Your search keyword '"biological aerosol"' showing total 26 results

1. Effects of Pollen on Hydrometeors and Precipitation in a Convective System.

Author

Zhang, Yingxiao, Subba, Tamanna, Matthews, Brianna H., Pettersen, Claire, Brooks, Sarah D., and Steiner, Allison L.

Subjects

THUNDERSTORMS, MESOSCALE convective complexes, CLOUD condensation nuclei, POLLEN, CLOUD droplets, METEOROLOGICAL research

Abstract

Anemophilous (wind‐driven) pollen is one type of primary biological aerosol particle, which can rupture under high humidity conditions and form smaller sub‐pollen particles (SPPs). Both pollen and SPPs can reach the upper troposphere under convective conditions, acting as cloud condensation nuclei (CCN) and ice nucleating particles (INPs), thus influencing cloud formation and precipitation. However, the impacts of these biological aerosols on cold cloud formation and local climate remain unclear as there are large uncertainties on their emission flux and ice nucleating abilities. Here, we incorporate pollen emission and rupture processes in the Weather Research and Forecasting Model with Chemistry (WRF‐Chem) simulations and update the Morrison microphysics scheme within WRF‐Chem using aerosol‐aware INP parameterizations to account for pollen in addition to other anthropogenic and biogenic aerosol. INP parameterizations for pollen and SPP are derived from laboratory experiments. When including pollen rupture rates as observed in a series of chamber studies, SPP concentrations increase, leading to an increase of cloud ice and water by up to 50% and potentially extending the duration of the convective system. Among all simulated hydrometeors, graupel and raindrops exhibit the largest enhancements from the inclusion of SPPs, with intensifying precipitation at the backside of the convective system and a greater spatial extent. Sensitivity simulations indicate that SPPs have a greater effect on cloud microphysical processes than whole pollen grains, and further observational evidence is needed to constrain these processes. Plain Language Summary: Pollen grains are emitted by vegetation and carry the reproductive material of plants. Under certain conditions (e.g., high humidity, lightning), pollen grains can rupture to form smaller sub‐pollen particles (SPPs). Both intact pollen grain and SPPs have been observed to influence the formation of cloud liquid droplets and ice crystals, potentially impacting cloud properties and precipitation. In this study, we include pollen emission and pollen‐cloud interactions into a meteorology‐chemistry model and investigate the effects of pollen grains and SPPs on a strong thunderstorm event associated with a mesoscale convective system. We find that SPPs have a greater impact than whole pollen grains on the convective system properties by increasing cloud ice and water content, facilitating the transition of cloud droplets and ice into graupel, and ultimately intensifying precipitation. These changes alter the impact of the convective system, leading to an extension of the storm width and lengthening of its duration. Key Points: Sub‐pollen particles (SPPs) enhance cloud microphysical processes more than intact pollen grainsSPPs influence the spatial extent and vertical structure of convective systemsSimulated SPP impacts are intensified when incorporating laboratory measured pollen rupture rates [ABSTRACT FROM AUTHOR]

Published

2024

2. Analysing the performance of machine learning algorithms for bio-aerosol detection

Author

Ruske, Simon, Gallagher, Martin, and Topping, David

Subjects

UV-LIF, biological aerosol, bioaerosol, bio-aerosol, ultra-violet light induced fluorescence, clustering, machine learning, multiparameter bioaerosol spectrometer, MBS, Wideband integrated bioaerosol sensor, WIBS, gradient boosting, hierarchical agglomerative clustering

Abstract

Primary biological aerosol particles, including bacteria, fungal spores and pollen are a crucial component of the atmosphere. These particles have a significant impact on human health, especially for those who suffer from hay fever and asthma. They can also influence the weather, acting as ice nuclei (IN) or cloud condensation nuclei (CCN) and can be impactful on agriculture through destruction of crops caused by fungal diseases. It is also vital to monitor these particles in an indoor environment: in hospitals as well as cleanrooms within the pharmaceutical manufacturing process. There are several different techniques that scientists can use to analyse bio-aerosol. Manual techniques, including tape and filter sampling, are often used by meteorological institutions to provide a pollen forecast. Alternatively, in a clean indoor environment, pharmaceutical manufacturers may use culture-based techniques to help prevent contamination. These approaches, however, can suffer from low time resolution and substantial human labour costs. As a consequence, interest in ultraviolet light-induced fluorescence (UV-LIF), which can provide real-time particle measurements, has increased in the last decade. Such technological advancements, especially instruments that produce high resolution data, bring a wealth of complex data that can be difficult to analyse. Consequently, it becomes ever more important to question the algorithmic approach used to analyse the data. One of the potential solutions to overcome this obstacle is machine learning, which has seen increased interest in recent years, with a vast number of applications. As more laboratory data have also become available, it has been possible to test the applicability of a wider variety of algorithms. In this thesis, we evaluate the applicability of these algorithms to data collected using both an earlier developed instrument called the WIBS and an updated version of the WIBS called the MBS. Hierarchical agglomerative clustering is a technique that has been used by researchers in previous studies using the WIBS. In this thesis, we present the first paper, using the MBS as well as extend the current body of research that uses the WIBS, showing some previously unseen disadvantages to this technique. We demonstrate excellent discrimination between laboratory particles for the newer instrument using supervised machine learning techniques but identify critical areas where the application of such algorithms to ambient data are limited and need improvement. Primary biological aerosol particles, including bacteria, fungal spores and pollen are a crucial component of the atmosphere. These particles have a significant impact on human health, especially for those who suffer from hay fever and asthma. They can also influence the weather, acting as ice nuclei (IN) or cloud condensation nuclei (CCN) and can be impactful on agriculture through destruction of crops caused by fungal diseases. It is also vital to monitor these particles in an indoor environment: in hospitals as well as cleanrooms within the pharmaceutical manufacturing process. There are several different techniques that scientists can use to analyse bio-aerosol. Manual techniques, including tape and filter sampling, are often used by meteorological institutions to provide a pollen forecast. Alternatively, in a clean indoor environment, pharmaceutical manufacturers may use culture-based techniques to help prevent contamination. These approaches, however, can suffer from low time resolution and substantial human labour costs. As a consequence, interest in ultraviolet light-induced fluorescence (UV-LIF), which can provide real-time particle measurements, has increased in the last decade. Such technological advancements, especially instruments that produce high resolution data, bring a wealth of complex data that can be difficult to analyse. Consequently, it becomes ever more important to question the algorithmic approach used to analyse the data. One of the potential solutions to overcome this obstacle is machine learning, which has seen increased interest in recent years, with a vast number of applications. As more laboratory data have also become available, it has been possible to test the applicability of a wider variety of algorithms. In this thesis, we evaluate the applicability of these algorithms to data collected using both an earlier developed instrument called the WIBS and an updated version of the WIBS called the MBS. Hierarchical agglomerative clustering is a technique that has been used by researchers in previous studies using the WIBS. In this thesis, we present the first paper, using the MBS as well as extend the current body of research that uses the WIBS, showing some previously unseen disadvantages to this technique. We demonstrate excellent discrimination between laboratory particles for the newer instrument using supervised machine learning techniques but identify critical areas where the application of such algorithms to ambient data are limited and need improvement.

Published

2020

3. Surface Acoustic Wave Immunosensor for Detection of Botulinum Neurotoxin.

Author

Grabka, Michał, Jasek, Krzysztof, and Witkiewicz, Zygfryd

Subjects

*ACOUSTIC surface waves, *BOTULINUM A toxins, *BOTULINUM toxin, *SOUND waves, *BIOLOGICAL weapons, *MONOCLONAL antibodies

Abstract

A Love-type acoustic wave sensor (AT-cut quartz substrate, SiO2 guiding layer) with a center frequency of approximately 120 MHz was used to detect a simulant of pathogenic botulinum neurotoxin type A—recombinant of BoNT-A light chain—in liquid samples. The sensor was prepared by immobilizing monoclonal antibodies specific for botulinum neurotoxin via a thiol monolayer deposited on a gold substrate. Studies have shown that the sensor enables selective analyte detection within a few minutes. In addition, the sensor can be used several times (regeneration of the sensor is possible using a low pH buffer). Nevertheless, the detectability of the analyte is relatively low compared to other analytical techniques that can be used for rapid detection of botulinum neurotoxin. The obtained results confirm the operation of the proposed sensor and give hope for further development of this label-free technique for detecting botulinum neurotoxin. [ABSTRACT FROM AUTHOR]

Published

2023

4. 基于神经网络的小尺度环境下生物气溶胶溯源方法研究.

Author

岳 超, 杜耀华, 张 宁, and 薛 腾

Abstract

Copyright of Chinese Medical Equipment Journal is the property of Chinese Medical Equipment Journal Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

5. 我国实验室获得性感染的回顾性分析.

Author

叶琳琳, 冯媛媛, and 张耀东

Abstract

Copyright of China Tropical Medicine is the property of China Tropical Medicine Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

6. Surface Acoustic Wave Immunosensor for Detection of Botulinum Neurotoxin

Author

Michał Grabka, Krzysztof Jasek, and Zygfryd Witkiewicz

Subjects

SAW, label-free detection, botulinum neurotoxin, biological warfare agents (BWA), on-site detection of BWA, biological aerosol, Chemical technology, TP1-1185

Abstract

A Love-type acoustic wave sensor (AT-cut quartz substrate, SiO2 guiding layer) with a center frequency of approximately 120 MHz was used to detect a simulant of pathogenic botulinum neurotoxin type A—recombinant of BoNT-A light chain—in liquid samples. The sensor was prepared by immobilizing monoclonal antibodies specific for botulinum neurotoxin via a thiol monolayer deposited on a gold substrate. Studies have shown that the sensor enables selective analyte detection within a few minutes. In addition, the sensor can be used several times (regeneration of the sensor is possible using a low pH buffer). Nevertheless, the detectability of the analyte is relatively low compared to other analytical techniques that can be used for rapid detection of botulinum neurotoxin. The obtained results confirm the operation of the proposed sensor and give hope for further development of this label-free technique for detecting botulinum neurotoxin.

Published

2023

7. Investigation of fungi diversity in airborne dust and their sources identification in Khuzestan province

Author

Forough Tajiki, Hossein Mohammad Asgari, Isaac Zamani, and Farshid Ghanbari

Subjects

dust storms, modis satellite, biological aerosol, fungus, khuzestan, Environmental sciences, GE1-350

Abstract

Background and Objective: Considering the fact that Iran is located in semi-arid climate and the harmful effects of dust storms on different ecosystems, this study aimed to identify and locate dust storms using fungal bio-aerosols (spores) and HYSPLIT model in southwestern region of Iran. Materials and Methods: MODIS satellite images and HYSPLIT model were used to investigate the temporal changes of dust masses entering the Khuzestan province. Sampling was carried out from dust storms in Abadan and Khorramshahr cities and from the soil of the dried parts of Hur al-Azim and Shadegan wetlands in a two-month period (from May to July 2019). Results: The results of numerical modeling show that Abadan and Khorramshahr cities were affected by dust storms of internal origin (from Hur-al-Azim wetland). After isolation of bioaerosols from air and soil samples, a total of 6 fungal genera were identified in soil samples and 6 genera in dust samples of internal origin by PCR-Sequencing method. Talaromyces, Alternaria, Penicillium and Aspergillus were identified as the predominant genera fungi in soil and air samples. Conclusion: With 70% similarity of fungi found in soil and air samples, it can be concluded that the main source of fungi in Abadan and Khorramshahr is Hur al-Azim wetland.

Published

2021

8. Disinfection of Biological Aerosols in the Removed Gas During the Fermentation Stage of the Biotechnological Process

Author

A. V. Komissarov, K. M. Morozov, A. I. Perepelitsa, A. Yu. Ul’yanov, O. A. Volokh, and A. K. Nikiforov

Subjects

biological aerosol, biotechnological processes, the removal or inactivation of microorganisms, methodological approaches and engineering solutions, Infectious and parasitic diseases, RC109-216

Abstract

The aim of this review is to consider the literature data on methods and engineering solutions for decontamination of gases vented from equipment, containing microorganisms, during the cultivation process. Methodological approaches and engineering solutions for the removal or inactivation of microorganisms contained in a biological aerosol are addressed. A number of examples demonstrate the advantages and disadvantages of biological aerosol decontamination systems used. Presented is the information about modern, non-moisture-absorbing membrane filters, announced by manufacturers as elements that allow for sterilization of air supplied for oxygen saturation of the culture medium in bioreactors and neutralization of the gas removed from them. Discussed in detail are designed by specialists of the Institute “Microbe” system for purification of exhaust gases from the bioreactor, where hydrophobic filters based on sintered mass of nickel powders are the main element. Requirements for the construction of systems for the neutralization of microorganisms in gases drawn off from equipment in which biotechnological processes take place are formulated.

Published

2021

9. بررسی تنوع قار چها در گرد و غبار و شناسایی منشأ آنها در استان خوزستان.

Author

فروغ تاجیکی, حسین محمد عسگری, اسحاق زمانی, and فرشید قنبری

Subjects

*DUST storms, *SOIL air, *SOIL sampling, *AIR sampling, *SOIL fungi, *MICROBIOLOGICAL aerosols, *WETLAND soils

Abstract

Background and Objective: Considering the fact that Iran is located in semiarid climate and the harmful effects of dust storms on different ecosystems, this study aimed to identify and locate dust storms using fungal bio-aerosols (spores) and HYSPLIT model in southwestern region of Iran. Materials and Methods: MODIS satellite images and HYSPLIT model were used to investigate the temporal changes of dust masses entering the Khuzestan province. Sampling was carried out from dust storms in Abadan and Khorramshahr cities and from the soil of the dried parts of Hur al-Azim and Shadegan wetlands in a two-month period (from May to July 2019). Results: The results of numerical modeling show that Abadan and Khorramshahr cities were affected by dust storms of internal origin (from Hur-al-Azim wetland). After isolation of bioaerosols from air and soil samples, a total of 6 fungal genera were identified in soil samples and 6 genera in dust samples of internal origin by PCR-Sequencing method. Talaromyces, Alternaria, Penicillium and Aspergillus were identified as the predominant genera fungi in soil and air samples. Conclusion: With 70% similarity of fungi found in soil and air samples, it can be concluded that the main source of fungi in Abadan and Khorramshahr is Hur al-Azim wetland. [ABSTRACT FROM AUTHOR]

Published

2021

10. Detection of Airborne Biological Particles in Indoor Air Using a Real-Time Advanced Morphological Parameter UV-LIF Spectrometer and Gradient Boosting Ensemble Decision Tree Classifiers

Author

Ian Crawford, David Topping, Martin Gallagher, Elizabeth Forde, Jonathan R. Lloyd, Virginia Foot, Chris Stopford, and Paul Kaye

Subjects

PBAP, biological aerosol, bioaerosol, UV-LIF, supervised machine learning, real-time bioaerosol detection, Meteorology. Climatology, QC851-999

Abstract

We present results from a study evaluating the utility of supervised machine learning to classify single particle ultraviolet laser-induced fluorescence (UV-LIF) signatures to investigate airborne primary biological aerosol particle (PBAP) concentrations in a busy, multifunctional building using a Multiparameter Bioaerosol Spectrometer. First we introduce and demonstrate a gradient boosting ensemble decision tree algorithm’s ability to accurately classify laboratory generated PBAP samples into broad taxonomic classes with a high level of accuracy. We then develop a framework to appraise the classification accuracy and performance using the Hellinger distance metric to compare product parameter probability density function similarity; this framework showed that key training classes were sufficiently different in terms of particle fluorescence and morphology to facilitate classification. We also demonstrate the utility of including advanced morphological parameters to minimise inter-class conflation and improve classification confidence, where relying on the fluorescent spectra alone would likely result in misattribution. Finally, we apply these methods to ambient data collected within a large multi-functional building where ambient bacterial- and fungal-like classes were identified to display trends corresponding to human activity; fungal-like classes displayed a consistent diurnal trend with a maximum at midday and hourly peaks correlating to movements within the building; bacteria-like aerosol displayed complex, episodic events during opening hours. All PBAP classes fell to low baseline concentrations when the building was unoccupied overnight and at weekends.

Published

2020

11. Use of Virtual Impactor (VI) Technology in Biological Aerosol Detection

Author

Jim Ho

Subjects

virtual impactor, biological aerosol, anthrax, aerosol samplers, threat agents, Technology (General), T1-995, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

Detecting biological threat aerosol is difficult in that a small cloud lasting only a few seconds at a point location may contain sufficient material to infect large numbers of exposed individuals. Clinical analytical methods require relative large amounts of the sample in liquid form to facilitate positive measurements. Biological agents may be fragile because of their lipid membranes that can be susceptible to harsh sample collection treatment. Damaged organisms may render subsequent analyses to be invalid. Virtual impaction (VI) sample collectors have been theorized to provide usable concentration rates yet are sufficiently gentle with the aerosol particles to preserve cellular viability. This review will discuss different implementations of VI technology and examine their merits. Outstanding issues will be outlined to aid future experimentation.

Published

2014

12. Environmental and Health Aspects of Metalworking Fluid Use.

Author

Schwarz, Marián, Dado, Miroslav, Hnilica, Richard, and Veverková, Darina

Subjects

*METALWORKING industries & the environment, *AIR pollution, *PUBLIC health, *RESPIRATORY diseases, *WORK environment, *PARTICULATE matter

Abstract

The utilization of metalworking fluids in the metal machining technological process provides, apart from benefits, certain negatives that are mainly associated with air contamination of the working environment. Typical health problems that result from inhalant exposure of metalworking machine operators to the metalworking fluid mist include respiratory diseases (asthma, chronic bronchitis, hypersensitivity pneumonitis), cancer, and skin diseases. Possible health risks posed by the utilization of metalworking fluids, various methods for measuring their concentration in the working environment, and treatment of MWFs are discussed. A typical particle size range of liquid aerosol (oil mist) is in the range from 0.1 to 10 µm and more than 75% of MWF particulate matter is located in the sphere of respirable fraction (particle size less than 5 µm) that poses the highest risk for the human body. MWF aerosol mass concentration in the working atmosphere varies depending on the type of working activity, and MWFs used in a wider range (average exposure in the range of 0.55 to 5.36 mg⋅m-3 ). Attention also should be paid to microbiological contamination of water-based MWFs, when they are used or stored after dilution for longer term. The most often occurring microbial species at considerable concentration is the bacteria Pseudomonas pseudoalcaligenes. Other important species include Mycobacterium, Pseudomonas, Morganella, Citrobacter freundii, Acinetobacter, Bacillus, Fusarium, Trichoderma, Penicillium, etc. [ABSTRACT FROM AUTHOR]

Published

2015

13. Detection of Airborne Biological Particles in Indoor Air Using a Real-Time Advanced Morphological Parameter UV-LIF Spectrometer and Gradient Boosting Ensemble Decision Tree Classifiers

Author

Chris Stopford, Paul H. Kaye, Virginia Foot, Martin Gallagher, Ian Crawford, Elizabeth Forde, David Topping, and Jonathan R. Lloyd

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Computer science, Decision tree, Probability density function, lcsh:QC851-999, 010501 environmental sciences, Environmental Science (miscellaneous), bioaerosol, 01 natural sciences, biological aerosol, supervised machine learning, building mycology, Hellinger distance, Indoor air quality, Supervised machine learning, PBAP, 0105 earth and related environmental sciences, Bioaerosol, Building mycology, Spectrometer, business.industry, Decision tree learning, Pattern recognition, Real-time bioaerosol detection, UV-LIF, Biological aerosol, Metric (mathematics), real-time bioaerosol detection, lcsh:Meteorology. Climatology, Gradient boosting, Artificial intelligence, business, indoor air quality

Abstract

We present results from a study evaluating the utility of supervised machine learning to classify single particle ultraviolet laser-induced fluorescence (UV-LIF) signatures to investigate airborne primary biological aerosol particle (PBAP) concentrations in a busy, multifunctional building using a Multiparameter Bioaerosol Spectrometer. First we introduce and demonstrate a gradient boosting ensemble decision tree algorithm&rsquo, s ability to accurately classify laboratory generated PBAP samples into broad taxonomic classes with a high level of accuracy. We then develop a framework to appraise the classification accuracy and performance using the Hellinger distance metric to compare product parameter probability density function similarity, this framework showed that key training classes were sufficiently different in terms of particle fluorescence and morphology to facilitate classification. We also demonstrate the utility of including advanced morphological parameters to minimise inter-class conflation and improve classification confidence, where relying on the fluorescent spectra alone would likely result in misattribution. Finally, we apply these methods to ambient data collected within a large multi-functional building where ambient bacterial- and fungal-like classes were identified to display trends corresponding to human activity, fungal-like classes displayed a consistent diurnal trend with a maximum at midday and hourly peaks correlating to movements within the building, bacteria-like aerosol displayed complex, episodic events during opening hours. All PBAP classes fell to low baseline concentrations when the building was unoccupied overnight and at weekends.

Published

2020

14. Integrated high performance computational tools for simulations of transport and diffusion of contaminants in urban areas.

Author

Aliabadi, S., Tu, S., Watts, M., Ji, A., and Johnson, A.

Subjects

*DIFFUSION, *BIOLOGICAL transport, *AEROSOLS, *HIGH performance computing, *FLUID dynamics, *GEOGRAPHIC information systems, *FINITE element method

Abstract

Rapid analysis of transport and diffusion of chemical and biological aerosols and contaminants in an urban environment is a critical part of any homeland security response team. High performance computing (HPC) is a valuable technique for such analysis. The time constraint needed to create fully developed complex 3D city terrain models to support such dispersion simulations requires a task of converting agency data to the format necessary on the simulation platform. Numerous data sets have been employed in the development of complex 3D city models. Such data include the use of multi-layer building morphology data, the use of geographic information system (GIS) based shapefiles and digital elevation models (DEM), and the use of remote sensing data such as Light Detection and Ranging (LIDAR). The constructed geometry models are used to generate large-scale computational domains on a platform that supports our HPC tools. These tools include fully automated unstructured mesh generation, parallel and scalable flow solvers based on stabilized finite element formulations and a remote client-server environment for large-scale flow visualization. The stabilized finite element formulations, which are based on the SUPG and PSPG techniques, are parallelized and vectorized on the Cray X1. The 3D validation problem involves transient simulation of flow past a building with a source point releasing traces. A 3D application problem is presented to demonstrate the capability of the integrated HPC tools. [ABSTRACT FROM AUTHOR]

Published

2006

15. Estimating aerosol hazards from an anthrax letter

Author

Ho, J. and Duncan, S.

Subjects

*ANTHRAX, *BACTERIAL diseases, *BACILLUS (Bacteria), *ENVIRONMENTAL health, *PREVENTIVE medicine

Abstract

Abstract: Events following the anthrax letter incidences in 2001 changed many previously held assumptions regarding biological aerosol hazards. As there were significant fatalities resulting from the sorting of a single anthrax letter, it suggests there is a need to reevaluate how best to measure biological aerosols and to use the information to make accurate predictions. This paper describes the biological aerosol created from manipulating envelopes containing Bacillus subtilis globigii spores (a simulant for anthrax). In addition, the measurements on dispersion of spores from an envelope processed by a mail sorter provide important dynamic aerosol characteristics, information previously unavailable for health risk assessment. The findings produced a number of significant aerosol dosage estimates related to spore contaminated letters. Graphic presentations show significant hazard in handling anthrax-laced letters. Aerosol particle dynamics are described and specific lethal dosage values are listed for a range of activities; these will be useful in assisting the modeling community to create more realistic predictions in hazard assessment studies. [Copyright &y& Elsevier]

Published

2005

16. Characterizing biological aerosol in a chamber: an approach to estimation of viable organisms in a single biological particle.

Author

Ho, Jim, Spence, Melvin, and Ogston, Jim

Abstract

There are practical and valid reasons topresent biological field trial referenceresults as agent containing particles per literof air (ACPLA). However, workers in biologicalaerosol research have a need to know how manyviable individual organisms are contained in asingle particle of a given diameter. Anecdotalevidence may exist suggesting that the task hasbeen accomplished but without a way toreplicate the measurements, it is difficult toaccept unsubstantiated claims. It is verydifficult to declare a finite number thatsatisfies all the experimental requirements, asthe problem is a statistical probability issue. This paper describes a method for estimatingthe number with practical instructions forreplicating the work in other laboratories. The test aerosol was contained in a 90 m3chamber at concentrations as low as 5 ACPLA. Amodified version of slit sampler collectedviable particles. A statistical method was usedto demonstrate sampling predictability at 95%confidence level. By using glass fiber filtersmounted in a dichotomous sampler, samplingefficiencies were estimated for a variety ofcommon aerosol collectors. The accumulated datapermitted the estimation of the number ofviable spores per particle. For a 2.5 to4 µm particle, arguments have beenpresented for considering 4.5 as the mostprobable ACPLA value. [ABSTRACT FROM AUTHOR]

Published

2001

17. Intercomparison of Multiple UV-LIF Spectrometers Using the Aerosol Challenge Simulator

Author

Alexis Attwood, Martin Gallagher, Warren Stanley, Paul H. Kaye, Maurice Walker, Roland Sarda-Esteve, Virginia Foot, Elizabeth Forde, David Topping, and Gary Granger

Subjects

Atmospheric Science, Spectrometer, Instrumentation, Biological particles, Environmental Science (miscellaneous), bioaerosol, Aerosol, Fluorescence intensity, biological aerosol, MBS, WIBS-NEO, UV-LIF, WIBS, WIBS New Electronic Option (WIBS-NEO), Particle, Environmental science, PBAP, Simulation, Bioaerosol

Abstract

Measurements of primary biological aerosol particles (PBAPs) have been conducted worldwide using ultraviolet light-induced fluorescence (UV-LIF) spectrometers. However, how these instruments detect and respond to known biological and non-biological particles, and how they compare, remains uncertain due to limited laboratory intercomparisons. Using the Defence Science and Technology Laboratory, Aerosol Challenge Simulator (ACS), controlled concentrations of biological and non-biological aerosol particles, singly or as mixtures, were produced for testing and intercomparison of multiple versions of the Wideband Integrated Bioaerosol Spectrometer (WIBS) and Multiparameter Bioaerosol Spectrometer (MBS). Although the results suggest some challenges in discriminating biological particle types across different versions of the same UV-LIF instrument, a difference in fluorescence intensity between the non-biological and biological samples could be identified for most instruments. While lower concentrations of fluorescent particles were detected by the MBS, the MBS demonstrates the potential to discriminate between pollen and other biological particles. This study presents the first published technical summary and use of the ACS for instrument intercomparisons. Within this work a clear overview of the data pre-processing is also presented, and documentation of instrument version/model numbers is suggested to assess potential instrument variations between different versions of the same instrument. Further laboratory studies sampling different particle types are suggested before use in quantifying impact on ambient classification.

Published

2019

18. Detection of Airborne Biological Particles in Indoor Air Using a Real-Time Advanced Morphological Parameter UV-LIF Spectrometer and Gradient Boosting Ensemble Decision Tree Classifiers.

Author

Crawford, Ian, Topping, David, Gallagher, Martin, Forde, Elizabeth, Lloyd, Jonathan R., Foot, Virginia, Stopford, Chris, and Kaye, Paul

Subjects

*DECISION trees, *SUPERVISED learning, *LASER-induced fluorescence, *AIRBORNE lasers, *PROBABILITY density function, *SPECTROMETERS, *PARTICLES

Abstract

We present results from a study evaluating the utility of supervised machine learning to classify single particle ultraviolet laser-induced fluorescence (UV-LIF) signatures to investigate airborne primary biological aerosol particle (PBAP) concentrations in a busy, multifunctional building using a Multiparameter Bioaerosol Spectrometer. First we introduce and demonstrate a gradient boosting ensemble decision tree algorithm's ability to accurately classify laboratory generated PBAP samples into broad taxonomic classes with a high level of accuracy. We then develop a framework to appraise the classification accuracy and performance using the Hellinger distance metric to compare product parameter probability density function similarity; this framework showed that key training classes were sufficiently different in terms of particle fluorescence and morphology to facilitate classification. We also demonstrate the utility of including advanced morphological parameters to minimise inter-class conflation and improve classification confidence, where relying on the fluorescent spectra alone would likely result in misattribution. Finally, we apply these methods to ambient data collected within a large multi-functional building where ambient bacterial- and fungal-like classes were identified to display trends corresponding to human activity; fungal-like classes displayed a consistent diurnal trend with a maximum at midday and hourly peaks correlating to movements within the building; bacteria-like aerosol displayed complex, episodic events during opening hours. All PBAP classes fell to low baseline concentrations when the building was unoccupied overnight and at weekends. [ABSTRACT FROM AUTHOR]

Published

2020

19. Intercomparison of Multiple UV-LIF Spectrometers Using the Aerosol Challenge Simulator.

Author

Forde, Elizabeth, Gallagher, Martin, Walker, Maurice, Foot, Virginia, Attwood, Alexis, Granger, Gary, Sarda-Estève, Roland, Stanley, Warren, Kaye, Paul, and Topping, David

Subjects

*AEROSOLS, *SPECTROMETERS, *LASER-induced fluorescence, *LABORATORIES

Abstract

Measurements of primary biological aerosol particles (PBAPs) have been conducted worldwide using ultraviolet light-induced fluorescence (UV-LIF) spectrometers. However, how these instruments detect and respond to known biological and non-biological particles, and how they compare, remains uncertain due to limited laboratory intercomparisons. Using the Defence Science and Technology Laboratory, Aerosol Challenge Simulator (ACS), controlled concentrations of biological and non-biological aerosol particles, singly or as mixtures, were produced for testing and intercomparison of multiple versions of the Wideband Integrated Bioaerosol Spectrometer (WIBS) and Multiparameter Bioaerosol Spectrometer (MBS). Although the results suggest some challenges in discriminating biological particle types across different versions of the same UV-LIF instrument, a difference in fluorescence intensity between the non-biological and biological samples could be identified for most instruments. While lower concentrations of fluorescent particles were detected by the MBS, the MBS demonstrates the potential to discriminate between pollen and other biological particles. This study presents the first published technical summary and use of the ACS for instrument intercomparisons. Within this work a clear overview of the data pre-processing is also presented, and documentation of instrument version/model numbers is suggested to assess potential instrument variations between different versions of the same instrument. Further laboratory studies sampling different particle types are suggested before use in quantifying impact on ambient classification. [ABSTRACT FROM AUTHOR]

Published

2019

20. Aerosol agent detection using spectroscopic characterization

Author

V. Sivaprakasam, M. Currie, J. Lou, J. Czege, J. Eversole, and Office of Naval Research, Defense Threat Reduction Agency

Subjects

Physics, OCIS codes: (300.2530) Fluorescence, laser-induced, (290.5850) Scattering, particles, optical spectroscopy, aerosol particle, biological aerosol, biological agent detection, lcsh:Science (General), lcsh:Q1-390

Abstract

We present here a brief description of our efforts to develop optical spectroscopic characterization and classification methods for air-borne biological particles. While the bulk of our experimental investigation has used laser-induced fluorescence in conjunction with incident laser elastic scattering, we have also developed novel methods for generating, handling, interrogating and collecting aerosol particles. A method known as a Structured Trigger Beam (STB) for obtaining optical measurements from individual aerosol particles that are normalized with respect to the instrument response function is described here. Our latest results will be included in our presentation.

Published

2011

21. Interinstrument Variability and Validation Study for the XMX/2L-MIL Biological Air Sampler

Author

SCHOOL OF AEROSPACE MEDICINE WRIGHT PATTERSON AFB OH, Black, Jon E, Cooper, Casey W, SCHOOL OF AEROSPACE MEDICINE WRIGHT PATTERSON AFB OH, Black, Jon E, and Cooper, Casey W

Abstract

The interinstrument variability of the XMX/2L-MIL (XMX) biological air sampler was controlled by operating it with a fixed final nozzle orientation. Three XMXs were operated in a 12-m3 aerosol test chamber (ATC) in which a Bacillus globigii (Bg) aerosol was uniformly distributed for 18 experimental trials. An analysis of variance (ANOVA) was performed on the XMX results and had an Fvalue of 0.36, compared to the F-critical of 3.22 for a p-value of 0.05. This experiment was repeated using male-specific 2 bacteriophage (MS2) viral agent surrogate for 16 experimental trials. An ANOVA was performed on the XMX results and had an Fvalue of 0.09, compared to the F-critical of 3.22 for a p-value of 0.05. Therefore, it was concluded that operating XMXs at the specified final nozzle orientation would lead to precise laboratory culture results with acceptable interinstrument variability. Three XMXs were used to determine if Remel M5(registered trademark) collection media would better preserve MS2 for laboratory culture analysis than the commonly used PBS solution collection media. The XMXs were operated in the ATC in which MS2 aerosol was uniformly distributed for 16 experimental trials, with 8 conducted using Remel M5? and 8 with PBS solution as collection media. An ANOVA was performed on the XMX results and had an F-value of 6.73, compared to the F-critical of 5.30 for a p-value of 0.05. Therefore, it was concluded that Remel M5(registered trademark) produced superior results, as its culture results were 2.3 times greater than those for PBS solution.

Published

2012

22. The biological aerosol as a factor of biodegradation

Author

Caneva, G., Maggi, Oriana, Nugari, M. P., Pietrini, A. M., Piervittori, R., Ricci, S., and Roccardi, A.

Subjects

biological aerosol, biodeterioration, cultural heritage

Published

2003

23. Analysis of the Biological Aerosol

Author

F. Gallo, Rosanna Piervittori, P. Mandrioli, Claudia Sorlini, A. M. Pietrini, Sandra Ricci, Giovanna Pasquariello, E. Pacini, A. Roccardi, Oriana Maggi, M. A. Favali, and G. Ranalli

Subjects

Microscope, analysis, cultural heritage, biological aerosol, food and beverages, Computational biology, MOLECULAR BIOLOGY METHODS, law.invention, Aerosol, Cultural heritage, law, Environmental science, Identification (biology)

Abstract

The techniques currently available for the identification of biological aerosol can be divided into five categories: cultural techniques; direct counting through a microscope; rapid biochemical methods; immunological methods; molecular biology methods.

Published

2003

24. Monitoring the Biological Aerosol

Author

Claudia Sorlini, P. De Nuntiis, Paolo Mandrioli, Oriana Maggi, and Giancarlo Ranalli

Subjects

sampling, biology, Chemistry, Microorganism, cultural heritage, dispersion of particles, deposition, biological aerosol, biology.organism_classification, Aerosol, Spore, Suspension (chemistry), Deposition (aerosol physics), Algae, Propagule, Environmental chemistry, Lichen

Abstract

The air of indoor and outdoor environments contains a great number of particles in suspension, having various origins, shapes and sizes. These particles form the atmospheric aerosol (Table 5.1). The criterion for classifying the particles may vary, depending on the purpose of the work: they may be classified on the basis of their nature (biological, organic, inorganic), of their location (marine, continental, rural, industrial, urban), and of the effects (chemical, toxic, pathogenic, of degradation) that they produce on their deposition surfaces, which may be either materials or living systems. Among the particles of biological origin, a distinction is generally made between viable ones, which are able to reproduce or stimulate biological processes, and non viable ones or their fragments. The term microorganisms is used in this chapter to indicate viruses, bacteria, algae, protozoa, fungi (yeasts and moulds), spores etc.. Spores may be clusters or single particles originated from fungal fruiting bodies, or resistant forms produced by some bacteria. To these microorganisms we may add the spores of Bryophyta and Pteridophyta, lichen propagules, algal cells, pollen grains and Protozoa cysts. These are often found aggregated or included in other liquid or solid particles.

Published

2003

25. Backscatter and Transmission of Aerosol at UV Through Middle IR Wavelengths.

Author

UNIVERSITY COLL GALWAY (UNITED KINGDOM), Jennings, S. G., UNIVERSITY COLL GALWAY (UNITED KINGDOM), and Jennings, S. G.

Abstract

The total biological pollen and spore number concentration, per m3 , at the Mace Head Environmental field research station on the west coast of Ireland is presented for consecutive months from September 1993 to June 1994 using a continuous (with a resolution of 4 hours) Burkard volumetric spore sampler. Pollen grain and spore concentration per m3 are also presented for individual taxa (species). The biological aerosol concentration for clean (maritime), polluted (continental) and modified maritime air flows are interpreted with the support of the locally measured wind direction data together with air flow back trajectories from the Mace Head site.

Published

1994

26. Sump Bay Fever: Inhalational Fever Associated with a Biologically Contaminated Water Aerosol

Author

Anderson, Kenneth, McSharry, Charles P., Clark, Colin, Clark, Christopher J., Barclay, G. Robin, and Morris, George P.

Published

1996