Impact of Filter Material and Holding Time on Spore Sampling Efficiency in Water

Overview

Journal Lett Appl Microbiol

Publisher Oxford University Press

Specialty Microbiology

Date 2023 Jan 27

PMID 36705271

Authors

Katherine Ratliff

Ahmed Abdel-Hady

Mariela Monge

Anne Mikelonis

Abderrahmane Touati

Affiliations

Soon will be listed here.

Abstract

Bacillus anthracis and other environmentally persistent pathogens pose a significant threat to human and environmental health. If contamination is spread over a wide area (e.g. resulting from a bioterrorism or biowarfare incident), readily deployable and scalable sample collection methods will be necessary for rapidly developing and implementing effective remediation strategies. A recent surge in environmental (eDNA) sampling technologies could prove useful for quantifying the extent and levels of contamination from biological agents in environmental and drinking water. In this study, three commonly used membrane filtration materials (cellulose acetate, cellulose nitrate, and nylon) were evaluated for spore filtration efficiency, yielding recoveries from 17%-68% to 25%-117% for high and low titer samples, respectively, where cellulose nitrate filters generated the highest recoveries. A holding time test revealed no statistically significant differences between spore recoveries when analyzed at the specified timepoints, suggesting that eDNA filter sampling techniques can yield and maintain a relatively high recovery of spores for an extended period of time between filtration and analysis without a detrimental impact on spore recoveries. The results shown here indicate that emerging eDNA technologies could be leveraged for sampling following a wide-area contamination incident and for other microbiological water sampling applications.

Citing Articles

Comparison of liquid and filter sampling techniques for recovery of Bacillus spores and Escherichia coli from environmental water.

Abdel-Hady A, Monge M, Aslett D, Mikelonis A, Touati A, Ratliff K J Environ Manage. 2024; 370:122711.

PMID: 39366227 PMC: 11836889. DOI: 10.1016/j.jenvman.2024.122711.

The potential to manage releases of Bacillus anthracis using bioretention and a high flow media filter: Results of simulated runoff testing with tracer spores Bacillus globigii.

Boening-Ulman K, Mikelonis A, Heckman J, Calfee M, Ratliff K, Youn S J Environ Manage. 2024; 354:120286.

PMID: 38354613 PMC: 11649060. DOI: 10.1016/j.jenvman.2024.120286.

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