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The role of population pharmacokinetic- pharmacodynamic modelling in antimalarial chemotherapySimpson, Julie Ann January 2001 (has links)
No description available.
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The basis for naphthoquinone and biguanide synergyJones, Karen January 2001 (has links)
No description available.
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Synthesis and evaluation of polyamines as antimalarial agentsSlater, Lindsay Anne January 1998 (has links)
No description available.
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Plasmodium falciparum : studies on the mechanism of chloroquine resistance and its reversalBray, Patrick Gerrard January 1992 (has links)
No description available.
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Quantifying the Quality of Antimalarial Drugs in GhanaBoakye-Agyeman, Felix 01 January 2017 (has links)
Malaria is still an epidemic in many parts of the world-about 220 million people are still infected with malaria worldwide and about 700 thousand people die from this disease per year. Most of the drugs used to treat malaria work well if they are used as required and they contain the right amounts of the active ingredient; however, it is estimated that more than 10% of drugs traded worldwide are counterfeits including 38% to 53% of antimalarial tablets produced in China and India. Due to the lack of data covering the extent of counterfeit antimalarial drugs in Ghana, the purpose of this quantitative study was to determine the percentage of counterfeit antimalarial drugs sold in Ghana by assessing the amounts of the 2 most common antimalarial drugs, artemether (ATMT) and lumefantrine (LMFT) in drugs sold in Ghana retail outlets. These drugs were purchased from retail outlets in Ghana and analyses at the Mayo Clinic Pharmacology core lab (Rochester, MN). The quality of the drugs were characterized by comparing the actual amount of ATMT & LMFT in each tablet to the expected amount. Using explanatory theory along with dose response-response occupancy theory, the researcher addressed quantitative solutions to questions related to the percentage and distribution of counterfeit ATMT and LMFT tablets. The results revealed that overall 20% of the drugs are counterfeit; this is not dependent on the location or kind of outlet but rather depends on whether the tablets were imported or locally manufactured and whether the tablets had a pedigree scratch panel. This study provides a better understanding of how much antimalarial medication is counterfeit in Ghana, which will aid interventions to minimize the adverse effects of counterfeit antimalarial medication in Ghana
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Automated structural annotation of the malaria proteome and identification of candidate proteins for modelling and crystallization studiesJoubert, Yolandi 29 July 2008 (has links)
Malaria is the cause of over one million deaths per year, primarily in African children. The parasite responsible for the most virulent form of malaria, is Plasmodium falciparum. Protein structure plays a pivotal role in elucidating mechanisms of parasite functioning and resistance to anti-malarial drugs. Protein structure furthermore aids the determination of protein function, which can together with the structure be used to identify novel drug targets in the parasite. However, various structural features in P. falciparum proteins complicate the experimental determination of protein three dimensional structures. Furthermore, the presence of parasite-specific inserts results in reduced similarity of these proteins to orthologous proteins with experimentally determined structures. The lack of solved structures in the malaria parasite, together with limited similarities to proteins in the Protein Data Bank, necessitate genome-scale structural annotation of P. falciparum proteins. Additionally, the annotation of a range of structural features facilitates the identification of suitable targets for structural studies. An integrated structural annotation system was constructed and applied to all the predicted proteins in P. falciparum, Plasmodium vivax and Plasmodium yoelii. Similarity searches against the PDB, Pfam, Superfamily, PROSITE and PRINTS were included. In addition, the following predictions were made for the P. falciparum proteins: secondary structure, transmembrane helices, protein disorder, low complexity, coiled-coils and small molecule interactions. P. falciparum protein-protein interactions and proteins exported to the RBC were annotated from literature. Finally, a selection of proteins were threaded through a library of SCOP folds. All the results are stored in a relational PostgreSQL database and can be viewed through a web interface (http://deepthought.bi.up.ac.za:8080/Annotation). In order to select groups of proteins which fulfill certain criteria with regard to structural and functional features, a query tool was constructed. Using this tool, criteria regarding the presence or absence of all the predicted features can be specified. Analysis of the results obtained revealed that P. falciparum protein-interacting proteins contain a higher percentage of predicted disordered residues than non-interacting proteins. Proteins interacting with 10 or more proteins have a disordered content concentrated in the range of 60-100%, while the disorder distribution for proteins having only one interacting partner, was more evenly spread. Comparisons of structural and sequence features between the three species, revealed that P. falciparum proteins tend to be longer and vary more in length than the other two species. P. falciparum proteins also contained more predicted low complexity and disorder content than proteins from P. yoelii and P. vivax. P. falciparumprotein targets for experimental structure determination, comparative modeling and in silico docking studies were putatively identified based on structural features. For experimental structure determination, 178 targets were identi_ed. These targets contain limited contents of predicted transmembrane helix, disorder, coiled-coils, low complexity and signal peptide, as these features may complicate steps in the experimental structure determination procedure. In addition, the targets display low similarity to proteins in the PDB. Comparisons of the targets to proteins with crystal structures, revealed that the structures and predicted targets had similar sequence properties and predicted structural features. A group of 373 proteins which displayed high levels of similarity to proteins in the PDB, were identified as targets for comparitive modeling studies. Finally, 197 targets for in silico docking were identified based on predicted small molecule interactions and the availability of a 3D structure. / Dissertation (MSc)--University of Pretoria, 2008. / Biochemistry / unrestricted
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Assessment of prescribing patterns and availability of anti-malarial drugs to children under five years of age in a rural district in KenyaAdhiambo, Oreje Joy Susan January 2013 (has links)
Magister Public Health - MPH / Aim: The aim of this study was to assess the prescribing practices and availability of antimalarial
drugs to children under five years of age in primary health care facilities in Bondo
district.
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Unique Features Of Heme-Biosynthetic Pathway In The Human Malaria Parasite, Plasmodium FalciparumArun Nagaraj, V 07 1900 (has links)
Malaria is a life-threatening vector borne infectious disease caused by protozoan parasites of the genus Plasmodium. More than 100 species of Plasmodium can infect numerous animal species such as reptiles, birds and various mammals. However, human malaria is caused by four Plasmodium species -Plasmodium falciparum, Plasmodium vivax, Plasmodium ovale and Plasmodium malariae, and occasionally by the simian malaria parasite, Plasmodium knowlesi. Of these, P. falciparum and P. vivax are the major causative agents and P. falciparum is the most virulent. About 300-500 million malaria infections occur every year leading to over 1-2 million deaths, of which 75% occur in African children of less than 5 years infected with P. falciparum. In spite of major global efforts to eliminate this disease over the past few decades, it continues to persist as a major affliction of human-kind imposing serious health and economic burden, especially to the poor countries. In India, the present scenario is about 2 million malaria positive cases every year, with almost 50% being caused by P. falciparum.
Although remarkable attempts have been made over the years to develop vaccines against sexual and asexual stages of malaria parasite, an effective vaccine is still not in sight and remains as a distant goal. Hence, highly potent, less toxic and affordable antimalarial drugs remain as a first line therapy for malaria. Unfortunately, these parasites have been evolving against every known antimalarial drug and many of these drugs have lost their potency due to rapid emergence and spread of drug resistant strains. With development of resistance against frontline antimalarials such as chloroquine and antifolates, artemisinin and its derivatives seem to be the only effective antimalarials. However, recent reports on the possible emergence of artemisinin resistant strains, have led to the implementation of artemisinin-based combination therapies as a strategy to prevent drug resistance. Also, this continuous emergence of drug resistance has necessitated the development of new antimalarial drugs to combat this disease. While, Anopheles mosquitoes transmit parasites that infect humans, monkeys and rodents, Culex and Aedes mosquitoes predominate in the natural transmission to birds, and vectors of reptilian parasites are largely unknown. Of the approximately 400 species of Anopheles throughout the world, about 60 are malaria vectors under natural conditions, and 30 of which are of major importance. Ironically, the strategies implemented for controlling Anopheles, have also been hampered by insecticide resistance and other practical difficulties that exist in the scope of their applicability.
In the past few years several milestones have been achieved in parasite genome, transcriptome and proteome studies, which could be exploited for the development of new drugs and drug targets. One such promising target includes the metabolic pathways of the malaria parasite which differ significantly from its human host. This thesis entitled “Unique Features of the Heme-Biosynthetic Pathway in Human Malaria Parasite, Plasmodium falciparum” unravels the unique biochemical features of heme-biosynthetic enzymes of P. falciparum, which have the potential for being drug targets. This pathway was first identified in this laboratory over 15 years ago. In the present study, five of the 7 enzymes of this pathway have been cloned, expressed, properties studied and sites of localization identified. With the knowledge on the first two enzymes coming from earlier studies, it is now possible to depict the unique hybrid pathway for heme biosynthesis in
P. falciparum with full experimental validation.
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Computational And Biochemical Studies On The Enzymes Of Type II Fatty Acid Biosynthesis Pathway : Towards Antimalarial And Antibacterial Drug DiscoveryKumar, Gyanendra 02 1900 (has links)
Malaria, caused by the parasite Plasmodium, continues to exact high global morbidity and mortality rate next only to tuberculosis. It causes 300-500 million clinical infections out of which more than a million people succumb to death annually. Worst affected are the children below 5 years of age in sub-Saharan Africa. Plasmodium is a protozoan parasite classified under the phylum Apicomplexa that also includes parasites such as Toxoplasma, Lankestrella, Eimeria and Cryptosporidium. Of the four species of Plasmodium affecting man viz., P. falciparum, P. vivax, P. ovale and P. malariae, Plasmodium falciparum is the deadliest as it causes cerebral malaria. The situation has worsened recently with the emergence of drug resistance in the parasite. Therefore, deciphering new pathways in the parasite for developing lead antimalarial compounds is the need of the hour. The discovery of the type II fatty acid biosynthesis pathway in Plasmodium falciparum has opened up new avenues for the design of new antimalarials as this pathway is different from the one in human hosts. Although many biochemical pathways such as the purine, pyrimidine and carbohydrate metabolic pathways, and the phospholipid, folate and heme biosynthetic pathways operate in the malaria parasite and are being investigated for their amenability as antimalarial therapeutic targets, no antimalarial of commercial use based on the direct intervention of these biochemical pathways has emerged so far. This is due to the fact that the structure and function of the targets of these drugs overlaps with that of the human host.
A description of the parasite, its metabolic pathways, efforts to use these pathways for antimalarial drug discovery, inhibitors targeting these pathways, introduction to fatty acid biosynthesis pathway, discovery of type II fatty acid biosynthesis pathway in Plasmodium falciparum and prospects of developing lead compounds towards antimalarial drug discovery is given in Chapter 1 of the thesis.
In the exploration of newly discovered type II fatty acid biosynthesis pathway of P. falciparum as a drug target for antimalarial drug discovery, one of the enzymes; β-hydroxyacyl- acyl carrier protein dehydratase (PfFabZ) was cloned and being characterized in the lab. The atomic structure of PfFabZ was not known till that point of time. Chapter 2 describes the homology modeled structure of PfFabZ and docking of the discovered inhibitors with this structure to provide a rationale for their inhibitory activity. Despite low sequence identity of ~ 21% with the closest available atomic structure then, E. coli FabA, a good model of PfFabZ could be built. A comparison of the modeled structure with recently determined crystal structure of PfFabZ is provided and design of new potential inhibitors is described. This study provides insights to further improve the inhibition of this enzyme.
Enoyl acyl carrier protein reductase (ENR) is the most important enzyme in the type II fatty acid biosynthesis pathway. It has been proved as an important target for antibacterial as well as antimalarial drug discovery. The most effective drug against tuberculosis – Isoniazid targets this enzyme in M. tuberculosis. The well known antibacterial compound – Triclosan, a diphenyl ether, also targets this enzyme in P. falciparum. I designed a number of novel diphenyl ether compounds. Some of these compounds could be synthesized in the laboratory. Chapter 3 describes the design, docking studies and inhibitory activity of these novel diphenyl ether compounds against PfENR and E. coli ENR. Some of these compounds inhibit PfENR in nanomolar concentrations and EcENR in low micromolar concentrations, and many of them inhibit the growth of parasites in culture also. The structure activity relationship of these compounds is discussed that provides important insights into the activity of this class of compounds which is a step towards developing this class of compounds into an antimalarial and antibacterial candidate drugs.
Components of the green tea extract and polyphenols are well known for their medicinal properties since ages. Recently they have been shown to inhibit components of the bacterial fatty acid biosynthesis pathway. Some selected tea catechins and polyphenols were tested in the laboratory for their inhibitory activity against PfENR. I conducted docking studies to find their probable binding sites in PfENR. On kinetic analysis of their inhibition, these compounds were found to be competitive with respect to the cofactor NADH. This has an implication that they could potentiate inhibition of PfENR by Triclosan in a fashion similar to that of NADH. As a model case, one of the tea catechins; EGCG ((-) Epigalocatechin gallate) was tested for this property. Indeed, in the presence of EGCG, the inhibition of PfENR improved from nanomolar to picomolar concentration of Triclosan.conducted molecular modeling studies and propose a model for the formation of a ternary complex consisting of EGCG, Triclosan and PfENR. Docking studies of these inhibitors and a model for the ternary complex is described in Chapter 4. Docking simulations show that these compounds indeed occupy NADH binding site. This study provides insights for further improvements in the usage of diphenyl ethers in conjugation or combination with tea catechins as possible antimalarial therapeutics.
In search for new lead compounds against deadly diseases, in silico virtual screening and high throughput screening strategies are being adopted worldwide. While virtual screening needs a large amount of computation time and hardware, high throughput screening proves to be quite expensive. I adopted an intermediate approach, a combination of both these strategies and discovered compounds with a 2-thioxothiazolidin-4-one core moiety, commonly known as rhodanines as a novel class of inhibitors of PfENR with antimalarial properties. Chapter 5 describes the discovery of this class of compounds as inhibitors of PfENR. A small but diverse set of 382 compounds from a library of ~2,00,000 compounds was chosen for high throughput screening. The best compound gave an IC50 of 6.0 µM with many more in the higher micromolar range. The compound library was searched again for the compounds similar in structure with this best compound, virtual screening was conducted and 32 new compounds with better binding energies compared to the first lead and reasonable binding modes were tested. As a result, a new compound with an IC50 of 240 nM was discovered. Many more compounds gave IC50 values in 3-15 µM range. The best inhibitor was tested in red blood cell cultures of Plasmodium, it was found to inhibit the growth of the malaria parasite at an IC50 value of 0.75 µM. This study provides a new scaffold and lead compounds for further exploration towards antimalarial drug discovery.
The summary of the results and conclusions of studies described in various chapters is given in Chapter 6. This chapter concludes the work described in the thesis.
Cloning, over-expression and purification of PanD from M. tuberculosis, FabA and FabZ from E. coli are described in the Appendix.
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