A
polarized light micrograph of iron(II) sulfate crystals (background) that can
catalyze formation of amide compounds (white structures) cheaply and
efficiently.
Safe
and inexpensive iron catalysts provide a ‘greener’ alternative to typical
pharmaceutical production methods
More than one-quarter of all known
pharmaceuticals contain the chemical group known as amides: carboxylic acid
derivatives derived from ammonia or amines. Most methods for synthesizing
amides, however, are inefficient and use hazardous reagents. New work from Anqi
Chen and co-workers at the A*STAR Institute of Chemical and Engineering
Sciences in Singapore promises to make amide chemistry more economical and
sustainable than before1. The team has uncovered a way to convert aldehydes and
amine salts into amides using iron(II) sulfate — a harmless, inexpensive
substance as the catalyst to perform this transformation efficiently and with
little waste.
Most alternative methods to produce amide
molecules use expensive noble metal catalysts such as palladium and ruthenium,
which are incompatible with industrial demands for cost-efficiency. Funded by a
GlaxoSmithKline (GSK)–Singapore Economic Development Board (EDB) endowment on
sustainable drug manufacturing, the researchers investigated a different
approach known as ‘direct oxidative amidation’. This method couples an aldehyde
and an amine salt in the presence of a catalyst and an oxidant, generating an
amide in one step.
Nontoxic and cheap catalysts with sufficient
chemical activity for amide transformation are hard to find. To identify an
efficient and inexpensive catalyst, the team screened a range of iron compounds
and discovered that iron(II) sulfate (see image), a supplement for anemia that
costs less than a dollar per kilogram, has strong potential to catalyze amide
formation from aldehydes with amine salts.
Apart from the environmentally benign iron
catalyst, the transformation uses an inexpensive oxidant known as tert-butyl
hydroperoxide and very cheap calcium carbonate, the main composition of
limestone, as a base. By combining these inexpensive ingredients together, the
researchers achieved excellent amide yields under conditions convenient for
both laboratory and industrial operations.
Further experiments revealed the versatility
of this amide synthesis. A range of amine salts and aldehydes with different
structural and electronic features could be transformed into amides with
good-to-excellent yields. Importantly, salts derived from natural amino acids
such as valine and proline also underwent oxidative amidation without
disrupting their chirality or ‘handedness’ — a critical structural phenomenon
for drug molecules and peptides.
The team demonstrated the potential of this
iron-catalyzed amidation for drug manufacturing by synthesizing the
antiarrhythmic drug N-acetylprocainamide in a one-step procedure that is more
efficient than previous multiple-step routes. “This environmentally benign
method has significant advantages over conventional techniques,” says Chen,
“and we intend to identify pharmaceutical targets where this promising method
could bring about significant cost-savings and improved sustainability.”
The A*STAR-affiliated researchers
contributing to this research are from the Institute of Chemical and
Engineering Sciences
References
- Ghosh, S. C., Ngiam, J. S. Y., Chai, C. L. L.,
Seayad, A. M., Dang, T. T. & Chen, A. Iron-catalyzed efficient
synthesis of amides from aldehydes and amine hydrochloride salts. Advanced
Synthesis & Catalysis 354,1407–1412 (2012). | article
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