Asymmetric hydrophosphonylation aldehydes

Scheme 5-32 Titanium alkoxide-catalyzed asymmetric hydrophosphonylation of aldehydes...

An improved preparation of Shibasaki s LLB catalyst allowed higher asymmetric induction in the chemistry shown in Scheme 5-28. The new recipe involved mixing LaCl3 7H20 (1 equiv.), BINOL-dilithium salt (2.7 equiv.) and NaOt-Bu (0.3 equiv.) in THF at 50°C. This catalyst allowed asymmetric hydrophosphonylation of aldehydes in high yields and up to 95% ee (Scheme 5-33, Eq. 1), and gave better results for aliphatic aldehydes than a related aluminum catalyst (ALB, see Scheme 5-37 below). 

Scheme 5-33 LLB-catalyzed asymmetric hydrophosphonylation of aldehydes and a proposed mechanism LLB = La/Li/BINOL...

In comparison to related P(III) chemistry, metal-catalyzed additions of P-H bonds in P(V) compounds to unsaturated substrates have been studied in more detail, and several synthetically useful processes have been developed. In particular, the use of heterobimetallic BINOL-based catalysts allows asymmetric hydrophosphonylation of aldehydes and imines in high yield and enantiomeric excess. 

Akiyama et al. disclosed an asymmetric hydrophosphonylation in 2005 (Scheme 32) [55], Addition of diisopropyl phosphite (85a) to A-arylated aldimines 86 in the presence of BINOL phosphate (R)-M (10 mol%, R = 3,5-(CF3)j-C Hj) afforded a-amino phosphonates 87 in good yields (72-97%). The enantioselectivities were satisfactory (81-90% ee) in the case of imines derived from a,(3-unsaturated aldehydes and moderate (52-77% ee) for aromatic substrates. 

The second part of the chapter deals with several kinds of asymmetric reactions catalyzed by unique heterobimetallic complexes. These reagents are lanthanoid-alkali metal hybrids which form BINOL derivative complexes (LnMB, where Ln = lanthanoid, M = alkali metal, and B = BINOL derivative). These complexes efficiently promote asymmetric aldol-type reactions as well as asymmetric hydrophosphonylations of aldehydes (catalyzed by LnLB, where L = lithium), asymmetric Michael reactions (catalyzed by LnSB, where S = sodium), and asymmetric hydrophosphonylations of imines (catalyzed by LnPB, where P = potassium) to give the corresponding desired products in up to 98% ee. Spectroscopic analysis and computer simulations of these asymmetric reactions have revealed the synergistic cooperation of the two different metals in the complexes. These complexes are believed to function as both Brpnsted bases and as Lewis acids may prove to be applicable to a variety of new asymmetric catalytic reactions.1,2... 

Scheme 20. LLB-catalyzed asymmetric hydrophosphonylation of heteroaromatic aldehydes.

In conclusion, chiral heterobimetallic lanthanoid compexes LnMB, which were recently developed by Shibasaki et al., are highly efficient catalysts in stereoselective synthesis. This new and innovative type of chiral catalyst contains a Lewis acid as well as a Bronsted base moiety and shows a similar mechanistic effect as observed in enzyme chemistry. A broad variety of asymmetric transformations were carried out using this catalysts, including asymmetric C-C bond formations like the nitroaldol reaction, direct aldol reaction, Michael addition and Diels-Alder reaction, as well as C-0 bond formations (epoxidation of enones). Thereupon, asymmetric C-P bond formation can also be realized as has been successfully shown in case of the asymmetric hydrophosphonylation of aldehydes and imines. It is noteworthy that all above-mentioned reactions proceed with high stereoselectivity, resulting in the formation of the desired optically active products in high to excellent optical purity. 

A logical extension of these themes is for one catalyst to activate both the P-nucleophile and the unsaturated electrophile. This approach has been especially popular in asymmetric hydrophosphonylation of aldehydes and imines, which has been reviewed recently [59]. 

Some of the metal-based catalysts used in the asymmetric hydrophosphonylation of aldehydes (see Section 6.4) can also be applied to the phosphonylation of imines. For instance, Shibasaki s heterobimetallic BINOL complexes work well for the catalytic asymmetric hydrophosphonylation of imines. In this case lanthanum-potassium-BINOL complexes (6.138) have been found to provide the highest enantioselectivities for the hydrophosphonylation of acyclic imines (6.139). The hydrophosphonylation of cyclic imines using heterobimetallic lanthanoid complexes has been reported. Ytterbium and samarium complexes in combination with cyclic phosphites have shown the best results in the cases investigated so far. For example, 3-thiazoline (6.140) is converted into the phosphonate (6.141) with 99% ee using ytterbium complex (6.142) and dimethyl phosphite (6.108). The aluminium(salalen) complex (6.110) developed by Katsuki and coworkers also functions as an effective catalyst for the hydrophosphonylation of both aromatic and aliphatic aldimines providing the resulting a-aminophosphonate with 81-91% ee. ... 

The asymmetric hydrophosphonylation of aldehydes has been achieved using a catalyst based upon a triaminoiminophosphorane (Scheme 4.155) [245]. This was an interesting approach to this chemistry and generated the a-hydroxyphosphonates in excellent yields with high enantioselectivity. In addition to the hydrophosphonylation chemistry, the authors also investigated how readily common bases deprotonated phosphites in order to provide... 

Under optimized reaction conditions, the asymmetric hydrophosphonylation of aldehydes with corresponding cyclic phosphonates M18-2 could be achieved in good yields with excellent enantioselectivities. On the basis of optimization, a series... 

Davies SR, Mitchell MC., Cain CP, Devitt PG, Taylor RJ, Kee TP. Phospho-transfer catalysis on the asymmetric hydrophosphonylation of aldehydes. J. Org. Chem. 1998 550 29-57. 

Gou S, Zhou X, Wang J, Liu X, Feng X (2008) Asymmetric hydrophosphonylation of aldehydes catalyzed by bifunctional chiral Al(III) Complexes. Tetrahedron 64 2864-2870... 

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