key: cord-0754899-gdkp9yi5
authors: Li, Jie; Schoenrock, Carla; Fink, James B.
title: Aerosol particle concentrations with different oxygen devices and interfaces for spontaneous breathing patients with tracheostomy: a randomised crossover trial
date: 2021-11-22
journal: ERJ Open Res
DOI: 10.1183/23120541.00486-2021
sha: 7949e81022eab834a2ef64998c07943da4eeb6b2
doc_id: 754899
cord_uid: gdkp9yi5

For stable spontaneously breathing tracheostomy patients with uncuffed airways, different humidification devices and interfaces did not generate clinically significant differences of aerosol particle concentrations https://bit.ly/2Y1HSO2

A heat-moisture exchange filter (HMEF) provides heat and humidification while filtering the exhaled gas from patients (figure 1) [6, 8] , but is not suitable for patients with copious or thick secretions, and can be occluded by secretions, resulting in an increased work of breathing or complete obstruction of the inner cannula. Large volume nebulisers (LVNs) are commonly used with tracheostomy mask for patients with a tracheostomy, despite concerns that cool gas may cause airway irritation or dry secretions. A venturi adapter with tracheostomy mask is commonly utilised during transport or patient mobilisation. Lastly, heated high-flow high humidity has been shown to improve comfort and secretion management in tracheostomy patients [9] [10] [11] . The aerosol particle concentrations generated by patients via tracheostomy stoma with these devices are unknown. This study aimed to investigate the ambient aerosol particle concentrations among different oxygen and humidification devices for spontaneous breathing patients with a tracheostomy, in order to assess the transmission risk.

This prospective, randomised cross-over trial was approved by the Rush University ethics committee (approval No. 20112506-IRB01) and registered with clinicaltrials.gov (NCT04654754). Adult tracheostomy patients who were able to breathe without ventilator support were enrolled. Patients were excluded if they met any of the following criteria: had positive test for COVID-19 within the past 2 weeks; were non-English speaking or unable to communicate or make any decision; refused to participate in the study; or were receiving palliative care or extracorporeal membrane oxygenation.

After signing the consent form, patients received oxygen therapy with four devices in a random order: 1) heated high-flow high humidity device with tracheostomy adapter (Airvo2; Fisher & Paykel healthcare, Auckland, New Zealand) operated at 30 L·min −1 (figure 1); 2) LVN (AirLife Prefilled Nebulizer Kit; Vyaire Medical, Mettawa, IL, USA) with tracheostomy mask (AirLife; Vyaire Medical); 3) LVN with T-piece and a bacterial/viral filter (AirLife; Vyaire Medical) [8] ; and 4) Venturi-adapter with tracheostomy mask. Both the LVN and Venturi-adapter were operated at 6 L·min −1 and fraction of inspired oxygen (F IO 2 ) at 0.28. Each device was used for 5 min. An HMEF placed at the tracheostomy tube was used prior to the study and between devices, with an interval of 10 min. A particle counter (Model 3889; Kanomax, Andover, NJ, USA) was placed at 1 foot from patient's face to continuously measure aerosol particle concentrations in the room. During the study, the investigator wore an N95 mask and stayed in the room with the patient, and activities (talking or moving around) were discouraged. The door of the patient's room remained closed and none of the rooms had negative pressure. If suctioning was required, aerosol particle concentration measurement was paused and restarted 10 min after suctioning. Patient's comfort was self-evaluated using a visual numerical scale ranging between 1 (very uncomfortable) and 5 (very comfortable) [12] .

HMEF was expected to reduce the aerosol particle concentrations, with treatment effect set at medium to large as 0.1. Using G-power software to calculate the sample size in repeated ANOVA measures, with confidence level (α) of 95%, power (1-β) of 80%, the number of patients was 12. Friedman test was used to compare the aerosol particle concentrations and comfort scores among five devices (including baseline with HMEF) and Wilcoxon signed-rank test was used to analyse the differences between devices. A p-value <0.05 was statistically significant for all tests. Data analysis was conducted with SPSS software (SPSS 26.0; IBM Corp., Armonk, NY, USA).

12 patients were enrolled, with mean±SD age of 50.5±16.6 years, height of 166.5±10.4 cm, weight of 83.1±27.6 kg, and body mass index of 29.5±7.6 kg·m −2 . Tracheostomy had been in place for 18.5 (5.3-250.5) days, 10 patients had tracheostomy tube size of 6, of whom four had cuffed tubes, while two patients had tracheostomy tube size of 4. All cuffs were deflated during the study. Patients required suctioning with a frequency of 3 (2-5) times in the past 24 h. Only two patients required suctioning during the duration of the study, which lasted ∼90 min per patient. No significant differences in aerosol particle concentrations at each size were found among the different devices (figure 1). Patients' comfort was similar among the devices as well.

Aerosol particle concentrations were similar among different humidification devices used with tracheostomy patients with a deflated cuff. These findings differ from our previous study of high-flow nasal cannula for COVID-19 patients, in which aerosol particle concentrations at 1 foot from patients were reduced when placing a surgical mask over nasal cannula at particle sizes of 0.3-5.0 μm [5] . In contrast, the effect of placing a bacterial/viral filter or HMEF on the tracheostomy tube was negligible. Hypothetically, a bacterial/viral filter or HMEF should have higher efficiency to filter aerosol particles than a surgical mask. However, all of the tracheostomy patients could breathe via their mouth and nose, and none wore a surgical mask. In contrast to COVID-19 patients in the acute phase, the stable tracheostomy patients enrolled in our study required minimal suctioning and barely coughed during the study, while cough in patients without tracheostomy was found to generate higher fugitive aerosol particle concentrations than nebulisation [13] . Future studies should explore whether placing a surgical mask to cover the mouth and nose for tracheostomy patients with a deflated cuff could reduce the aerosol particle concentrations, and to investigate the effects of a bacterial/viral filter or HMEF with a surgical mask during cough or suctioning.

Interestingly, LVN with tracheostomy mask did not generate higher aerosol particles than the other devices, in contrast to a small volume nebuliser, which was found to significantly increase the aerosol particle concentrations [14] . This difference might be explained by the long tubing (3 m) used to connect the LVN and tracheostomy mask and the aerosol output produced with more particles deposited in the tubing, allowing mostly small particles of 0.3-0.5 μm to reach the patients.

There are several limitations. Due to the unknown transmission risk of tracheostomy, we did not enrol COVID-19 patients; however, COVID-19 patients recovered from the acute phase and weaned off the ventilator would be expected to have low virus load [15] , and less frequent cough, thus our results might provide a reference for future studies with tracheostomy patients with airborne disease. We did not investigate the virus load, while the aerosol concentrations only indirectly reflected the transmission risk, future studies are needed to measure the virus load with different devices. Regardless, appropriate PPE is still recommended when taking care of tracheostomy patients, especially during suctioning.

For stable tracheostomy patients with uncuffed airways, different humidification devices and interfaces did not generate clinically significant differences in aerosol particle concentrations. Future studies are still needed to assess the effects of humidification devices during coughing or suctioning, and the effects of wearing a surgical mask. 

Aerodynamic characteristics and RNA concentration of SARS-CoV-2 aerosol in Wuhan hospitals during COVID-19 outbreak

Coughs and sneezes: their role in transmission of respiratory viral infections, including SARS-CoV-2

High-flow nasal cannula for COVID-19 patients: low risk of bio-aerosol dispersion

High flow aerosol dispersing-versus aerosol generating procedures

Placing a mask on COVID-19 patients during high-flow nasal cannula therapy reduces aerosol particle dispersion

Tracheostomy care and decannulation during the COVID-19 pandemic. A multidisciplinary clinical practice guideline

Tracheostomy in the COVID-19 era: global and multidisciplinary guidance

Practical strategies to reduce nosocomial transmission to healthcare professionals providing respiratory care to patients with COVID-19

High-flow oxygen with capping or suctioning for tracheostomy decannulation

High-flow oxygen therapy in tracheostomized subjects with prolonged mechanical ventilation: a randomized crossover physiologic study

Heated air humidification versus cold air nebulization in newly tracheostomized patients

Impact of flow and temperature on patient comfort during respiratory support by high-flow nasal cannula

Risk of aerosol formation during high-flow nasal cannula treatment in critically ill subjects

Characterization of aerosols generated during patient care activities

Clinical and virological data of the first cases of COVID-19 in Europe: a case series

Acknowledgement: We thank all the patients who participated in this study. We also thank Amnah Alolaiwat and Lauren J. Harnois from Rush University Medical Center for their help in recruiting patients and implementing the study. We also appreciate Sharon Foley from Rush University for her consultancy in statistical analysis.Provenance: Submitted article, peer reviewed.This study is registered at www.clinicaltrials.gov with identifier number NCT04654754. Deidentified data will be available upon reasonable request after publication.