Reaerosolization of Fluidized Spores in Ventilation Systems

Krauter, Paula; Biermann, A.H.

doi:10.1128/aem.02289-06

Cited by 50 publications

(42 citation statements)

References 20 publications

(23 reference statements)

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“…B. atrophaeus subsp. globigii has been used (39,40) to model the dispersal and deposition behavior of B. anthracis spores, but the work presented here, supported by morphological comparisons (8,9), suggests that it might not be the best surrogate, at least under some conditions. Further testing and characterization of BtcryϪ aerosols under different conditions are required; there is a need for a safe, accurate surrogate for B. anthracis spores to produce experimental data to augment the modeling methods currently available (41)(42)(43).…”

Section: Discussionmentioning

confidence: 97%

Aerosol and Surface Deposition Characteristics of Two Surrogates for Bacillus anthracis Spores

Bishop

Stapleton

2016

Appl Environ Microbiol

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Spores of an acrystalliferous derivative of Bacillus thuringiensis subsp. kurstaki, termed Btcry؊, are morphologically, aerodynamically, and structurally indistinguishable from Bacillus anthracis spores. Btcry؊ spores were dispersed in a large, openended barn together with spores of Bacillus atrophaeus subsp. globigii, a historically used surrogate for Bacillus anthracis. Spore suspensions (2 ؋ 10 12 CFU each of B. atrophaeus subsp. globigii and Btcry؊) were aerosolized in each of five spray events using a backpack misting device incorporating an air blower; a wind of 4.9 to 7.6 m s ؊1 was also flowing through the barn in the same direction. Filter air samplers were situated throughout the barn to assess the aerosol density of the spores during each release. Trays filled with a surfactant in aqueous buffer were placed on the floor near the filter samplers to assess spore deposition. Spores were also recovered from arrays of solid surfaces (concrete, aluminum, and plywood) that had been laid on the floor and set up as a wall at the end of the barn. B. atrophaeus subsp. globigii spores were found to remain airborne for significantly longer periods, and to be deposited on horizontal surfaces at lower densities, than Btcry؊ spores, particularly near the spray source. There was a 6-fold-higher deposition of Btcry؊ spores than of B. atrophaeus subsp. globigii spores on vertical surfaces relative to the surrounding airborne density. This work is relevant for selecting the best B. anthracis surrogate for the prediction of human exposure, hazard assessment, and hazard management following a malicious release of B. anthracis. IMPORTANCEThere is concern that pathogenic bacteria could be maliciously disseminated in the air to cause human infection and disruption of normal life. The threat from spore-forming organisms, such as the causative agent of anthrax, is particularly serious. In order to assess the extent of this risk, it is important to have a surrogate organism that can be used to replicate the dispersal characteristics of the threat agent accurately. This work compares the aerosol dispersal and deposition behaviors of the surrogates Btcry؊ and B. atrophaeus subsp. globigii. Btcry؊ spores remained in the air for a shorter time, and were markedly more likely to adhere to vertical surfaces, than B. atrophaeus subsp. globigii spores. Bacillus anthracis is an important bacterial agent of concern (1). It is pathogenic to humans, particularly by inhalational exposure (2). The organism's endospores manifest greater environmental persistence and higher resistance to chemical decontaminants than those of other bacteria. Understanding of the threat posed by malicious use of B. anthracis and the development of effective countermeasures require a comparable, nonpathogenic surrogate. Bacillus atrophaeus subsp. globigii has, for many decades, been a B. anthracis surrogate (3). B. atrophaeus subsp. globigii and other surrogates related to Bacillus subtilis have generated useful information regarding spore dispersal (4, 5)....

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Section: Discussionmentioning

confidence: 97%

Aerosol and Surface Deposition Characteristics of Two Surrogates for Bacillus anthracis Spores

Bishop

Stapleton

2016

Appl Environ Microbiol

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“…Resuspension from the surfaces of ventilation ducts is primarily associated with aerodynamic removal forces (Krauter and Biermann 2007;Wang et al 2012). For most residential and commercial building applications, velocities in ventilation ducts are generally below 10 m/s.…”

Section: Ventilation Ductsmentioning

confidence: 99%

“…Resuspension from indoor particle deposits can occur due to airflow in ven-tilation ducts (Krauter and Biermann 2007;Wang et al 2012) and human activities indoors (Thatcher and Layton 1995;Ferro et al 2004;Qian and Ferro 2008;Tian et al 2011;Shaughnessy and Vu 2012). Additionally, resuspension can be an exposure pathway to the multitude of pollutants that are commonly found in settled indoor dust, such as: allergens (O'Meara and Tovey 2000), lead, pesticides, phthalates, and flame retardants (Roberts et al 2009).…”

Section: Introductionmentioning

confidence: 99%

Monolayer and Multilayer Particle Deposits on Hard Surfaces: Literature Review and Implications for Particle Resuspension in the Indoor Environment

Boor

Siegel

Novoselac

2013

Aerosol Science and Technology

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Particle deposits on indoor surfaces can be as complex and diverse as the indoor environments in which they exist. Dust loading can range over several orders of magnitude, suggesting the existence of different types of particle deposits. These deposits can be broadly classified as either a monolayer, in which particles are sparsely deposited on a surface, or a multilayer, in which particles are deposited on top of one another and there is particle-toparticle adhesion and interaction. Particles within these diverse structures of settled indoor dust can become airborne through a process known as resuspension, which can occur due to airflow in ventilation ducts or human activity indoors. The dust loading and deposit structure on an indoor surface may have important implications for resuspension in the indoor environment. This literature review provides a summary of dust loads found on indoor surfaces in field studies and classifies each dust load as either a monolayer or multilayer particle deposit. The article highlights the unique attributes associated with resuspension from both types of particle deposits by summarizing key findings of the experimental resuspension literature. The fundamental differences in the resuspension process between monolayer and multilayer deposits suggest that resuspension may vary considerably among the broad spectrum of dust loads found on indoor surfaces.

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“…Further treatment of the bioagent (e.g. applying a uniform charge to the particles, adding a fluidizing agent) can enhance the ability of the powder to disperse by inhibiting particle impacted by deposition techniques (Krauter and Biermann 2007;Byers et al 2013). Aerobiological standards for applying micro-organisms to surfaces are becoming more common and, recently, ASTM International (ASTM) approved two standards that describe methods for depositing influenza-infused droplets and droplet nuclei onto surfaces (ASTM International 2010a,b).…”

Section: Introductionmentioning

confidence: 99%

Standard method for deposition of dry, aerosolized, silica-coated Bacillus spores onto inanimate surfaces

et al. 2014

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Aims: To evaluate a standard aerosolization method for uniformly depositing threat-representative spores onto surfaces. Methods and Results: Lyophilized Bacillus anthracis DSterne spores, coated in silica, were aerosolized into a containment chamber and deposited onto nine surface types by two independent laboratories. Laboratory A produced a mean loading concentration of 1Á78 9 10 5 CFU cm À2 ; coefficient of variation (CV) was <40% for 96% of samples. Laboratory B produced a mean loading concentration of 7Á82 9 10 6 CFU cm À2 ; 68% of samples demonstrated CV <40%. Conclusions: This method has been shown to meet the goal of loading threatrepresentative spores onto surfaces with low variability at concentrations relevant to the Department of Defense. Significance and Impact of the Study: As demonstrated in 2001, a biological attack using anthrax disseminated as a dry powder is a credible threat. This method will provide a means to load spores onto surfaces that mimic a 'realworld' scenario of an aerosolized anthrax attack. The method has utility for evaluating sporicidal technologies and for nondecontamination studies, for example fate and transport or reaerosolization.

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Reaerosolization of Fluidized Spores in Ventilation Systems

Cited by 50 publications

References 20 publications

Aerosol and Surface Deposition Characteristics of Two Surrogates for Bacillus anthracis Spores

Aerosol and Surface Deposition Characteristics of Two Surrogates for Bacillus anthracis Spores

Monolayer and Multilayer Particle Deposits on Hard Surfaces: Literature Review and Implications for Particle Resuspension in the Indoor Environment

Standard method for deposition of dry, aerosolized, silica-coated Bacillus spores onto inanimate surfaces

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