Titanium catalysts diastereoselectivity

Diels-Alder reaction of 2-bromoacrolein and cyclopentadiene using 10 mol% of titanium catalyst 74 gave the synthetically versatile (R)-bromoaldehyde adduct 75 in 94% yield, 67 1 exo. endo diastereoselectivity, and 93% ee. The absolute stereochemical outcome of the reaction is consistent with the proposed transition state assembly 76 in which the dienophile coordinates at the axial site of the metal, proximal to the indane moiety through Ji-attractive interactions. In this complex, the 7t-basic indole and the Ji-acidic dienophile can assume a parallel orientation facilitated by the octahedral geometry of the transition metal. The aldehyde would then react through a preferential s-cis conformation (Scheme 17.27).54... 

Epoxidation of allylic alcohols with peracids or hydroperoxide such as f-BuOaH in the presence of a transition metal catalyst is a useful procedure for the synthesis of epoxides, particularly stereoselective synthesis [587-590]. As the transition metal catalyst, molybdenum and vanadium complexes are well studied and, accordingly, are the most popular [587-590], (Achiral) titanium compounds are also known to effect this transformation, and result in stereoselectivity different from that of the aforementioned Mo- and V-derived catalysts. The stereochemistry of epoxidation by these methods has been compared for representative examples, including simple [591] and more complex trcMs-disubstituted, rrans-trisubstituted, and cis-trisubstituted allyl alcohols (Eqs (253) [592], (254) [592-594], and (255) [593]). In particular the epoxidation of trisubstituted allyl alcohols shown in Eqs (254) and (255) highlights the complementary use of the titanium-based method and other methods. More results from titanium-catalyzed diastereoselective epoxidation are summarized in Table 25. 

Ti/silica catalysts have been prepared by grafting Cp2TiCl2 on hydrophilic amorphous silica with different Ti contents under mild conditions, active for the epoxidation of cyclohexene.1937 Titanium catalysts prepared by grafting Cp2TiCl2 on Si02 are active for the diastereoselective epoxidation of hydroxy-containing unsaturated terpenes.1938... 

Chiral titanium complexes 4 and 5, which were developed as chiral catalysts for asymmetric carbonyl-ene reactions with prochiral glyoxylate esters [50], were first apphed to the catalytic asymmetric allylation of carbonyl compounds by Mikami and Nakai (Scheme 5) [9]. The titanium catalysts are prepared from (S)-binaphthol and diisopropoxytitanium dihahde (X=C1 and Br) in the presence of 4 A molecular sieves. Using these catalysts, glyoxylates are enantio- and diastereoselectively allylated with allylic trimethylsilanes or allylic tributylstan-nanes. High levels of enantioselectivity and syn selectivity are observed for (E)-crotylsilane and -stannane. The syn selective allylation reaction is believed to proceed mainly through an antiperiplanar transition state. 

Like the vanadium-based catalysts, the Sharpless AE system intrinsically favors 1,2-anti products this is because the cyclohexyl group in Scheme 8.8a occupies the position denoted by group Ra in Figure 8.2, away from the catalyst. In fact, this diastereoselectivity is somewhat amplified relative to achiral titanium catalysts. When the S allylic alcohol is used with (-f)-DIPT, a matched pair results (Scheme 8.8a). The strong enantiofacial selectivity of the L-(-f-)-DIPT catalyst clashes with the R substrate s resident chirality (this is the case shown in Figure 8.2 with Rb = cyclohexyl). In this mismatched pair, the preference of the chiral catalyst for a attack moderately exceeds that of the allylic alcohol for 1,2-anti product (Scheme 8.8b). The most important consequence is that the latter reaction is 140 times slower than the former. 

FogUa, T.A., P.E. Sonnet, A. Nunez, and R.L. Dudley, Selective Oxidations of Methyl Ricinoleate Diastereoselective Epoxidation with Titanium Catalysts, J. Am. Oil Chem. Soc. 75 601-607 (1998). 

The amount of cyclopentadiene was lowered to 2.5 equiv. by Altava et al. in a study of the DA using similar catalysts prepared by grafting and good conversion and diastereoselectivity were obtained.In most cases, the grafted polymeric titanium catalysts were nonenantioselective " compared to those obtained by copolymerisation by Seebach " " (for instance, 83d by grafting gave 0% enantiomeric excess). 

Asymmetric catalysis of Friedel-Crafts reaction with fluoral is established using chiral binaphthol-derived titanium catalysts with or without asymmetric activation to provide a practical synthetic route not only for chiral a-trifluorobenzylalcohols but so for highly enantiopure functionalized jS-trifluoroaldols through the sequential diastereoselective reactions of the resultant vinyl ethers or silyl enol ethers with electrophiles. 

The above-mentioned results indicate the additive effect of protons. Actually, a catalytic process is formed by protonation of the metal-oxygen bond instead of silylation. 2,6-Lutidine hydrochloride or 2,4,6-collidine hydrochloride serves as a proton source in the Cp2TiCl2-catalyzed pinacol coupling of aromatic aldehydes in the presence of Mn as the stoichiometric reduc-tant [30]. Considering the pKa values, pyridinium hydrochlorides are likely to be an appropriate proton source. Protonation of the titanium-bound oxygen atom permits regeneration of the active catalyst. High diastereoselectivity is attained by this fast protonation. Furthermore, pyridine derivatives can be recovered simply by acid-base extraction or distillation. 

Titanium-catalyzed cyclization/hydrosilylation of 6-hepten-2-one was proposed to occur via / -migratory insertion of the G=G bond into the titanium-carbon bond of the 77 -ketone olefin complex c/iatr-lj to form titanacycle cis-ll] (Scheme 16). cr-Bond metathesis of the Ti-O bond of cis- iij with the Si-H bond of the silane followed by G-H reductive elimination would release the silylated cyclopentanol and regenerate the Ti(0) catalyst. Under stoichiometric conditions, each of the steps that converts the enone to the titanacycle is reversible, leading to selective formation of the more stable m-fused metallacycle." For this reason, the diastereoselective cyclization of 6-hepten-2-one under catalytic conditions was proposed to occur via non-selective, reversible formation of 77 -ketotitanium olefin complexes chair-1) and boat-1), followed by preferential cyclization of chair-1) to form cis-11) (Scheme 16). 

The Diels-Alder reaction is one of the most fundamental means of preparing cyclic compounds. Since discovery of the accelerating effect of Lewis acids on the Diels-Alder reaction of a,)3-unsaturated carbonyl compounds [341-344], its broad and fine application under mild reaction conditions has been amplified. Equations (140) [341] and (141) [345], respectively, illustrate typical dramatic effects from an early reaction and from one reported more recently. Lewis acid-promoted Diels-Alder reactions have been reviewed [7,8,346-353]. In addition to the acceleration of the reaction, other important feature is its alteration of chemo-, regio-, and diastereoselectivity this will be discussed below. The titanium compounds used in Diels-Alder reaction are titanium halides (TiX4), alkoxides (Ti(OR)4), or their mixed salts (TiX (OR)4 n = 1-3). A cyclopentadienyl complex such as Cp2Ti(OTf)2 is also documented as a very effective promoter of a Diels-Alder reaction [354], In addition to these titanium salts, a few compounds such as those in Eq. (142) [355] have recently been reported to effect the Diels-Alder reaction. The third, [(/-PrO)2Ti(bpy)(OTf)(i-PrOH)] (OTf), was estimated to be a more active catalyst than Cp2Ti(OTf)2. 

We have found that the BINOL-derived titanium complex serves as an efficient catalyst for the Mukaiyama-type aldol reaction of ketone silyl enol ethers with good control of both absolute and relative stereochemistry (Sch. 31) [90], Surprisingly, however, the aldol products were obtained in the silyl enol ether (ene product) form, with high syn diastereoselectivity from either geometrical isomer of the starting silyl enol ethers. 

---