Your search keyword '"UV-LIF"' showing total 12 results

1. Data for improved algorithmic methods for identification of biological airborne particulate matter

Author

Forde, Elizabeth, Gallagher, Martin, and Topping, David

Subjects

UV-LIF, Bioaerosol, PBAPs, Primary biological aerosol particles

Abstract

Primary biological aerosol particles (PBAPs), otherwise commonly referred to as 'bioaerosols', are a subset of atmospheric aerosol particles that comprise pollen, fungal spores, bacteria, and viruses, and other biological matter suspended in the atmosphere. Whilst PBAPs are naturally produced, these particles play a fundamental role in the Earth system, influencing natural and agricultural ecosystems, potentially exacerbating animal and human diseases, and contributing to climate processes. However, a considerable lack of understanding remains concerning the pathways that these particles contribute to, owing to the difficulties in detecting and quantifying these particles. This thesis focuses on the detection and characterisation of PBAPs using a real-time online detection technique, known as ultraviolet light-induced fluorescence (UV-LIF) spectrometry. Whilst various UV-LIF spectrometers have been deployed for measurement campaigns in a range of geographic locations worldwide, studies quantifying classification performance and inter-comparisons of different UV-LIF spectrometers are limited. As such, there remain some considerable uncertainties in the detection abilities and consistency of these instruments, with consequent impacts on training algorithms for PBAP classification. Multiple UV-LIF spectrometers were deployed in both ambient measurement campaigns, and laboratory experiments. The initial ambient study, characterising and inter-comparing biofluorescent aerosol emissions from four sites in the UK indicated a similar dominance of wet-discharged fungal spores across most of the study sites, but illustrated the difficulties that currently exist when attempting to characterise these particles following collection by UV-LIF spectrometers. By conducting a laboratory UV-LIF inter-comparison study to assess instrument detection abilities, distinct fluorescent responses could not be identified between the different biological particle groups sampled (bacteria, fungal spores, and pollen). Differences in fluorescent responses were, however, identified between instruments which were nominally the same, and therefore it was suggested that due to these differences training data for supervised techniques is not cross-compatible between instruments. The final comparison study of UV-LIF spectrometers and offline, traditional measurement techniques, illustrated that these instruments are adept at detecting select fungal spores, and bacterial particles in ambient conditions. However, the results from using both unsupervised and supervised analysis techniques illustrated some continuing issues in distinguishing between these two particle groups when using UV-LIF spectrometers. By conducting both ambient and laboratory studies, and demonstrating the use of both unsupervised and supervised particle discrimination and characterisation methods, the findings in this thesis contribute towards an improved understanding of how different UV-LIF spectrometers respond to both known and unknown particle types. The results of which consequently highlight the impacts that this has for the application of different analysis techniques for PBAP characterisation.

Published

2021

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. Collection and Identification of Biological Samples Based on Military On-Site Detection Devices

Author

Monika Kuligowska and Sławomir Neffe

Subjects

chemical sciences, biological weapon, bioterrorism, CBRN, PCR, UV-LIF, Technology

Abstract

Due to still current biological threats related to the activities of terrorist groups, crisis situations in many regions of the world, as well as cyclical epidemics, fast and reliable detection of biological contamina-tion is an essential element of ensuring broadly understood safety of the population. The work deals with the sampling and verification procedures. This paper focuses on sample preparation techniques for analysis and details analytical methods for identifying biological agents. Additionally, on-site technologies implemented in military devices for the detection of biological contamination were discussed. The work enables the reader to get acquainted with modern techniques of detection of factors of biological origin and their identification, which is the knowledge necessary when choosing the appropriate equipment depending on the purpose of the contamination recognition sub-unit and the task at hand. Knowledge of sam-pling and preparation of samples for analysis will help to increase the skills of the sampling teams to do so and to achieve reliable results by using appropriate procedures and eliminating the possibility of loss of the analyte or inadvertent contamination of the sample. It will also increase safety at every stage of working with biological samples. All these activities can contribute to the global increase in security of the population around the world. Keywords: chemical sciences, biological weapon, bioterrorism, CBRN, PCR, UV-LIF

Published

2021

4. Mobile Stand-off and Stand-in Surveillance Against Biowarfare and Bioterrorism Agents

Author

Kambouris, Manousos E., Masys, Anthony J., Editor-in-chief, Bichler, Gisela, Series editor, Bourlai, Thirimachos, Series editor, Johnson, Chris, Series editor, Karampelas, Panagiotis, Series editor, Leuprecht, Christian, Series editor, Morse, Edward C., Series editor, Skillicorn, David, Series editor, and Yamagata, Yoshiki, Series editor

Published

2018

5. 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

6. 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

7. 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

8. 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

9. A support vector machine approach to the automatic identification of fluorescence spectra emitted by biological agents

Author

Jesús Vega, M. Lungaroni, Roberto Pizzoferrato, Andrea Malizia, O Cenciarelli, Andrea Murari, Emmanuele Peluso, Pasquale Gaudio, M Carestia, Stefano Parracino, and Michela Gelfusa

Subjects

Process (engineering), Noise reduction, SVM, Data analysis, Biology, 01 natural sciences, Fluorescence, 010305 fluids & plasmas, 010309 optics, LIDAR, 0103 physical sciences, Electronic, Optical and Magnetic Materials, Electrical and Electronic Engineering, Laser-induced fluorescence, Remote sensing, Denoising, Applied Mathematics, Settore FIS/01 - Fisica Sperimentale, Ranging, Computer Science Applications1707 Computer Vision and Pattern Recognition, Condensed Matter Physics, Bas, Support vector machine, Identification (information), Lidar, UV-LIF, Transmission (telecommunications), CBRNe, Filtering, Electronic, Optical and Magnetic Materials, Biological system

Abstract

Two of the major new concerns of modern societies are biosecurity and biosafety. Several biological agents (BAs) such as toxins, bacteria, viruses, fungi and parasites are able to cause damage to living systems either humans, animals or plants. Optical techniques, in particular LIght Detection And Ranging (LIDAR), based on the transmission of laser pulses and analysis of the return signals, can be successfully applied to monitoring the release of biological agents into the atmosphere. It is well known that most of biological agents tend to emit specific fluorescence spectra, which in principle allow their detection and identification, if excited by light of the appropriate wavelength. For these reasons, the detection of the UVLight Induced Fluorescence (UV-LIF) emitted by BAs is particularly promising. On the other hand, the stand-off detection of BAs poses a series of challenging issues; one of the most severe is the automatic discrimination between various agents which emit very similar fluorescence spectra. In this paper, a new data analysis method, based on a combination of advanced filtering techniques and Support Vector Machines, is described. The proposed approach covers all the aspects of the data analysis process, from filtering and denoising to automatic recognition of the agents. A systematic series of numerical tests has been performed to assess the potential and limits of the proposed methodology. The first investigations of experimental data have already given very encouraging results.

Published

2016

10. 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

11. Multispectral analysis of biological agents to implement a quick tool for stand-off biological detection

Author

Andrea Murari, M Carestia, M. Lungaroni, Andrea Malizia, Roberto Pizzoferrato, Pasquale Gaudio, O Cenciarelli, J. Gabriele, Gian Marco Ludovici, and Michela Gelfusa

Subjects

Chemistry, Applied Mathematics, Multispectral image, Settore FIS/01 - Fisica Sperimentale, Analytical chemistry, Support Vector Regression, Computer Science Applications1707 Computer Vision and Pattern Recognition, Condensed Matter Physics, Endospore, Fluorescence, Spectral line, Settore FIS/07 - Fisica Applicata(Beni Culturali, Ambientali, Biol.e Medicin), Biological warfare agents, Multispectral analysis, stand-off detection, UV-LIF, Electrical and Electronic Engineering, Electronic, Optical and Magnetic Materials, Wavelength, Electronic, Optical and Magnetic Materials, Laser-induced fluorescence, Luminescence, Excitation

Abstract

With the aim of identifying an approach to exploit the differences in the fluorescence signatures of biological agents BAs, we have investigated the response of some BAs simulants to a set of different excitation wavelengths in the UV spectral range (i.e. 266, 273, 280, 300, 340, 355 nm). Our preliminary results on bacterial spores and vegetative forms, dispersed in water, showed that the differences in the fluorescence spectra can be enhanced, and more easily revealed, by using different excitation wavelengths. Specifically, the photo luminescence (PL) spectra coming from different species of Bacillus, in the form of spores (used as simulants of Bacillus anthracis), show significant differences under excitation at all the wavelengths, with slightly larger differences at 300, 340, 355 nm. On the other hand, the vegetative forms of two Bacillus species, did not show any appreciable difference, i.e. the PL spectra are virtually identical, for the excitation wavelengths of 266, 273, 280 nm. Conversely, small yet appreciable difference appear at 300, 340, 355 nm. Finally, large difference appear between the spore and the vegetative form of each species at all the wavelengths, with slightly larger variations at 300, 340, 355 nm. Together, these preliminary results support the hypothesis that a multi-wavelength approach could be used to improve the sensitivity and specificity of UV-LIF based BAs detection systems. The second step of this work concerns the application of a Support Vector Regression (SVR) method, as evaluated in our previous work to define a methodology for the setup of a multispectral database for the stand-off detection of BAs.

Published

2015

12. Fluorescence measurements for the identification of biological agents features for the construction of a spectra database

Author

Roberto Pizzoferrato, Michela Gelfusa, D. Scarpellini, Andrea Malizia, F D'Amico, Pasquale Gaudio, M Carestia, and O Cenciarelli

Subjects

Early detection, Optical emission spectra, computer.software_genre, Fluorescence, Spectral line, law.invention, law, Biological warfare agents, Standoff detection, Biological warfare, Biological weapons, Chemical warfare, Database systems, Emission spectroscopy, Biological warfare agents, Different boundary condition, Fluorescence features, Fluorescence measurements, Identification techniques, UV-LIF, Fluorescence, Laser-induced fluorescence, Remote sensing, Database, Chemistry, Settore FIS/01 - Fisica Sperimentale, Emission spectroscopy, Laser, Settore FIS/07 - Fisica Applicata(Beni Culturali, Ambientali, Biol.e Medicin), Spectral database, Identification (information), UV-LIF, computer

Abstract

The use of biological weapons represents a great concern both from a military and civilian point of view. The early detection of biological warfare agents (BWAs) in atmosphere is a huge challenge that could be addressed through UV-LIF (Ultra Violet Laser Induced Fluorescence) techniques. Fluorescence measurements of aerosol particles can provide gross discrimination between bio-agents and atmospheric background particles, In this work we intend to investigate the capability of discriminating among different biological warfare agents (BWA) through the analysis of the optical emission spectra. To accomplish this task, a deep knowledge of fluorescence features with different boundary conditions is required, in order to create a database of comparable spectral fingerprints. Preliminary results, obtained through a laboratory setup with a standard UV lamp source, showed that significant differences can be appreciated among BWAs simulants' spectra. This represents a first step towards the implementation of a spectral database and a laser-based biological stand-off identification technique.

Published

2014