Efficiency of household water treatment devices, systems in removing pathogenic bacteria causing gastrointestinal diseases.

Mwabi, Jocelyne Kamwanya.

January 2012

Thesis (MTech. degree in Environmental management.)-Tshwane University of Technology, 2012 / Aims to assist communities on the selection of suitable household water treatment devices/systems that can produce bacteriologically safe drinking water of high quality, at low cost, five selected household water treatment filters were used in this study.

Water--Purification.

Pathogenic bacteria--Inactivation

Applications of High Voltage Power Supplies in the Purification of Water

Johnstone, Paul Trevor

January 2001

High voltage treatment technology has been developed in this thesis and had initially shown promise in its effectiveness in reducing microorganisms found in water supplies. Initial testing found that the high voltage could destroy over 99.9% of the bacteria S. marcescens (a 3-log reduction). Cited literature on the effects of high voltage pulsed electric fields (PEFs) on various microorganisms have shown that high destruction rates of up to 9-log can be achieved. Thus by increasing the electric field strength or exposure time, or by improving the design of the electrode flow chamber, better results should be achieved using high voltage on water. However, contrary to this, upon further design improvements the 99.9% destruction threshold was rarely increased. The initial slow flow device of one litre-per-minute (1 LPM) was scaled up to flows of 10 LPM and 33 LPM. However, these faster flow devices were even less effective in the destruction of bacteria, destroying only 99% of S. marcescens (2-log reduction). No physical or technical design parameters could account for this low performance. One possible reason for these low results was in the preparation of the bacteria themselves. It was discovered that the growth stage of bacteria prepared for experiments had a large effect on the results. Bacteria harvested in the early growth stage could be nearly all destroyed by the high voltage (greater then 4-log reduction), whereas those harvested in the late stationary stage were much more resistant (less than 0.5-log reduction). Bacteria naturally occurring in water supplies will mostly be in a non-metabolising state. This implies that they will be more resistant to high voltage exposure than bacteria grown in a laboratory under standard testing procedures. Thus standard testing procedures for this device do not give accurate results. Further research into the mechanism behind the bacterial resistance is required to improve the performance of high voltage devices. A combination of different technologies may also prove effective in overcoming the resistance mechanism. These improvements are required before high voltage treatment can be properly developed and commercially exploited.

water purification

water treatment

bacteria inactivation

pulsed electric fields

PEF

Effects and mechanisms of interleukin-10 promoter polymorphisms on HIV-1 susceptibility and pathogenesis.

Naicker, Dshanta Dyanedi.

11 November 2013

HIV infection has risen to pandemic proportions. Interleukin-10 (IL-10), a potent antiinflammatory cytokine has been shown to enhance the establishment and persistence of chronic viral infections through inactivation of effector antiviral immune responses and it may also directly influence HIV-1 replication in cells of diverse lineages. IL-10 promoter polymorphisms have been shown to affect HIV-1 susceptibility and pathogenesis. However, the underlying mechanisms are poorly understood. We investigated the relationship between IL-10 promoter variants, plasma IL-10 levels, and markers of disease outcome in chronically HIV-1-infected individuals. To investigate the mechanistic role of IL-10 and its genetic variants on HIV pathogenesis, we studied markers of activation on B cells, CD4+ and CD8+ T cells, and assessed effects on CD4+ T cell proliferation with and without blockade of the IL- 10 pathway. We used Taqman genotyping assays to genotype three IL-10 promoter single nucleotide polymorphisms (SNPs) in our study cohort. Baseline plasma IL-10 levels were measured using Luminex technology for 112 individuals. Viral load, CD4+ T cell counts and cytotoxic T lymphocyte (CTL) immune responses were measured at baseline. The rate of CD4+ T cell decrease was calculated in 300 individuals with a median follow-up of 25 months. CD38, CD95, Ki67, IgG and PD-1, markers of activation or exhaustion were measured on B cells, and CD38, CD95, Ki67, HLA-DR and PD-1 were measured on CD4+ and CD8+ T cells in a subset of 63 individuals. CD4+ T cell proliferation was measured using Carboxyfluorescein succinimidyl ester (CFSE) assays, following IL-10 receptor blockade in a subset of 31 individuals. The IL-10 -1082G, -592A and -3575 variants were observed at frequencies of 0.3, 0.34 and 0.23 respectively, in our study cohort. Plasma IL-10 levels were significantly higher in the - 1082GG group than in the combined AA/AG group (p=0.0006). There was a significant association between the 592AA genotype and a greater breadth of CTL responses compared to the CC and CA (p= 0.002 and 0.004 respectively). The -592AA genotype associated significantly with an attenuated loss of CD4 cells (p= 0.0496), with -592AA having the least change in CD4 cells per year. The median expression of HLA-DR, a marker of T cell activation was significantly higher in the-1082AA group for CD8 cells (p= 0.047), and the - 592AA group for CD4 T cells (p= 0.01). The median expression of IgG on the surface of B cells was significantly higher in the -1082GG genotype and the -592CC genotype (p=0.0183 and 0.0659 respectively). Overall, IL-10 variants correlated with IL-10 expression and CD4 decline during chronic HIV-1 infection. IL-10 promoter variants may influence the rate of HIV-1 disease progression by regulating IL-10 levels, which in-turn, may affect the breadth of CTL responses. Furthermore, the increased expression of HLA-DR and PD-1 on CD8+ and CD4+ T cells, indicates that lower IL-10 levels are associated with increased immune activation and immune exhaustion. The increased expression of IgG on B cells, suggests that in a setting of lower IL-10, there is possibly a bias towards a Th2 immune response. These data suggest a significant role for IL-10 genetic variants and IL-10 in HIV pathogenesis. Further studies to determine whether and how the IL-10 pathway may be manipulated for therapeutic or vaccine strategies for HIV are warranted. / Thesis (Ph.D.)-University of KwaZulu-Natal, Durban, 2012.

Interleukin-10.

HIV infections--Alternative treatment.

Pathogenic bacteria--Inactivation.

Theses--Immunology.

Influence of pathogenic bacterial determinants on genome stability of exposed intestinal cells and of distal liver and spleen cells

Walz, Paul S

January 2011

Most bacterial infections can be correlated to contamination of consumables such as food and water. Upon contamination, boil water advisories have been ordered to ensure water is safe to consume, despite the evidence that heat-killed bacteria can induce genomic instability of exposed (intestine) and distal cells (liver and spleen). We hypothesize that exposure to components of heat-killed Escherichia coli O157:H7 will induce genomic instability within animal cells directly and indirectly exposed to these determinants. Mice were exposed to various components of dead bacteria such as DNA, RNA, protein or LPS as well as to whole heat-killed bacteria via drinking water. Here, we report that exposure to whole heat-killed bacteria and LPS resulted in significant alterations in the steady state RNA levels and in the levels of proteins involved in proliferation, DNA repair and DNA methylation. Exposure to whole heat-killed bacteria and their LPS components also leads to increased levels of DNA damage. / xiv, 132 leaves : ill. (chiefly col.) ; 29 cm

Escherichia coli O157:H7 -- Research

Microbial carcinogenesis -- Research

DNA damage -- Research

Intestines -- Infections -- Pathogenesis

Liver cells

Spleen -- Pathogenesis -- Research

Endotoxins -- Research

Mice as laboratory animals

Dissertations, Academic

Pollution de l’air intérieur : mesure, impact sur la santé et traitement par méthodes photochimiques. / Indoor air pollution : measurement, health impact and photochemical methods treatment.

Le Bechec, Mickael

20 October 2016

L’accroissement de la population humaine, l’agriculture intensive et le développement industriel créent une pollution de l’air qui aujourd’hui devient préoccupante pour notre santé et notre environnement. Si la qualité de l’air extérieur fait l’objet depuis plusieurs décennies de règlementations qui permettent aujourd’hui de constater une diminution globale de la pollution dans les grandes agglomérations européennes, la pollution de l’air intérieur a quant à elle été longtemps sous-estimée. En effet, avec le développement de matériaux composites pour la construction et l’ameublement, la gamme de polluants de l’air intérieur s’est très largement agrandie et les concentrations ont globalement augmenté. Plusieurs études ont ainsi montré que de nombreux composés organiques volatils étaient détectés dans l’air intérieur à des concentrations bien plus élevées qu’à l’extérieur. D’autre part, la modification des modes de vie sédentaires et citadines ont pour conséquence une augmentation du temps passé dans des espaces confinés comme les logements, les lieux de travail et les transports en commun. Le simple renouvellement de l’air intérieur par de l’air extérieur devenant de moins en moins satisfaisant dans les grandes agglomérations, de nouvelles méthodes de traitement sont actuellement développées pour diminuer les concentrations de ces polluants tout en limitant la consommation d’énergie. La photocatalyse, en tant que procédé d’oxydation avancé fait partie des technologies intéressantes pour minéraliser des composés organiques volatils (COV). Après un rapide rappel du contexte sociétal de la pollution atmosphérique, les conditions de mesures et les méthodes possibles pour le traitement de cette pollution sont présentées. Le chapitre suivant regroupe les résultats sur le développement de matériaux photocatalytiques innovants et la mesure de leur efficacité. La première partie de ce chapitre fait le bilan des réacteurs photocatalytiques adaptés à l’étude de réactions à l’interface solide-gaz et résume les nombreuses difficultés liées à l’évaluation des performances de divers matériaux dans des conditions le plus souvent difficilement comparables. Dans la seconde partie, un premier matériau composite constitué de film polymère et de dioxyde de titane a été caractérisé par sa capacité à oxyder un composé volatil, le diméthyle disulfure, utilisé en agriculture pour la fumigation. Le développement d’un second matériau photocatalytique original, constitué de fibres de TiO2 pur a, quant à lui, été caractérisé par sa capacité à minéraliser des COV représentatifs de la pollution de l’air intérieur (acétone, heptane, toluène). Les deux dernières parties de ce chapitre se situent à l’interface entre la photochimie et la biologie. Dans un premier temps, la capacité d’inactivation bactérienne d’un textile « intelligent » sur lequel sont fixées des particules de dioxyde de titane couplées à un photosensibilisateur a été étudiée et l’efficacité sous rayonnement visible de ce tissu original a été analysée. L’impact de la pollution de l’air intérieur sur des cellules de la peau fait l’objet de la dernière partie de ce chapitre. Pour cela un montage permettant d’exposer des cellules de kératinocytes en culture, mais également des biopsies de peau humaine, à des concentrations contrôlées en COV a été mis au point. Nous avons ainsi pu mettre en évidence une réponse cellulaire à ce stress environnemental et préciser l’origine de ce stress. Enfin ce travail se termine par une ouverture sur des projets de recherche actuellement en cours ayant pour objet la mesure des espèces réactives de l’oxygène impliquées dans les réactions photochimiques et le développement de nouveau matériaux hybrides polymère/photosensibilisateurs. Des idées de projets à l’interface de la photochimie et de la biologie ouvrent de nouvelles perspectives à la suite de ces premiers résultats. / The increase of human population, the modern agriculture and industrial development generate air pollution, which is nowadays worrying for health and environment. Since several decades, outdoor air pollution has been regulated giving rise a global decrease of pollution in the most important European cities. However indoor air pollution was neglected for a long time. Indeed with development of composite materials for building and furnishing, the number of air pollutants strongly increased together with their concentrations. Several studies have thus demonstrated that numerous volatile organic compounds (VOC) were detected indoor at much higher concentration than outdoor. Moreover, due to the modification of sedentary and urban lifestyles, the time spent in confined spaces like housing, working places and public transportation increases. It is less and less satisfactory to simply renew indoor air with outdoor air in most of urban agglomerations. Accordingly, new processes for air treatment are developed in order to decrease indoor air pollutant concentrations while limiting energetic consumption. Photocatalysis is an advanced oxidation process potentially interesting for VOC removal. After a short reminder on the societal context of atmospheric pollution, measurement and treatment methods are presented in chapters I and II. The following chapter gathers the results obtained on the development of new photocatalytic materials and on the measure of their efficiency. The first part of this chapter is devoted to an overview of photocatalytic reactors for gas solid reactions and summarizes the numerous problems arising from the comparison of different materials under various conditions, which are not always similar. In the second part, a composite material made of titanium dioxide encapsulated in a polymer film is characterized and used for the oxidation of a volatile compound used for agricultural fumigation, dimethyl disulfide. The spectroscopic analysis led to the optimization of the material as a function of its thickness and its titanium dioxide loading. A second innovative photocatalytic material made of pure TiO2 fibers is characterized by its mineralization ability of representative indoor air VOC (acetone, heptane, and toluene). The performance of this material is compared to that of a commercial one, Quartzel ® made of TiO2 deposited on quartz fibers, under strictly identical conditions. The two last parts of this chapter are at the interface between photochemistry and biology. In a first strep, bacterial inactivation by a smart textile where titanium dioxide particles coupled with a photosensitizer is studded under visible light. In the last part, the impact of indoor air pollution on skin cells is presented. A dedicated device allowing keratinocytes culture cells and skin biopsies exposures to controlled VOC concentrations is developed. It is thus possible to evidence and to determine the origin of the cellular response to this environmental stress. At last, new research projects for a near future are then presented. They concern the determination of reactive oxygen species involved in photochemical reactions and the development of new hybrid polymers encapsulating photosensitizing molecules. Prospective ideas at the interface of photochemistry and biology conclude this memory.

Pollution atmosphérique

COV

Toxicité

Photocatalyse

Photosensibilisateur

Traitement de l’air

Espèces réactives de l’oxygène

Matériaux innovants

Inactivation bactérienne

Atmospheric pollution

VOC

Toxicity

Photocatalysis

Phyotosensitizers

Air treatment,

Reactive oxygen species

Innovative materials

Bacteria inactivation