Global ETD Search

61	Spatially Explicit Modeling of West Nile Virus Risk Using Environmental Data Kala, Abhishek K. 12 1900 (has links) West Nile virus (WNV) is an emerging infectious disease that has widespread implications for public health practitioners across the world. Within a few years of its arrival in the United States the virus had spread across the North American continent. This research focuses on the development of a spatially explicit GIS-based predictive epidemiological model based on suitable environmental factors. We examined eleven commonly mapped environmental factors using both ordinary least squares regression (OLS) and geographically weighted regression (GWR). The GWR model was utilized to ascertain the impact of environmental factors on WNV risk patterns without the confounding effects of spatial non-stationarity that exist between place and health. It identifies the important underlying environmental factors related to suitable mosquito habitat conditions to make meaningful and spatially explicit predictions. Our model represents a multi-criteria decision analysis approach to create disease risk maps under data sparse situations. The best fitting model with an adjusted R2 of 0.71 revealed a strong association between WNV infection risk and a subset of environmental risk factors including road density, stream density, and land surface temperature. This research also postulates that understanding the underlying place characteristics and population composition for the occurrence of WNV infection is important for mitigating future outbreaks. While many spatial and aspatial models have attempted to predict the risk of WNV transmission, efforts to link these factors within a GIS framework are limited. One of the major challenges for such integration is the high dimensionality and large volumes typically associated with such models and data. This research uses a spatially explicit, multivariate geovisualization framework to integrate an environmental model of mosquito habitat with human risk factors derived from socio-economic and demographic variables. Our results show that such an integrated approach facilitates the exploratory analysis of complex data and supports reasoning about the underlying spatial processes that result in differential risks for WNV. This research provides different tools and techniques for predicting the WNV epidemic and provides more insights into targeting specific areas for controlling WNV outbreaks. West Nile virus spatial modeling epidemiology environmental health geovisualization multivariate analysis geographically weighted regression West Nile virus. Medical mapping. Medical geography. Epidemiology.
62	Emerging arboviruses in Harris County, Texas. Rodriguez, Liliana F. Bueno, Rudy, DuPont, Herbert L., Lloyd, Linda E., January 2008 (has links) Thesis (Dr. P.H.)--University of Texas School of Public Health, 2008. Thesis (Dr. P.H.)--University of Texas Health Science Center at Houston, School of Public Health, 2008. / Source: Dissertation Abstracts International, Volume: 69-02, Section: B, page: 0973. Adviser: Kristy O. Murray. Includes bibliographical references.
63	La protéine non-structurale NS1 du virus West Nile : étude fonctionnelle et cible potentielle de nouvelles molécules antivirales / Functional study of sNS1 viral protein during West Nile Virus infection and screening of novel molecules anti-WNV Furnon, Wilhelm 18 January 2018 (has links) Parmi les virus émergents transmis par des moustiques (arbovirus), le genre flavivirus est fortement représenté avec les virus Dengue, Zika, et le virus West Nile (WNV). Le WNV est responsable de nombreux cas de maladies neuroinvasives sévères, parfois mortelles, chez l'humain et les chevaux. Ce virus représente donc un problème de santé publique humaine et animale. Il n'existe pour le moment aucun vaccin humain ni aucun traitement spécifique anti-WNV.Parmi les déterminants viraux essentiels à l'infection par les flavivirus, la glycoprotéine non-structurale NS1 possède des propriétés multifonctionnelles. La forme sNS1, sécrétée dans le milieu extracellulaire, est fortement impliquée dans la dérégulation du système immunitaire de l'hôte. Ces mécanismes participent à l'évasion du virus à la réponse antivirale et, paradoxalement, à la pathogenèse observée dans les formes sévères de la maladie. L'essentiel de ces données concernant le virus de la Dengue, nous souhaitions étudier les propriétés fonctionnelles, in vitro, de la protéine sNS1WNV au cours de l'infection de cellules épithéliales, gliales et neuronales de mammifères. En effet, la structure des protéines sNS1 de flavivirus étant très similaire, notre hypothèse suppose un rôle de sNS1WNV dans les infections neuroinvasives.Si la protéine sNS1WNV ne semble pas moduler les étapes de l'infection virale, elle est cependant à l'origine d'un remodelage du cytosquelette d'actine dans les cellules épithéliales. Elle est aussi impliquée dans l'activation de voies antivirales chez les cellules neuronales non infectées. D'autre part, en ciblant sNS1 et la protéine d'enveloppe E du WNV, nous avons pu isoler, par criblage de molécules aRep (protéines artificielles à motifs répétés), des ligands de haute affinité pour ces déterminants viraux. Ces nouvelles molécules, capables de se lier spécifiquement aux protéines sNS1 et E, ont le potentiel pour servir de base au développement de nouveaux outils de diagnostics et d'agents thérapeutiques antiviraux / Among emerging mosquito-borne viruses (arboviruses), flaviviruses like Dengue, Zika and West Nile virus (WNV) are very often involved in outbreaks. WNV causes several neuroinvasive diseases, which can be lethal, in humans and horses each year. This virus is a threat for both, human and animal public health. Furthermore, there is no human vaccine currently or any specific antiviral treatments against WNV.Among viral factors which are essential for flavivirus infection, the nonstructural glycoprotein NS1 is a multifunctional protein. The secreted form sNS1, is released in the extracellular medium from infected cells and is strongly involved in immune system dysregulation. The functions of sNS1 play roles in immune escape and, paradoxically, in pathogenesis which is observed in severe forms of the disease. Because most of this data are about Dengue Virus, we would like to study, in vitro, functional properties of the sNS1WNV during infection of epithelial, glial and neuronal mammalian cells. Based on the high sNS1 protein structure similarities among flaviviruses, our hypothesis suggests a role of sNS1WNV in neuroinvasive infections.The sNS1WNV protein doesn’t seem to modulate viral infection steps. However, it is involved in actin cytoskeleton remodeling in epithelial cells. sNS1WNV is also involved in the activation of antiviral response pathways in non-infected neuronal cells. On the other hand, by targeting sNS1 and envelope protein E of WNV, we performed a screening of aRep molecules (artificial proteins with alphahelicoïdal repeats) and isolated ligands with high affinity for these viral factors. Because this new type of molecules is able to specifically bind to sNS1 and E, they have potential to be used for the development of new diagnostic tools and antiviral therapeutic agents Arbovirus Flavivirus West Nile Protéine NS1 Pathogenèse Protéine E Criblage Molécules alphaRep Arbovirus Flavivirus West Nile Virus NS1 protein Pathogenesis E protein Screening AlphaRep molecules 579.2
64	Marqueurs d'exposition aux piqûres de moustiques du genre Culex et processus physiopathologiques d'infection au virus de West Nile / Markers of exposure to Culex mosquito bites and pathophysiological processes of West Nile virus infection Bakli, Mahfoud 25 November 2013 (has links) Le virus West Nile,WNV est responsable de milliers de cas de morbidité et de mortalité chez les oiseaux, les chevaux et l’homme. Le WNV se transmet par des moustiques du genre Culex. Les méthodes entomologiques ne permettent pas l’évaluation individuelle directe du contact hôte/vecteur. 5 protéines salivaires de Culex ont été sélectionnées, produites, et évaluées comme des candidats antigéniques de l'exposition aux piqûres de Culex. Des sérums humains du sud de France exposés à des densités de Culex distinctes et des sérums de chevaux exposés à l'infection par le WNV ont été testés. Une protéine 30kD est reconnue par les chevaux exposés à Culex. Cependant, pas de différence de réponse d’anticorps n’a été observée entre les animaux faiblement et fortement exposés. Concernant les processus physiopathologiques de la maladie causée par le WNV, la cinétique des profils d'expression de protéines de l’hôte dans le cerveau de souris infectées par le WNV, a été étudiée sur des échantillons prélevés avant et après l’apparition des signes cliniques, en utilisant 2D-DIGE et iTRAQ. 148 protéines différentiellement exprimées. Les voies de signalisation altérées au cours de l'infection précoce et tardive ont été identifiées. Les profils protéiques de LCR de patients atteints de WNND et des individus témoins ont été comparés, en utilisant l’approche iTRAQ. 47 protéines ont été trouvées différemment exprimées chez les patients WNND. Un candidat potentiel biomarqueur, la Defensine-alpha1, a été évalué par ELISA sur des échantillons humains de LCR/sérum. Les biomarqueurs putatifs identifiés dans cette étude peuvent être un outil précieux d’évaluation de la mesure de la gravité du WNV. / West Nile Virus,WNV is responsible for thousands of cases of morbidity and mortality in birds, horses and humans. WNV is transmitted mainly by mosquitoes by Culex species, to avian hosts. Entomological methods did not give direct individual evaluation of the host/vector contact. 5 salivary proteins from the Culex genus were selected for a production under recombinant forms for further evaluation as potential antigenic candidates of exposure to Culex bites. Sera from individuals living in south of France exposed to distinct Culex density and sera from horses exposed to WNV infection were tested. The recombinant protein30 kDa was recognized only by horses exposed to Culex. However, no difference of antibody response between low and high exposed to Culex. Concerning the pathophysiological processes of WNV disease, a kinetics host brain protein expression profiles of WNV-infected mice using samples collected prior and after clinical signs apparition was performed using proteomic approaches 2D-DIGE and iTRAQ. 148 distinct proteins was found altered following WNV infections. The functional signaling networks in samples collected during early and late infection have been identified. Un examination of CSF protein profiles between patients with neuroinvasive disease (WNND) and control individuals was performed using iTRAQ approach. 47 proteins were found differentially expressed in WNND patients compared to controls. A potential biomarker candidates, defensin-alpha1 was assessed by ELISA using other human paired CSF/serum samples. The putative biomarker identified in this study may potentially be a valuable tool in the assessment of the extent of WNV severity. Culex West Nile virus Biomarqueurs Protéines salivaires Réponse d’anticorps Processus physiopathologiques Culex West Nile virus Biomarkers Salivary protein Antibody response Pathophysiological processes
65	Identifying Comorbid Risk Factors of West Nile Neuroinvasive Disease in the Ontario Population, 2002-2012, Using Laboratory and Health Administrative Data Sutinen, Jessica 12 June 2020 (has links) Background/Objectives: West Nile neuroinvasive disease (WNND) is a severe neurological illness that develops in approximately 1% of individuals infected with West Nile virus (WNV). Manifesting most frequently as encephalitis (WNE), meningitis (WNM), or acute flaccid paralysis (WNP), there is no cure for WNND beyond supportive care and rehabilitation, and death or permanent disability are common outcomes. As the virus arrived in North America less than 20 years ago, determinants of severe disease progression following infection are still being explored. This project is the first to examine comorbid conditions as risk factors of WNND in Ontario using a population-based study design. As prevention is the only avenue of defence against WNND, identifying comorbid risk factors of WNND would allow for public health prevention campaigns targeted to high-risk groups. The main objectives of this thesis were to explore whether pre-existing chronic diseases were associated with the development of WNND, or any of its three manifestations (i.e., encephalitis, meningitis, acute flaccid paralysis). Methods: This was a retrospective, population-based study including all Ontario residents with a confirmed diagnosis of WNV infection between January 1, 2002 and December 31, 2012. A cohort of individuals with WNV was identified from a provincial laboratory database and individually-linked to health administrative databases. In the WNV cohort, individuals with WNND and 13 comorbid conditions were identified using algorithms based on ICD-10-CA diagnostic codes. Incidence of WNND following WNV infection was then compared among individuals with and without comorbid conditions using relative risks estimated by log binomial regression. Additionally, risk ratios were calculated for associations between specific comorbid conditions and WNND neuroinvasive manifestation (i.e., encephalitis, meningitis, acute flaccid paralysis). Finally, associations between Charlson Comorbidity Index (CCI) scoring and development of WNND was examined through calculation of relative risk using log binomial regression. Results/Potential Impact: Risk factors for WNND included male sex (aRR: 1.21; 95% CI: 1.00-1.46) in addition to the combined effect of hypertension and increasing age (5-year intervals) (aRR: 1.16; 95% CI: 1.08-1.24); WNND was also associated with increasing CCI scores; individuals in low, medium, and high categories had increased risk compared to individuals with a score of zero, but the greatest risk was in the high CCI category (aRR: 3.45; 95% CI: 2.25-4.83) Male sex (aRR: 1.32; 95% CI: 1.00-1.76), increasing age (aRR: 1.02; 95% CI: 1.02-1.03), and being immunocompromised (aRR: 2.61; 95% CI: 1.23-4.53) were associated with development of WNE. No risk factors were identified for WNM and WNP. Identification of comorbid risk factors of WNND will allow public health officials to identify high-risk groups and to develop prevention strategies targeted for vulnerable individuals. West Nile virus West Nile neuroinvasive disease Risk factor Comorbidity Chronic disease Ontario Health administrative data Encephalitis Meningitis Charlson Comorbidity Index
66	Primary and Secondary Immune Responses During Sequential West Nile Virus and Japanese Encephalitis Virus Infections: A Dissertation Trobaugh, Derek W. 14 February 2012 (has links) Japanese encephalitis virus (JEV) and West Nile virus (WNV) are closely related Flaviviruses that are important arthropod-borne human pathogens. Both of these viruses can cause encephalitis with significant morbidity and mortality after infection. Flaviviruses co-circulate in many areas of the world, which raises the risk for sequential infection between heterologous viruses. Sequential infection between dengue virus serotypes can lead to cross-protection, but in some cases, it leads to a severe outcome, dengue hemorrhagic fever. Previous work in hamsters and non-human primates demonstrated that prior JEV immunity protects against a lethal WNV infection. However, the ability of prior WNV immunity to protect against a lethal JEV infection has been inconclusive. WNV-immune hamsters were fully protected from JEV viremia, but in non-human primates, prior WNV-immunity only reduced disease severity, with symptoms of encephalitis still observed. These differences in cross-protection led to further investigation on the directionality as well as the underlying mechanisms for this phenomenon. Previous work in our lab found that JEV-immune C57BL/6J (B6) mice were fully protected against a lethal WNV infection, and JEV-immune CD4+ and CD8+ T cells were required for this cross-protection. In other mouse models, memory cross-reactive CD4+ and CD8+ T cell responses may induce protection or immunopathology upon secondary heterologous viral challenge. We hypothesize that JEV/WNV cross-reactive CD4+and CD8+ T cells preferentially expand upon 2o infection and contribute to cross-protection. To elucidate the potential role of T cells in sequential flavivirus infection, we identified and characterized cross-reactive CD4+ and CD8+ T cell responses between JEV and WNV. A previously reported WNV NS4b CD8+ T cell epitope and its JEV variant elicited CD8+ T cell responses in both JEV- and WNV-infected mice. Despite similarities in viral burden for pathogenic JEV and WNV viruses, CD8+ T cells from pathogenic JEV-infected mice exhibited functional and phenotypic profiles similar to those seen for the attenuated JEV strain. We believe the differences in the CD8+ T cell responses during primary JEV and WNV infection are due at least in part to the low levels of peripheral replication seen in JEV-infected mice compared to WNV-infected mice. We also found that WNV-immune B6 mice were protected against a lethal JEV infection. Cross-reactive CD8+ T cells in JEV-immune mice rapidly expanded after WNV infection. Even though WNV-immune mice had higher frequencies of memory CD8+ T cells, cross-reactive CD8+ T cells did not expand after secondary JEV infection. Neutralizing antibodies to JEV were detected in WNV-immune mice; however, cross-reactive CD8+ T cells did not expand even in the absence of these cross-reactive neutralizing antibodies. We did not detect any differences in the CD8+ T cell repertoires between JEV- and WNV-infected mice nor were WNV-immune CD8+ T cells functionally exhausted. In fact, proliferation of memory CD8+ T cells did not correlate with the ability of WNV-immune CD8+ T cells to restrict recombinant vaccinia viruses expressing the cross-reactive epitope or lyse peptide-coated targets. These data suggest that the higher frequency of memory CD8+ T cells and cross-reactive antibodies in WNV-immune mice are better able to prevent neuroinvasion following 2o JEV infection. Encephalitis Virus Japanese West Nile virus Encephalitis West Nile Fever Cross Protection CD8-Positive T-Lymphocytes Cells Hemic and Immune Systems Immunology and Infectious Disease Virology Virus Diseases Viruses
67	Equine innate and adaptive immunity to viral infections Zhang, Yuwen January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / Elizabeth G. Davis / Activation of innate immunity through Toll-like receptor (TLR) signaling can also enhance antigen-specific adaptive immunity. TLR9 is an endosomal receptor for unmethylated bacterial and viral cytosine-phosphate-guanine DNA (CpG-DNA). West Nile virus (WNV) infection may result in meningitis and encephalitis in humans and horses, especially aged and immunocompromised individuals. Using flow cytometric analyses and quantitative reverse transcriptase-polymerase chain reaction (RT-PCR), we investigated equine cell-mediated immunity (CMI) to an inactivated West Nile virus vaccine in healthy yearling and adult horses. We also studied the potential of enhancing equine adaptive immunity to viruses and other pathogens by activation of innate immunity though TLR9 signaling pathway. We found vaccination with inactivated WNV vaccine induced strong WNV-specific T helper type 1 (Th1) and Th2 CMI with a Th1 bias, also effectively induced WNV-specific CTLs in yearling horses. In adult horses, the pre-existing Th1 CMI bias against WNV was enhanced following booster vaccination with inactivated WNV vaccine. Molecular characterization and flow cytometric analysis of TLR9 expression using a cross-reactive TLR9 mAb identified high constitutive expression of equine TLR9 in neutrophils (PMNs), CD4[superscript]+ and CD8[superscript]+ T cells and other leukocytes. Conservation of equine TLR9 and a high expression profile among leukocytes suggests that equine TLR9 is a frequent target for unmethylated CpG-DNA, an essential mechanism for the activation of innate immunity. Unmethylated CpG-DNA can significantly activate equine PMNs. It also induces expression of interferon (IFN)-[Alpha], IFN-[Beta], IFN-[Gamma], and interleukin (IL)-12p35 in PBMCs, as well as IFN-[alpha] and IFN-[gamma] in monocyte-derived DCs. Enhanced expression of IFNs in immune cells by CpG-DNA is not only crucial for host viral clearance, but also important in mediating host immune responses due to IFNs' anti-inflammatory effects. Compared to the relatively weaker activation of equine innate immunity by inactivated WNV, the tested CpG-DNA species showed potential as vaccine adjuvants for enhancement of CTLs and Th1 CMI against intracellular pathogens, characterized by significant induction of type I IFNs and Th1-specific cytokines such as IL-12p35 and IFN-γ. These data provide a basis for further investigation of these CpG-DNA species as potentially effective vaccine adjuvants in horses. equine West Nile virus adaptive immunity innate immunity CpG-DNA interferon Health Sciences, Immunology (0982)
68	Characterizing putative cellular mediators of West Nile virus infections in bird and mosquito tissues Partridge, Alison 14 September 2015 (has links) West Nile virus (WNV) is a mosquito-borne virus that infects many bird species. Examination of American crows and house sparrows from the Winnipeg region confirmed that WNV levels were at least 1000 times higher in crows than sparrows. No species differences were observed in the level of transcripts encoding a putative WNV receptor, β3 integrin. Differences in mosquito vector competence can be due to differences in the ability of WNV to enter mosquito cells. Using RNAi techniques, the role of two clathrin coat adaptor proteins in facilitating WNV infections in mosquito cells was examined, and the findings suggest that these proteins may act as resistance factors in Aedes aegypti, and as susceptibility factors in Culex quinquefasciatus. These findings will contribute to our understanding of the molecular basis of vector competence in different mosquitoes, and may help us determine whether other species could serve as potential vectors of this health-threatening virus. / October 2015
69	Ecological profiling of bird-mosquito interactions in Central Virginia Riggan, Anna 18 July 2011 (has links) Current methods of mosquito surveillance estimate general population abundances, but fail to represent the relationship of vector abundance to host density important to determining transmission risk of mosquito-borne pathogens (MBP). We sought to address this limitation by creating a novel mosquito trap that directly sampled mosquitoes seeking to feed on nesting birds. The primary objectives of this study were to (1) assess the efficiency of the Nest Mosquito Trap (NMT) and how this is affected by nest box size. (2) assess whether the NMT affects bird, specifically nest success in Prothonotary Warblers (Protonotaria citrea), and adult behavior. (3) compare our novel trap to existing methods. (4) profile the ecological parameters associated with bird/ mosquito interactions. Our results allow us to conclude that the NMT is not only an effective means of capturing host-seeking mosquitoes and measuring mosquito/ bird interactions, but does not have a deleterious effect on avian nesting success. mosquito Nest Mosquito Trap bird West Nile virus Environmental Sciences Physical Sciences and Mathematics
70	A two host species stage-structured model of West Nile virus transmission Beebe, Taylor A 01 January 2016 (has links) We develop and evaluate a novel host-vector model of West Nile virus (WNV) transmission that incorporates multiple avian host species and host stage-structure (juvenile and adult stages), with both species-specific and stage-specific biting rates of vectors on hosts. We use this model to explore WNV transmission dynamics that occur between vectors and multiple structured host populations as a result of heterogeneous biting rates. Our analysis shows that increased exposure of juvenile hosts results in earlier, more intense WNV transmission when compared to the effects of differential host species exposure, regardless of other parameter values. We also find that, in addition to competence, increased juvenile exposure is an important mechanism for determining the effect of species diversity on the disease risk of a community. Vector-borne disease Host stage structure Heterogeneity Differential equation West Nile virus Applied Mathematics

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