A research team led by Prof. Sun Jianwei has achieved an advancement in organic synthesis and medicinal chemistry by developing an air-stable chiral phosphine-catalyzed enantioselective approach to synthesize enantioenriched S(IV)-stereogenic vinyl sulfinamides—an under-explored class of organosulfur compounds with promising antiviral activity.

The importance of chiral-at-sulfur compounds in drug discovery and organic synthesis is indisputable. More than a quarter of top-selling small molecule pharmaceuticals contain sulfur atoms, and chiral sulfinamides bearing S(IV) chirality are key building blocks for medicinal chemistry, asymmetric synthesis auxiliaries, and catalytic ligands. However, current methods to access enantioenriched sulfinamides rely on transition metal catalysis with organometallic nucleophiles, and efficient organocatalytic strategies have long remained unexplored, creating a critical gap in synthetic chemistry for this valuable chemical space.

To address this challenge, Prof. Sun’s team published a study in Nature Chemistry detailing the design and synthesis of a novel C₂-symmetric chiral phosphine catalyst—QianPhos—derived from the SPHENOL chiral skeleton. This custom catalyst exhibits extraordinary air stability and structural rigidity, which enables highly chemo-, enantio-, and diastereoselective C−S bond formation via a [3+2] annulation between Morita–Baylis–Hillman (MBH) esters and sulfinylamines.

Researchers at the University of Bath have discovered a renewable, bio-based polymer membrane capable of efficiently capturing toxic “forever chemicals” from water, offering a potential new route to more sustainable water treatment. The paper is published in the journal ACS Applied Materials & Interfaces.

Perfluorooctanoic acid (PFOA), a member of the per-and polyfluoroalkyl substances (PFAS) family and once commonly used in non-stick coatings, has now been widely detected in water sources worldwide. High levels of exposure have been linked to cancers, hormone disruption, and immune system suppression, with governments around the world taking action to protect people and the environment.

Unlike many conventional water treatment materials that require frequent replacement or generate secondary waste, the new bio-based membrane can trap and hold over 94% of PFOA from water. It can later be treated with heat to remove the trapped pollutants, allowing the polymer to be reused and reprocessed into a new membrane.