Your search keyword '"Grinshpun SA"' showing total 140 results

1. Effect of Microbial Contamination of Water-Based Metalworking Fluids on the Aerosolization of Particles and Microbial Fragments

Author

Reponen, T, primary, Wang, HX, additional, and Grinshpun, SA, additional

Published

2005

2. High environmental relative moldiness index during infancy as a predictor of asthma at 7 years of age.

Author

Reponen T, Vesper S, Levin L, Johansson E, Ryan P, Burkle J, Grinshpun SA, Zheng S, Bernstein DI, Lockey J, Villareal M, Khurana Hershey GK, and Lemasters G

Published

2011

3. Large particle penetration through N95 respirator filters and facepiece leaks with cyclic flow.

Author

Cho KJ, Reponen T, Mckay R, Shukla R, Haruta H, Sekar P, and Grinshpun SA

Published

2010

4. Size distribution of airborne mist and endotoxin-containing particles in metalworking fluid environments [corrected] [published erratum appears in J OCCUP ENVIRON HYG 2007 May;4(5):D53].

Author

Wang H, Reponen T, Lee S, White E, and Grinshpun SA

Abstract

The objective of the study was to investigate size-selective concentrations of airborne particles and endotoxin in metalworking fluid (MWF) environments. The experiments were conducted under two conditions: (1) MWF collected in the field was aerosolized with a laboratory-scale simulator (MWF simulator) in the laboratory; and (2) MWFs were aerosolized during routine field operations. All experiments included size-selective measurement of airborne concentrations of particle numbers and endotoxin mass using an electrical low-pressure impactor. During field sampling, the total microbial and endotoxin concentrations in the air were also measured with a BioSampler, and the mass concentration of MWF mists was measured with a photometer. Airborne particle concentrations were highest in the fine particle size ranges in the areas affected by MWFs. Relatively high concentrations of endotoxin were detected at particle size below 0.39 mum, which is smaller than the size of intact bacterial cells. The total microbial and endotoxin analysis revealed high microbial contamination in one sampling site although the total particle mass was not elevated. It was concluded that MWF sites can be contaminated with high concentrations of fine particles, and these fine particles may contain microbial components, such as endotoxin. The results call for the size-selective measurement of particles and endotoxin for more comprehensive exposure assessment in MWF facilities. [ABSTRACT FROM AUTHOR]

Published

2007

5. A comparison of proximity and land use regression traffic exposure models and wheezing in infants.

Author

Ryan PH, LeMasters GK, Biswas P, Levin L, Hu S, Lindsey M, Bernstein DI, Lockey J, Villareal M, Hershey GKK, and Grinshpun SA

Abstract

Background: We previously reported an association between infant wheezing and residence < 100 m from stop-and-go bus and truck traffic. The use of a proximity model, however, may lead to exposure misclassification.Objective: Results obtained from a land use regression (LUR) model of exposure to truck and bus traffic are compared with those obtained with a proximity model. The estimates derived from the LUR model were then related to infant wheezing.Methods: We derived a marker of diesel combustion--elemental carbon attributable to traffic sources (ECAT)--from ambient monitoring results of particulate matter with aerodynamic diameter < 2.5 microm. We developed a multiple regression model with ECAT as the outcome variable. Variables included in the model were locations of major roads, bus routes, truck traffic count, and elevation. Model parameter estimates were applied to estimate individual ECAT levels at infants' homes.Results: The levels of estimated ECAT at the monitoring stations ranged from 0.20 to 1.02 microg/m[3]. A LUR model of exposure with a coefficient of determination (R[2]) of 0.75 was applied to infants' homes. The mean (+/- SD) ambient exposure of ECAT for infants previously categorized as unexposed, exposed to stop-and-go traffic, or exposed to moving traffic was 0.32 +/- 0.06, 0.42 +/- 0.14, and 0.49 +/- 0.14 microg/m[3], respectively. Levels of ECAT from 0.30 to 0.90 microg/m[3] were significantly associated with infant wheezing.Conclusions: The LUR model resulted in a range of ECAT individually derived for all infants' homes that may reduce the exposure misclassification that can arise from a proximity model. [ABSTRACT FROM AUTHOR]

Published

2007

6. Respiratory protection provided by N95 filtering facepiece respirators against airborne dust microorganisms in agricultural farms.

Author

Lee S, Adhikari A, Grinshpun SA, McKay R, Shukla R, Zeigler HL, and Reponen T

Abstract

A new system was used to determine the workplace protection factors (WPF) for dust and bioaerosols in agricultural environments. The field study was performed with a subject wearing an N95 filtering facepiece respirator while performing animal feeding, grain harvesting and unloading, and routine investigation of facilities. As expected, the geometric means (GM) of the WPFs increased with increasing particle size ranging from 21 for 0.7-1 microm particles to 270 for 5-10 microm particles (p < 0.001). The WPF for total culturable fungi (GM = 35) was significantly greater than for total culturable bacteria (GM = 9) (p = 0.01). Among the different microorganism groups, the WPFs of Cladosporium, culturable fungi, and total fungi were significantly correlated with the WPFs of particles of the same sizes. As compared with the WPFs for dust particles, the WPFs for bioaerosols were found more frequently below 10, which is a recommended assigned protection factor (APF) for N95 filtering facepiece respirators. More than 50% of the WPFs for microorganisms (mean aerodynamic diameter < 5 microm) were less than the proposed APF of 10. Even lower WPFs were calculated after correcting for dead space and lung deposition. Thus, the APF of 10 for N95 filtering facepiece respirators seems inadequate against microorganisms (mean aerodynamic size < 5 microm). These results provide useful pilot data to establish guidelines for respiratory protection against airborne dust and microorganisms on agricultural farms. The method is a promising tool for further epidemiological and intervention studies in agricultural and other similar occupational and nonoccupational environments. [ABSTRACT FROM AUTHOR]

Published

2005

7. Comments on a recent protection factor study.

Author

Nelson T, Lee S, Adhikari A, Grinshpun SA, McKay R, Shukla R, Zeigler HL, and Reponen T

Published

2006

8. Fit evaluation of NIOSH approved N95 filtering facepiece respirators with various skin protectants: A pilot study.

Author

Bergman MS, Grinshpun SA, Yermakov MV, Zhuang Z, Vollmer BE, and Yoon KN

Subjects

United States, Humans, N95 Respirators, National Institute for Occupational Safety and Health, U.S., Pilot Projects, Materials Testing, Equipment Design, Respiratory Protective Devices, Occupational Exposure prevention & control

Abstract

Widespread disease outbreaks can result in prolonged wear times of National Institute for Occupational Safety and Health Approved N95 filtering facepiece respirators by healthcare personnel. Prolonged wear times of these devices can cause the development of various adverse facial skin conditions. Healthcare personnel have been reported to apply "skin protectants" to the face to reduce the pressure and friction of respirators. Because tight-fitting respirators rely on a good face seal to protect the wearer, it is important to understand if the fit is affected when skin protectants are used. This laboratory pilot study included 10 volunteers who performed quantitative fit tests to evaluate respirator fit while wearing skin protectants. Three N95 filtering facepiece respirator models and three skin protectants were evaluated. Three replicate fit tests were performed for each combination of subject, skin protectant (including a control condition of no protectant), and respirator model. Fit Factor (FF) was affected differently by the combination of the protectant type and respirator model. The main effects of the protectant type and respirator model were both significant ( p  < 0.001); additionally, their interaction was significant ( p  = 0.02), indicating FF is affected by the combined effects of the protectant type and respirator model. Compared to the control condition, using a bandage-type or surgical tape skin protectant decreased the odds of passing the fit test. Using a barrier cream skin protectant also decreased the odds of passing the fit test across all models compared to the control condition; however, the probability of passing a fit test was not statistically significantly different from the control condition ( p  = 0.174). These results imply that all three skin protectants reduced mean fit factors for all N95 filtering facepiece respirator models tested. The bandage-type and surgical tape skin protectants both reduced fit factors and passing rates to a greater degree than the barrier cream. Respirator users should follow respirator manufacturers' guidance on the use of skin protectants. If a skin protectant is to be worn with a tight-fitting respirator, the fit of the respirator should be evaluated with the skin protectant applied before use in the workplace.

Published

2023

9. Assessing the Fit of N95 Filtering Facepiece Respirators Fitted with an Ear Loop Strap System: A Pilot Study.

Author

Niu X, Koehler RH, Yermakov M, and Grinshpun SA

Subjects

Humans, N95 Respirators, Pilot Projects, Pandemics prevention & control, Equipment Design, Occupational Exposure, COVID-19 prevention & control

Abstract

Throughout the COVID-19 pandemic, hundreds of millions of people worldwide have become new users of respiratory protective devices. Facemasks and KN95 respirators utilizing an ear loop straps system (ELSS) have recently become popular among occupational and non-occupational populations. Part of this popularity is due to the ease of wearability as compared with traditional devices utilizing two headbands, one worn over the head and the other behind the neck-a universal strap system used in NIOSH-certified N95 filtering facepiece respirators (FFRs). Some users convert the two-strap configuration to an adjustable ELSS. The first objective of this pilot study was to quantitatively characterize how such a conversion impacts the respirator fit. Additionally, a novel faceseal (NFS) technology, which has been previously demonstrated to enhance the fit of N95 FFRs, was deployed to modify the ELSS-converted N95 FFRs. The second objective of this study was to quantify the fit improvement that results from adding the NFS to the ELSS. The study was conducted by performing the Occupational Safety and Health Administration (OSHA)-approved quantitative fit testing (QNFT) on 16 human subjects featuring different facial shapes and dimensions. Three models of cup-shaped N95 FFRs were tested in three versions: the standard version with manufacturer's strap system, the ELSS-converted, and the ELSS-converted version modified by adding the NFS. QNFT demonstrated that the fit of an N95 FFR featuring the traditional/standard headbands strap system is negatively impacted when this system is converted to an ELSS. The fit of an ELSS-converted respirator can be significantly improved by the addition of the NFS. We found that the FFR model and the strap system version are significant factors affecting the QNFT-determined respirator fit factor (FF), as well as the OSHA QNFT pass rate (FF ≥100). The findings suggest that the current NFS, if further improved, has a potential for developing a 'universally fitting' ELSS-equipped N95 FFR that can be used by the general public, the vast majority of whom do not have access to OSHA fit requirements., (© The Author(s) 2022. Published by Oxford University Press on behalf of the British Occupational Hygiene Society.)

Published

2023

10. Technical note: Impact of face covering on aerosol transport patterns during coughing and sneezing.

Author

Grinshpun SA and Yermakov M

Abstract

COVID-19 is spread via different routes, including virus-laden airborne particles generated by human respiratory activities. In addition to large droplets, coughing and sneezing produce a lot of small aerosol particles. While face coverings are believed to reduce the aerosol transmission, information about their outward effectiveness is limited. Here, we determined the aerosol concentration patterns around a coughing and sneezing manikin and established spatial zones representing specific elevations of the aerosol concentration relative to the background. Real-time measurements of sub-micrometer aerosol particles were performed in the vicinity of the manikin. The tests were carried out without any face covering and with three different types of face covers: a safety faceshield, low-efficiency facemask and high-efficiency surgical mask. With no face covering, the simulated coughing and sneezing created a powerful forward-propagating fine aerosol flow. At 6 ft forward from the manikin head, the aerosol concentration was still 20-fold above the background. Adding a face covering reconfigured the forward-directed aerosol transmission pattern. The tested face coverings were found capable of mitigating the risk of coronavirus transmission; their effectiveness is dependent on the protective device. The outward leakage associated with a specific face covering was shown to be a major determinant of the exposure level for a person standing or seating next to or behind the coughing or sneezing "spreader" in a bus/train/aircraft/auditorium setting. Along with reports recently published in the literature, the study findings help assess the infectious dose and ultimately health risk for persons located within a 6-ft radius around the "spreader.", Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2021 Published by Elsevier Ltd.)

Published

2021

11. Coronavirus Disease 2019 Patients in Earlier Stages Exhaled Millions of Severe Acute Respiratory Syndrome Coronavirus 2 Per Hour.

Author

Ma J, Qi X, Chen H, Li X, Zhang Z, Wang H, Sun L, Zhang L, Guo J, Morawska L, Grinshpun SA, Biswas P, Flagan RC, and Yao M

Subjects

Humans, Respiratory System, COVID-19, SARS-CoV-2

Abstract

Coronavirus disease 2019 (COVID-19) patients exhaled millions of severe acute respiratory syndrome coronavirus 2 RNA copies per hour, which plays an important role in COVID-19 transmission. Exhaled breath had a higher positive rate (26.9%, n = 52) than surface (5.4%, n = 242) and air (3.8%, n = 26) samples., (© The Author(s) 2020. Published by Oxford University Press for the Infectious Diseases Society of America. All rights reserved. For permissions, e-mail: journals.permissions@oup.com.)

Published

2021

12. Evaluation of AccuFIT 9000: A Novel Apparatus for Quantitative Fit Testing of Particulate Respirators.

Author

Grinshpun SA, Yermakov M, and Kano M

Subjects

Humans, Japan, Materials Testing, SARS-CoV-2, Ventilators, Mechanical, COVID-19, Occupational Exposure

Abstract

Various strategies developed for protecting frontline workers and the general public from the novel coronavirus, SARS-CoV-2, largely rely on respiratory protective devices (RPDs), especially considering recent evidence about the aerosol transmission route of COVID-19. Performance of an RPD primarily depends on how well the protective device fits the wearer. Therefore, quantitative fit testing of particulate respirators is crucial for achieving the intended protection level. Millions of fit tests are conducted every year using a US OSHA-accepted standard protocol involving a PortaCount® (TSI Inc., Shoreview, MN, USA) which measures a respirator fit factor. Recently, several alternative fit testing instruments have been developed and introduced to the market. Among them is an AccuFIT 9000 (Kanomax-Japan Inc., Suita-city, Osaka, Japan), which, like the PortaCount®, utilizes the condensation particle counting principle, but features an advanced saturation chamber design allowing for a longer residence time and greater flow stability. It is also claimed to have a more cost-efficient assembly than its predecessors. In this study, the novel AccuFIT apparatus was extensively evaluated against the PortaCount® (the reference instrument) using the traditional standard fit testing protocol and following the American National Standards Institute (ANSI) standard (Z88.10-2010 Annex A2). The evaluation was performed with three types of respirators, N95 filtering facepiece respirator (FFR), P100 FFR, and half-mask elastomeric facepiece, of different models and manufacturers donned on 25 subjects. The comparative testing and analysis showed that the AccuFIT 9000 is capable of identifying an inadequate fit of the tested respirators with a sensitivity 0.95 and specificity of 0.97, which meets the ANSI requirement of ≥0.95. The other ANSI requirements/recommendations were also met. It was concluded that the novel fit testing apparatus demonstrated an acceptable performance and, thus, can be successfully deployed for the quantitative respirator fit testing., (© The Author(s) 2020. Published by Oxford University Press on behalf of the British Occupational Hygiene Society.)

Published

2021

13. Breath-, air- and surface-borne SARS-CoV-2 in hospitals.

Author

Zhou L, Yao M, Zhang X, Hu B, Li X, Chen H, Zhang L, Liu Y, Du M, Sun B, Jiang Y, Zhou K, Hong J, Yu N, Ding Z, Xu Y, Hu M, Morawska L, Grinshpun SA, Biswas P, Flagan RC, Zhu B, Liu W, and Zhang Y

Abstract

The COVID-19 pandemic has brought an unprecedented crisis to the global health sector. When discharging COVID-19 patients in accordance with throat or nasal swab protocols using RT-PCR, the potential risk of reintroducing the infection source to humans and the environment must be resolved. Here, 14 patients including 10 COVID-19 subjects were recruited; exhaled breath condensate (EBC), air samples and surface swabs were collected and analyzed for SARS-CoV-2 using reverse transcription-polymerase chain reaction (RT-PCR) in four hospitals with applied natural ventilation and disinfection practices in Wuhan. Here we discovered that 22.2% of COVID-19 patients (n = 9), who were ready for hospital discharge based on current guidelines, had SARS-CoV-2 in their exhaled breath (~10 5 RNA copies/m 3 ). Although fewer surface swabs (3.1%, n = 318) tested positive, medical equipment such as face shield frequently contacted/used by healthcare workers and the work shift floor were contaminated by SARS-CoV-2 (3-8 viruses/cm 2 ). Three of the air samples (n = 44) including those collected using a robot-assisted sampler were detected positive by a digital PCR with a concentration level of 9-219 viruses/m 3 . RT-PCR diagnosis using throat swab specimens had a failure rate of more than 22% in safely discharging COVID-19 patients who were otherwise still exhaling the SARS-CoV-2 by a rate of estimated ~1400 RNA copies per minute into the air. Direct surface contact might not represent a major transmission route, and lower positive rate of air sample (6.8%) was likely due to natural ventilation (1.6-3.3 m/s) and regular disinfection practices. While there is a critical need for strengthening hospital discharge standards in preventing re-emergence of COVID-19 spread, use of breath sample as a supplement specimen could further guard the hospital discharge to ensure the safety of the public and minimize the pandemic re-emergence risk., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2020 Elsevier Ltd. All rights reserved.)

Published

2021

14. ¿Cómo afecta la frecuencia respiratoria el desempeño de una mascarilla respiratoria autofiltrante N95 y de una mascarilla quirúrgica contra sustitutos de partículas virales?

Author

He X, Reponen T, McKay R, and Grinshpun SA

Abstract

ResumenLa frecuencia respiratoria (respiraciones/min) difiere entre los individuos y dependiendo de los niveles de actividad física. Las partículas ingresan a las mascarillas respiratorias mediante dos vías principales de penetración: infiltración a través del sellado facial y penetración a través de filtros. Sin embargo, se desconoce la forma en que la frecuencia respiratoria afecta el desempeño general de las mascarillas autofiltrantes N95 (filtering facepiece respirators, FFR) y las mascarillas quirúrgicas (MQ) contra partículas virales y otras partículas submicrómicas de importancia para la salud. En un maniquí de respiración a cuatro flujos inspiratorios medios (FIM) (15, 30, 55 y 85 L/min) y cinco frecuencias respiratorias (10, 15, 20, 25 y 30 respiraciones/min) se probaron una FFR y una MQ. En los dispositivos de protección respiratoria probados se determinaron la penetración a través del filtro (P filtro ) y la infiltración total hacia el interior (ITI) de partículas de aerosol de cloruro de sodio (NaCl) en tamaños que oscilaban entre 20 y 500 nm. Asimismo, se calcularon las proporciones de penetración de la "infiltración a través del sellado facial con respecto al filtro" (ISFF). Tanto el FIM como la frecuencia respiratoria mostraron efectos significativos (p < 0.05) en el P filtro y la ITI. El aumento de la frecuencia respiratoria incrementó la ITI para las FFR N95 mientras que en las MQ no se observaron tendencias claras. El aumento del FIM incrementó la P filtro y disminuyó la ITI, lo que dio lugar a una disminución de la proporción de la ISFF. La mayoría de las proporciones de la ISFF fueron >1, lo que sugiere que la infiltración a través del sellado facial fue la vía primaria de penetración de partículas a diversas frecuencias respiratorias. La frecuencia respiratoria es otro factor (además del FIM) que puede afectar significativamente el desempeño de las FFR N95: las frecuencias respiratorias más altas aumentan la ITI. En el caso de las MQ probadas no se observó ninguna tendencia consistente de aumento o disminución de la ITI relacionada con el FIM o la frecuencia respiratoria. Para ampliar potencialmente estos hallazgos más allá del maniquí/sistema respiratorio utilizado, se necesitan estudios futuros orientados a comprender plenamente el mecanismo que hace que la frecuencia respiratoria afecte el desempeño de los dispositivos de protección respiratoria en los sujetos humanos.

Published

2021

15. Eficacia de la mascarilla facial con filtro de partículas N95 y de la mascarilla quirúrgica durante la respiración humana: dos vías para la penetración de partículas.

Author

Grinshpun SA, Haruta H, Eninger RM, Reponen T, McKay RT, and Lee SA

Abstract

RESUMENEl nivel de protección ofrecido por las mascarillas con filtro de partículas y las mascarillas se establece considerando el porcentaje de partículas ambientales que penetran dentro del dispositivo de protección. Existen dos vías de penetración: (1) la infiltración a través del sellado facial de la mascarilla y (2) a través del medio filtrante. El objetivo principal de este estudio fue diferenciar el aporte proveniente de cada una de estas dos vías para partículas cuyo tamaño oscila entre 0.03-1 μm en condiciones de respiración reales. Así, mientras se realizaban pruebas de ajuste convencionales, se evaluaron una mascarilla respiratoria autofiltrante N95 y una mascarilla quirúrgica usada comúnmente en entornos de atención médica en 25 sujetos (número coincidente con el último panel de pruebas de ajuste del Instituto Nacional de Seguridad y Salud Laborales). Asimismo, ambas mascarillas fueron evaluadas empleando maniquíes de respiración que imitaban de forma precisa los patrones de respiración registrados previamente en los sujetos evaluados. Posteriormente, se compararon los datos de penetración obtenidos en las evaluaciones realizadas con sujetos humanos y con maniquíes para determinar los diferentes tamaños de partículas, así como los patrones de respiración. Así se determinaron 5,250 valores de penetración específicos correspondientes al ejercicio y el tamaño de las partículas. Para cada valor se calcularon la tasa de infiltración a través del sellado facial de la mascarilla y la tasa de infiltración a través del filtro, con la finalidad de cuantificar los aportes relativos realizados por cada vía de penetración. El número de partículas que penetra mediante infiltración del sellado facial de la mascarilla autofiltrante/mascarilla quirúrgica probadas excedió ampliamente el número de aquellas que lo hacen a través del filtro. Para la mascarilla autofiltrante N95, el exceso fue (en promedio) de un orden de magnitud y se incrementó notablemente al aumentar el tamaño de las partículas (p < 0.001): ∼7 veces mayor para 0,04 μm, ∼10 veces para 0.1 μm y ∼20 veces para 1 μm. En el caso de la mascarilla quirúrgica, la tasa de infiltración a través del sellado facial de la misma con respecto al filtro osciló entre 4.8 y 5.8 y no se vio significativamente afectada por el tamaño de las partículas para la fracción del submicrómetro evaluado. El movimiento facial/corporal tuvo un efecto pronunciado en el aporte relativo de las dos vías de penetración. La intensidad de la respiración y las dimensiones faciales mostraron alguna influencia (aunque limitada). Considerando que la mayoría de las partículas que penetraron ingresaron a través del sellado facial, al desarrollar la mascarilla autofiltrante/mascarilla quirúrgica la prioridad debería ser realizar una adecuación que permitiera eliminar o minimizar la infiltración a través del sellado facial y no mejorar la eficiencia del medio de filtro.

Published

2021

16. New respirator performance monitor (RePM) for powered air-purifying respirators.

Author

Grinshpun SA, Corey J, Yermakov M, Wu B, Strickland KT, Bergman M, and Zhuang Z

Subjects

Manikins, Occupational Exposure prevention & control, Particle Size, Sensitivity and Specificity, Sodium Chloride chemistry, Aerosols analysis, Equipment Failure Analysis methods, Respiratory Protective Devices standards

Abstract

Powered air-purifying respirators (PAPRs) that offer protection from particulates are deployed in different workplace environments. Usage of PAPRs by healthcare workers is rapidly increasing; these respirators are often considered the best option in healthcare settings, particularly during public health emergency situations, such as outbreaks of pandemic diseases. At the same time, lack of user training and certain vigorous work activities may lead to a decrease in a respirator's performance. There is a critical need for real-time performance monitoring of respiratory protective devices, including PAPRs. In this effort, a new robust and low-cost real-time performance monitor (RePM) capable of evaluating the protection offered by a PAPR against aerosol particles at a workplace was developed. The new device was evaluated on a manikin and on human subjects against a pair of condensation nuclei counters (P-Trak) used as the reference protection measurement system. The outcome was expressed as a manikin-based protection factor (mPF) and a Simulated Workplace Protection Factor (SWPF) determined while testing on subjects. For the manikin-based testing, the data points collected by the two methods were plotted against each other; a near-perfect correlation was observed with a correlation coefficient of 0.997. This high correlation is particularly remarkable since RePM and condensation particle counter (CPC) measure in different particle size ranges. The data variability increased with increasing mPF. The evaluation on human subjects demonstrated that RePM prototype provided an excellent Sensitivity (96.3% measured on human subjects at a response time of 60 sec) and a Specificity of 100%. The device is believed to be the first of its kind to quantitatively monitor PAPR performance while the wearer is working; it is small, lightweight, and does not interfere with job functions.

Published

2020

17. Autoclave sterilization and ethanol treatment of re-used surgical masks and N95 respirators during COVID-19: impact on their performance and integrity.

Author

Grinshpun SA, Yermakov M, and Khodoun M

Subjects

Betacoronavirus, COVID-19, Guidelines as Topic, Humans, SARS-CoV-2, United States, Coronavirus Infections prevention & control, Ethanol, Masks standards, Occupational Exposure prevention & control, Pandemics prevention & control, Pneumonia, Viral prevention & control, Respiratory Protective Devices standards, Sterilization standards, Ventilators, Mechanical standards

Abstract

Background: An exceptionally high demand for surgical masks and N95 filtering facepiece respirators (FFRs) during the COVID-19 pandemic has considerably exceeded their supply. These disposable devices are generally not approved for routine decontamination and re-use as a standard of care, while this practice has widely occurred in hospitals. The US Centers for Disease Control and Prevention allowed it "as a crisis capacity strategy". However, limited testing was conducted on the impact of specific decontamination methods on the performance of N95 FFRs and no data was presented for surgical masks., Aim: We evaluated common surgical masks and N95 respirators with respect to the changes in their performance and integrity resulting from autoclave sterilization and a 70% ethanol treatment; these methods are frequently utilized for re-used filtering facepieces in hospitals., Methods: The filter collection efficiency and pressure drop were determined for unused masks and N95 FFRs, and for those subjected to the treatments in a variety of ways. The collection efficiency was measured for particles of approximately 0.037-3.2 μm to represent aerosolized single viruses, their agglomerates, bacteria and larger particle carriers., Findings: The initial collection efficiency and the filter breathability may be compromised by sterilization in an autoclave and ethanol treatment. The effect depends on a protective device, particle size, breathing flow rate, type of treatment and other factors. Additionally, physical damages were observed in N95 respirators after autoclaving., Conclusion: Strategies advocating decontamination and re-use of filtering facepieces in hospitals should be re-assessed considering the data obtained in this study., (Copyright © 2020 The Healthcare Infection Society. Published by Elsevier Ltd. All rights reserved.)

Published

2020

18. Estimated dermal exposure to nebulized pharmaceuticals for a simulated home healthcare worker scenario.

Author

Ishau S, Reichard JF, Maier A, Niang M, Yermakov M, and Grinshpun SA

Subjects

Humans, Nebulizers and Vaporizers, Drug-Related Side Effects and Adverse Reactions etiology, Home Care Services, Occupational Exposure analysis, Skin drug effects

Abstract

The duties of home healthcare workers are extensive. One important task that is frequently performed by home healthcare workers is administration of nebulized medications, which may lead to significant dermal exposure. In this simulation study conducted in an aerosol exposure chamber, we administered a surrogate of nebulizer-delivered medications (dispersed sodium chloride, NaCl) to a patient mannequin. We measured the amount of NaCl deposited on the exposed surface of the home healthcare worker mannequin, which represented the exposed skin of a home healthcare worker. Factors such as distance and position of the home healthcare worker, room airflow rate and patient's inspiratory rate were varied to determine their effects on dermal exposure. There was a 2.78% reduction in dermal deposition for every centimeter the home healthcare worker moved away from the patient. Increasing the room's air exchange rate by one air change per hour increased dermal deposition by about 2.93%, possibly due to a decrease in near field particle settling. For every 10-degrees of arc the home healthcare worker is positioned from the left side of the patient toward the right and thus moving into the ventilation airflow direction, dermal deposition increased by about 4.61%. An increase in the patient's inspiratory rate from 15-30 L/min resulted in an average of 14.06% reduction in dermal deposition for the home healthcare worker, reflecting a relative increase in the aerosol fraction inhaled by the patient. The findings of this study elucidate the interactions among factors that contribute to dermal exposure to aerosolized pharmaceuticals administered by home healthcare workers. The results presented in this paper will help develop recommendations on mitigating the health risks related to dermal exposure of home healthcare workers.

Published

2020

19. Inactivation of bacterial and fungal spores by UV irradiation and gaseous iodine treatment applied to air handling filters.

Author

Nakpan W, Yermakov M, Indugula R, Reponen T, and Grinshpun SA

Subjects

Aspergillus fumigatus drug effects, Aspergillus fumigatus physiology, Bacillus thuringiensis drug effects, Bacillus thuringiensis physiology, Gases administration & dosage, Spores, Bacterial physiology, Spores, Fungal physiology, Air Filters microbiology, Air Pollution, Indoor analysis, Disinfection methods, Iodine administration & dosage, Spores, Bacterial drug effects, Spores, Fungal drug effects, Ultraviolet Rays

Abstract

Exposure to viable bacterial and fungal spores re-aerosolized from air handling filters may create a major health risk. Assessing and controlling this exposure have been of interest to the bio-defense and indoor air quality communities. Methods are being developed for inactivating stress-resistant viable microorganisms collected on ventilation filters. Here we investigated the inactivation of spores of Bacillus thuringiensis var. kurstaki (Btk), a recognized simulant for B. antracis, and Aspergillus fumigatus, a common opportunistic pathogen used as an indicator for indoor air quality. The viability change was measured on filters treated with ultraviolet (UV) irradiation and gaseous iodine. The spores were collected on high-efficiency particulate air (HEPA) and non-HEPA filters, both flattened for testing purposes to represent "surface" filters. A mixed cellulose ester (MCE) membrane filter was also tested as a reference. Additionally, a commercial HEPA unit with a deep-bed (non-flattened) filter was tested. Combined treatments of Btk spores with UV and iodine on MCE filter produced a synergistic inactivation effect. No similar synergy was observed for A. fumigatus. For spores collected on an MCE filter, the inactivation effect was about an order of magnitude greater for Btk compared to A. fumigatus. The filter type was found to be an important factor affecting the inactivation of Btk spores while it was not as influential for A. fumigatus. Overall, the combined effect of UV irradiation and gaseous iodine on viable bacterial and fungal spores collected on flat filters was found to be potent. The benefit of either simultaneous or sequential treatment was much lower for Btk spores embedded inside the deep-bed (non-flattened) HEPA filter, but for A. fumigatus the inactivation on flattened and non-flattened HEPA filters was comparable. For both species, applying UV first and gaseous iodine second produced significantly higher inactivation than when applying them simultaneously or in an opposite sequence., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

20. Indoor particulate matter and lung function in children.

Author

Isiugo K, Jandarov R, Cox J, Ryan P, Newman N, Grinshpun SA, Indugula R, Vesper S, and Reponen T

Subjects

Adolescent, Asthma physiopathology, Child, Cross-Over Studies, Female, Humans, Indiana, Kentucky, Male, Ohio, Spirometry, Air Pollutants adverse effects, Air Pollution, Indoor adverse effects, Environmental Monitoring, Particulate Matter adverse effects

Abstract

People generally spend more time indoors than outdoors resulting in a higher proportion of exposure to particulate matter (PM) occurring indoors. Consequently, indoor PM levels, in contrast to outdoor PM levels, may have a stronger relationship with lung function. To test this hypothesis, indoor and outdoor PM 2.5 and fungal spore data were simultaneously collected from the homes of forty-four asthmatic children aged 10-16 years. An optical absorption technique was utilized on the collected PM 2.5 mass to obtain concentrations of black carbon (BC) and ultraviolet light absorbing particulate matter, (UVPM; a marker of light absorbing PM 2.5 emitted from smoldering organics). Enrolled children completed spirometry after environmental measurements were made. Given the high correlation between PM 2.5 , BC, and UVPM, principal component analysis was used to obtain uncorrelated summaries of the measured PM. Separate linear mixed-effect models were developed to estimate the association between principal components of the PM variables and spirometry values, as well as the uncorrelated original PM variables and spirometry values. A one-unit increase in the first principal component variable representing indoor PM (predominantly composed of UVPM and PM 2.5 ) was associated with 4.1% decrease (99% CI = -6.9, -1.4) in FEV 1 /FVC ratio. 11.3 μg/m 3 increase in indoor UVPM was associated with 6.4% and 14.7% decrease (99% CI = -10.4, -2.4 and 99% CI = -26.3, -2.9, respectively) in percent predicted FEV 1 /FVC ratio and FEF 25-75 respectively. Additionally, 17.7 μg/m 3 increase in indoor PM 2.5 was associated with 6.1% and 12.9% decrease (99% CI = -10.2, -1.9 and 99% CI = -24.9, -1.0, respectively) in percent predicted FEV 1 /FVC ratio and FEF 25-75 , respectively. Outdoor PM, indoor BC, and indoor fungal spores were not significantly associated with lung function. The results indicate that indoor PM is more strongly associated with lung function in children with asthma as compared with outdoor PM., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

21. Predicting Indoor Concentrations of Black Carbon in Residential Environments.

Author

Isiugo K, Jandarov R, Cox J, Chillrud S, Grinshpun SA, Hyttinen M, Yermakov M, Wang J, Ross J, and Reponen T

Abstract

Black carbon (BC) is a descriptive term that refers to light-absorbing particulate matter (PM) produced by incomplete combustion and is often used as a surrogate for traffic-related air pollution. Exposure to BC has been linked to adverse health effects. Penetration of ambient BC is typically the primary source of indoor BC in the developed world. Other sources of indoor BC include biomass and kerosene stoves, lit candles, and charring food during cooking. Home characteristics can influence the levels of indoor BC. As people spend most of their time indoors, human exposure to BC can be associated to a large extent with indoor environments. At the same time, due to the cost of environmental monitoring, it is often not feasible to directly measure BC inside multiple individual homes in large-scale population-based studies. Thus, a predictive model for indoor BC is needed to support risk assessment in public health. In this study, home characteristics and occupant activities that potentially modify indoor levels of BC were documented in 23 homes, and indoor and outdoor BC concentrations were measured twice. The homes were located in the Cincinnati-Kentucky-Indiana tristate region and measurements occurred from September 2015 through August 2017. A linear mixed-effect model was developed to predict BC concentration in residential environments. The measured outdoor BC concentrations and the documented home characteristics were utilized as predictors of indoor BC concentrations. After the model was developed, a leave-one-out cross-validation algorithm was deployed to assess the predictive accuracy of the output. The following home characteristics and occupant activities significantly modified the concentration of indoor BC: outdoor BC, lit candles and electrostatic or high efficiency particulate air (HEPA) filters in heating, ventilation and air conditioning (HVAC) systems. Predicted indoor BC concentrations explained 78% of the variability in the measured indoor BC concentrations. The data show that outdoor BC combined with home characteristics can be used to predict indoor BC levels with reasonable accuracy., Competing Interests: Competing Interests Declarations of interest: none. Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests:

Published

2019

22. Evaluation of total and inhalable samplers for the collection of carbon nanotube and carbon nanofiber aerosols.

Author

Dahm MM, Evans DE, Bertke S, and Grinshpun SA

Abstract

A growing number of carbon nanotubes and nanofibers (CNT/F) exposure and epidemiologic studies have utilized 25-mm and 37-mm open-faced cassettes (OFC) to assess the inhalable aerosol fraction. It has been previously established that the 37-mm OFC under-samples particles greater than 20 μm in diameter, but the size-selective characteristics of the 25-mm OFC have not yet been fully evaluated. This article describes an experimental study conducted to determine if the 25- and 37-mm OFCs performed with relative equivalence to a reference inhalable aerosol sampler when challenged with CNT/F particles. Side-by-side paired samples were collected within a small Venturi chamber using a 25-mm styrene OFC, 37-mm styrene OFC, 25-mm aluminum OFC, and Button Inhalable Aerosol Sampler. Three types of CNT/F materials and an Arizona road dust were used as challenge aerosols for the various sampler configurations. Repeated experiments were conducted for each sampler configuration and material. The OFC samplers operated at flow rates of 2 and 5 liters per minute. Results showed that the 25-mm OFC performed comparably to the Button Sampler when challenged with CNT/F aerosols, which was demonstrated in five of the six experimental scenarios with an average error of 20%. Overall, the results of this study indicate that the sampling efficiency of the 25- and 37-mm OFCs adequately followed the ISO/ACGIH/CEN inhalable sampling convention when challenged with CNT/F aerosols. Past exposure and epidemiologic studies that used these OFC samplers can directly compare their results to studies that have used other validated inhalable aerosol samplers.

Published

2019

23. Combining sensor-based measurement and modeling of PM 2.5 and black carbon in assessing exposure to indoor aerosols.

Author

Cox J, Cho SH, Ryan P, Isiugo K, Ross J, Chillrud S, Zhu Z, Jandarov R, Grinshpun SA, and Reponen T

Abstract

Accurate, cost-effective methods are needed for rapid assessment of traffic-related air pollution (TRAP). Typically, real-time data of particulate matter (PM) from portable sensors have been adjusted using data from reference methods such as gravimetric measurement to improve accuracy. The objective of this study was to create a correction factor or linear regression model for the real-time measurements of the RTI's Micro Personal Exposure Monitor (MicroPEM ™ ) and AethLab's microAeth® black carbon (AE51) sensor to generate accurate real-time data for PM 2.5 (PM 2.5RT ) and black carbon (BC RT ) in Cincinnati metropolitan homes. The two sensors and an SKC PM 2.5 Personal Modular impactor were collocated in 44 indoor sampling events for 2 days in residences near major roadways. The reference filter-based analyses conducted by a laboratory included particle mass (SKC PM 2.5 and MicroPEM ™ PM 2.5 ) and black carbon (SKC BC); these methods are more accurate than real-time sensors but are also more cumbersome and costly. For PM 2.5 , the average correction factor, a ratio of gravimetric to real-time, for the MicroPEM ™ PM 2.5 and SKC PM 2.5 utilizing the PM 2.5RT and was 0.94 and 0.83, respectively, with a coefficient of variation (CV) of 84% and 52%, respectively; the corresponding linear regression model had a CV of 54% and 25%. For BC, the average correction factor utilizing the BC RT and SKC BC was 0.74 with a CV of 36% with the associated linear regression model producing a CV of 56%. The results from this study will help ensure that the real-time exposure monitors are capable of detecting an estimated PM 2.5 after an appropriate statistical model is applied.

Published

2019

24. Assessing the accuracy of commercially available gas sensors for the measurement of ambient ozone and nitrogen dioxide.

Author

Isiugo K, Newman N, Jandarov R, Grinshpun SA, and Reponen T

Subjects

Air Pollutants analysis, Environmental Monitoring instrumentation, Humidity, Occupational Exposure analysis, Temperature, Nitrogen Dioxide analysis, Ozone analysis

Abstract

The objective of the National Institute for Occupational Safety and Health (NIOSH) accuracy criterion is to ensure that measurements from monitoring devices are within ±25% of the true concentration of the analyte with 95% certainty. To determine whether NO 2 and O 3 sensors meet this criterion, three commercially available units (Cairclip O 3 /NO 2 , Aeroqual NO 2 , and Aeroqual O 3 sensors) were co-located three times with validated instruments (NO x chemiluminescence [NO 2mon ] and photometric O 3 analyzers [O 3mon ]) at an outdoor monitoring station. As cofactors of sensor performance such as temperature (T) and relative humidity (RH) potentially influence the response of NO 2 and O 3 sensors, corrections for cofactors were made by using T, RH, and the sensor measurements to predict measurements made by NO 2mon and O 3mon during the first co-location period (training dataset). The developed models were tested in the merged data obtained from the second and third co-location periods (testing dataset). In the training and testing datasets, the mean NO 2 as measured by NO 2mon was 4.6 ppb (range = 0.4-35 ppb) and 9.4 ppb (range = 1-37 ppb), respectively. The mean O 3 in the training and testing datasets as measured by O 3mon was 38.8 ppb (range = 1-65 ppb) and 35.7 ppb (range = 1-61 ppb), respectively. None of the sensor measurements in the training dataset were within the NIOSH accuracy criterion (mean error ≥25%). After correcting for cofactors of sensor performance, the accuracy of the Cairclip O 3 /NO 2 and the Aeroqual O 3 sensors considerably improved when tested with the testing dataset (mean error = -1% and 14%, respectively). However, the Aeroqual NO 2 sensor had an error that was not within ±25%. Raw measurements from the tested sensors may be unsuitable for assessing workers' exposure to NO 2 and O 3 . Corrections for cofactors of Cairclip O 3 /NO 2 and Aeroqual O 3 sensor performance are required for more accurate occupational exposure assessment.

Published

2018

25. Effectiveness of a portable air cleaner in removing aerosol particles in homes close to highways.

Author

Cox J, Isiugo K, Ryan P, Grinshpun SA, Yermakov M, Desmond C, Jandarov R, Vesper S, Ross J, Chillrud S, Dannemiller K, and Reponen T

Subjects

Carbon, Environmental Monitoring, Humidity, Regression Analysis, Housing, Particulate Matter analysis, Vehicle Emissions analysis, Air Filters

Abstract

Outdoor traffic-related airborne particles can infiltrate a building and adversely affect the indoor air quality. Limited information is available on the effectiveness of high efficiency particulate air (HEPA) filtration of traffic-related particles. Here, we investigated the effectiveness of portable HEPA air cleaners in reducing indoor concentrations of traffic-related and other aerosols, including black carbon (BC), PM 2.5 , ultraviolet absorbing particulate matter (UVPM) (a marker of tobacco smoke), and fungal spores. This intervention study consisted of a placebo-controlled cross-over design, in which a HEPA cleaner and a placebo "dummy" were placed in homes for 4-weeks each, with 48-hour air sampling conducted prior to and during the end of each treatment period. The concentrations measured for BC, PM 2.5 , UVPM, and fungal spores were significantly reduced following HEPA filtration, but not following the dummy period. The indoor fraction of BC/PM 2.5 was significantly reduced due to the HEPA cleaner, indicating that black carbon was particularly impacted by HEPA filtration. This study demonstrates that HEPA air purification can result in a significant reduction of traffic-related and other aerosols in diverse residential settings., (© 2018 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2018

26. Performance of a novel real-time respirator seal integrity monitor on firefighters: Simulated workplace pilot study.

Author

Leppänen M, Wu B, Corey J, Yermakov M, and Grinshpun SA

Subjects

Female, Humans, Inhalation Exposure prevention & control, Male, Occupational Exposure prevention & control, Pilot Projects, Sodium Chloride, Aerosols analysis, Firefighters, Respiratory Protective Devices standards

Abstract

Millions of workers, including firefighters, use respiratory protective device. The key aspect in assuring the intended protection level of a respirator is its fit. However, even if the respirator originally fits well, the faceseal may be breached during its use. Until now, there have been no practically viable, inexpensive means to monitor the performance of a respirator during actual use. A novel Respirator Seal Integrity Monitor (ReSIM) was developed and recently evaluated on manikins by our team. The objective of this study was to evaluate the ReSIM effectiveness on respirator-wearing firefighters exposed to aerosols while performing simulated routine operational activities. Initially, 15 subjects were recruited for the study. Following a preliminary investigation that resulted in modifications in the ReSIM prototype and testing protocol, a subset of nine firefighters was chosen for a full-scale evaluation. The testing was conducted in a 24.3-m 3 exposure chamber using NaCl as the challenge aerosol. Controlled faceseal leaks were established by opening a solenoid valve for 10, 15, or 20 sec. Leaks were also established as the tested firefighter slightly repositioned the respirator on his/her face. During the testing, the ReSIM measured particles inside a full-face elastomeric respirator with a 72.7% leak detection sensitivity (probability of correct leak identification) and an 84.2% specificity (probability of correct identification of the intervals which are absent of any leak). After adjusting for false negatives and persistent false positives, sensitivity and specificity increased to 83.6% and 92.2%, respectively. The factors causing minor limitations in leak detection sensitivity and specificity can be attributed to variability among subjects, moisture's effect on the particle sensor, and some in-mask sampling bias. In conclusion, the ReSIM can promptly detect the breach in a respirator faceseal with high sensitivity and specificity. Due to its capability to alert the wearer of possible overexposure to hazardous aerosols, the ReSIM concept has a remarkable potential to be applied in various working environments, where respirators are used.

Published

2018

27. Laboratory Evaluation of a Novel Real-Time Respirator Seal Integrity Monitor.

Author

Wu B, Corey J, Yermakov M, Liu Y, and Grinshpun SA

Subjects

Humans, Manikins, Particle Size, Aerosols analysis, Air Pollutants, Occupational analysis, Occupational Exposure analysis, Respiratory Protective Devices standards

Abstract

Background: A low-cost real-time Respirator Seal Integrity Monitor (ReSIM) was recently developed to monitor a respirator's actual performance at a workplace. The objective of this study was to evaluate the capability of the new ReSIM prototype in manikin-based laboratory experiments to rapidly detect induced leakage of a half-mask elastomeric respirator., Methods: Two phases of testing were conducted in this study. First, the accuracy of ReSIM measuring an aerosol concentration was assessed by comparing the outputs of ReSIM against a reference optical aerosol spectrometer (OAS) in a flow-through set-up. Second, the capability to detect a leak was tested using a manikin-based set-up to simulate leaks into a functional respirator., Results: The regression curve of ReSIM versus OAS had an R2 of 0.936, indicating its high accuracy within the targeted particle size range of 0.5-2 µm. The ReSIM provided a leak detection sensitivity (probability of correctly identifying intervals with the true leak) of 98.4% when challenged with a combustion aerosol, compared to 71.8% when challenged with a NaCl aerosol. Its specificity (probability of identifying intervals without a leak) was 99.8% after adjusting for persistent false positives for both types of challenge aerosol., Conclusion: The ReSIM prototype not only can estimate the particle concentration with high accuracy but also can rapidly detect respirator faceseal leakage in real time with sufficient sensitivity and specificity. In addition, it can trigger an alarm when the faceseal integrity is compromised.

Published

2018

28. Exposure assessments for a cross-sectional epidemiologic study of US carbon nanotube and nanofiber workers.

Author

Dahm MM, Schubauer-Berigan MK, Evans DE, Birch ME, Bertke S, Beard JD, Erdely A, Fernback JE, Mercer RR, and Grinshpun SA

Subjects

Air Pollutants, Occupational adverse effects, Carbon adverse effects, Cross-Sectional Studies, Environmental Monitoring, Humans, Inhalation Exposure adverse effects, Microscopy, Electron, Transmission, Occupational Diseases etiology, Occupational Exposure adverse effects, Occupations, Respiratory Tract Diseases etiology, Skin Diseases etiology, Sputum, United States, Work, Workplace, Air Pollutants, Occupational analysis, Industry, Inhalation Exposure analysis, Nanofibers adverse effects, Nanofibers analysis, Nanotubes, Carbon adverse effects, Nanotubes, Carbon analysis, Occupational Exposure analysis, Particle Size

Abstract

Background: Recent animal studies have suggested the potential for wide-ranging health effects resulting from exposure to carbon nanotubes and nanofibers (CNT/F). To date, no studies in the US have directly examined the relationship between occupational exposure and potential human health effects., Objectives: Our goal was to measure CNT/F exposures among US workers with representative job types, from non-exposed to highly exposed, for an epidemiologic study relating exposure to early biologic effects., Methods: 108 participants were enrolled from 12 facilities across the US. Personal, full-shift exposures were assessed based on the mass of elemental carbon (EC) at the respirable and inhalable aerosol particle size fractions, along with quantitatively characterizing CNT/F and estimating particle size via transmission electron microscopy (TEM). Additionally, sputum and dermal samples were collected and analyzed to determine internal exposures and exposures to the hands/wrists., Results: The mean exposure to EC was 1.00 μg/m 3 at the respirable size fraction and 6.22 μg/m 3 at the inhalable fraction. Analysis by TEM found a mean exposure of 0.1275 CNT/F structures/cm 3 , generally to agglomerated materials between 2 and 10 μm. Internal exposures to CNT/F via sputum analysis were confirmed in 18% of participants while ∼70% had positive dermal exposures., Conclusions: We demonstrated the occurrence of a broad range of exposures to CNT/F within 12 facilities across the US. Analysis of collected sputum indicated internal exposures are currently occurring within the workplace. This is an important first step in determining if exposures in the workforce have any acute or lasting health effects., (Published by Elsevier GmbH.)

Published

2018

29. Surgical Smoke Simulation Study: Physical Characterization and Respiratory Protection.

Author

Elmashae Y, Koehler RH, Yermakov M, Reponen T, and Grinshpun SA

Abstract

Exposure of operating room (OR) personnel to surgical smoke, a unique aerosol generated from the common use of electrocautery during surgical procedures, is an increasing health risk concern. The main objective of this simulation study was to characterize the surgical smoke exposure in terms of the particle number concentration and size distribution in a human breathing zone. Additionally, the performance of respiratory protective devices designed for ORs was examined using two commercially available N95 facepiece filtering respirators (FFRs) as well as the same FFRs modified with new faceseal technology. The tests were conducted in an OR-simulating exposure chamber with the surgical smoke generated by electrocautery equipment applied to animal tissue and measured in the breathing zone with four aerosol spectrometers. The simulated workplace protection factor of each tested respirator was determined for ten subjects by measuring the total aerosol concentrations inside and outside of a respirator. The peak of the particle size distribution was in a range of 60-150 nm. The concentration of particles generated during the simulated surgical procedure significantly exceeded the background concentration under all tested air exchange conditions. The data suggest that wearing N95 filtering facepiece respirators significantly decreased the human exposure to surgical smoke. The new faceseal technology provided significantly higher respiratory protection than the commercial N95 FFRs.

Published

2018

30. Performance of two respiratory protective devices used by home-attending health care workers (a pilot study).

Author

Elmashae RBY, Grinshpun SA, Reponen T, Yermakov M, and Riddle R

Subjects

Air Pollutants, Occupational analysis, Female, Health Personnel, Home Care Services, Humans, Inhalation Exposure prevention & control, Occupational Exposure prevention & control, Pilot Projects, Aerosols analysis, Filtration instrumentation, Masks statistics & numerical data, Respiratory Protective Devices statistics & numerical data

Abstract

Objectives: This pilot study aimed at determining the Workplace Protection Factor (WPF) for respiratory protective devices widely used by health care workers to reduce exposure to potentially hazardous aerosols when attending patients in their homes. Two devices were tested, an N95 filtering facepiece respirator (FFR) and a surgical mask (SM)., Methods: Three home-attending health care workers were recruited, medically cleared and fit tested. At the workplace, the aerosol concentrations outside (C out ) and inside (C in ) of the tested respiratory protective device worn by a subject were measured using two simultaneously operating P-Trak condensation particle counters within the particle size range of approximately 20-1,000 nm. Real-time and integrated (time-weighted average, TWA) values of WPF = C out /C in were determined., Results: This pilot study demonstrated that the WPF of the tested N95 FFR consistently exceeded that of the SM. The WPF TWA(C) values calculated for the entire test time (based on the TWA aerosol concentration values) ranged from 29 to 40 and 2 to 9, respectively. In all cases, the N95 FFR provided protection above the Occupational Safety and Health Administration's (OSHA) assigned protection factor of 10, whereas the SM often offered little or essentially no protection against the measured sub-micrometer aerosol particles. For both devices, the protection level was found to depend on activity. For example, the WPF TWA(C) for one subject wearing the N95 FFR was 56 during normal activity but fell almost 70% during tracheal suctioning. It is explicable considering that different procedures implemented by health care workers in homes generate particles of different sizes and require different body movements; both factors are anticipated to affect the WPF., Conclusions: Wearing an N95-certified respirator helps significantly reduce the aerosol inhalation exposure of home-attending health care workers. An SM offers much lower protection. The WPF depends on several factors, including, but not limited to, the health care worker's activity and/or body movements; the WPF varies from one worker to another.

Published

2017

31. Evaluation of personal inhalable aerosol samplers with different filters for use during anthrax responses.

Author

Grinshpun SA, Weber AM, Yermakov M, Indugula R, Elmashae Y, Reponen T, and Rose L

Subjects

Bioterrorism, Equipment Design, Inhalation Exposure, Materials Testing, Spores, Bacterial, Aerosols analysis, Bacillus anthracis, Environmental Monitoring methods, Filtration instrumentation

Abstract

Risk of inhalation exposure to viable Bacillus anthracis (B. anthracis) spores has primarily been assessed using short-term, stationary sampling methods which may not accurately characterize the concentration of inhalable-sized spores reaching a person's breathing zone. While a variety of aerosol sampling methods have been utilized during previous anthrax responses, no consensus has yet been established for personal air sampling. The goal of this study was to determine the best sampler-filter combination(s) for the collection and extraction of B. anthracis spores. The study was designed to (1) evaluate the performance of four filter types (one mixed cellulose ester, MCE (pore size = 3 µm), two polytetrafluoroethylene, PTFE (1 and 3 µm), and one polycarbonate, PC (3 µm)); and (2) evaluate the best performing filters in two commercially available inhalable aerosol samplers (IOM and Button). Bacillus thuringiensis kurstaki [Bt(k)], a simulant for B. anthracis, served as the aerosol challenge. The filters were assessed based on criteria such as ability to maintain low pressure drop over an extended sampling period, filter integrity under various environmental conditions, spore collection and extraction efficiencies, ease of loading and unloading the filters into the samplers, cost, and availability. Three of the four tested collection filters-except MCE-were found suitable for efficient collection and recovery of Bt(k) spores sampled from dry and humid as well as dusty and clean air environments for up to 8 hr. The PC (3 µm) filter was identified as the best performing filter in this study. The PTFE (3 µm) demonstrated a comparable performance, but it is more expensive. Slightly higher concentrations were measured with the IOM inhalable sampler which is the preferred sampler's performance criterion when detecting a highly pathogenic agent with no established "safe" inhalation exposure level. Additional studies are needed to address the effects of environmental conditions and spore concentration. The data obtained in this investigation are crucial for future efforts on the development and optimization of a method for assessing inhalation exposure to B. anthracis.

Published

2017

32. Performance of N95 FFRs Against Combustion and NaCl Aerosols in Dry and Moderately Humid Air: Manikin-based Study.

Author

Gao S, Kim J, Yermakov M, Elmashae Y, He X, Reponen T, Zhuang Z, Rengasamy S, and Grinshpun SA

Subjects

Air Pollutants, Occupational, Equipment Design, Filtration instrumentation, Humans, Materials Testing methods, Occupational Exposure, Particle Size, Plastics analysis, Respiratory Protective Devices standards, Respiratory Rate, United States, Aerosols analysis, Humidity, Inhalation Exposure analysis, Manikins, Respiratory Protective Devices statistics & numerical data, Sodium Chloride analysis

Abstract

Objectives: The first objective of this study was to evaluate the penetration of particles generated from combustion of plastic through National Institute for Occupational Safety and Health (NIOSH)-certified N95 filtering facepiece respirators (FFRs) using a manikin-based protocol and compare the data to the penetration of NaCl particles. The second objective was to investigate the effect of relative humidity (RH) on the filtration performance of N95 FFRs., Methods: Two NIOSH-certified N95 FFRs (A and B) were fully sealed on a manikin headform and challenged with particles generated by combustion of plastic and NaCl particles. The tests were performed using two cyclic flows [with mean inspiratory flow (MIF) rates = 30 and 85 l min(-1), representing human breathing under low and moderate workload conditions] and two RH levels (≈20 and ≈80%, representing dry and moderately humid air). The total and size-specific particle concentrations inside (C in) and outside (C out) of the respirators were measured with a condensation particle counter and an aerosol size spectrometer. The penetration values (C in/C out) were calculated after each test., Results: The challenge aerosol, RH, MIF rate, and respirator type had significant (P < 0.05) effects on the performance of the manikin-sealed FFR. Its efficiency significantly decreased when the FFR was tested with plastic combustion particles compared to NaCl aerosols. For example, at RH ≈80% and MIF = 85 l min(-1), as much as 7.03 and 8.61% of combustion particles penetrated N95 respirators A and B, respectively. The plastic combustion particles and gaseous compounds generated by combustion likely degraded the electric charges on fibers, which increased the particle penetration. Increasing breathing flow rate or humidity increased the penetration (reduced the respirator efficiency) for all tested aerosols. The effect of particle size on the penetration varied depending on the challenge aerosol and respirator type. It was observed that the peak of the size distribution of combustion particles almost coincided with their most penetrating particle size, which was not the case for NaCl particles. This finding was utilized for the data interpretation., Conclusions: N95 FFRs have lower filter efficiency when challenged with contaminant particles generated by combustion, particularly when used under high humidity conditions compared to NaCl particles., (© The Author 2016. Published by Oxford University Press on behalf of the British Occupational Hygiene Society.)

Published

2016

33. Indoor air quality in green-renovated vs. non-green low-income homes of children living in a temperate region of US (Ohio).

Author

Coombs KC, Chew GL, Schaffer C, Ryan PH, Brokamp C, Grinshpun SA, Adamkiewicz G, Chillrud S, Hedman C, Colton M, Ross J, and Reponen T

Subjects

Air Pollutants analysis, Air Pollution, Indoor statistics & numerical data, Child, Conservation of Natural Resources, Construction Materials, Environmental Monitoring, Formaldehyde analysis, Humans, Ohio, Poverty, Volatile Organic Compounds analysis, Air Pollution, Indoor analysis, Environmental Exposure statistics & numerical data

Abstract

Green eco-friendly housing includes approaches to reduce indoor air pollutant sources and to increase energy efficiency. Although sealing/tightening buildings can save energy and reduce the penetration of outdoor pollutants, an adverse outcome can be increased buildup of pollutants with indoor sources. The objective of this study was to determine the differences in the indoor air quality (IAQ) between green and non-green homes in low-income housing complexes. In one housing complex, apartments were renovated using green principles (n=28). Home visits were conducted immediately after the renovation, and subsequently at 6 months and at 12 months following the renovation. Of these homes, eight homes had pre-renovation home visits; this allowed pre- and post-renovation comparisons within the same homes. Parallel visits were conducted in non-green (control) apartments (n=14) in a nearby low-income housing complex. The IAQ assessments included PM2.5, black carbon, ultrafine particles, sulfur, total volatile organic compounds (VOCs), formaldehyde, and air exchange rate. Data were analyzed using linear mixed-effects models. None of the indoor pollutant concentrations were significantly different between green and non-green homes. However, we found differences when comparing the concentrations before and after renovation. Measured immediately after renovation, indoor black carbon concentrations were significantly lower averaging 682 ng/m(3) in post-renovation vs. 2364 ng/m(3) in pre-renovation home visits (p=0.01). In contrast, formaldehyde concentrations were significantly higher in post-renovated (0.03 ppm) than in pre-renovated homes (0.01 ppm) (p=0.004). Questionnaire data showed that opening of windows occurred less frequently in homes immediately post-renovation compared to pre-renovation; this factor likely affected the levels of indoor black carbon (from outdoor sources) and formaldehyde (from indoor sources) more than the renovation status itself. To reduce IAQ problems and potentially improve health, careful selection of indoor building materials and ensuring sufficient ventilation are important for green building designs., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2016

34. Performance of Facepiece Respirators and Surgical Masks Against Surgical Smoke: Simulated Workplace Protection Factor Study.

Author

Gao S, Koehler RH, Yermakov M, and Grinshpun SA

Subjects

Air Pollutants, Occupational analysis, Female, Humans, Male, Materials Testing, Particle Size, Workplace, Inhalation Exposure prevention & control, Masks, Occupational Exposure prevention & control, Operating Rooms, Respiratory Protective Devices, Smoke

Abstract

Objective: Surgical smoke generated during electrocautery contains toxins which may cause adverse health effects to operating room (OR) personnel. The objective of this study was to investigate the performance of surgical masks (SMs), which are routinely used in ORs, more efficient N95 surgical mask respirator (SMRs) and N100 filtering facepiece respirator (FFRs), against surgical smoke., Methods: Ten subjects were recruited to perform surgical dissections on animal tissue in a simulated OR chamber, using a standard electrocautery device, generating surgical smoke. Six respiratory protective devices (RPDs) were tested: two SMs, two SMRs, and two N100 FFRs [including a newly developed faceseal (FS) prototype]. Fit testing was conducted before the experiment. Each subject was then exposed to the surgical smoke while wearing an RPD under the tests. Concentrations inside (C in) and outside (C out) of the RPD were measured by a particle size spectrometer. The simulated workplace protection factor (SWPF) was determined by the ratio of C out and C in for each RPD-wearing subject., Results: For the SMs, the geometric means of SWPFtotal (based on the total aerosol concentration) were 1.49 and 1.76, indicating minimal protection. The SWPFtotal values of the SMRs and N100 FFRs were significantly higher than those of the SMs: for the two SMRs, the SWPFtotal were 208 and 263; for the two N100s, the SWPFtotal values were 1,089 and 2,199. No significant difference was observed between either the two SMs or the two SMRs. The SWPFtotal for the novel FS prototype N100 FFR was significantly higher than the conventional N100 FFR. The correlation between SWPFtotal and fit factor (FF) determined for two N95 SMRs was not significant., Conclusions: SMs do not provide measurable protection against surgical smoke. SMRs offer considerably improved protection versus SMs, while the N100 FFRs showed significant improvement over the SMRs. The FS prototype offered a higher level of protection than the standard N100 FFR, due to a tighter seal. While we acknowledge that conventional N100 FFRs (equipped with exhalation valves) are not practical for human OR use, the results obtained with the FS prototype demonstrate the potential of the new FS technology for implementation on various types of respirators., (© The Author 2016. Published by Oxford University Press on behalf of the British Occupational Hygiene Society.)

Published

2016

35. Culturability of Bacillus spores on aerosol collection filters exposed to airborne combustion products of Al, Mg, and B·Ti.

Author

Adhikari A, Yermakov M, Indugula R, Reponen T, Driks A, and Grinshpun SA

Subjects

Aerosols, Bacillus drug effects, Bacillus physiology, Bacillus anthracis isolation & purification, Bacillus anthracis physiology, Bacillus thuringiensis isolation & purification, Bacillus thuringiensis physiology, Bioterrorism, Boron pharmacology, Magnesium pharmacology, Microbial Viability drug effects, Spores, Bacterial drug effects, Titanium pharmacology, Air Filters microbiology, Aluminum pharmacology, Bacillus isolation & purification, Fires, Models, Theoretical, Spores, Bacterial isolation & purification

Abstract

Destruction of bioweapon facilities due to explosion or fire could aerosolize highly pathogenic microorganisms. The post-event air quality assessment is conducted through air sampling. A bioaerosol sample (often collected on a filter for further culture-based analysis) also contains combustion products, which may influence the microbial culturability and, thus, impact the outcome. We have examined the interaction between spores deposited on collection filters using two simulants of Bacillus anthracis [B. thuringiensis (Bt) and B. atrophaeus (referred to as BG)] and incoming combustion products of Al as well as Mg and B·Ti (common ingredient of metalized explosives). Spores extracted from Teflon, polycarbonate, mixed cellulose ester (MCE), and gelatin filters (most common filter media for bioaerosol sampling), which were exposed to combustion products during a short-term sampling, were analyzed by cultivation. Surprisingly, we observed that aluminum combustion products enhanced the culturability of Bt (but not BG) spores on Teflon filters increasing the culturable count by more than an order of magnitude. Testing polycarbonate and MCE filter materials also revealed a moderate increase of culturability although gelatin did not. No effect was observed with either of the two species interacting on either filter media with products originated by combustion of Mg and B·Ti. Sample contamination, spore agglomeration, effect of a filter material on the spore survival, changes in the spore wall ultrastructure and germination, as well as other factors were explored to interpret the findings. The study raises a question about the reliability of certain filter materials for collecting airborne bio-threat agents in combustion environments., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

36. Performance of an improperly sized and stretched-out loose-fitting powered air-purifying respirator: Manikin-based study.

Author

Gao S, McKay RT, Yermakov M, Kim J, Reponen T, He X, Kimura K, and Grinshpun SA

Subjects

Aerosols analysis, Air Pollutants, Occupational analysis, Humans, Inhalation Exposure analysis, Inhalation Exposure prevention & control, Manikins, Occupational Exposure analysis, Occupational Exposure prevention & control, Particle Size, Sodium Chloride analysis, Materials Testing, Respiratory Protective Devices

Abstract

The objective of this study was to investigate the protection level offered by a Powered Air-Purifying Respirator (PAPR) equipped with an improperly sized or stretched-out loose-fitting facepiece using constant and cyclic flow conditions. Improperly sized PAPR facepieces of two models as well as a stretched-out facepiece were tested. These facepieces were examined in two versions: with and without exhaust holes. Loose-fitting facepieces (size "large") were donned on a small manikin headform and challenged with sodium chloride (NaCl) aerosol particles in an exposure chamber. Four cyclic flows with mean inspiratory flows (MIFs) of 30, 55, 85, and 135 L/min were applied using an electromechanical Breathing Recording and Simulation System (BRSS). The manikin Fit Factor (mFF) was determined as the ratio of aerosol concentrations outside (Cout) to inside (Cin) of the facepiece, measured with a P-Trak condensation particle counter (CPC). Results showed that the mFF decreased exponentially with increasing MIF. The mFF values of the stretched-out facepiece were significantly lower than those obtained for the undamaged ones. Facepiece type and MIF were found to significantly affect the performance of the loose-fitting PAPR. The effect of the exhaust holes was less pronounced and depended on the facepiece type. It was concluded that an improperly sized facepiece might potentially offer relatively low protection (mFF < 250) at high to strenuous workloads. The testing was also performed at a constant inhalation flow to explore the mechanism of the particle-facepiece interaction. Results obtained with cyclic flow pattern were consistent with the data generated when testing the loose-fitting PAPR under constant flow conditions. The time-weighted average values of mFF calculated from the measurements conducted under the constant flow regime were capable of predicting the protection under cyclic flow regime. The findings suggest that program administrators need to equip employees with properly sized facepieces and remove stretched-out ones from workplace. Manufacturers should emphasize the importance of proper sizing with their user instructions.

Published

2016

37. Timing and Duration of Traffic-related Air Pollution Exposure and the Risk for Childhood Wheeze and Asthma.

Author

Brunst KJ, Ryan PH, Brokamp C, Bernstein D, Reponen T, Lockey J, Khurana Hershey GK, Levin L, Grinshpun SA, and LeMasters G

Subjects

Age Factors, Child, Child, Preschool, Female, Humans, Infant, Longitudinal Studies, Male, Risk Factors, Time Factors, Air Pollutants adverse effects, Air Pollution adverse effects, Asthma epidemiology, Environmental Exposure adverse effects, Respiratory Sounds etiology, Vehicle Emissions

Abstract

Rationale: The timing and duration of traffic-related air pollution (TRAP) exposure may be important for childhood wheezing and asthma development., Objectives: We examined the relationship between TRAP exposure and longitudinal wheezing phenotypes and asthma at age 7 years., Methods: Children completed clinical examinations annually from age 1 year through age 4 years and age 7 years. Parental-reported wheezing was assessed at each age, and longitudinal wheezing phenotypes (early-transient, late-onset, persistent) and asthma were defined at age 7 years. Participants' time-weighted exposure to TRAP, from birth through age 7 years, was estimated using a land-use regression model. The relationship between TRAP exposure and wheezing phenotypes and asthma was examined., Measurements and Main Results: High TRAP exposure at birth was significantly associated with both transient and persistent wheezing phenotypes (adjusted odds ratio [aOR] = 1.64; 95% confidence interval [CI], 1.04-2.57 and aOR = 2.31; 95% CI, 1.28-4.15, respectively); exposure from birth to age 1 year and age 1 to 2 years was also associated with persistent wheeze. Only children with high average TRAP exposure from birth through age 7 years were at significantly increased risk for asthma (aOR = 1.71; 95% CI, 1.01-2.88)., Conclusions: Early-life exposure to TRAP is associated with increased risk for persistent wheezing, but only long-term exposure to high levels of TRAP throughout childhood was associated with asthma development.

Published

2015

38. MS2 virus inactivation by atmospheric-pressure cold plasma using different gas carriers and power levels.

Author

Wu Y, Liang Y, Wei K, Li W, Yao M, Zhang J, and Grinshpun SA

Subjects

Bacteriophages ultrastructure, Electrophoresis, Polyacrylamide Gel, Microscopy, Electron, Scanning, RNA, Viral analysis, Reverse Transcriptase Polymerase Chain Reaction, Time Factors, Viral Proteins analysis, Atmospheric Pressure, Bacteriophages physiology, Disinfection methods, Microbial Viability, Plasma Gases, Virus Inactivation

Abstract

In this study, airborne MS2 bacteriophages were exposed for subsecond time intervals to atmospheric-pressure cold plasma (APCP) produced using different power levels (20, 24, and 28 W) and gas carriers (ambient air, Ar-O2 [2%, vol/vol], and He-O2 [2%, vol/vol]). In addition, waterborne MS2 viruses were directly subjected to the APCP treatment for up to 3 min. MS2 viruses with and without the APCP exposure were examined by scanning electron microscopy (SEM), reverse transcription-PCR (RT-PCR), and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Viral inactivation was shown to exhibit linear relationships with the APCP generation power and exposure time (R(2) > 0.95 for all energy levels tested) up to 95% inactivation (1.3-log reduction) after a subsecond airborne exposure at 28 W; about the same inactivation level was achieved for waterborne viruses with an exposure time of less than 1 min. A larger amount of reactive oxygen species (ROS), such as atomic oxygen, in APCP was detected for a higher generation power with Ar-O2 and He-O2 gas carriers. SEM images, SDS-PAGE, and agarose gel analysis of exposed waterborne viruses showed various levels of damage to both surface proteins and their related RNA genes after the APCP exposure, thus leading to the loss of their viability and infectivity., (Copyright © 2015, American Society for Microbiology. All Rights Reserved.)

Published

2015

39. Protection of firefighters against combustion aerosol particles: simulated workplace protection factor of a half-mask respirator (pilot study).

Author

Dietrich J, Yermakov M, Reponen T, Kulkarni P, Qi C, and Grinshpun SA

Subjects

Adult, Aerosols analysis, Female, Fires, Humans, Inhalation Exposure prevention & control, Male, Occupational Exposure analysis, Occupational Exposure prevention & control, Particle Size, Particulate Matter analysis, Pilot Projects, Air Pollutants, Occupational analysis, Firefighters, Inhalation Exposure analysis, Respiratory Protective Devices

Abstract

The present pilot study investigated the penetration of ultrafine particles originated by combustion of different materials into elastomeric half-mask respirators equipped with two P100 filters. We determined the Simulated Workplace Protection Factor (SWPF) for 11 firefighters wearing elastomeric half-mask respirators and performing activities simulating those conducted during fire overhaul operations. The tests were performed in a controlled laboratory setting. A newly-developed battery-operated Portable Aerosol Mobility Spectrometer (PAMS) was used to measure size-resolved aerosol particle concentrations outside (C(out)) and inside (Cin) of an air-purifying respirator donned on a firefighter, and the SWPF was calculated as C(out)/C(in). Based on the total aerosol concentration, the "total" SWPF ranged from 4,222 (minimum) to 35,534 (maximum) with values falling primarily in a range from 11,171 (25 percentile) to 26,604 (75 percentile) and a median value being ≈15,000. This is consistent with the recently reported fit factor (FF) data base.((1)) The size-resolved SWPF data revealed a dependency on the particle size. It was concluded that a portable device such as PAMS can be used on firefighters during overhaul operations (as well as on other workers wearing elastomeric half-mask respirators) to monitor the aerosol concentrations in real time and ultimately help prevent overexposure.

Published

2015

40. Penetration of Combustion Aerosol Particles Through Filters of NIOSH-Certified Filtering Facepiece Respirators (FFRs).

Author

Gao S, Kim J, Yermakov M, Elmashae Y, He X, Reponen T, and Grinshpun SA

Subjects

Aerosols, National Institute for Occupational Safety and Health, U.S., Particle Size, Respiratory Rate, Sodium Chloride, United States, Air Filters, Air Pollutants, Occupational, Respiratory Protective Devices, Smoke

Abstract

Filtering facepiece respirators (FFRs) are commonly worn by first responders, first receivers, and other exposed groups to protect against exposure to airborne particles, including those originated by combustion. Most of these FFRs are NIOSH-certified (e.g., N95-type) based on the performance testing of their filters against charge-equilibrated aerosol challenges, e.g., NaCl. However, it has not been examined if the filtration data obtained with the NaCl-challenged FFR filters adequately represent the protection against real aerosol hazards such as combustion particles. A filter sample of N95 FFR mounted on a specially designed holder was challenged with NaCl particles and three combustion aerosols generated in a test chamber by burning wood, paper, and plastic. The concentrations upstream (Cup) and downstream (Cdown) of the filter were measured with a TSI P-Trak condensation particle counter and a Grimm Nanocheck particle spectrometer. Penetration was determined as (Cdown/Cup) ×100%. Four test conditions were chosen to represent inhalation flows of 15, 30, 55, and 85 L/min. Results showed that the penetration values of combustion particles were significantly higher than those of the "model" NaCl particles (p < 0.05), raising a concern about applicability of the N95 filters performance obtained with the NaCl aerosol challenge to protection against combustion particles. Aerosol type, inhalation flow rate and particle size were significant (p < 0.05) factors affecting the performance of the N95 FFR filter. In contrast to N95 filters, the penetration of combustion particles through R95 and P95 FFR filters (were tested in addition to N95) were not significantly higher than that obtained with NaCl particles. The findings were attributed to several effects, including the degradation of an N95 filter due to hydrophobic organic components generated into the air by combustion. Their interaction with fibers is anticipated to be similar to those involving "oily" particles. The findings of this study suggest that the efficiency of N95 respirator filters obtained with the NaCl aerosol challenge may not accurately predict (and rather overestimate) the filter efficiency against combustion particles.

Published

2015

41. Glyphosate-rich air samples induce IL-33, TSLP and generate IL-13 dependent airway inflammation.

Author

Kumar S, Khodoun M, Kettleson EM, McKnight C, Reponen T, Grinshpun SA, and Adhikari A

Subjects

Agricultural Workers' Diseases chemically induced, Agricultural Workers' Diseases immunology, Agricultural Workers' Diseases metabolism, Airway Resistance drug effects, Animals, Dose-Response Relationship, Drug, Female, Glycine toxicity, Humans, Immunity, Humoral drug effects, Immunity, Innate drug effects, Inhalation Exposure, Interleukin-13 deficiency, Interleukin-13 genetics, Interleukin-33, Lung immunology, Lung metabolism, Lung pathology, Lung physiopathology, Mice, Inbred C57BL, Mice, Knockout, Pneumonia immunology, Pneumonia metabolism, Pneumonia pathology, Pneumonia physiopathology, Pneumonia prevention & control, Risk Assessment, Time Factors, Toll-Like Receptor 4 genetics, Toll-Like Receptor 4 metabolism, Thymic Stromal Lymphopoietin, Glyphosate, Air Pollutants toxicity, Cytokines metabolism, Glycine analogs & derivatives, Herbicides toxicity, Inflammation Mediators metabolism, Interleukin-13 metabolism, Interleukins metabolism, Lung drug effects, Pneumonia chemically induced

Abstract

Several low weight molecules have often been implicated in the induction of occupational asthma. Glyphosate, a small molecule herbicide, is widely used in the world. There is a controversy regarding a role of glyphosate in developing asthma and rhinitis among farmers, the mechanism of which is unexplored. The aim of this study was to explore the mechanisms of glyphosate induced pulmonary pathology by utilizing murine models and real environmental samples. C57BL/6, TLR4-/-, and IL-13-/- mice inhaled extracts of glyphosate-rich air samples collected on farms during spraying of herbicides or inhaled different doses of glyphosate and ovalbumin. The cellular response, humoral response, and lung function of exposed mice were evaluated. Exposure to glyphosate-rich air samples as well as glyphosate alone to the lungs increased: eosinophil and neutrophil counts, mast cell degranulation, and production of IL-33, TSLP, IL-13, and IL-5. In contrast, in vivo systemic IL-4 production was not increased. Co-administration of ovalbumin with glyphosate did not substantially change the inflammatory immune response. However, IL-13-deficiency resulted in diminished inflammatory response but did not have a significant effect on airway resistance upon methacholine challenge after 7 or 21 days of glyphosate exposure. Glyphosate-rich farm air samples as well as glyphosate alone were found to induce pulmonary IL-13-dependent inflammation and promote Th2 type cytokines, but not IL-4 for glyphosate alone. This study, for the first time, provides evidence for the mechanism of glyphosate-induced occupational lung disease., (Copyright © 2014 Elsevier Ireland Ltd. All rights reserved.)

Published

2014

42. Dustborne and airborne Gram-positive and Gram-negative bacteria in high versus low ERMI homes.

Author

Adhikari A, Kettleson EM, Vesper S, Kumar S, Popham DL, Schaffer C, Indugula R, Chatterjee K, Allam KK, Grinshpun SA, and Reponen T

Subjects

Air Pollution, Indoor statistics & numerical data, Fungi growth & development, Fungi isolation & purification, Gram-Negative Bacteria isolation & purification, Gram-Positive Bacteria isolation & purification, Housing statistics & numerical data, Air Microbiology, Air Pollution, Indoor analysis, Dust analysis, Endotoxins analysis, Environmental Monitoring, Gram-Negative Bacteria growth & development, Gram-Positive Bacteria growth & development

Abstract

The study aimed at investigating Gram-positive and Gram-negative bacteria in moldy and non-moldy homes, as defined by the home's Environmental Relative Moldiness Index (ERMI) value. The ERMI values were determined from floor dust samples in 2010 and 2011 and homes were classified into low (<5) and high (>5) ERMI groups based on the average ERMI values as well as 2011 ERMI values. Dust and air samples were collected from the homes in 2011 and all samples were analyzed for Gram-positive and Gram-negative bacteria using QPCR assays, endotoxin by the LAL assay, and N-acetyl-muramic acid using HPLC. In addition, air samples were analyzed for culturable bacteria. When average ERMI values were considered, the concentration and load of Gram-positive bacteria determined with QPCR in house dust, but not air, were significantly greater in high ERMI homes than in low ERMI homes. Furthermore, the concentration of endotoxin, but not muramic acid, in the dust was significantly greater in high ERMI than in low ERMI homes. In contrast, when ERMI values of 2011 were considered, Gram-negative bacteria determined with QPCR in air, endotoxin in air, and muramic acid in dust were significantly greater in high ERMI homes. The results suggest that both short-term and long-term mold contamination in homes could be linked with the bacterial concentrations in house dust, however, only the current mold status was associated with bacterial concentrations in air. Although correlations were found between endotoxin and Gram-negative bacteria as well as between muramic acid and Gram-positive bacteria in the entire data set, diverging associations were observed between the different measures of bacteria and the home moldiness. It is likely that concentrations of cells obtained by QPCR and concentrations of cell wall components are not equivalent and represent too broad categories to understand the bacterial composition and sources of the home microbiota., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2014

43. Effects of breathing frequency and flow rate on the total inward leakage of an elastomeric half-mask donned on an advanced manikin headform.

Author

He X, Grinshpun SA, Reponen T, McKay R, Bergman MS, and Zhuang Z

Subjects

Aerosols analysis, Elastomers, Environmental Monitoring methods, Humans, Inhalation Exposure analysis, Inhalation Exposure prevention & control, Manikins, Masks, Occupational Exposure prevention & control, Particle Size, Air Pollutants, Occupational analysis, Equipment Failure, Particulate Matter analysis, Respiratory Protective Devices, Respiratory Rate, Smoke analysis

Abstract

Objectives: The objective of this study was to investigate the effects of breathing frequency and flow rate on the total inward leakage (TIL) of an elastomeric half-mask donned on an advanced manikin headform and challenged with combustion aerosols., Methods: An elastomeric half-mask respirator equipped with P100 filters was donned on an advanced manikin headform covered with life-like soft skin and challenged with aerosols originated by burning three materials: wood, paper, and plastic (polyethylene). TIL was determined as the ratio of aerosol concentrations inside (C in) and outside (C out) of the respirator (C in/C out) measured with a nanoparticle spectrometer operating in the particle size range of 20-200nm. The testing was performed under three cyclic breathing flows [mean inspiratory flow (MIF) of 30, 55, and 85 l/min] and five breathing frequencies (10, 15, 20, 25, and 30 breaths/min). A completely randomized factorial study design was chosen with four replicates for each combination of breathing flow rate and frequency., Results: Particle size, MIF, and combustion material had significant (P < 0.001) effects on TIL regardless of breathing frequency. Increasing breathing flow decreased TIL. Testing with plastic aerosol produced higher mean TIL values than wood and paper aerosols. The effect of the breathing frequency was complex. When analyzed using all combustion aerosols and MIFs (pooled data), breathing frequency did not significantly (P = 0.08) affect TIL. However, once the data were stratified according to combustion aerosol and MIF, the effect of breathing frequency became significant (P < 0.05) for all MIFs challenged with wood and paper combustion aerosols, and for MIF = 30 l/min only when challenged with plastic combustion aerosol., Conclusions: The effect of breathing frequency on TIL is less significant than the effects of combustion aerosol and breathing flow rate for the tested elastomeric half-mask respirator. The greatest TIL occurred when challenged with plastic aerosol at 30 l/min and at a breathing frequency of 30 breaths/min.

Published

2014

44. Concentration gradient patterns of traffic and non-traffic-generated fine and coarse aerosol particles.

Author

Sparks C, Reponen T, Grinshpun SA, Ryan P, Yermakov M, Simmons M, Alam M, and Howard LA

Subjects

Aerosols chemistry, Air Pollutants chemistry, Analysis of Variance, Environmental Monitoring, Ohio, Particle Size, Particulate Matter chemistry, Seasons, Aerosols analysis, Air Pollutants analysis, Air Pollution analysis, Air Pollution statistics & numerical data, Particulate Matter analysis, Vehicle Emissions analysis

Abstract

The research project described in this article was undertaken to establish baseline information for a Health Impact Assessment (HIA) project of Interstate 75 road construction in Cincinnati, Ohio. The objective of the authors' study was to evaluate the concentrations of elemental and organic carbon (EC and OC), as well as characterize particle number concentrations using devices that measure the fine fraction in the range of 0.02-1 microm and the coarse fraction up to 20 pm. The measurements were conducted at two sites located in the proximity of an interstate highway (at 124 and 277 m) as well as at a remote control site (at >2000 m from any interstate highway). Samples were collected for 24 hours over 12 days in each season (i.e., summer, fall, and winter). Wind data were obtained from the area weather station. Data were analyzed using mixed linear models. Significant increases in concentrations of EC, OC, and fine particles as well as in EC/OC ratios were observed with decreased distance to the highway; this difference was more pronounced in the fall. These results suggest that residents and workers in areas near high-traffic highways may be exposed to elevated levels of airborne fine particles. The results can be used as a baseline for future HIAs of road construction in the area.

Published

2014

45. How does breathing frequency affect the performance of an N95 filtering facepiece respirator and a surgical mask against surrogates of viral particles?

Author

He X, Reponen T, McKay R, and Grinshpun SA

Subjects

Equipment Safety, Occupational Exposure prevention & control, Masks, Respiration, Respiratory Protective Devices, Virion

Abstract

Breathing frequency (breaths/min) differs among individuals and levels of physical activity. Particles enter respirators through two principle penetration pathways: faceseal leakage and filter penetration. However, it is unknown how breathing frequency affects the overall performance of N95 filtering facepiece respirators (FFRs) and surgical masks (SMs) against viral particles, as well as other health-relevant submicrometer particles. A FFR and SM were tested on a breathing manikin at four mean inspiratory flows (MIFs) (15, 30, 55, and 85 L/min) and five breathing frequencies (10, 15, 20, 25, and 30 breaths/min). Filter penetration (Pfilter) and total inward leakage (TIL) were determined for the tested respiratory protection devices against sodium chloride (NaCl) aerosol particles in the size range of 20 to 500 nm. "Faceseal leakage-to-filter" (FLTF) penetration ratios were calculated. Both MIF and breathing frequency showed significant effects (p < 0.05) on Pfilter and TIL. Increasing breathing frequency increased TIL for the N95 FFR whereas no clear trends were observed for the SM. Increasing MIF increased Pfilter and decreased TIL resulting in decreasing FLTF ratio. Most of FLTF ratios were >1, suggesting that the faceseal leakage was the primary particle penetration pathway at various breathing frequencies. Breathing frequency is another factor (besides MIF) that can significantly affect the performance of N95 FFRs, with higher breathing frequencies increasing TIL. No consistent trend of increase or decrease of TIL with either MIF or breathing frequency was observed for the tested SM. To potentially extend these findings beyond the manikin/breathing system used, future studies are needed to fully understand the mechanism causing the breathing frequency effect on the performance of respiratory protection devices on human subjects.

Published

2014

46. The impact of an anti-idling campaign on outdoor air quality at four urban schools.

Author

Ryan PH, Reponen T, Simmons M, Yermakov M, Sharkey K, Garland-Porter D, Eghbalnia C, and Grinshpun SA

Subjects

Child, Humans, Schools, Vehicle Emissions analysis, Air Pollutants analysis, Air Pollution analysis, Environmental Monitoring, Motor Vehicles, Particulate Matter analysis

Abstract

Idling school buses may increase concentrations of air pollutants including fine particulate matter (PM2.5) and elemental carbon (EC) near schools. Efforts to reduce vehicle idling near schools have rarely included air sampling to objectively assess changes in concentrations of air pollutants. The objective was to determine the impact of an anti-idling campaign on outdoor air quality at four schools with varying exposure to bus and automobile traffic. Outdoor air sampling for PM2.5, EC and particle number concentration (PNC) was conducted at four schools for five days before and after an anti-idling campaign. Sampling began before the morning arrival of buses and concluded after their afternoon departure. Sampling was simultaneously conducted at four corresponding community sites. Differences in PM2.5, EC, and PNC measured at school and community sites for each sampling day were calculated before and after the campaign. Before the campaign, the average outdoor concentration of PM2.5 during the school day at three of the four schools exceeded community background levels and the difference was greatest (4.11 μg m(-3), p < 0.01) at the school with the most buses (n = 39). The largest difference in EC between school and community sites was also observed at the school with the greatest number of buses (0.40 μg m(-3), p < 0.01). Following the anti-idling campaign, the average difference in PM2.5 at the school with the most buses decreased from 4.11 μg m(-3) to 0.99 μg m(-3) (p < 0.05). Similarly, at this school, the difference in the EC level decreased from 0.40 μg m(-3) to 0.15 μg m(-3) and PNC decreased from 11,560 to 1690 particles per cm(3) (p < 0.05). The outdoor concentrations of pollutants at schools with fewer buses (n = 5-11) were not significantly reduced. The concentration of air pollutants near schools may significantly exceed community background levels, particularly in the presence of idling school buses. Anti-idling campaigns are effective in reducing PM2.5, EC and PNC at schools with significant amounts of buses and passenger cars.

Published

2013

47. Stenotrophomonas, Mycobacterium, and Streptomyces in home dust and air: associations with moldiness and other home/family characteristics.

Author

Kettleson E, Kumar S, Reponen T, Vesper S, Méheust D, Grinshpun SA, and Adhikari A

Subjects

Dust, Polymerase Chain Reaction, Regression Analysis, Air Microbiology, Fungi isolation & purification, Mycobacterium isolation & purification, Stenotrophomonas maltophilia isolation & purification, Streptomyces isolation & purification

Abstract

Respiratory illnesses have been linked to children's exposures to water-damaged homes. Therefore, understanding the microbiome in water-damaged homes is critical to preventing these illnesses. Few studies have quantified bacterial contamination, especially specific species, in water-damaged homes. We collected air and dust samples in twenty-one low-mold homes and twenty-one high-mold homes. The concentrations of three bacteria/genera, Stenotrophomonas maltophilia, Streptomyces sp., and Mycobacterium sp., were measured in air and dust samples using quantitative PCR (QPCR). The concentrations of the bacteria measured in the air samples were not associated with any specific home characteristic based on multiple regression models. However, higher concentrations of S. maltophilia in the dust samples were associated with water damage, that is, with higher floor surface moisture and higher concentrations of moisture-related mold species. The concentrations of Streptomyces and Mycobacterium sp. had similar patterns and may be partially determined by human and animal occupants and outdoor sources of these bacteria., (© 2013 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2013

48. Laboratory evaluation of the particle size effect on the performance of an elastomeric half-mask respirator against ultrafine combustion particles.

Author

He X, Grinshpun SA, Reponen T, Yermakov M, McKay R, Haruta H, and Kimura K

Subjects

Aerosols analysis, Humans, Inhalation Exposure analysis, Inhalation Exposure prevention & control, Manikins, Materials Testing, Occupational Exposure prevention & control, Air Pollutants, Occupational analysis, Particle Size, Particulate Matter analysis, Respiratory Protective Devices standards, Smoke analysis

Abstract

Objectives: This study quantified the particle size effect on the performance of elastomeric half-mask respirators, which are widely used by firefighters and first responders exposed to combustion aerosols., Methods: One type of elastomeric half-mask respirator equipped with two P-100 filters was donned on a breathing manikin while challenged with three combustion aerosols (originated by burning wood, paper, and plastic). Testing was conducted with respirators that were fully sealed, partially sealed (nose area only), or unsealed to the face of a breathing manikin to simulate different faceseal leakages. Three cyclic flows with mean inspiratory flow (MIF) rates of 30, 85, and 135 L/min were tested for each combination of sealing condition and combustion material. Additional testing was performed with plastic combustion particles at other cyclic and constant flows. Particle penetration was determined by measuring particle number concentrations inside and outside the respirator with size ranges from 20 to 200 nm., Results: Breathing flow rate, particle size, and combustion material all had significant effects on the performance of the respirator. For the partially sealed and unsealed respirators, the penetration through the faceseal leakage reached maximum at particle sizes >100 nm when challenged with plastic aerosol, whereas no clear peaks were observed for wood and paper aerosols. The particles aerosolized by burning plastic penetrated more readily into the unsealed half-mask than those aerosolized by the combustion of wood and paper. The difference may be attributed to the fact that plastic combustion particles differ from wood and paper particles by physical characteristics such as charge, shape, and density. For the partially sealed respirator, the highest penetration values were obtained at MIF = 85 L/min. The unsealed respirator had approximately 10-fold greater penetration than the one partially sealed around the bridge of the nose, which indicates that the nose area was the primary leak site.

Published

2013

49. Family and home characteristics correlate with mold in homes.

Author

Reponen T, Levin L, Zheng S, Vesper S, Ryan P, Grinshpun SA, and LeMasters G

Subjects

Asthma epidemiology, Child, Cohort Studies, Humans, Linear Models, Multivariate Analysis, Socioeconomic Factors, Asthma microbiology, Fungi growth & development, Housing

Abstract

Previously, we demonstrated that infants residing in homes with higher Environmental Relative Moldiness Index were at greater risk for developing asthma by age seven. The purpose of this analysis was to identify the family and home characteristics associated with higher moldiness index values in infants' homes at age one. Univariate linear regression of each characteristic determined that family factors associated with moldiness index were race and income. Home characteristics associated with the moldiness index values were: air conditioning, carpet, age of the home, season of home assessment, and house dust mite allergen. Parental history of asthma, use of dehumidifier, visible mold, dog and cat allergen levels were not associated with moldiness index. Results of multiple linear regression showed that older homes had 2.9 units higher moldiness index (95% confidence interval [CI]=0.4, 5.4), whereas homes with central air conditioning had 2.5 units lower moldiness index (95% CI=-4.7, -0.4). In addition, higher dust mite allergen levels and carpeting were positively and negatively associated with higher moldiness index, respectively. Because older homes and lack of air conditioning were also correlated with race and lower income, whereas carpeting was associated with newer homes, the multivariate analyses suggests that lower overall socioeconomic position is associated with higher moldiness index values. This may lead to increased asthma risk in homes inhabited by susceptible, vulnerable population subgroups. Further, age of the home was a surrogate of income, race and carpeting in our population; thus the use of these factors should carefully be evaluated in future studies., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

50. Effect of Particle Size on the Performance of an N95 Filtering Facepiece Respirator and a Surgical Mask at Various Breathing Conditions.

Author

He X, Reponen T, McKay RT, and Grinshpun SA

Abstract

The effect of aerosol particle size on the performance of an N95 filtering facepiece respirator (FFR) and a surgical mask (SM) was evaluated under different breathing conditions, including breathing frequency and mean inspiratory flow (MIF) rate. The FFR and SM were sealed on a manikin headform and challenged with charge-equilibrated NaCl aerosol. Filter penetration (P filter ) was determined as the ratio of aerosol concentrations inside and outside the FFR/SM size-selectively (28 channels) within a range of 20 to 500 nm. In addition, the same models of the FFR and SM were donned, but not sealed, on an advanced manikin headform covered with skin-like material. Total inward leakage (TIL), which represents the total particle penetration, was measured under conditions identical to the filter penetration experiment. Testing was conducted at four mean MIFs (15, 30, 55 and 85 L/min) combined with five breathing frequencies (10, 15, 20, 25 and 30 breaths/min). The results show that SM produced much higher P filter and TIL values, and thus provide little protection against aerosols in the size range tested. P filter was significantly affected by particle size and breathing flow rate ( p <0.05) for the tested FFR and SM. Surprisingly, for both devices, P filter as a function of the particle size exhibited more than one peak under all tested breathing conditions. The effect of breathing frequency on P filter was generally less pronounced, especially for lower MIFs. For the FFR and SM, TIL increased with increasing particle size up to about 50 nm; for particles above 50 nm, the total penetration was not significantly affected by particle size and breathing frequency; however, the effect of MIF remained significant.

Published

2013