Hydroxylation benzylic enantioselectivity

The third approach to obtain diarylmethylpiperazine derivatives uses the highly stereospecific chiral oxazaborolidine-catalyzed reduction, using catecholborane as the reductant of the 4-bromobenzophenone chromium tricarbonyl complex, as described by Corey and Helal [59], followed by the stereospecific displacement of the hydroxyl benzyl group by the /V-substituted-piperazine [44]. As outlined in Scheme 2, Delorme et al. [44] used this approach for the enantioselective synthesis of compound 31, (+)-4-[ (aS)-a-(4-benzyl-l-piperazinyl)benzyl]-lV,lV-diethylben-zamide. Lithiation of the readily available benzene chromium tricarbonyl with n-BuLi in the presence of TMEDA in THF at —78 °C, followed by addition of... 

Porcine liver esterase (PLE) gives excellent enantioselectivity with both dimethyl 3-methylglutarate [19013-37-7] (lb) and malonate (2b) diester. It is apparent from Table 1 that the enzyme s selectivity strongly depends on the size of the alkyl group in the 2-position. The hydrolysis of ethyl derivative (2c) gives the S-enantiomer with 75% ee whereas the hydrolysis of heptyl derivative (2d) results in the R-monoester with 90% ee. Chymotrypsin [9004-07-3] (CT) does not discriminate glutarates that have small substituents in the 3-position well. However, when hydroxyl is replaced by the much bulkier benzyl derivative (Ic), enantioselectivity improves significantly. 

The importance of the o-hydroxyl moiety of the 4-benzyl-shielding group of R,R-BOX/o-HOBn-Cu(OTf)2 complex was indicated when enantioselectivities were compared between the following two reactions. Thus, the enantioselectivity observed in the reaction of O-benzylhydroxylamine with l-crotonoyl-3-phenyl-2-imi-dazolidinone catalyzed by this catalyst was 85% ee, while that observed in a similar reaction catalyzed by J ,J -BOX/Bn.Cu(OTf)2 having no hydroxyl moiety was much lower (71% ee). In these reactions, the same mode of chirality was induced (Scheme 7.46). We believe the free hydroxyl groups can weakly coordinate to the copper(II) ion to hinder the free rotation of the benzyl-shielding substituent across the C(4)-CH2 bond. This conformational lock would either make the coordination of acceptor molecules to the metallic center of catalyst easy or increase the efficiency of chiral shielding of the coordinated acceptor molecules. 

The high stereopreference was rationalized by considering complex 388 in which an attractive n-n donor-acceptor interaction favors co-ordination of the dienophile to the face of the boron center which is cis to the 2-hydroxyphenyl substituent. Hydrogen bonding of the hydroxyl proton of the 2-hydroxyphenyl group to an oxygen of the adjacent B—O bond played an important role in the asymmetric induction. Protection of this hydroxy functionality with a benzyl group caused reversal of enantioselectivity in the cycloaddition of cyclopentadiene with methacrolein (model 389)244. 

TABLE 15.1 Enantioselectivity and Activity of the Hydroxylation of A-Benzylpyrrolidine to Ai-Benzyl-3-hydroxypyrrolidine with Several Alkane-Degrading Strains... 

Enantioselective Benzylic Microbial Hydroxylation of Indan and Tetralin... 

The enantioselective benzylic hydroxylation of indan and tetralin can be achieved with M. isabellina, affording 78 % conversion to 1-indanol (64 % yield, 86 % (11 )- ee) in a 2-day incubation and 52 % conversion to 1-tetralol (38 % yield, 92 % (11 )- ee) in a 4-day incubation. The good yields and ee allow their use in future scahng-up processes however, to avoid the lack of efficiency, careful control of the temperature, pH and medium is necessary, since the reactions are strongly dependent on the incubation and reaction conditions. Tables 12.2 and 12.3 give details of some of the different incubation condi-tions/results and time-course analysis found in the benzyhc hydroxylation of indan and tetrahn mediated by M. isabellina CCT3498. 

Enantioselective metabolism oxidative deamination and reduction to 2-ol (R) benzylic 2 -methyl hydroxylation C-3 or 4 aromatic hydroxylations (S)... 

Both, a-hydroxylated lignans of the dibenzyllactone-type and of the biarylcyclooctane-type have been enantioselectively prepared from the corresponding / -benzyl-y-butyrolactones via a-alkylation followed by a-oxy-genation (Scheme 5). The hydroxy group was introduced in two different... 

Two classes of a-hydroxylated lignans have been enantioselectively prepared a) wikstromol (3) [10, 38] and related natural products [39] and b) gomisin A (1) and congeners [40, 41]. In both cases, chiral, non-racemic ita-conic acid derivatives have been synthesized as key compounds for the preparation of -benzyl-y-butyrolactones (either by resolution (g [32]) or by asymmetric hydrogenation (h [25])). 

The tra x-[Ru (0)2(por)] complexes are active stoichiometric oxidants of alkenes and alkylaro-matics under ambient conditions. Unlike cationic macrocyclic dioxoruthenium I) complexes that give substantial C=C bond cleavage products, the oxidation of alkenes by [Ru (0)2(por)] affords epoxides in good yields.Stereoretentive epoxidation of trans- and cw-stilbenes by [Ru (0)2(L)1 (L = TPP and sterically bulky porphyrins) has been observed, whereas the reaction between [Ru (0)2(OEP)] and cix-stilbene gives a mixture of cis- and trani-stilbene oxides. Adamantane and methylcyclohexane are hydroxylated at the tertiary C—H positions. Using [Ru (0)2(i)4-por)], enantioselective epoxidation of alkenes can be achieved with ee up to 77%. In the oxidation of aromatic hydrocarbons such as ethylbenzenes, 2-ethylnaphthalene, indane, and tetrahydronaphthalene by [Ru (0)2(Z>4-por )], enantioselective hydroxylation of benzylic C—H bonds occurs resulting in enantioenriched alcohols with ee up to 76%. ... 

Enantioselective hydroxylation of 2-benzyl (3-ketoesters was catalysed by [RuCl(OEt3)(PNNP)]/aq. H O /CH Cy thus ethyl 2-benzyl-3-oxo-butanoate gave ethyl 2-hydroxy-2-benzyl-yoxo-butanoate. Better results were obtained with cumyl hydroperoxide as co-oxidant [14]. The reagent Ru(CO)(TPP) or Ru(CO) (TMP)/(Cl3pyNO)/aq. HBr/C Hy40°C oxidised 5 3-steroids to the corresponding Sp-hydroxy derivatives with retention of configuration [15]. 

The chiral quaternary ammonium salt 47a with a single tartrate moiety and free hydroxyl groups gave disappointing results for the Michael addition of Schiff s base 20 with tert-butyl acrylate in the presence of CsOH base. However, the benzyl-protected catalyst 47b promoted Michael addition, and the adduct (S)-49 was obtained in 57% yield, although the enantioselectivity remained low (Table 7.6, entry 2). The use of catalyst 48a,b with two tartrate moieties afforded the best results at —60 ° C, and Michael adduct (S)-49 was obtained in good enantioselectivity up to 77% ee (entries 4 and 5). 

The antibiotic ( + )-kjellmanianone (2) has been prepared by asymmetric hydroxylation of the sodium enolate of the P-keto ester 1 with several (camphoryl)oxaziri-dines. The highest enantioselectivity (68.5% ee) was obtained by use of the p-(trifluoromethyl)benzyl derivative 3.3... 

Iron-containing cytochrome P-450 constitutes the most famous example of a selective C-H bond oxidizer. Although the exact nature of the mechanism remains controversial, the reaction most likely proceeds through radical intermediates [2]. The hydroxylation of activated C-H bonds has also been carried out in the presence of synthetic porphyrin complexes. In these biomimetic processes, ruthenium plays a relatively minor role when compared with iron. Zhang et al. [50], however, recently reported the enantioselective hydroxylation of benzylic C-H bonds using ruthenium complexes supported by a D4-sym-metric porphyrin bearing a crafted chiral cavity. Thus, complex 23 reacts in a stoichiometric manner with ethylbenzene to give phenethyl alcohol with a... 

BQC is derived from quinine, which is a member of the cinchona family of alkaloids. Ammonium salts derived from quinidine, a diastereomer of (1) at the hydroxyl substituent, have been used less frequently in catalysis than BQC. Quini-dinium salts often give rise to products with enantioselectivity opposite to that from (1). Other related compounds, such as those derived from cinchonine and cinchonidine (which lack the methoxy substituent on the quinoline nucleus), have found application in organic synthesis. The cinchona alkaloids, as well as salt derivatives in which the benzyl group bears various substituents, have also been studied. Results from polymer-bound catalysts have not been promising. ... 

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