News Release

Chemists use electrochemistry to amp up drug manufacturing

Peer-Reviewed Publication

Cornell University

Song Lin, Cornell University

image: Song Lin, assistant professor of chemistry at Cornell University. Lin and his team have developed a technique that creates vicinal diamines more easily and without the toxic waste. view more 

Credit: Cornell University

ITHACA, N.Y. - Give your medicine a jolt. By using electrochemistry, future pharmaceuticals – including many of the top prescribed medications in the United States – soon may be easily scaled up to be manufactured in a more sustainable way.

Currently, making pharmaceuticals involves creating complex organic molecules that require several chemical steps and intense energy. The process also spawns copious amounts of environmentally harmful - and usually toxic - waste.

At the heart of many popular pharmaceuticals are vicinal diamines, which contain carbon-nitrogen chemical bonds, a bioactive foundation for the medicine. According to Song Lin, assistant professor of chemistry, many widely consumed therapeutic agents have these diamines, including prescription-strength flu medicines, penicillin and some anti-cancer drugs.

Lin and his team have developed a technique that creates vicinal diamines more easily and without the toxic waste. The process uses electricity and chemistry - electrochemistry - and then employs Earth-abundant manganese.

"The current process generates a lot of waste product to make this chemical bond. When you can create a product electrosynthetically, rather than chemically, it is much more straightforward and sustainable," Lin said.

In addition to Lin as a senior author, "Metal-catalyzed Electrochemical Diazidation of Alkenes" was written by lead author postdoctoral researcher Niankai Fu, graduate student Greg Sauer; Ambarneil Saha and Aaron Loo. Cornell laboratory startup money funded this research, and the National Science Foundation provides funding to Sauer.

###


Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.