Dynamic kinetic enantioselective

At the end of 2007, Widenhoefer et al. reported the first examples of the dynamic kinetic enantioselective hydroamination of axially chiral allenes, catalyzed by a dinuclear complex of gold (Figure 8.1) and silver perchlorate [46, 47]. 

The first strategy involves discrimination between enantiotopic leaving groups (Type A). In the second approach, two enantiomers of a racemic substrate converge into a meso-n-al y complex wherein preferential attack of the nucleophile at one of either allylic termini leads to asymmetric induction, a process that may be referred to as a dynamic kinetic enantioselective transformation (Type B). The third requires differentiation between two enantiotopic transition... 

The enantioselective hydroaminations of allenes with chiral phosphine catalysts was accomplished with substrates that had a terminal symmetric substitution and with the amines protected as carbamates or sulfonamides. The same symmetric substituents were necessary for the enantioselective transformation nsing chiral counterions. However, very recently, high enantiomeric excesses were reached with trisubstituted asymmetric allenes by a dynamic kinetic enantioselective hydroamination of allenyl carbamates (eqnation 110), even thongh the E/Z ratio of the prodncts was not optimal. 

Chan VS, Bergman RG, Toste FD (2007) Pd-catalyzed dynamic kinetic enantioselective arylation of silylphosphines. J Am Chem Soc 129 15122-15123... 

Zhang Z, Bender CF, Widenhoefer RA. Gold(I)-catalyzed dynamic kinetic enantioselective intramolecular hydroamination of allenes. J. Am. Chem. Soc. 2007 129(46) 14148-14149. 

Hydantoinases belong to the E.C.3.5.2 group of cyclic amidases, which catalyze the hydrolysis of hydantoins [4,54]. As synthetic hydantoins are readily accessible by a variety of chemical syntheses, including Strecker reactions, enantioselective hydantoinase-catalyzed hydrolysis offers an attractive and general route to chiral amino acid derivatives. Moreover, hydantoins are easily racemized chemically or enzymatically by appropriate racemases, so that dynamic kinetic resolution with potential 100% conversion and complete enantioselectivity is theoretically possible. Indeed, a number of such cases using WT hydantoinases have been reported [54]. However, if asymmetric induction is poor or ifinversion ofenantioselectivity is desired, directed evolution can come to the rescue. Such a case has been reported, specifically in the production of i-methionine in a whole-cell system ( . coli) (Figure 2.13) [55]. 

Other biocatalysts were also used to perform the dynamic kinetic resolution through reduction. For example, Thermoanaerobium brockii reduced the aldehyde with a moderate enantioselectivity [30b,c], and Candida humicola was found, as a result of screening from 107 microorganisms, to give the (Jl)-alcohol with 98.2% ee when ester group was methyl [30dj. 

Figure 10.47 Dynamic kinetic resolution ofThrA generated diastereomers by enantioselective decarboxylation (a).

Liang J, Ruble JC, Fu GC (1998) Dynamic kinetic resolutions catalyzed by a planar-chiral derivative of DMAP enantioselective synthesis of protected a-amino acids from racemic azlactones. J Org Chem 63 3154—3155... 

The ability of enzymes to achieve the selective esterification of one enantiomer of an alcohol over the other has been exploited by coupling this process with the in situ metal-catalysed racemisation of the unreactive enantiomer. Marr and co-workers have used the rhodium and iridium NHC complexes 44 and 45 to racemise the unreacted enantiomer of substrate 7 [17]. In combination with a lipase enzyme (Novozyme 435), excellent enantioselectivities were obtained in the acetylation of alcohol 7 to give the ester product 43 (Scheme 11.11). A related dynamic kinetic resolution has been reported by Corberdn and Peris [18]. hi their chemistry, the aldehyde 46 is readily racemised and the iridium NHC catalyst 35 catalyses the reversible reduction of aldehyde 46 to give an alcohol which is acylated by an enzyme to give the ester 47 in reasonable enantiomeric excess. 

The next step in the use of transfer hydrogenation catalysts for recycling of the unwanted enantiomer is the dynamic kinetic resolution. This is a combination of two reaction systems (i) the continuous racemization of the alcohol via hydrogen transfer and (ii) the enantioselective protection of the alcohol using a... 

Dynamic kinetic resolution is possible for a-alkyl or a-alkoxy cyclic ketones in the presence of KOH, which causes mutation of the stereogenic center syn-alco-hols were obtained selectively with high enantioselectivity using ruthenium-3,5-xyl-binap. Dynamic kinetic resolution of 2-arylcycloalkanones also proceeded with extremely high syn-selectivity and with high enantioselectivity using ruthenium-binap-diamine as catalyst (Table 21.23) [12, 139, 140]. 

The enantioselective synthesis of an allenic ester using chiral proton sources was performed by dynamic kinetic protonation of racemic allenylsamarium(III) species 237 and 238, which were derived from propargylic phosphate 236 by the metalation (Scheme 4.61) [97]. Protonation with (R,R)-(+)-hydrobcnzoin and R-(-)-pantolactone provided an allenic ester 239 with high enantiomeric purity. The selective protonation with (R,R)-(+)-hydrobenzoin giving R-(-)-allcnic ester 239 is in agreement with the... 

The kinetic resolution using a chiral zirconocene-imido complex 286 took place with high enantioselectivity to result in chiral allenes 287 (up to 98% ee) (Scheme 4.74) [116]. However, a potential drawback of these methods is irreversible consumption of half of the allene even if complete recovery of the desired enantiomer is possible. Dynamic kinetic resolutions avoid this disadvantage in the enantiomer-differentiating reactions. Node et al. transformed a di-(-)-L-menthyl ester of racemic allene-l,3-dicarboxylate [(S)- and (RJ-288] to the corresponding chiral allene dicarbox-ylate (R)-288 by an epimerization-crystallization method with the assistance of a catalytic amount of Et3N (Scheme 4.75) [117]. 

After some early examples of bio-chemo combinations in the 1980s, there was then over a decade of silence , followed by clearly increasing interest from the mid-1990s in the field of dynamic kinetic resolution processes (i.e., chemocata-lyzed racemization combined with enantioselective enzymatic conversion, giving, in principle, 100% yield of an optically pure compound). 

Asymmetric synthesis can refer to any process which accesses homochiral products. We will focus on asymmetric synthesis from racemic or prochiral starting materials in the presence of an enantioselective catalyst (enzyme). There are four general methodologies commonly applied kinetic resolution, dynamic kinetic resolution, deracemization and... 

Dynamic kinetic resolution (DKR) is an extension to the kinetic resolution process, in which an enantioselective catalyst is usually used in tandem with a chemoselective catalyst. The chemoselective catalyst is used to racemize the starting material of the kinetic resolution process whilst leaving the product unchanged. As a consequence, the enantioselective catalyst is constantly supplied with fresh fast-reacting enantiomer so that the process can be driven to theoretical yields of up to 100 %. There are special cases where the starting material spontaneously racemizes under the reaction conditions and so a second catalyst is not required. 

Dynamic kinetic resolution enables the limit of 50 % theoretical yield of kinetic resolution to be overcome. The application of lipase-catalyzed enzymatic resolution with in situ thiyl radical-mediated racemization enables the dynamic kinetic resolution of non-benzylic amines to be obtained. This protocol leads to (/f)-amides with high enantioselectivities. It can be applied either to the conversion of racemic mixtures or to the inversion of (5)-enantiomers. 

Enantioselective and Diastereoselective Enzyme-catalyzed Dynamic Kinetic Resolution of an Unsaturated Ketone... 

The reversibility of hydrogen transfer reactions has been exploited for the racemi-zation of alcohols and amines. By coupling the racemization process with an enantioselective enzyme-catalyzed acylation reaction, it has been possible to achieve dynamic kinetic resolution reactions. The combination of lipases or... 

Three years later. List and coworkers extended their phosphoric acid-catalyzed dynamic kinetic resolution of enoUzable aldehydes (Schemes 18 and 19) to the Kabachnik-Fields reaction (Scheme 33) [56]. This transformation combines the differentiation of the enantiomers of a racemate (50) (control of the absolute configuration at the P-position of 88) with an enantiotopic face differentiation (creation of the stereogenic center at the a-position of 88). The introduction of a new steri-cally congested phosphoric acid led to success. BINOL phosphate (R)-3p (10 mol%, R = 2,6- Prj-4-(9-anthryl)-C H3) with anthryl-substituted diisopropylphenyl groups promoted the three-component reaction of a-branched aldehydes 50 with p-anisidine (89) and di-(3-pentyl) phosphite (85b). P-Branched a-amino phosphonates 88 were obtained in high yields (61-89%) and diastereoselectivities (7 1-28 1) along with good enantioselectivities (76-94% ee) and could be converted into... 

---