Rhodium(I)‐Catalyzed Reductive Carbon–Carbon Bond Formation

“…7 Since then, enzymes have been isolated, mass-produced, and re-engineered to fit almost any chemical reaction by the application of highly complex protein engineering techniques, like directed evolution [8][9][10] and in silico or de novo enzyme design. 11,12 While chemical catalysis with various metal catalysts is still prevalent in industrial organic synthesis, [13][14][15] it shows its own drawbacks in the form of high market price and limited availability of required precious metals, like rhodium and palladium, 16 along with multiple protection and de-protection steps that make the process economically unfeasible, and may result in the production of large amounts of dangerous or toxic waste. 17,18 Those drawbacks are especially noticeable in the pharmaceutical industry, which is known for its long and rigorous drug design and production times.…”

Biocatalysis for the Production of Pharmaceutical Intermediates

“…7 Since then, enzymes have been isolated, mass-produced, and re-engineered to fit almost any chemical reaction by the application of highly complex protein engineering techniques, like directed evolution [8][9][10] and in silico or de novo enzyme design. 11,12 While chemical catalysis with various metal catalysts is still prevalent in industrial organic synthesis, [13][14][15] it shows its own drawbacks in the form of high market price and limited availability of required precious metals, like rhodium and palladium, 16 along with multiple protection and de-protection steps that make the process economically unfeasible, and may result in the production of large amounts of dangerous or toxic waste. 17,18 Those drawbacks are especially noticeable in the pharmaceutical industry, which is known for its long and rigorous drug design and production times.…”

Biocatalysis for the Production of Pharmaceutical Intermediates