Enantioselective synthesis chiral metal complexes

The same reasoning applies to the synthesis of pure enantiomers as to organic synthesis in general processes should be atom efficient and have low E factors, i.e. involve catalytic methodologies. This is reflected in the increasing attention being focused on enantioselective catalysis, using either enzymes or chiral metal complexes. 

Cyanohydrination (addition of a cyano group to an aldehyde or ketone) is another classic reaction in organic synthesis. Enantioselective addition of TMSCN to aldehyde, catalyzed by chiral metal complexes, has also been an active area of research for more than a decade. The first successful synthesis using an (5,)-binaphthol based complex came from Reetz s group142 in 1986. Their best result, involving Ti complex, gave 82% ee. Better results were reported shortly thereafter by Narasaka and co-workers.143 They showed that by... 

Asymmetric induction in the ylide formation/[l,2]-shift has also been studied with chiral metal complexes. Katsuki and co-workers examined the reaction of ( )-2-phenyloxetane with 0.5 equiv. of /< //-butyl diazoacetate in the presence of Gu(i) catalyst. With chiral bipyridine ligand 53, trans- and m-tetrahydrofurans 54 and 55 are obtained with 75% and 81% ee, respectively (Equation (6)). This asymmetric ring expansion was applied by the same group to their enantioselective synthesis of translactone. 

Chiral sulfoxides have emerged as versatile building blocks and chiral auxiliaries in the asymmetric synthesis of pharmaceutical products. The asymmetric oxidation of prochiral sulfides with chiral metal complexes has become one of the most effective routes to obtain these chiral sulfoxides.We have recently developed a new heterogeneous catalytic system (WO3-30% H2O2) which efficiently catalyzes both the asymmetric oxidation of a variety of thioethers (1) and the kinetic resolution of racemic sulfoxides (3), when used in the presence of cinchona alkaloids such as hydroquinidine 2,5-diphenyl-4,6-pyrimidinediyl diether [(DHQD)2-PYR], Optically active sulfoxides (2) are produced in high yields and with good enantioselectivities (Figure 9.3). ... 

At the synthetic level we may expect increased emphasis on enantioselective catalysis usin metal complex catalysts as a key component of the manufacturing process (84). For biocatalysts there will unquestionably continue to be increasing interest in the "custom synthesis" of enzymes engineered for specific functions and conditions. The first example of the "ultimate" enzyme has been reported with the synthesis of the all-D form of HIV-1 protease (85-87). This enzyme exhibits a chiral specificity opposite to that of the naturally occurring L form and it may be generally predicted that enantiomeric proteins will exhibit reciprocal chiral specificity in all aspects of their interactions. These reciprocal chiral... 

In the last decade, optically pure cyanohydrins (a-hydroxynitriles) have become a versatile source for the synthesis of a variety of chiral building blocks. Diverse methods for the enantioselective synthesis of cyanohydrins have been published and reviewed111. Besides enzyme catalyzed methods, hydrocyanation or silylcyanation of aldehydes or ketones controlled by chiral metal complexes or cyclic dipeptides, as well as diastereoselective hydrocyanation of chiral carbonyl compounds, have been applied with moderate success. 

Keywords Arene chromium complexes Arene ruthenium complexes Enantioselective total synthesis Planar-chiral metal complexes Natm-al products... 

It is a paradox that whereas the search for P-stereogenic compounds is spurred by their application in enantioselective catalysis, little elfort has been devoted so far to the preparation of these ligands via catalytic methods. However, this situation has started to change in the last decade. In particular, catalytic reactions where a chiral metal complex controls the stereochemistry of the P-C bond formation are extremely promising. Despite this, the field has not reached yet enough maturity to provide practical methods for the synthesis of a wide variety of phosphines. The good news is that modern techniques of characterisation, especially the availability of high field NMR spectrometers, easily provide a wealth of mechanistic information about catalytic reactions, and should assist the development of better processes. 

The demonstration of the optical activity of octahedral complexes was important in confirming Alfred Werner s intuitive ideas about coordination chemistry. Early work involved the resolution of complexes characterized by optical rotations. Modem instmments for optical rotatory dispersion were developed first, but circular dichroism (CD) spectra proved to be more useful. CD has been a powerful tool for detailed studies of the stereochemistry of octahedral complexes. Contributions to rotational strength of chelate ring conformational, configurational, and vicinal contributions are additive. Chiral metal complexes are now used in enantioselective synthesis of chiral pharmaceuticals. 

Synthesis of Chiral Pharmaceuticals. Biologically active compounds are usually chiral. Synthetic drugs produced in the past were usually racemic products. Commonly, oidy one enantiomer is active. Production of the active enantiomer permits the use of lower dosage with possible reduction of side effects. Applications of chiral metal complexes in enantioselective syntheses are increasing rapidly in the pharmaceutical industry (33). 

Sherrington et al. were the first to attempt the synthesis of chiral polymeric metal complexes by the chemical modification route,78,177,178 whereby the [Mn(salen)Cl] units are attached in a pendant fashion, by only one of the aromatic rings, to poly(styrene) or poly(methacrylate) resin beads of various morphology. Epoxidation of 1-phenylcyclohexene gave enantioselectivity values between 61% and 91%. 

Keywords Asymmetric Catalysis a Natural Product Synthesis a Chiral Metal-Based Complexes a Enantioselective C-C Bond Formation a Enantioselective C-O Bond Formation... 

---