Fighting malariaLess costly anti-malarial drug
Malaria sickens 300-500 million people, and kills more than one million, annually; scientists are reporting development of a new, higher-yield, two-step, less costly process that may ease supply problems and zigzagging prices for the raw material essential for making the mainstay drug for malaria
Scientists are reporting development of a new, higher-yield, two-step, less costly process that may ease supply problems and zigzagging prices for the raw material essential for making the mainstay drug for malaria. That disease sickens 300-500 million people annually and kills more than one million. The report on the process, which uses readily available substances and could be easily implemented by drug companies, appears in ACS’ journal Organic Process Research & Development.
An American Chemical Society release reports that David Teager and Rodger Stringham of the Clinton Health Access Initiative explain that artemisinin combination therapy (ACT) is the most effective treatment for malaria, a parasitic infection that is transferred to humans from the bite of an infected mosquito. Artemisinin, which is used to produce the key ingredient in ACT, comes from Artemisia annua, a medicinal plant grown in China. In recent years, the price for artemisinin has undergone huge market fluctuations, ranging from about $180 to $410 per pound, due to weather conditions and the demand for ACT. Keeping costs down is important because most cases of malaria occur in developing areas in the tropics and subtropics.
The release notes that the researchers reasoned that one way to help stabilize prices would be to improve the current ACT manufacturing process, which consistently yields less of the ingredient than expected. That improvement would reduce the amount of Artemisia annua needed to make ACT.
The new process is much simpler and generates less potentially hazardous waste than the current method. It also reduced the amount of artemisinin required to make ACT, which makes the process less costly. A “semisynthetic” version of artemisinin also worked well as a starting material in the new method. “We are in the process of sharing this procedure with manufacturing partners in our global fight to combat malaria,” say the researchers.
— Read more in Rodger W. Stringham and David S. Teager, “Streamlined Process for the Conversion of Artemisinin to Artemether,” Organic Process Research & Development 16, no. 5 (7 April 2012): 764–68 (DOI: 10.1021/op300037e)