Prolinol catalysts derivatives

Activity of these supported Lewis acids was again assayed for the Diels-AIder reaction between methacrolein and cyclopentadiene and results were compared with those obtained for related homogeneous catalysts, such as 16 and 17, prepared from the corresponding N-benzylated aminoalcohols. Results obtained for the catalysts derived from (5)-prolinol are summarized in Table 2. 

The same method, using Co(acac)2 and the chiral diamines has also been applied to several other stabilized carbanions and enones with up to 100% yield, however, the asymmetric inductions did not exceed 40% ee59. Similarly, a catalyst derived from Ni(acac), and (+ )-(S)-2-(anili-nomethyl)pyrrolidine, (—)-(5)-prolinamide or (—)-(S)-prolinol catalyzes the conjugate addition of nitromethane to benzalacetone, chalcone and 2-cyclohexenone with up to 59% ee62,67. 

Prolinol derivatives of boron tribromide 4 give excellent results in the [4 + 2] cycloaddition of methacrolein (8a) to cyclopentadiene (exojendo ratio 99 1, 97% ee)21. Several boron catalysts derived from /V-sulfonamides of a-amino acids 7a-d have been developed. In the cycloaddition of methacrolein (8a) or croton aldehyde (8b) to cyclopentadiene these catalysts produce enan-tioselectivities ranging from medium to good8-22 23. Chiral oxazaborolidinone 6 is an excellent catalyst for the addition of 2-bromoacrolein (8e) to various dienes24 (see table overleaf)-... 

Bromomalonate, selected as the pronucleophile, is proposed to undergo deprotonation by the diaryl prolinol catalysts lej to give the corresponding reactive enolate involved in the conjugate addition with different electron-poor alkenes (Scheme 7.9). The intramolecular alleviation proceeds with more nucleophilic indandione-derived enolate, under one-pot conditions, in... 

Organocatalysts were also reported in the synthesis of azepines. In this way, a-ketoamides 8 were reacted with a,p unsaturated aldehydes 9 and a prolinol catalyst 11 to form oxobridged azepine derivatives 10 with good stereocontrol. 

E. V. Dehmlow, R. Klauck, S. Diittmann, R Neumann, H.-G. Stammler, Revisiting Optically Active Quaternary Derivatives made from Prolinol as Phase Transfer Catalysts , Tetrahedron Asymmetry 1998, 9,2235-2244. 

Kobayashi and colleagues227 prepared chiral boron reagent 355 from BBr3 and chiral prolinol derivative 354 (equation 100). This catalyst afforded the exo Diels-Alder adduct of cyclopentadiene and methacrolein with 97% cc (equation 101). In the same way, norbomene (2/J)-357 was obtained from 356 and cyclopentadiene. 

Borane reduction catalyzed by chiral oxazaborolidines (CBS reduction, CBS = Corey, Bakshi, and Shibata) exhibits excellent enantio- and chemoselectiv-ity for a wide variety of ketonic substrates (Figure 1.27). This reaction was originally developed as a stoichiometric system consisting of diphenylvalinol and borane, ° but was later extended to a useful catalytic method. Because of the high efficiency of this reaction, many chiral oxazaborolidines have been synthesized from p-amino alcohols.Among them the prolinol-derived oxazaboro-lidine is one of the most widely used catalysts. ... 

Prolinol derived catalyst 30 has also been used in the [3+2] cycloaddition of nitrones with a,P-unsaturated aldehydes (Scheme 10) [69]. Importantly, the reactions proceed at room temperature in just 24 h, showing excellent levels of cata-lystactivity, withuniformly high endo exo ratios (11.5 1-99 1) andenantioselectivity... 

Other centrally chiral amine catalysts reported for kinetic resolution of alcohols include the (S)-prolinol-derived dihydroisoindolines 12a,b (Scheme 12.4), devel-... 

In the pioneering studies of Melchiorre and Jorgensen and colleagues, a variety of pyrrolidine-derived catalysts was tested (Scheme 2.51) [40]. Whilst modest selectivity was obtained with proline, and unhindered prolinol derivatives, (S)-2-(bis(phenyl)methyl)pyrrolidine derivative, 45c, allowed good conversion and enantio selectivity in the addition of linear aldehydes to methyl-vinyl ketone (MVK) (revalues up to 85%). Cyclic enones as well as -substituted enones afforded no, or perhaps poor, results. 

In 1981, Hirao and others reported that the chiral borane-amine complex 25a, derived from (S)-prolinol and 1 equivalent of BH3 THF, enantioselec-tively reduced propiophenone to afford (R )-l -phenyl-1 -propanol (26) in 44% ee9 (Scheme 4.3h). The chiral complex 25b was even better than 25a, affording the same secondary alcohol in 60% ee. Two years after the initial disclosure, Hirao et al. uncovered a new catalyst system that improved the previous experimental conditions dramatically10 (Scheme 4.3i). When the chiral aminoalcohol 27, prepared from (S)-valine methyl ester hydrochloride and phenylmagnesium bromide, was used along with 2 equivalents of BH3 THF, the enantioselectivity of the alcohol 26 jumped to 94% ee. In addition, the reaction time was shortened to 2 hours. 

Other nucleophiles that have been used in this context are acetylides (alkynes). The addition of those to iminium cations generated in situ from aldehydes and secondary amines accomplishes a gold(III)-catalyzed three-component coupling for the synthesis of propargylamines, as can be observed in equation (124). The reactions are performed in water or in tetrahydrofuran (THF) when supported catalysts are employed.Chiral prolinol derivatives as... 

Mukaiyama and co-workers have reported that prolinol derivatives combined with BBrs produce promising catalysts for some Diels-Alder reactions [26]. Methacrolein and cyclopentadiene, for example, afford the exo adduct (exoiendo > 99 1) in 97 % ee (reaction at -78 °C in dichloromethane with 20 mol % catalyst). The chiral catalyst is believed to be the HBr adduct salt of the amino boron derivative (Eq. 26). 

Non-catalyzed aldol reactions via hypervalent silicon species have also been studied. An aldol reaction between aldehydes and silyl enol ethers of amides was reported by Myers [105]. The reaction can be conducted under mild conditions to produce anti aldol without Lewis acid or base catalysts (Sch. 62). Asymmetric induction was particularly high when the (Z)-silyl ketene A/,0-acetal derived from prolinol was used. 

The first report of a polymer-supported approach to this reaction appeared in 1987 [48]. Enantiopure amino alcohols such as ephedrine, prolinol, and 3-exo-amino-isoborneol were attached to Merrifield polymer. The use of polymer-supported 3-exo-aminoisoborneol 40 resulted in quite high enantioselectivity ( 95 % ee) in the ethylation of aldehydes with diethylzinc (Eq. 15), a result comparable with those obtained from the corresponding low-molecular-weight catalyst system (Eq. 16). A similar system was also reported in 1989, this time using ephedrine derivatives (41,42) and prolinol derivative (43) [49]. A methylene spacer was introduced between the polymer and the amino alcohol to improve activity [50]. Despite this the selectivity was always somewhat lower than that obtained from the low-molecular-weight catalyst (44). These chiral polymers were all prepared by the chemical modification method using Merrifield polymer. 

Electron-rich catalysts such as 38 are rather better than electron-poor ones. In contrast, those containing electron withdrawing groups, i.e., 39-41, are poor catalysts. A radical redesign of the catalyst structure led Wills and his coworkers to synthesize catalyst 45 derived from (S)-diphenyl prolinol [45]. In this case, upon reaction with borane, a borate ester would be formed and act as the Lewis acid site. 

Degni et al. developed a new method for the anchoring of chiral prohnol derivatives, whereby N-(4-vinylbenzyl)-a,a-diphenyl-prolinol was immobihzed on polyethylene fibers by electron beam-induced pre-irradiahon grafting using styrene as a comonomer. The chirally modified polymer fibers 2 were used as a catalyst for the asymmetric ethylation of aldehyde, with moderate enanhoselectivity [3]. 

Palomo et al. have extended the range of nucleophiles amenable in asymmetric organocatalysed Michael reactions of nitronates and malonates to oc,P-unsaturated aldehydes Inspired by the prolinol motif, they proposed a series of derivatives, among which 21 was the most efficient catalyst for the nitro-Michael reaction of Scheme 1.11 and the Michael reaction of Scheme 1.12. These reactions required the use of benzoic acid as co-catalyst to optimize results. 

Derivatives of (S)-tyrosine were supported on silica gel through the phenolic oxygen atom and treated with BH3 to give Lewis acids able to accelerate the Diels-Alder reactions of methacrolein and bromoacrolein with cyclopentadiene. (S)-Prolinol has been supported on silica gel and alumina and then treated with EtAICI2 to give a supported catalyst... 

Chiral boronales are generated m situ by reaction of binaphthols 3.7 (R = H, Ph) [231] with BH3 in the presence of acetic acid [778], with H BBr [781] or with B(OPh)3 [782, 783], Chiral borates are formed by reactions of substituted (S)-prolinol derivative 2.13 (R =- CPl OH) and BBr3 [784], These boronates and borates are valuable catalysts in asymmetric Diels-Alder reactions [73, 231, 601, 780], Tartaric acid derivatives, such as borate 3.8 and acyloxyboranes 3.9 recommended by Yamamoto and coworkers [73,601,778,780,785-791], are very efficient catalysts in asymmetric Diels-Alder reactions and in condensations of aldehydes with allylsilanes, enoxysilanes or ketene acetals. These catalysts are generated in situ from substituted monobenzoates of (RJl)- or (S -tartaric acid and BH3 (R = H) or an arylboric acid (R = Ar). The best asymmetric inductions are observed with catalysts 3.9, R = /-Pr. 1,3,2-OxazaboroMnes 3.10, prepared from a-aminoacids [44, 601, 780, 792, 793], are efficient catalysts in asymmetric Diels-Alder reactions. The catalyst generated from A -tosyltrytophan 3.11 is more efficient than borolidines 3.10 (R = Et, /-Pr). The catalysts 3.10 prepared from 3.11, 3.12 and 3.13 are also useful in asymmetric condensations of aldehydes with ketene acetals [794-797]. 

Cycloaddition reactions. Asymmetric induction in cycloaddition of enals is based on the formation of conjugated iminium salts with bulky prolinol derivatives. Reaction partners include enamides and cyclopentadiene. The Diels-Alder reaction (catalyst 3B) is exo-... 

This reduction method has a number of advantages that include wide scope, predictable absolute stereochemistry, ready availability of the chiral catalyst in both enantiomeric forms, high yields, experimental ease, recovery of the catalyst (as the amino alcohol), and low cost of goods. The most common form of the chiral oxazaborolidine is derived from prolinol and has a methyl substituent on the boron atom (B-Me-CBS) 1. When one conducts a reduction on a novel system for the first time, this catalyst provides a good compromise of cost, enantioselectivity, and experimental ease. If sufficient control is not observed with this reagent, one can then systematically evaluate the numerous variations of this framework. 

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