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Fit testing of masks worn by frontline healthcare workers

Published online by Cambridge University Press:  03 January 2023

Louisa M. Sasko*
Affiliation:
Westmead Hospital, Western Sydney Local Health District, Sydney, Australia
Brian Oliver
Affiliation:
School of Life Sciences, University of Technology Sydney, Ultimo, Sydney, Australia
Sheree M. Smith
Affiliation:
School of Nursing and Midwifery, Western Sydney University, Sydney, Australia School of Clinical Medicine, Faculty of Medicine, University of Queensland, Brisbane, Australia
*
Author for correspondence: Louisa Sasko, BNursing, MPhil, Western Sydney Local Health District, Sydney, Australia. E-mail: Louisa.Sasko@health.nsw.gov.au
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Abstract

Type
Research Brief
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Society for Healthcare Epidemiology of America

During the coronavirus disease 2019 (COVID-19) global pandemic, healthcare organizations have faced increasing pressure to establish and maintain a reliable supply of respirators for frontline clinical staff. Due to supply disruption, additional types of respirators have been sought, which have caused concern from frontline healthcare workers regarding their effectiveness to protect from viral aerosol exposure. Do additional masks brought in to address the shortfall of supply meet the expected standards for a mask seal? Healthcare workers have increasingly requested mask fit testing of regular and additional N95 and P2 masks.

International, national, and local guidance provide the quantitative assessment process for mask fit testing using a portacount machine. 13 The fit-test short protocol is consistent with the international Occupational Safety and Health Administration (OSHA), 2,4 Standards Australia, 5 and the Canadian Standards Association, 6 and it is supported by the US Centers for Disease Control and Prevention (CDC). 1 The protocol comprises 4 exercises while a mask is being worn: bending, talking, head up and down, and head side to side. The mask fit is tested, and an overall fit factor score is generated as a culmination of the exercise scores. For each exercise, a numerical value is generated reflecting the seal of the mask. To pass an exercise, the value must be ≥100. Irrespective of whether an exercise is passed or failed, the score contributes to a final overall mask fit result; a positive score is between 100 and ≥200. 4 According to the current OSHA guidance for quantitative fit testing, the overall fit factor is important, not the individual exercise scores. 4 This guidance differs from the UK Health Safety Executive mask fit-testing guidance. 3 In this study, we utilized the OHSA quantitative fit-test short protocol 4 to determine whether the usual masks and additional masks obtained due to lack of mask supply had similar fit-testing results.

Methods

A cross-sectional survey was conducted using the OSHA short protocol across 3 hospitals in Sydney, Australia. A specialist external company was hired to undertake quantitative fit testing, and frontline workers were advised of the availability of mask fit testing at their hospital. A retrospective analysis of deidentified data from the cross-sectional survey was granted ethical approval by the Local Health District Human Research Ethics Committee (nos. X20-163 and 202/ETH00982).

Results

In total, 719 fit tests were conducted; 686 tests were performed on disposable N95 and P2 masks, and 33 fit tests were performed on reusable respirators. Only 1 reusable mask failed. Of all 686 disposable N95 and P2 masks tested, 377 (55%) achieved a passing positive fit score; however, 22.3% of these masks failed at least 1 or more exercises of the OSHA protocol. Of the 294 usual brands supplied before the pandemic, 37.1% achieved an overall passing score for fit factor, whereas 68.4% of the 392 additional masks supplied achieved an overall passing score for fit factor. The differences in mask-sealing scores were for the exercises that were performed as part of the OSHA protocol. Of the 294 usually sourced masks tested, 52% failed bending exercises, 54.8% failed talking exercises, 60.5% failed head side-to-side exercises, and 68.4% failed the head up-and-down exercises. Among the 392 additionally sourced masks, 31.4% failed bending exercises, 30.45% failed talking exercises, 33.7% failed head side-to-side exercises, and 34.7% failed the head up-and-down exercises.

Discussion

COVID-19 healthcare worker infections have been reported in which personal protective equipment (PPE) breaches could not be identified. Reference Nguyen, Drew and Graham7 With a reduction in supply of usual brands of N95 and P2 masks, there was growing concern among frontline healthcare workers about the mask-sealing capabilities of the additional mask brands. With the introduction of additional brands, the question arose of whether these masks provided the same level of aerosol protection when fit tested compared to the usual brands supplied to the health service. Our results indicate that the usual N95 and P2 masks did not fit as many frontline healthcare workers compared to the additional N95 and P2 masks supplied during the pandemic. This finding would not have been identified if the supply chain for N95 and P2 masks had not been disrupted due to the pandemic.

The additional masks had a higher rate of overall fit than the usual masks supplied. This rate of mask fit is consistent with other published studies on mask fit testing associated with healthcare workers. Reference Ciotti, Pellissier and Rabaud8,Reference Suen, Yang and Ho9 Importantly, a percentage of masks with an overall positive fit test failed at least 1 OSHA exercise. Previously published N95 and P2 quantitative mask fit-testing studies have not reported the pass or failure rates of exercises in the OHSA QNFT protocols. In this study, failure of a QNFT exercise did not prevent an overall positive fit-test result. The OSHA protocol exercises are consistent with healthcare workers’ regular actions or movements when caring for COVID-19 patients, and failure of an exercise potentially places frontline workers at risk of viral exposure at the point of care. Reference Suen, Yang and Ho9,Reference Degesys, Wang, Kwan, Fahimi, Noble and Raven10 Is an overall passing score for a mask fit-test result sufficient during a pandemic in determining aerosol protection for frontline healthcare workers when not all test exercises are passed in a controlled quantitative mask fit-testing environment?

Our findings suggest that a wider variety of brands of N95 and P2 masks should be available to healthcare workers to ensure optimal protection from respiratory airborne viruses through better fitting N95 and P2 masks. Although we did not focus on the physical face shape or nose size and shape as part of the mask-fitting process, future studies could consider these important facial characteristics in determining brands and mask types that are more effective in providing a mask seal. In addition, future research is required to understand the differences in risk associated with international mask fit-testing protocols (ie, OSHA or UK HSE guidance). Risk assessment associated with airborne viruses should consider healthcare workers’ head and body movements in the delivery of clinical care.

Acknowledgments

The authors would like to thank Dr Timothy Gray for his support of this research and his Infectious Diseases knowledge.

Financial support

No financial support was provided relevant to this article.

Conflicts of interest

All authors report no conflicts of interest relevant to this article.

References

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