TADDOL-derived catalyst, enantioselective

Titanium-TADDOL derived catalyst enantioselective cyclopropanation of cinnamyl alcohol37... 

The diamine and TADDOL-derived catalysts 44 were tested on substrates 36-39, giving good enantioselectivities however, high catalyst loadings of 4 mol% were required for full conversion [34]. 

The tartrate (or TADDOL) derived approach to catalyst design has also been applied to the enantioselective a-hydroxylation of p-ketoesters. In this case, an enantiospecihc titanium(IV) complex combines with a sulfonyloxaziridine as the... 

So far, few data are available which allow the comparison of differences in efficacy and selectivity of one catalytic system attached to different supports. As far as the TADDOLate complexes are concerned, no clear rules can be drawn. Polystyrene-based catalysts derived from (8) and (10) show similar enantioselectivities and reaction rates. Differences appear, however, when comparing them with a polystyrene-embedded dendritic ligand system, generated by co-polymerization from TADDOL-derivative (32) (Scheme 4.18) which is described in Section 4.3.2.1. Re-cydabihty seems to be easier for the dendritic catalyst and the enantioselectivity. 

Lewis acid-promoted asymmetric addition of dialkylzincs to aldehydes is also an acceptable procedure for the preparation of chiral secondary alcohol. Various chiral titanium complexes are highly enantioselective catalysts [4]. C2-Symmet-ric disulfonamide, chiral diol (TADDOL) derived from tartaric acid, and chiral thiophosphoramidate are efficient chiral ligands. C2-Symmetric chiral diol 10, readily prepared from 1-indene by Brown s asymmetric hydroboration, is also a good chiral source (Scheme 2) [17], Even a simple a-hydroxycarboxylic acid 11 can achieve a good enantioselectivity [18]. 

A TADDOL derivative (49, Ar = 1-naphthyl) is a potent diastereo- and enantioselective catalyst an X-ray structure of a complex of (49) with an aldehyde indicates (i) an intramolecular hydrogen bond in the catalyst and (ii) a hydrogen bond from catalyst to aldehyde.135 It is therefore proposed that the asymmetric activation of the aldehyde arises from hydrogen bonding to a pre-organized catalyst. 

Highly porous silica gel served as a support for the TADDOL moiety derived from inexpensive and readily available i-tartaric acid, which provided access to htanium-based Lewis acid catalysts (Heckel, 2000). Such entihes are employed successfully for enantioselective reactions. TADDOLs were covalently attached to the trimethyl-silyl-hydrophobized silica gel, controlled-pore glass (CPG) at about 300 m2 g-1, at a loading of 0.3-0.4 mmol gl (Heckel, 2002). In a carefully monitored mulh-step immobilization procedure, the TADDOLs were titanated to yield dichloro-, diisopropyl-, or ditosyl-TADDOLates. These catalysts were employed in dialkylzinc addihon to benzaldehydes and diphenyl nitrone addihon to 3-crotonyloxazolidinone, a [3+2] cycloaddition. 

Enantioselective carbonyl addition of dialkylzinc reagents to aldehydes is one of the most important and fundamental asymmetric reactions [2,15]. Several chiral titanium complexes have been developed to accelerate this type of reaction (Sch. 3) [16,18-26] since Ohno and Kobayashi achieved high enantioselectivity in the presence of Ti(OPr )4 and chiral disulfonylamide [16,17]. Seebach has also demonstrated that TADDOL-derived titanium complexes function as efficient asymmetric catalysts [18]. 

Narasaka reported that TADDOL-TiCl2 was able to catalyze asymmetric DA reaction of cyclopentadiene with oxazolidinone derivatives of acrylates in the presence of 4A MS [148]. A remarkable solvent effect on the enantioselectivity was observed, and high enantioselectivity was attained using mesitylene as the solvent. Cycloadditions to oxazolidinone derivatives of acrylates were also efficiently catalyzed by dendritic or polymer-supported TADDOL-Ti catalysts [149]. From the structural determination of the 3-(( )-3-cinnamoyl)-l,3-oxazolidin-2-one adduct, it can be deduced that the transition state involves binding of the dienophile to the titanium catalyst via the N-acyl-oxazolidinone [19a] (Scheme 14.59). The diastereo-and enantioselectivity of this type of catalyst are thus probably owing to both electronic and steric effects from TADDOL ligand. 

Catalytic enantioselective nitrone cycloadditions were first published in 1994, by Scheeren [84] and by Jorgensen [85, 86]. Jorgensen reported that the TADDOL-derived titanium catalyst 92 [87] promoted the cycloaddition re-... 

In a more recent study on 1,3-dipolar cycloaddition reactions the use of succi-nimide instead of the oxazolidinone auxiliary was introduced (Scheme 6.19) [58]. The succinimide derivatives 24a,b are more reactive towards the 1,3-dipolar cycloaddition reaction with nitrone la and the reaction proceeds in the absence of a catalyst. In the presence of TiCl2-TADDOLate catalyst 23a (5 mol%) the reaction of la with 24a proceeds at -20 to -10 °C, and after conversion of the unstable succinimide adduct into the amide derivative, the corresponding product 25 was obtained in an endojexo ratio of <5 >95. Additionally, the enantioselectivity of the reaction of 72% ee is also an improvement compared to the analogous reaction of the oxazolidinone derivative 19. Similar improvements were obtained in reactions of other related nitrones with 24a and b. 

The BIPOLato-Ti-TADDOLato catalysts prepared by addition of BIPOL and TADDOL to Ti(0 Pr)4, catalyze methylation with an achiral methyltitanium reagent to give highly enantiomerically pure methylcarbinol. Since the sterically bulky 3,3 -substituents leads to an increase in enantioselectivity, the chirality of BlPOLato-Ti(0 Pr)2 catalyst 30 can be dynamically controlled by the chiral TADDOL moiety (Scheme 8.25). 3,3 -Dimethoxy derivative affords complete enantioselectivity (100% ee), while the moderate enantioselectivity is obtained with the parent BIPOL (73% ee). 

The Rawal group next applied diol catalysis to the enantioselective vinylogous Mukaiyama aldol (VMA) reaction of electron-deficient aldehydes [105]. Screening of various known chiral diol derivatives, including VANOL, VAPOL, BINOL, BAMOL, and TADDOL, revealed that 38a was the only catalyst capable of providing products in acceptable levels ofenantioselection (Scheme 5.55). Subsequent to this work, Scettri reported a similar study of TADDOL-promoted VMA reactions with Chan s diene [106]. 

Essentially concurrently, the C2-symmetric ketone catalysts 8-10 were reported . In regard to the enantioselectivity, the TADDOL (o ,Q ,Q , Q -tetraaryl-l,3- oxolane-4,5-dimethanol)-derived ketone 10 performs better than the binaphthalene-based ketone 6, but not as well as the fructose-modified ketone 7, whereas 10 is more resistant than 7 in regard to oxidative degradation. ... 

Seebach et al. (350), who first developed the TADDOL ligands, have also developed a number of polymer- and dendrimer-bound TiCl2-TADDOLate catalysts derived from the monomeric TADDOLs (361). The use of catalysts derived from polymers and dendrimers of 249 and 250, respectively, in the reactions between the nitrone 225a and the alkene 241a led to endo/exo-ratios of between 18 82 and 8 92, and enantioselectivities of up to 56% ee (Scheme 12.78). The enantioselectivities are thus slightly decreased compared to the similar reactions of... 

Currently, this area is not as well developed as the use of cinchona alkaloid derivatives or spiro-ammonium salts as asymmetric phase-transfer catalysts, and the key requirements for an effective catalyst are only just becoming apparent. As a result, the enantioselectivities observed using these catalysts rarely compete with those obtainable by ammonium ion-derived phase-transfer catalysts. Nevertheless, the ease with which large numbers of analogues - of Taddol, Nobin, and salen in particular- can be prepared, and the almost infinite variety for the preparation of new, chiral metal(ligand) complexes, bodes well for the future development of more enantioselective versions of these catalysts. 

A related approach has recently been reported by Belokon and Kagan et al. These workers used chiral TADDOL-type diols, derived from tartaric acid and 2-amino-2 -hydroxy-1,1 -binaphthyl (NOBIN), as catalysts to obtain yields of up to 95% and enantioselectivity up to 93% ee [59-61], The catalytically active species seem to be the sodium salts of the diols. 

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]. 

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