Issue 36, 2023

A safer framework to evaluate characterization technologies of exhaled biologic materials using electrospun nanofibers

Abstract

Exhaled biologic material is the source for the spread of many respiratory tract infections. To avoid the high-level of biosafety required to manage dangerous pathogens, we developed a safer framework using the endogenous surrogate targets RNase P and Streptococcus mitis as a means to sample exhaled biologics. Our exhalation collection scheme uses nanoscale fibrous poly(vinyl alcohol) substrates as facemask inserts. After a period of breathing or speaking, the inserts are removed and dissolved. RNase P RNA and S. mitis DNA are extracted for quantification by multiplexed RT-qPCR. Both surrogate biomarkers were detected in all samples obtained during breathing for at least five minutes or speaking for one minute. Phrases repeated 30 times had the most copies with 375 ± 247 of S. mitis and 54 ± 33 of RNase P. When the phrases were repeated just 5 times, the S. mitis copies collected were still detectable but at a significantly lower level of 11 ± 5 for S. mitis and 12 ± 9 for RNase P. These results demonstrate a collection and quantification framework that can be readily adapted to further characterize the exhalation of nanoscale biologic materials from healthy individuals, explore new collection designs safely, and serve as a method to incorporate sample controls for future pathogen exhalation studies.

Graphical abstract: A safer framework to evaluate characterization technologies of exhaled biologic materials using electrospun nanofibers

Supplementary files

Article information

Article type
Paper
Submitted
21 4 2023
Accepted
17 8 2023
First published
25 8 2023
This article is Open Access
Creative Commons BY-NC license

Nanoscale, 2023,15, 14822-14830

A safer framework to evaluate characterization technologies of exhaled biologic materials using electrospun nanofibers

D. T. Evans, D. J. Nelson, M. E. Pask and F. R. Haselton, Nanoscale, 2023, 15, 14822 DOI: 10.1039/D3NR01859H

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