Your search keyword '"Kent C. Hofacre"' showing total 3 results

1. Comparison of Simulated Respirator Fit Factors Using Aerosol and Vapor Challenges

Author

Paul D. Gardner, Kent C. Hofacre, and Aaron W. Richardson

Subjects

business.product_category, Analytical chemistry, complex mixtures, chemistry.chemical_compound, Materials Testing, Humans, Particle Size, Respiratory Protective Devices, Respirator, Inert gas, Aerosols, Inhalation Exposure, Spectrometer, Public Health, Environmental and Occupational Health, Reproducibility of Results, Equipment Design, Models, Theoretical, Organic vapor, Aerosol, Sulfur hexafluoride, chemistry, Equipment Failure, Gas chromatography, Volatilization, business, Body orifice

Abstract

Although not well established, mask leakage measured using submicron aerosol challenges is generally accepted as being representative of vapor challenges. The purpose of this study was to compare simulated respirator fit factors (FFs) measured using vapor challenges to those measured using an aerosol challenge. A full-facepiece respirator was mounted on a headform inside a small enclosure and modified with controlled leaks (laser-drilled orifices) to produce FFs ranging from about 300 to 30,000. A breathing machine was used to simulate breathing conditions of 1.0 L tidal volume and 25 breaths/min. A monodisperse aerosol consisting of 0.72 micron polystyrene latex spheres (PSL) was used for the reference test aerosol, and FFs were measured using a laser aerosol spectrometer. An inert gas, sulfur hexafluoride (SF6), and an organic vapor, isoamyl acetate (IAA), were used as the vapor challenges. The in-mask concentration of SF6 was measured using a gas chromatograph (GC). A GC was also used to quantify in-mask IAA concentration samples actively collected with sorbent tubes. FF measurements made with the PSL aerosol challenge were conducted in sequence with the SF6 and IAA challenges, without disturbing the mask, to yield matched data pairs for regression analysis. FFs measured using the PSL reference aerosol were found to correlate well with those measured with the SF6 (r2 = 0.99) and IAA (r2 = 0.98) vapor challenges. FFs measured using IAA tended to be higher at values below 10,000. The best agreement was observed with the inert gas, SF6. The results of this study suggest that submicron aerosols are suitable as quantitative fit test challenges for assessing the performance of respirators against inert vapors.

Published

2004

2. Transfer and Reaerosolization of Biological Contaminant following Field Technician Servicing of an Aerosol Sampler

Author

Melanie A. Samsonow, Monique L. van Hoek, Richard J. Byers, Kent C. Hofacre, Steven R. Medley, and Michael L. Dickens

Subjects

Waste management, business.industry, Sample (material), Technician, Contamination, Biological materials, Aerosol, Toxicology, Deposition (aerosol physics), parasitic diseases, Medicine, business, Air quality index, Bioaerosol

Abstract

Over the last several years, aerosol samplers have been fielded in many locations to collect biological agents in the air, providing a sample that, once analyzed, will alert safety and public health officials of potential bioterrorism events. If a biological agent was present at the sampling location, the collector and surrounding area may be contaminated due to bioaerosol deposition, possibly posing a hazard to the technician maintaining the aerosol sampler. The technician may, in turn, serve as a source for cross-contamination to clean areas subsequently visited, potentially producing a hazard to others if transferred to indoor settings, such as a job site or analysis laboratory. To investigate our hypothesis about these potential exposure sources and cross-contamination, a study was performed to: (1) examine biological material transfer from a contaminated site to an individual; and (2) determine aerosol resuspension levels due to typical personnel activity at a contaminated, paved bioaerosol sampling site. Analysis of air samples indicated reaerosolization of spore-containing particles upon disturbance of a contaminated site by a field technician, and analysis of swatches taken from the technician’s clothing indicated substantial transfer of spores. These results provide insight into sources of cross-contamination and potential steps to mitigate consequences of infectious contaminant transfer, and also demonstrate potential exposure hazards for technicians servicing fielded bioaerosol collectors.

Published

2013

3. N95 and p100 respirator filter efficiency under high constant and cyclic flow

Author

Jonathan P. Eshbaugh, Paul D. Gardner, Kent C. Hofacre, and Aaron W. Richardson

Subjects

Inert, Air Pollutants, Inhalation Exposure, business.product_category, Materials science, Inhalation, Dispersity, Public Health, Environmental and Occupational Health, Environmental engineering, Analytical chemistry, Penetration (firestop), United States, Aerosol, Cartridge, Materials Testing, Particle size, Respirator, Particle Size, Respiratory Protective Devices, business, National Institute for Occupational Safety and Health, U.S, Filtration

Abstract

This study investigated the effect of high flow conditions on aerosol penetration and the relationship between penetration at constant and cyclic flow conditions. National Institute for Occupational Safety and Health (NIOSH)-approved N95 and P100 filtering facepiece respirators and cartridges were challenged with inert solid and oil aerosols. A combination of monodisperse aerosol and size-specific aerosol measurement equipment allowed count-based penetration measurement of particles with nominal diameters ranging from 0.02 to 2.9 microm. Three constant flow conditions (85, 270, and 360 L/min) were selected to match the minute, inhalation mean, and inhalation peak flows of the four cyclic flow conditions (40, 85, 115, and 135 L/min) tested. As expected, penetration was found to increase under increased constant and cyclic flow conditions. The most penetrating particle size (MPPS) generally ranged from 0.05 to 0.2 microm for P100 filters and was approximately 0.05 microm for N95 filters. Although penetration increased at the high flow conditions, the MPPS was relatively unaffected by flow. Of the constant flows tested, the flows equivalent to cyclic inhalation mean and peak flows best approximated the penetration measurements of the corresponding cyclic flows.

Published

2008