Abstract
Although the COVID-19 pandemic shows no signs of abating, public health strategies have transitioned from containment to harm reduction. In light of this paradigm shift, it is critical that individuals take steps to prevent the spread of SARS-CoV-2, the virus that causes COVID-19. In the United States, the CDC recommends that individuals wear face coverings in public places, such as grocery stores. As lockdowns are being phased out around the world, authorities are requiring the use of such masks in public places while maintaining social distance.
Individuals (including healthcare professionals outside of their clinical settings) and manufacturers are following the CDC’s recommendation. But, many currently available masks are not form-fitting, are not customizable, and are uncomfortable with even short-term use, thereby undercutting their effectiveness. Moreover, because cotton absorbs and retains the moisture found in an exhaled breath masks made of cotton have the potential to increase the wearer’s risk of infection. Thus, as we shift to harm reduction and social distancing measures relax, it is imperative that these shortcomings in fabric masks are addressed and that is the motivation for this research.
The overall objective of the research is to design, develop, and test a fabric mask that is effective while being comfortable during continuous use over long periods of time. As the first step in the design process, we reviewed the modes of transmission of SARS-CoV-2 virus. We analyzed a medical mask and a fabric mask in the market and identified their shortcomings. We carried out an in-depth analysis of user needs and developed the performance requirements of the proposed mask. We defined the architecture of the mask comprising the following principal components: Barrier, Form-Fitting, Positioning, and Fastening. We tested and evaluated candidate materials for the components and developed the design specifications and construction details for the mask. We produced the mask and carried out subjective testing on a user in a typical workplace setting; we demonstrated that the mask was form-fitting, customizable, washable, and could be worn continuously and routinely over extended periods of time by individuals and therefore could serve as an effective means to reduce the harm from SARS-CoV-2.
Acknowledgements
The authors gratefully acknowledge the comments and suggestions from the reviewers of the original manuscript and express their thanks to them. The authors are also grateful to Professor Xungai Wang, Editor, for providing us the opportunity to carry out filtration efficiency tests under more rigorous conditions simulating the typical conditions of mask usage compared to the earlier tests carried out under extenuating circumstances and restrictions due to COVID-19 and submitting this revised version of the manuscript. The authors regret the inadvertent error made in the notation for the dimensions of one of the pattern parts in Figure 8, which has been corrected in the new figure. The authors also provide additional information in the replacement figure to augment the easy creation of masks.
Disclosure statement
No potential conflict of interest was reported by the author(s).