Oxazaborolidines, as catalysts

The enantioselective reduction of ketones using borane and a chiral oxazaborolidine as catalyst (CBS Catalyst). Usually, MeCBS... 

The use of chiral oxazaborolidines as catalysts for the enantioselective addition of alkynylboranes to aldehydes took place in a manner analogous to the asymmetric reduction of ketones with boranes mediated by proline-derived oxazaborolidines (Equation (127)).587 Addition of alkynylboranes to A-aziridinylimines provided a convenient method to prepare allenes from carbonyl compounds (Equation (128)).5... 

For aryl ketones the Corey-Bakshi-Shibata (CBS) reduction using oxazaborolidines as catalysts for the boron hydride mediated hydrogenation is particularly useful, with maximum selectivities up to 99 % ee (see Scheme 4) [34]. The excellent review by Corey et al. [35] also shows clearly the power for chemo- and enantioselective reduction of purely aliphatic a,//-enones and -ynones only on the carbonyl group. In the re-... 

Fig. 4.9. Enantio-selective reduction of prochiral ketones using oxazaborolidines as catalysts. The transition state of the reaction and a stable transition state analogue are represented.

Corey-Bakshi-Shibata reduction Enantioselective reduction of ketones with BH3 using oxazaborolidines as catalysts. 100... 

In 1989, Brown et al. [15] suggested that since B-O and B-N bonds are shorter than metal-oxygen and metal-nitrogen bonds, there is a greater chance that boron complex will be a more effective catalyst. In order to substantiate this hypothesis, they carried out enantioselective addition of diethyl zinc to several aldehydes using (45,5/ )-3,4-dimethyl-5-phenyl-1,3,2-oxazaborolidine as catalyst and achieved very high yield and enantiomeric purity (upto 96 % ee) of secondary alcohols. 

Corey et al. [24] have used this oxazaborolidine as an effective catalyst for an efficient synthesis of cassiol and gibberellic acid. Similar high diastereo- (exo endo = 99 1) and enantioselectivity (96 4) was observed in the cycloaddition reaction of furan with 2-bro-moacrolein using oxazaborolidine as catalyst. 

The past fifteen years witnessed the development of oxazaborolidines as catalysts for various organic reactions (44). The Itsuno-Corey asymmetric reduction is a prominent example (Figure 12) (45, 46). This chemistry led... 

Although it is known that in some cases the lithium salts of chiral amino alcohols are even better catalysts than the chiral ligands themselves, the use of metals other than lithium has rarely been investigated. The oxazaborolidines A and B and the aluminum analog C have been used as catalysts for the enantioselective addition of diethylzinc to benzaldehyde35 (Table 32). 

Addition of triethylamine to the oxazaborolidine reaction system can significantly increase the enantioselectivity, especially in dialkyl ketone reductions.79 In 1987, Corey et al.80 reported that the diphenyl derivatives of 79a afford excellent enantioselectivity (>95%) in the asymmetric catalytic reduction of various ketones. This oxazaborolidine-type catalyst was named the CBS system based on the authors names (Corey, Bakshi, and Shibata). Soon after, Corey s group81 reported that another fi-methyl oxazaborolidine 79b (Fig. 6-6) was easier to prepare and to handle. The enantioselectivity of the 79b-catalyzed reaction is comparable with that of the reaction mediated by 79a (Scheme 6-36).81 The -naphthyl derivative 82 also affords high enantioselectivity.78 As a general procedure, oxazaborolidine catalysts may be used in 5-10 mol%... 

The CBS-reduction [137] of prochiral ketones is a well-known process which employs a chiral oxazaboroHdine as catalyst and BHs-THF or catecholborane as stoichiometric reductants. It is believed that the active catalytic species is a LLA, resulting from coordination of the oxazaborolidine nitrogen with the boron reagent to render the oxazaborolidine boron atom highly Lewis acidic [87]. Similarly, Corey... 

If 2-camphanyloxyacrylonitrile (15 R = C8H 02C00) is taken for cycloaddition, diastereoisomeric cycloadducts can be separated, and the basic system, 7-oxabicyclo-[2.2.1]hept-5-en-2-one 17, can be obtained in optically pure form [36]. Another way of obtaining enantiomeric ketones is based on crystallization of a brucine complex obtained from the corresponding cyanohydrines (see Sec. III). Ketone 17 can be converted [e.g., by cis-hydroxylation (—>18), protection of the diol system, and Baeyer-Villiger oxidation] to lactone 19, the opening of which leads to furanuronic acid 20. A new development in this field is based in cycloaddition between furan and 2-chloro- or 2-bromoacrolein in the presence of 5 mol% chiral oxazaborolidine 21 as catalyst [37],... 

Corey extended the utility of this catalytic hydroboration chemistry remarkably (38). Scheme 15 shows some examples of the highly en-antioselective asymmetric borane reduction of ketones. The well-designed chiral oxazaborolidines, which act as catalyst precursors, have... 

The asymmetric catalytic aldol reaction of silyl allenolates ICH=C=CR2OSiMe3 with aldehydes R CHO has been achieved by Li et al. by using N-C3F7CO oxazaborolidine as the catalyst [43], The fluoroacyl group of the catalyst was found to be crucial for control of enantioselectivity. The reaction provides the first enantioselective approach to / -halo Baylis-Hillman-type adducts. 

The pioneering studies by Itsuno [1] and Corey [2] on the development of the asymmetric hydroboration of ketones using oxazaborolidines have made it possible to easily obtain chiral secondary alcohols with excellent optical purity [3]. Scheme 1 shows examples of Corey s (Corey-Bakshi-Shibata) CBS reduction. When oxazaborolidines 1 were used as catalysts (usually 0.01-0.1 equiv), a wide variety of ketones were reduced by borane reagents with consistently high enan-tioselectivity [2]. The sense of enantioselection was predictable. Many important biologically active compounds and functional materials have been synthesized using this versatile reaction [2-4]. 

In reactions with polymer-bound catalysts, a mass-transfer limitation often results in slowing down the rate of the reaction. To avoid this disadvantage, homogenous organic-soluble polymers have been utilized as catalyst supports. Oxazaborolidine 5, supported on linear polystyrene, was used as a soluble immobilized catalyst for the hydroboration of aromatic ketones in THF to afford chiral alcohols with an ee of up to 99% [40]. The catalyst was separated from the products with a nanofiltration membrane and then was used repeatedly. The total turnover number of the catalyst reached as high as 560. An intramolecularly cross-linked polymer molecule (microgel) was also applicable as a soluble support [41]. 

R) -1 on a preparative scale. Variation of several reaction parameters such as catalyst loading, solvent, temperature, and addition order, have led to the development of an optimized procedure for this reduction. To achieve a selectivity of >90% ee, the reaction requires the use of 10 mol% of the oxazaborolidine catalyst, which is easily prepared in two steps from natural proline4 or in one step from commercially available... 

D. The use of chiral oxazaborolidines as enantioselective catalysts for the reduction of prochiral ketones, imines, and oximes, the reduction of 2-pyranones to afford chiral biaryls, the addition of diethylzinc to aldehydes, the asymmetric hydroboration, the Diels-Alder reaction, and the aldol reaction has recently been reviewed.15b d The yield and enantioselectivity of reductions using stoichiometric or catalytic amounts of the oxazaborolidine-borane complex are equal to or greater than those obtained using the free oxazaborolidine.13 The above procedure demonstrates the catalytic use of the oxazaborolidine-borane complex for the enantioselective reduction of 1-indanone. The enantiomeric purity of the crude product is 97.8%. A... 

The same reaction has also been catalyzed by chiral oxazaborolidinones derived from amino acids and boranes. They proved to be efficient catalysts for enantioselec-tive Diels-Alder reaction [91,92]. The polymer-supported chiral oxazaborolidinones 75 were reported to be efficient catalysts [93]. These polymer-supported chiral oxaza-borolidinone ligands were prepared both by chemical modification and by the copolymerization shown in Sch. 5 [94]. The polymer-supported chiral ligands were then reacted with borane to give the oxazaborolidines which were used as catalysts in Diels-Alder reaction of cyclopentadiene with methacrolein. 

Price, M. D., Sui, J. K., Kurth, M. J., Schore, N. E. Oxazaborolidines as Functional Monomers Ketone Reduction Using Polymer-Supported Corey, Bakshi, and Shibata Catalysts. J. Org. Chem. 2002, 67, 8086-8089. 

Nevalainen, V. Quantum chemical modeling of chiral catalysis. Part 17. On the diborane derivatives of chiral oxazaborolidines used as catalysts in the enantioselective reduction of ketones. Tetrahedron Asymmetry 1994, 5, 395-402. 

Linear polymers carrying chiral oxazaborolidine as a pendant group were prepared from a methylhydrosiloxane-dimethylsiloxane copolymer [72]. Borane reduction using the polymeric oxazaborolidine 25 gave (i )-phenylethylalcohol of 97% ee which is as high as in analogous reaction with non-polymeric catalyst. This chiral polymer can be retained by a nanofiltration membrane thus will be suitable for use in a continuously operated membrane reactor. 

Additional catalysts have also been proposed for the reaction of Et2Zn with aromatic aldehydes, including (proline derivative 2.13 (R = CPh2OH) [110] and a four-membered analog [646], (1S,2R)-1.61 (R = S02Tol), 2.47, and pyridine-derived aminoalcohols [110, 644, 651, 1173]. Other catalysts include sulfur derivatives of ephedra alkaloids [645, 728], the Li diamide of piperazine 2.46, diamines 1.64 (R = 2-Py) and other related 2-aminopyridines [367, 648, 649, 1174], p-Hydroxysulfoximines have also been used as catalysts in these reactions [1175], as has an oxazaborolidine derived from ephedrine [1176],... 

During the last decade, use of oxazaborolidines and dioxaborolidines in enantioselective catalysis has gained importance. [1, 2] One of the earliest examples of oxazaborolidines as an enantioselective catalyst in the reduction of ketones/ketoxime ethers to secondary alco-hols/amines was reported by Itsuno et al. [3] in which (5 )-valinol was used as a chiral ligand. Since then, a number of other oxazaborolidines and dioxaborolidines have been investigated as enantioselective catalysts in a number of organic transformations viz a) reduction of ketones to alcohols, b) addition of dialkyl zinc to aldehydes, c) asymmetric allylation of aldehydes, d) Diels-Alder cycloaddition reactions, e) Mukaiyama Michael type of aldol condensations, f) cyclopropana-tion reaction of olefins. 

Corey et al. [4] have investigated enantioselective reduction of ketones with THF-BHa and (5 )-diphenyl prolinol-borane adduct as catalyst. They further introduced modification of oxazaborolidines in which R = CH3, n-butyl as catalyst 1 and used along with other boranes as reducing agents (Scheme 1). The catalysts 1 are known as CBS catalysts and... 

Chiral oxazaborolidines 20 derived from various amino alcohols have been used as catalysts in asymmetric 1,3-dipolar cycloaddition reaction of nitrones with ketene acetals to give substituted isoxazoles in high yield and stereoselectivity but in moderate enantioselectivity (upto 62% ee). This method has also been used for the synthesis of 0-aminoesters... 

Oxazaborolidines of the general type (8.01) were reported by Yamamoto and by Helmchen to give good asymmetric induction as catalysts in Diels-Alder... 

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