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Malaria in the Amazon: An Agent-Based Approach to Epidemiological Modeling of Coupled SystemsKing, Joshua Michael Lloyd 17 August 2009 (has links)
The epidemiology of malaria considers a complex set of local interactions amongst host, vector, and environment. A history of reemergence, epidemic transition, and ensuing endemic transmission in Iquitos, Peru reveals an interesting case used to model and explore such interactions. In this region of the Peruvian Amazon, climate change, development initiatives and landscape fragmentation are amongst a unique set of local spatial variables underlying the endemicity of malaria. Traditional population-based approaches lack the ability to resolve the spatial influences of these variables. Presented is a framework for spatially explicit, agent-based modeling of malaria transmission dynamics in Iquitos and surrounding areas. The use of an agent-based model presents a new opportunity to spatially define causal factors and influences of transmission between mosquito vectors and human hosts. In addition to spatial considerations, the ability to model individual decisions of humans can define socio-economic and human-environment interactions related to malaria transmission. Three interacting sub-models representing human decisions, vector dynamics, and environmental factors comprise the model. Feedbacks between the interacting sub-models define individual decisions and ultimately the flexibility that will allow the model to function in a diagnostic capacity. Sensitivity analysis and simulated interactions are used to discuss this diagnostic capability and to build understanding of the physical systems driving local transmission of malaria.
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Detection of mutations in dihydropteroate synthase (dhps) and dihydrofolate reductase (dhfr) in Plasmodium falciparum in eastern SudanMariam, Nakintu January 2011 (has links)
No description available.
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Malaria in the Amazon: An Agent-Based Approach to Epidemiological Modeling of Coupled SystemsKing, Joshua Michael Lloyd 17 August 2009 (has links)
The epidemiology of malaria considers a complex set of local interactions amongst host, vector, and environment. A history of reemergence, epidemic transition, and ensuing endemic transmission in Iquitos, Peru reveals an interesting case used to model and explore such interactions. In this region of the Peruvian Amazon, climate change, development initiatives and landscape fragmentation are amongst a unique set of local spatial variables underlying the endemicity of malaria. Traditional population-based approaches lack the ability to resolve the spatial influences of these variables. Presented is a framework for spatially explicit, agent-based modeling of malaria transmission dynamics in Iquitos and surrounding areas. The use of an agent-based model presents a new opportunity to spatially define causal factors and influences of transmission between mosquito vectors and human hosts. In addition to spatial considerations, the ability to model individual decisions of humans can define socio-economic and human-environment interactions related to malaria transmission. Three interacting sub-models representing human decisions, vector dynamics, and environmental factors comprise the model. Feedbacks between the interacting sub-models define individual decisions and ultimately the flexibility that will allow the model to function in a diagnostic capacity. Sensitivity analysis and simulated interactions are used to discuss this diagnostic capability and to build understanding of the physical systems driving local transmission of malaria.
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Structure, function, and inhibition of enoyl reductasesKuo, Mack Ryan 15 May 2009 (has links)
Malaria and tuberculosis constitute two of the world’s deadliest infectious diseases.
Together, they afflict over one third of the world’s population. Once thought of
as one of a group of nearly vanquished diseases only 50 years ago, malaria and tuberculosis
have experienced renewed prominence due to issues such as multi-drug
resistance and a lack of responsiveness by the global community. Fatty acid biosynthesis
has been shown to be an essential pathway to the causative organisms of
malaria and tuberculosis. One integral component of the fatty acid biosynthesis
pathway, enoyl acyl-carrier-protein (ACP) reductase, has repeatedly been validated
as an appropriate drug target in other organisms. The 2.4 Å crystal structure of
the enoyl-ACP reductase from the human parasite Plasmodium falciparum (PfENR)
reveals a nucleotide-binding Rossmann fold, as well as the identity of several active
site residues important for catalysis. The 2.43 Å crystal structure of PfENR bound
with triclosan, a widely utilized anti-bacterial compound, provides new information
concerning key elements of inhibitor binding. Applying knowledge attained from
these initial crystal structures, several triclosan derivatives were synthesized, and
subsequently PfENR:inhibitor co-crystal structures were determined to extend our
knowledge of protein:inhibitor interactions within the active site. Additionally, the
crystal structures of the enoyl-ACP reductase from the mouse parasite Plasmodium
berghei (PbENR), in apo-form and in complex with triclosan, were refined to 2.9 Å and 2.5 Å resolution, respectively. These structures confirm the structural and active
site conservation between the human and mouse parasite enoyl-ACP reductases,
suggesting that utilizing a murine model for in vivo testing of promising inhibitors is
viable. The 2.6 Å crystal structure of the enoyl-ACP reductase from Mycobacterium
tuberculosis (InhA) in complex with triclosan reveals a novel configuration of triclosan
binding, where two molecules of triclosan are accommodated within the InhA active
site. Finally, high-throughput screening approaches using enoyl acyl-carrier-protein
reductases as the targets were utilized to identify new lead compounds for future
generations of drugs. The 2.7 Å crystal structure of InhA bound with Genz-10850
confirms the value of this technique.
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Structural determination of triclosan derivatives as inhibitors of Plasmodium falciparum enoyl reductase (PfENR)Lucumi Moreno, Edinson 25 April 2007 (has links)
Malaria is a disease that causes more than 1 million deaths per year world wide
and more than 400 million clinical cases. Due to the acquired resistance of Plasmodium
falciparum to the drugs used to control the infection, searching for new anti-malaria
drugs is necessary in modern days. Recent studies have shown that the parasite
synthesizes fatty acids using a fatty acid synthase type II (FAS-II) instead of a type-I fatty
acid synthase (FAS-I) that is present in other eukaryotes. Plasmodium falciparum enoyl
reductase (PfENR) is responsible for the last step of fatty acid biosynthesis in the
parasite. This enzyme is located within the apicoplast, a plastid-like organelle that is
responsible for several important metabolic pathways, including fatty acid biosynthesis. It
is known that triclosan is an inhibitor of ENR in bacteria and we and others have shown
that it is also effective against ENR in apicomplexan organisms such as P. falciparum.
However triclosan cannot be used to treat malaria in humans because it has metabolic
liability (glucoronidation) which limits its inhibitory potency. We have used X-ray crystallography and a Structural Activity Relationship (SAR) strategy to design and cocrystallize
a tertiary complex of PfENR with NAD+ and triclosan derivatives to improve
their properties as drugs to treat malaria. More than five hundred triclosan derivatives
were synthesized, and their in vitro and in vivo inhibitory activity evaluated. Furthermore,
structural studies were made of their affinity to interact with residues in PfENR active
sites, as well as with the cofactor NAD+. A total of six PfENR-NAD+-triclosan
analog/complexes structures were determined. Analogs which had replacements of
chloride groups at position 5 of ring A and 4' of ring B were determined, allowing the
structural analysis of the binding of these triclosan analogs to PfENR. In addition, the
urea derivatives (modification at position 1) as well as phenylsulphonamides
(modification at position 2') have shown to be more potent inhibitors than triclosan in the
in vivo assay. The analysis of the inhibitory properties and the structure of these analogs
bound to PfENR will provide novel compounds in the search for new anti-malarial drugs.
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Genotipia de Plasmodium vivax y su importancia en el manejo y control de la malaria de la amazonía peruanaCalderón Sánchez, Maritza Mercedes January 2006 (has links)
Los genotipos de Plasmodium vivax, junto con la densidad parasitaria pueden estar relacionados al grado de severidad de la malaria. El conocimiento de esta relación puede ayudar a un mejor manejo de la enfermedad, tratamiento con drogas y elaboración de posibles vacunas. El objetivo del trabajo fue determinar el número de genotipos de Plasmodium vivax presentes en la Amazonía Peruana. Para la genotipificación se usó el gen que codifica la proteína de superficie del merozoito (MSP3 alfa) y el polimorfismo generado por secuencias repetitivas de nucleótidos (TR) encontrado en un segmento de 100 Kilobases (Kb) de Plamodium vivax “sinténico” al cromosoma 3 de Plasmodium falciparum. Se trabajó con 302 muestras de sangre de pacientes, a todas ellas se les realizó el examen de la gota gruesa y frotis para el diagnóstico y conocimiento de la densidad parasitaria, dicho diagnóstico fue confirmado por Nested PCR. A las muestras confirmadas se les realizó la genotipificación. Con el marcador MSP3 alfa se identificaron 9 genotipos, de los cuales uno de ellos se encontró asociado a severidad de la enfermedad (P7) (P<0.05, OR>1), y otro relacionado con infecciones mixtas (P9), 1/9 (11%). Para los TR se seleccionaron 9 pares de “primers” de un total de 33. Encontrándose 102 genotipos diferentes de los cuales 24/102 (24%) fueron infecciones por genotipos mixtos. El hecho que exista una inserción en el tamaño de su ADN originalmente reportado, aumenta la posibilidad que se dé la enfermedad en forma más severa. Estos resultados indicarían que poblaciones de Plasmodium vivax son altamente diversos y que infecciones por múltiples clonas se darían en la región hipoendémica de la Amazonía Peruana, las cuales podrían representar un desafío para evaluación posterior de drogas y vacunas. / Genotypes of Plasmodium vivax along with parasite density may be associated with the severity level of malaria, and knowledge of this relation can help to better understand the disease, drug treatments and the development of new vaccines. The object of this project was to determine the number of Plasmodium vivax genotypes present in the Peruvian Amazon. This genotyping utilized the gene encoding a merozoite surface protein (MSP3 alpha) and the polymorphism generated by a sequence of nucleotide repeats (TR) found in a 100 kilobases (Kb) de Plasmodium vivax syntenic chromosome 3 of Plasmodium falciparum. In this project we used 302 blood samples from patients. A blood droplet and droplet smear were obtained for the diagnostic and observation of parasite density; these results were later confirmed through Nested PCR. All samples were submitted for genotyping. Using the marker MSP3 alpha, 9 genotypes were identified, one was found associated with disease severity (P7) (P<0.05, OR>1) and other with mixed infections (P9) 1/9 (11%). For the TR, 9 pairs of primers were selected from a pool of 33 describing 102 different genotypes of which 24 (24 %) were mixed infections. Observation supported by the existence of a DNA insertion that increases the original size of the sequence, increasing the possibility that the disease become more severe. These results would indicate that populations of Plasmodium vivax are highly diverse and can result in multiple infections by different clones in hypoendemic regions such as the Peruvian Amazon, making later evaluation of drugs and vaccines more challenging.
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Functional and structural characterization of the unique bifunctional enzyme complex involved in regulation of polyamine metabolism in Plasmodium falciparumBirkholtz, Lyn-Marie. January 2005 (has links)
Thesis (Ph.D.)(Biochemistry)--University of Pretoria, 2002. / Includes bibliographical references.
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Data based abnormality detectionPurwar, Yashasvi Unknown Date
No description available.
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A Study on Presumptive Diagnosis and Home Management of Childhood Malaria among Nomadic Fulani in Demsa, Nigeria.Akogun, Oladele B. January 2008 (has links)
<p>The broad aim of the study is to understand the process and identify the factors associated with presumptive diagnosis and home management of childhood malaria among nomadic Fulani in Demsa, Adamawa State of Nigeria during the immediate past malaria season.</p>
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Knowledge and practices of patent medicine vendors in the use of artemisinin based combination therapy in the treatment of malaria in an urban community in Lagos.Momodu, Rametu Omamegbe. January 2008 (has links)
<p>Malaria is a health, social and economic burden in Nigeria and consistently ranks amongst the four most common causes of childhood deaths. Treatment of malaria is usually started at home / care is only sought from the health facility when the treatment is ineffective (McCombie, 1996). Patent medicine vendors (PMVs) have been identified as a widely patronized source for drugs used in the home treatment of malaria (Breiger et al, 2001 / Goodman, et al, 2007 / Salako et al, 2001). Inadequate or poor knowledge and practices in the use of anti-malaria drugs (AMDs) increases morbidity and mortality, undermines therapeutic efficacy, and promotes the emergence and spread of drugresistant malaria. Aim: The aim of the study was to describe and quantify the knowledge and self-reported practices of PMVs in the use of antimalarials, particularly artemisinin-based combination therapies (ACTs), in a poor urban community in Lagos state, Nigeria.</p>
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