfort was more with the use of helmet mask than the face mask as detailed by the VAS score (7.20 ± 0.551 vs 4.53 ± 0.629, p = 0.00; (Fig. 3). No significant difference in heart rate and blood pressure was observed between the groups (Table 3).

Fig. 2: Graphical representation of PaO2/FiO2 ratio of both the interfaces

Fig. 3: Graphical representation of patient comfort on both the interfaces

Table 3: Primary and secondary outcomes
Parameters Helmet mask* Face mask* p value Mean difference Confidence interval
Duration of NIV 4.53 ± .77 7.60 ± 1.35 0.00 –3.06 –3.63–(–2.49)
Length of ICU stay 6.37 ± 0.55 11.57 ± 2.16 0.00 –5.200 –6.01–(–4.38)
PAO2/FIO2 263.57 ± 31.56 209.33 ± 20.53 0.00 54.233 40.47–67.99
Respiratory rate 22.53 ± 1.69 27.37 ± 1.15 0.00 –4.83 –5.58–(–4.08)
Heart rate 84.17 ± 1.48 83.93 ± 1.28 0.35 0.23 –0.48–0.95
Mean arterial blood pressure 82.6 ± 1.65 83.03 ± 1.09 0.46 –0.43 –1.15–0.29
Patient comfort 7.20 ± .551 4.53 ± .62 0.00 2.66 2.36–2.97
*Values are presented as mean and standard deviation.
p value less than 0.05 is considered significant;
PaO2/FiO2, ratio of partial pressure of oxygen and fraction of inspiratory oxygen

The in-hospital mortality was significantly less with the use of helmet mask NIV (13.3 vs 40%, p = 0.020). Thirteen patients (43.33%) in the face mask group developed ulceration over the bridge of the nose and cheeks as compared to three patients (10%) in the helmet mask group who complained of increased operating noise during helmet use (p = 0.004; Table 2).

DISCUSSION

NIV has been a well-established ventilatory support mode for patients with respiratory failure secondary to chronic obstructive pulmonary disease and acute cardiogenic pulmonary edema, but the evidence supporting its use in hypoxia secondary to ARDS is limited.7 Continuous positive airway pressure and NIV are routinely used to treat patients with moderate-to-severe acute respiratory failure secondary to COVID-19. Newer methods for respiratory assistance are being explored and hence an enhanced use and understanding of NIV is worthwhile.

In this single center, randomized open labeled clinical trial, the primary outcome noted was comparison of rate of endotracheal intubation among the two groups. The findings of our research back up our previous supposition. The patients who were given NIV by helmet mask, required lesser intubation, in comparison to the patients who were given NIV by face mask (10 vs 43.3%, p = 0.004). Our results are in agreement with the previous studies in which non-COVID patients of ARDS managed on helmet mask showed a better outcome with respect to intubation rates and oxygenation.5,8

On analysis of secondary outcomes in our study, the patients on helmet masks showed improved oxygenation and lower respiratory rate as compared to the patients on face mask (p = 0.00). Effective generation of positive-end expiratory pressure by helmet mask as compared to face mask9,10 may have led to opening of non-ventilated alveoli at the lung bases, increasing the functional residual capacity and a reduction in the shunt fraction. Studies have also pointed out that the use of helmet mask for NIV reduces the work of breathing by increasing the synchrony between patient and ventilator. The shifting of the tidal volume to a higher compliance point of the pressure-volume curve may be responsible for this better synchronization.11 The use of a helmet mask made prone positioning simple, safe, and practicable, which could be another cause for increased oxygenation and shorter NIV duration.12,13 In the early phases of the disease, continuous application of NIV is of paramount importance. With the use of helmet mask, the interruptions in NIV during drinking, communication, or clearing of sputum are minimized. This could have contributed to reduction in the total duration of NIV, length of ICU stay, and in-hospital mortality (p = 0.00).

Similar results were concluded by a study by Kyeremanteng K et al., on the comparison of cost analysis between NNV by helmet mask and face mask in ARDS. They reported that the use of the helmet mask interface in ARDS patients reduced the rate of intubation and mortality. The ICU stay and the resulting hospital costs were also decreased.14 This is of particular importance in the testing times of pandemic when there is shortage of ICU beds.

The use of helmet mask has been reported to have higher patient comfort and lower complication rate. In our study also, the helmet mask group reported better comfort level than those in the face mask group (p = 0.00). The complication rate with the use of helmet mask interface was significantly less as compared with the use of face mask (10 vs 43%, p = 0.004). Previous studies on long-term NIV use with face mask interface have also reported that development of ulcerative lesions on face and nasal bridge is frequently responsible for NIV failure in these patients.15

Helmet mask has no bony contact leading to decreased facial lesions as compared to face mask. Another reason for higher patient compliance with helmet mask is that it allows enteral nutrition and hydration.16 The use helmet mask allows the humidified expired gases to combine with the dry fresh gas flow. This raises the temperature and humidity of the inspired gases, improving patient comfort without the need for active humidification.17 A few patients in the helmet mask group reported increased operating noise as a barrier to helmet use. Use of ear plugs by the patients on helmet mask reduced this discomfort.18

Concerns about aerosol dispersion have been a major sticking point for NIV usage in COVID-19 patients. In comparison to HFNC or face mask, helmet masks have been shown to considerably reduce SARS-CoV-2 aerosolization and exposure risk for healthcare staff. The lower aerosol dispersion associated with helmet mask may be attributed to a better fit at the neck and fewer air leaks because it is not affected by the face anatomy of the patient. The use of heat-moisture exchange and high-efficiency particulate air filters attached to both the limbs of the circuit may further limit aerosolization.19

A similar study on COVID-19 ARDS patients has not been found to our knowledge, despite a thorough literature search. There are some studies and independent metanalysis evaluating the effectiveness of helmet mask as an interface for providing NIV in patients of ARDS, before the emergence of COVID-19.2023 They advocated for the use of a helmet mask as an effective treatment modality for respiratory failure, claiming that it improved the PaO2/FiO2 ratio, reduced intubation rates, and reduced in-hospital mortality. However, there were no randomized controlled trials that included COVID-19 participants for this comparison.

As we did an open-label trial, there is still a substantial risk of information bias. To minimize this effect, the variables chosen were objective. The presence of a small sample of patients from a single center could be another limitation. Third, we could not quantify the aerosol dispersion with either of the two methods of NIV due to the unavailability of device, technique, and expertise to measure the aerosol dispersion.

Helmet masks are a treatment alternative that has been utilized in Italy in the past, as well as during the COVID-19 pandemic.24 However, there was no consensus in the latest Surviving Sepsis Campaign guidelines on its clinical benefit in COVID-19.25 This study attempts to validate the feasibility and advantages of the use of helmet masks as compared to face mask for NIV in patients developing ARDS due to COVID-19.

CONCLUSION

COVID-19 pandemic has been a time of unparalleled medical challenges. In this regard, we suggest that an alternative respiratory support device like a helmet mask could be a feasible interface for the delivery of NIV. It results in a lower rate of endotracheal intubation, better oxygenation with greater patient comfort, and shorter ICU stay as compared to the face mask used for NIV. To generate more robust evidence, large and multi-center randomized controlled trials are required.

ORCID

Anupriya Saxena https://orcid.org/0000-0002-6203-3962

Nazia Nazir https://orcid.org/0000-0001-6950-2111

Ruchi Pandey https://orcid.org/0000-0002-4653-6738

Savita Gupta https://orcid.org/0000-0002-3104-7368

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