Germany: Synthesis of Sulfonamides How Electrochemistry Opens Way for the Sustainable Production of Sulfonamides
Researchers at Mainz University developed a new procedure for the quick, cost-effective, and environmentally-friendly production of essential substances required by the pharmaceutical industry.
Mainz/Germany — A research team at Johannes Gutenberg University Mainz (JGU) has developed a completely new, environmentally-friendly electrochemical procedure for producing sulfonamides rapidly and inexpensively.
Sulfonamides are used in many drugs including antibiotics and Viagra as well as in agrochemicals and dyes, which makes them an important class of molecules for the pharmaceutical and chemical industries. While to date it has been necessary to use corrosive chemicals, high temperatures, and expensive metal catalysts to produce sulfonamides, the new method requires only cheaper starting materials, electrical current, and largely safe solvents. The researchers recently reported their findings in the journal Angewandte Chemie International Edition. “The conventional procedure requires three reaction stages, with each stage driving up manufacturing costs by a factor of two to five. With the new method, just one reaction stage is needed. That makes it readily scalable and it can thus be applied on a technical scale,” said Professor Siegfried Waldvogel, head of the research team and spokesperson for JGU's cutting-edge Susinno Science — Sustainable Chemistry as the Key to Innovation in Resource-efficient Science in the Anthropocene research initiative.
The starting materials for the new reaction are molecules in the substance classes amines and aromatics as well as the pollutant sulfur dioxide, which is a waste product of many industrial processes. In effect, the new method makes it possible to convert this unwanted material into valuable products: The amines react with the sulfur dioxide in solution, producing amidosulfinate as an intermediate product. This makes oxygen and sulfur available to react with the aromatic molecules that have already been oxidized using an electrical current. However, it is necessary to prevent the bond formation of the oxygen during this process. “We do this by using a suitable solvent — and that is the really clever bit,” Waldvogel pointed out. The solvent forms strong hydrogen bonds with the oxygen atoms, thereby rendering them inactive — and clearing the way for the formation of the desired sulfur-carbon bonds. After the reaction, the solvent can be redistilled and used again. “Our technique of electrochemical production of sulfonamides represents a completely new approach in chemistry that can now be applied to a number of other reactions. In a sense, we opened a door and found a variety of new possibilities,” concluded Waldvogel, who is one of the world's leading scientists working in the field of electrosynthesis.