Imines hydrophosphonylation

Because organophosphorus compounds are important in the chemical industry and in biology, many methods have been developed for their synthesis [1]. This chapter reviews the formation of phosphorus-carbon (P-C) bonds by the metal-catalyzed addition of phosphorus-hydrogen (P-H) bonds to unsaturated substrates, such as alkenes, alkynes, aldehydes, and imines. Section 5.2 covers reactions of P(lll) substrates (hydrophosphination), and Section 5.3 describes P(V) chemistry (hydrophosphorylation, hydrophosphinylation, hydrophosphonylation). Scheme 5-1 shows some examples of these catalytic reactions. 

Shibasaki reported the first catalytic asymmetric hydrophosphonylation of imines in 1995 (Scheme 5-45) using heterobimetallic LLB-type catalysts. 

Scheme 5-47 Asymmetric hydrophosphonylation of a cyclic imine catalyzed by heterobimetallic rare earth/alkali metal/BI-NOL complexes or by chiral titanium alkoxide complexes...

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. 

Groeger, H., Saida, Y., Arai, S., Martens, J., Sasai, H., and Shibasaki, M., First catalytic asymmetric hydrophosphonylation of cyclic imines highly efficient enantioselective approach to a 4-thiazolidinylphosphonate via chiral titanium and lanthanoid catalysts,Tetrahedron Lett., 37, 9291, 1996. 

Meanwhile, chiral (thio)urea catalysts have been employed for a variety of imine addition reactions consisting of Mannich, aza-Henry, Pictet-Spengler, and hydrophosphonylation reactions. ... 

Based on prior results where Ricci used Cinchona alkaloids as phase-transfer-catalysts, the group proceeded to look at hydrophosphonylation of imines [48], Employing the chiral tertiary amine as a Brpnsted base, a-amino phosphonates products were synthesized in high yields and good selectivities. 

Jacobsen et al. found that cyclohexane-diamine bifunctional catalyst 216 promoted the enantioselective hydrophosphonylation of A-benzyl imines [110]. Using a modified... 

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 asymmetric catalytic hydrophosphonylation is an attractive approach for the synthesis of optically active a-amino phosphonates [84]. The first example of this type of reaction was reported by the Shibasaki group in 1995 using heterobimetal-lie lanthanoid catalysts for the hydrophosphonylation of acyclic imines [85a]. This concept has been extended to the asymmetric synthesis of cyclic a-amino phosphonates [85b—d]. Very recently, the Jacobsen group developed the first organocatalytic asymmetric hydrophosphonylation of imines [86], In the presence of 10 mol% of thiourea-type organocatalyst 71, the reaction proceeds under formation of a-amino phosphonates 72 in high yield (up to 93%) and with enantioselectivity of up to 99% ee [86], A selected example is shown in Scheme 5.42. Di-o-nitrobenzyl phosphite 70 turned out to be the preferred nucleophile. 

Hydrocyanation of imines [5.1] Mannich reaction [5.2] Hydrophosphonylation of imines [5.5]... 

A BINOL-derived phosphoric acid derivative has been used as a catalyst in the enantioselective synthesis of a-amino phosphonates via hydrophosphonylation of imines with diisopropyl phosphite.82... 

I. Catalytic, asymmetric hydrophosphonylation of imines promoted by the lanthanoid-potassium-BINOL catalyst (LnPB)... 

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... 

The proposed mechanism for this catalytic asymmetric hydrophosphonylation is shown in Figure 35. The first step of this reaction is the deprotonation of dimethyl phosphite by LPB to generate potassium dimethyl phosphite. This potassium phosphite immediately coordinates to a lanthanoid to give I due to the strong oxophilicity of lanthanoid metals. The complex I then reacts (in the stereochemistry-determining step) with an imine to give the potassium salt of the a-aminophosphonate. A proton-exchange reaction affords the product... 

The hydrophosphonylation of cyclic imines (thiazolines) has also been reported.69 Representative results are shown in Table 14. For example, reaction of 150 with dimethyl phosphite in the presence of 20 mol % of LPB gave 151 in only modest yield (53%) and enantioselectivity (Table 14, entry 1). The rate of the... 

Figure 35. Proposed catalytic cycle for hydrophosphonylation of imines.

Table 6.27 Thiourea-catalyzed hydrophosphonylations of N-benzyl imines.

Scheme 6.11 Phosphoric acid-catalyzed hydrophosphonylations of imines.

Discussion Catalyst 52 is prepared from Boc-(L)-ter -leucine in five steps, with a 75% overall yield [41]. Details of imine and phosphite preparation are also provided by Jacobsen and co-workers [81]. The hydrophosphonylation reactions as reported by Jacobsen can be carried out without any special precautions, in unpurified commercial diethyl ether (Et20) and under an ambient atmosphere. A reduction in temperature was shown to have a beneficial effect on product enantiopurities, but with a decrease in reaction rates. Unbranched aliphatic aldehydes were incompatible with the reaction conditions as reported, due to their rapid decomposition prior to phosphonylation. Although phosphite ester groups that are more electron-withdrawing than o-nitrobenzyl significantly increase the overall reaction rates, products are obtained with diminished optical purities, possibly due to a retro-addition pathway. 

Akiyama T, Morita H, Itoh J, Fuchibe K (2005a) Chiral Brpnsted acid catalyzed enantioselective hydrophosphonylation of imines asymmetric synthesis of alpha-amino phosphonates. Qrg Lett 7 2583-2585 Akiyama T, Saitoh Y, Morita H, Fuchibe K (2005b) Enantioselective Mannich-type reaction catalyzed by a chiral Bronsted acid derived from TADDOL. Adv Synth Catal 347 1523-1526... 

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