Enantioselective reduction of ketones

Lithium aluminium hydride (LAH) modified with chiral alkoxide ligands has been shown to proceed in good yield and high enantioselectivity. Chelating ligands such as BINOL are used to avoid disproportionation and background reduction by LAH. Chiral diamines and amino alcohols have also been used to modify LAH for enantioselective reductions. (4) Chirally modified borohydrides are also useful for enantioselective ketone reductions. Economical ligands derived from amino acids have been used to modify borohydrides, affording highly selective reducing agents. (5) Chiral alkylborohydrides are accessible through the diastereoselective hydroboration of chiral alkenes. Boranes derived from pinene have been used in this context for enantioselective reductions. Neutral alkoxyboranes may result from these reductions. (6) Oxazaborolidine reductions have also been demonstrated. Coordination of borane to the oxazaborolidine nitrogen generates the complex I, which then coordinates a molecule of ketone to yield complex II. In the transition state for hydride transfer (II → III), the large substituent of the ketone is aligned inward to avoid steric interactions with the outward-pointing R group of the oxazaborolidine, which is often tethered to the nitrogen atom. After hydride transfer, complex III releases the product and coordinates a second molecule of borane. (2) == Catalytic reductions ==

With borane or catecholborane as the stoichiometric reducing agent, chiral oxazaborolidine catalysts may be used to reduce ketones enantioselectively. Catecholborane may be used as an alternative to solutions of borane-Lewis base adducts. (7) Reduction via the net transfer of hydrogen from one organic molecule to another is known as transfer hydrogenation. Transfer hydrogenation to ketones leads to alcohols (the Meerwein-Ponndorf-Verley reduction), and in the presence of a chiral transition metal catalyst, this process may be rendered enantioselective. In the presence of a chiral diamine, ruthenium catalyzes the enantioselective transfer hydrogenation of aryl ketones with isopropanol. Other metals that have been employed include samarium(III), iridium(I), and rhodium(I). Formic acid and formate salts may also be used as reductants in transfer hydrogenations. Simple aryl ketones are reduced enantioselectively when a chiral amino alcohol ligand is employed. (9) Transition metal catalysts have also been used with hydrogen gas as the stoichiometric reductant. Ketones with a chelating group undergo enantioselective reduction in the presence of a chiral Ru(BINAP) catalyst. The configuration of the new stereocenter is predictable using the stereochemical model developed for hydrogenations employing BINAP (see equation (3) below). (10) Hydrosilylation may be used to reduce ketones after silyl ether hydrolysis. Rhodium(I) and rhodium(III) salts are the most common catalysts for hydrosilylation. Asymmetric induction may be conferred by chiral PYBOX ligands. (11) Transition metal catalyzed reductions are subject to the spatial properties of the chiral ligand bound to the metal center that determine the sense and extent of enantioselectivity. A reliable stereochemical model has been developed for reductions employing BINAP ligands. When BINAP chelates to a transition metal such as ruthenium, the phenyl groups attached to phosphorus reside in either pseudoaxial or psudeoequatorial positions. The pseudoequatorial phenyl groups project into the region of space on the other side of the BINAP ligand and influence the preferred binding conformation of chelating ketones (such as α-amino ketones or β-keto esters). The ketone typically occupies the more open regions of space, leading to hydride delivery to a single face of the ketone. The C2 symmetry of the coordination space ensures that only a single face of the ketone will be accessible to the catalyst, no matter in which open region the ketone binds. (3) == Enzymatic reductions ==

Microorganisms (or more specifically, their enzymes) reduce certain classes of simple ketones with extremely high enantioselectivity. Baker's yeast is the most common organism used to reduce ketones enzymatically, although other microorganisms may be used. Access to "unnatural" reduced enantiomers is difficult in most cases. (12) Carrots have been documented to reduce a wide range of ketones with similarly high enantioselectivity. ==Alpine reduction==

A well-known method to synthesize enantiopure alcohols by ketone reduction is the Midland Alpine borane reduction, named after its inventor Professor M. Mark Midland. The strategy uses a chiral organoborane, derived from the hydroboration of alpha-pinene by 9-BBN, to differentiate enantiotopic faces of a ketone. Following workup with alkaline hydrogen peroxide, the product alcohols can be obtained, often with high degrees of enantioselectivity. The reaction works best if one of the ketone groups has low steric hindrance, such as an alkyne or nitrile. ==CBS reduction==

Another method, first developed in the 1980s, is called the Corey–Bakshi–Shibata reduction (CBS), and it features the use of an oxazaborolidine catalyst along with borane as a reducing agent for accomplishing enantioselective ketone reductions. The CBS reduction has been used extensively by chemists en route to synthesizing a wide variety of natural products, including alkaloids, terpenoids, pheromones, and biotins. Fig. 1 shows an example of a diastereoselective CBS reduction being used to prepare a complex macrocyclic alcohol en route to the synthesis of 11-desmethyllaulimalide (an analog of the antitumor agent laulimalide). The authors noted that CBS reduction was much more effective than using either lithium tert-butoxyaluminum hydride or L-Selectride. The CBS catalyst, usually prepared from diphenylprolinol, often can be used in low catalyst loadings, even as low as 2%. ==References==