30 June 2021 | Wednesday | News
Chemistry in Water’ or ‘micellar chemistry’ uses surfactants which form microscopic spheres in water, called micelles. These function as nanoreactors and enable organic reactions, which are generally run in organic solvents, to be performed in water.
The successful integration of micellar chemistry into Evonik’s CDMO portfolio follows a collaboration with pioneering organic chemist Professor Bruce Lipshutz of the University of California, Santa Barbara.
“Improving the environmental footprint for the synthesis of active pharmaceutical ingredients is critically important for the sustainability of drug manufacturing going forward. It is a great pleasure to work with technology pioneer Professor Bruce Lipshutz and bring Chemistry in Water to commercial scale,” says Dr. Stefan Randl, head of Research, Development & Innovation for the Health Care business line of Evonik.
“After many years developing micellar chemistry, it is immensely rewarding to see industry applying and further developing its potential. I am confident that working together with Evonik, as the first adopter for CDMO purposes, will pave the way for wider application in industry and overall, more sustainable chemistry,” says Bruce Lipshutz.
Apart from reducing the need for organic solvents in organic reactions, micellar chemistry also has the potential to generate higher yields and increase selectivity under mild conditions. Significant reduction of catalyst loading, energy consumption and waste production has been achieved using this approach for many reaction processes.
Evonik’s Health Care business is part of the life sciences division Nutrition & Care, for which sustainability is the guiding business principle. Evonik Health Care is one of the world’s largest CDMO (Contract Development and Manufacturing Organization) with capabilities to manufacture customized APIs/HPAPIs.
To address specific customer needs, Evonik has established a broad portfolio of advanced technologies which can be combined to support multi-step API synthesis. These technologies include continuous processing, fermentation, highly pure PEGs and mPEGs, transition metal catalysis, biocatalysis, organometallic/cryogenic chemistry, and from now on Chemistry in Water.