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Malaria continues to be a major global health problem and seems to be increasing in some parts of the world. By way of an introduction, relevant aspects of the disease, including incidence and resistance, and of the parasite and its biochemistry and genetics are presented. The chemotherapeutic agents now available to prevent and treat malaria are discussed individually. Some of these drugs have been in use for decades or even centuries, such as quinine, chloroquine, and primaquine. Other agents are of more recent origin including mefloquine, halofantrine, atovaquone, and the artemisinins. Chloroquine had been the drug of first resort for many years. It is inexpensive, well‐tolerated, and extremely effective where parasites remain sensitive. But the development of resistance to chloroquine has emphasized the need for new agents and strategies to treat malaria. New information on the genetic basis of chloroquine resistance and on the overall mechanism of action of chloroquine holds promise for advances in therapy. Another important tactic in dealing with infection by resistant parasites is the use of drug combinations. The combination of pyrimethamine and sulfadoxine has been very successful, but resistance is developing. Newer, highly effective combinations include atovaquone with proguanil, lumefantrine with artemether, and chlorproguanil with dapsone. The artemisinin group of compounds has made a powerful positive impact on malaria chemotherapy although their use in monotherapy is not recommended. Details of the mechanism of action of these drugs are becoming clearer. Knowledge about action should assist in addressing issues of possible toxicity. Great progress has been made in sequencing the genome of Plasmodium falciparum . New molecular targets have been identified as a result and efforts are underway to develop antimalarial agents based on these targets. Researchers around the world are also exploring natural products for yet another lead in antimalarial chemotherapy. “If we take as our standard of importance the greatest harm to the greatest number, then there is no question that malaria is the most important of all infectious diseases 1 .” “Ah, poor heart! he is so shaked of a burning quotidian tertian, that it is most lamentable to behold [2].”
Malaria continues to be a major global health problem and seems to be increasing in some parts of the world. By way of an introduction, relevant aspects of the disease, including incidence and resistance, and of the parasite and its biochemistry and genetics are presented. The chemotherapeutic agents now available to prevent and treat malaria are discussed individually. Some of these drugs have been in use for decades or even centuries, such as quinine, chloroquine, and primaquine. Other agents are of more recent origin including mefloquine, halofantrine, atovaquone, and the artemisinins. Chloroquine had been the drug of first resort for many years. It is inexpensive, well‐tolerated, and extremely effective where parasites remain sensitive. But the development of resistance to chloroquine has emphasized the need for new agents and strategies to treat malaria. New information on the genetic basis of chloroquine resistance and on the overall mechanism of action of chloroquine holds promise for advances in therapy. Another important tactic in dealing with infection by resistant parasites is the use of drug combinations. The combination of pyrimethamine and sulfadoxine has been very successful, but resistance is developing. Newer, highly effective combinations include atovaquone with proguanil, lumefantrine with artemether, and chlorproguanil with dapsone. The artemisinin group of compounds has made a powerful positive impact on malaria chemotherapy although their use in monotherapy is not recommended. Details of the mechanism of action of these drugs are becoming clearer. Knowledge about action should assist in addressing issues of possible toxicity. Great progress has been made in sequencing the genome of Plasmodium falciparum . New molecular targets have been identified as a result and efforts are underway to develop antimalarial agents based on these targets. Researchers around the world are also exploring natural products for yet another lead in antimalarial chemotherapy. “If we take as our standard of importance the greatest harm to the greatest number, then there is no question that malaria is the most important of all infectious diseases 1 .” “Ah, poor heart! he is so shaked of a burning quotidian tertian, that it is most lamentable to behold [2].”
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