Titanium-Binol catalyst asymmetric reactions

This explanation is described as a mnemonic rule [228], which can only be taken as a first approximation of reality. The same rule can be used to rationalize the topicity of other asymmetric Diels-Alder reactions, such as those employing titanium BINOLate catalysts (Figure 6.18i, [230]), or iron bisoxazoline catalysts (Figure 6.18j,k [206,215]). Although the explanation seems reasonable, the picture is not complete, since it does not account for a number of observations, including the fact that the dioxolane substituents exert an extraordinary effect on catalyst efficiency (c/ Table 6.6, entries 2 and 5). Additionally, both titanium TADDOLate [228] and BINOLate [230] complexes show a nonlinear relationship between enantiomeric purity of the catalyst and that of the product, which suggests that some sort of dimerization phenomenon is involved. 

The catalytic asymmetric Michael reaction using silyl enol esters (Mukaiyama-Michael reaction) as the pronucleophiles has been reported using a titanium/BINOL catalyst (in up to 90% ee). Considering furan (11.36) as a silyl enol ether, this has been shown to undergo nucleophilic addition to the Michael acceptor (11.37). The product (11.38) canbe obtained with excellent diastereocon-trol with the scandium complex of hgand (11.39), or with excellent enantiocontrol... 

With environmental consideration in mind, the group has developed a version in concentrated media, i.e. without dichloromethane and only three equivalents of isopropanol. ° For instance, the ketone 64 was converted into the alcohol 65 in 93% yield and 95% enantiomeric excess using only 10 mol% of titanium-BINOL catalyst (Conditions B, Scheme 7.36). A slight decrease of efficiency was observed using 5 mol% of catalyst (Conditions C). The efficiency of the method was illustrated by a tandem asymmetric ally-lation/diastereoselective epoxidation reaction of cyclic enones that is based on the use of the allylation catalyst for a subsequent epoxidation with TBHP, as illustrated in Scheme 7.37. ° ... 

The activation of a racemic catalyst by a chiral additive was achieved by Mikami in a chiral titanium complex-catalyzed asymmetric carbonyl-ene reaction (Scheme 9.21) [39], The racemic catalyst ( )-BINOL-Ti-(0-i-Pr)2 37 (10 mol %) is activated by adding (R)-BINOL (5 mol %), and the ene product 38 with 90% ee is obtained. (R)-BINOL is selectively associated with (/f)-BIN0L-Ti-(0-i-Pr)2 to give a dimeric catalyst whose activity is kinetically calculated to be 25.6 times greater than that of the remaining (S)-BIN0L-Ti-(0-i-Pr)2. 

Two other types of catalysts have been investigated for the enantioselective Strecker-type reactions. Chiral N-oxide catalyst 24 has been utilized in the trimethylsilyl cyanide promoted addition to aldimines to afford the corresponding aminonitriles with enantioselectivities up to 73% ee [14]. Electron-deficient aldimines were the best substrates, but unfortunately an equimolar amount of catalyst 24 was used in these reactions. The asymmetric Strecker addition of trimethylsilyl cyanide to a ketimine with titanium-based BINOL catalyst 25 gave fast conversions to quarternary aminonitriles with enantiomeric excesses to 59%... 

Immobilization of chiral ligands to effect asymmetric induction in alkylation of aromatic aldehydes by diorganozinc reagents promoted by PEG-im-mobilized ligands 54-57 can also be promoted by soluble polystyrene-bound species. A recent example of this is work where a polystyrene-bound BINOL was prepared [ 105]. This polymer 69 was used to form titanium-BINOLate and AlLibis(binaphthoxide) catalysts for Et2Zn reaction with benzaldehyde and for asymmetric Michael additions of stabilized carbanions to cyclohexenone. While good stereoselectivities were obtained with these catalysts, the synthetic yields were modest. 

The use of ionic liquids to perform asymmetric sulfoxidation reactions was proposed by Halligudi and coworkers. A chiral titanium-BINOL complex was immobilised onto ionic liquid-modified mesoporous silica (SBA-15) support 14 and the resulting heterogeneous catalyst was successfully employed in asymmetric sulfoxidation of thioanisole using TBHP as... 

Z. Wang and K. Ding Asymmetric ring-opening aminolysis of 4,4-di-methyl-3,5,8-trioxabicyclo[5.1. OJoctane catalyzed by titanium/BINOLate/water system evidence for the Ti(BINOLate)2-bearing active catalyst entities was obtained and the role of water for ihe reaction was examined. [258]... 

The reactions of nitrones constitute the absolute majority of metal-catalyzed asymmetric 1,3-dipolar cycloaddition reactions. Boron, aluminum, titanium, copper and palladium catalysts have been tested for the inverse electron-demand 1,3-dipolar cycloaddition reaction of nitrones with electron-rich alkenes. Fair enantioselectivities of up to 79% ee were obtained with oxazaborolidinone catalysts. However, the AlMe-3,3 -Ar-BINOL complexes proved to be superior for reactions of both acyclic and cyclic nitrones and more than >99% ee was obtained in some reactions. The Cu(OTf)2-BOX catalyst was efficient for reactions of the glyoxylate-derived nitrones with vinyl ethers and enantioselectivities of up to 93% ee were obtained. 

Mikami and co-workers16-19 have done extensive work for developing catalysts for the asymmetric carbonyl-ene reaction. Excellent enantioselectivites are accessible with the binol-titanium catalyst 17 (Equation (10)) for the condensation of 2-methyl butadiene (R1 = vinyl) and glyoxalates (binol = l,T-binaphthalene-2,2 -diol).16 The products were further manipulated toward the total synthesis of (i )-(-)-ipsdienol. The oxo-titanium species 18 also provides excellent enantioselectivity in the coupling of a-methyl styrene with methyl glyoxalate.17 Reasonable yields and good enantioselectivites are also obtained when the catalyst 19 is formed in situ from titanium isopropoxide and the binol and biphenol derivatives.18... 

The self-assembly of a chiral Ti catalyst can be achieved by using the achiral precursor Ti(OPr )4 and two different chiral diol components, (R)-BINOL and (R,R)-TADDOL, in a molar ratio of 1 1 1. The components of less basic (R)-BINOL and the relatively more basic (R,R)-TADDOL assemble with Ti(OPr )4 in a molar ratio of 1 1 1, yielding chiral titanium catalyst 118 in the reaction system. In the asymmetric catalysis of the carbonyl-ene reaction, 118 is not only the most enantioselective catalyst but also the most stable and the exclusively formed species in the reaction system. 

Mikami et al. reported the first examples of catalytic asymmetric intramolecular carbonyl-ene reactions of types (3,4) and (2,4), using the BINOL-derived titanium complex (1) [46,49], The catalytic 7-(2,4) carbonyl-ene cyclization gives the corresponding oxepane with high enantiopurity, and the gem-dimethyl groups are not required (Scheme 8C.I8). In a similar catalytic 6-(3,4) ene cyclization, tran.v-tetrahydropyran is preferentially obtained with high enantiopurity (Scheme 8C. 19), The sense of asymmetric induction is the same as that observed for the glyoxylate-ene reaction, that is, (R)-BINOL-Ti catalyst provides (R)-alcohol. Therefore, the... 

Mikami reported a highly enantioselective carbonyl-ene reaction where a chiral titanium complex 11 prepared from enantiomerically pure binaphthol (BINOL) and Ti(0-i-Pr)2Br2 catalyzed a glyoxylate-ene reaction with a-methylstyrene to give chiral homoallyl alcohol 12 with 94.6% ee [22]. In this reaction, a remarkable asymmetric amplification was observed and almost the same enantioselectivity (94.4% ee) was achieved by using chiral catalyst prepared... 

Keck reported an asymmetric allylation with a catalytic amount of chiral titanium catalyst [24]. The enantioselective addition of methallylstannane to aldehydes is promoted by a chiral catalyst 13 prepared from chiral BINOL and Ti(0-i-Pr)4 (Scheme 9.10). An example of asymmetric amplification was reported by using (R)-BINOL of 50% ee, and the degree of asymmetric amplification was dependent on the reaction temperature. Tagliavini also observed an asymmetric amplification in the enantioselective allylation with a BIN0L-Zr(0-i-Pr)2 catalyst [25]. 

A Et2Zn-(5, S)-linked-BINOL (21) complex has been found suitable for chemos-elective enolate formation from a hydroxy ketone in the presence of isomerizable aliphatic iV-diphenylphosphinoylimines.103 The reaction proceeded smoothly and /9- alkyl-yS-amino-a-hydroxy ketones were obtained in good yield and high enantioselectivity (up to 99% ee). A titanium complex derived from 3-(3,5-diphenylphenyl)-BINOL (22) has exhibited an enhanced catalytic activity in the asymmetric alkylation of aldehydes, allowing the reduction of the catalyst amount to less than 1 mol% without deterioration in enantioselectivity.104... 

This was one of the first classes of catalyzed reactions that were shown to give rise to strong asymmetric amplifications (vide supra, Scheme 9).33 Many subsequent studies have been performed with variations in the structure of the chiral catalyst, generated from BINOL and titanium salts.50-52 Asymmetric amplification is frequently observed with these catalysts in the glyoxylate-ene reaction (Table 5). 

Keck also investigated asymmetric catalysis with a BINOL-derived titanium complex [102,103] for the Mukaiyama aldol reaction. The reaction of a-benzyloxyalde-hyde with Danishefsky s dienes as functionalized silyl enol ethers gave aldol products instead of hetero Diels-Alder cycloadducts (Sch. 40) [103], The aldol product can be transformed into hetero Diels-Alder type adducts by acid-catalyzed cyclization. The catalyst was prepared from BINOL and Ti(OPr )4, in 1 1 or 2 1 stoichiometry, and oven-dried MS 4A, in ether under reflux. They reported the catalyst to be of BINOL-Ti(OPr% structure. 

Narasaka has demonstrated that TADDOL-Ti dichloride prepared from TADDOL and Cl2Ti(OPr )2 in the presence of MS 4A acts as an efficient catalyst in asymmetric catalytic Diels-Alder reactions with oxazolidinone derivatives of acrylates, a results in extremely high enantioselectivity (Sch. 45) [112]. Narasaka reported an intramolecular version of the Diels-Alder reaction, the product of which can be transformed into key intermediates for the syntheses of dihydrocompactin and dihydromevinolin (Sch. 46) [113]. Seebach and Chapuis/Jurczak [114] independently reported asymmetric Diels-Alder reactions promoted by chiral TADDOL- and 3,3 -diphenyl BINOL-derived titanium alkoxides. Other types of chiral diol ligands were also explored by Hermann [115] and Oh [116]. 

The Diels-Alder reaction of methacrolein with 1,3-dienol derivatives can also be catalyzed by the BINOL-derived titanium complex, although the catalyst must be freed from molecular sieves (MS) to give the endo adduct with high enantioselectivity (Sch. 50) [131], because MS act as achiral catalysts in the Diels-Alder reaction. The asymmetric Diels-Alder reaction catalyzed by the MS-free (MS-(-)) BINOL-Ti complex (L) can be applied naphthoquinone derivatives as dienophiles to provide entry to the asymmetric synthesis of tetra- and anthracyclinone [132] aglycones (Sch. 51). The sense of asymmetric induction is exactly the same as that observed in the presence of MS in the asymmetric catalytic reactions described above. 

In the Diels-Alder reaction of glyoxylates with the Danishefsky diene (Sch. 53), asymmetric activation of (f )-BINOL-Ti(OPr )2 (2) by (/ )-BINOL is essential if enantioselectivity is to be higher than that achieved by use of the enantio-pure BINOL-Ti catalyst (5 % ee) [78], Effects of the torsional angles of 2,2 -biaryldiol ligands have been examined in the asymmetric Diels-Alder reaction of acrylate catalyzed by titanium complexes [133]. 

As shown above, asymmetric catalysis of Diels-Alder reactions has been achieved by use of chiral titanium complexes bearing chiral diol ligands. Yamamoto has reported a chiral helical titanium complex derived from Ti(OPr )4 and a BINOL-derived tetraol ligand (Sch. 54) [134], The Diels-Alder products are obtained with uniformly high enantioselectivity, irrespective of the substituent pattern of a,/3-unsaturated aldehydes. Corey has also reported a new type of chiral titanium complex derived from an amino alcohol ligand (Sch. 55) [135]. The chiral titanium complex serves as an efficient asymmetric catalyst for the reaction of 2-bromoacrolein the Diels-Alder product is obtained with high enantioselectivity. 

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