Titanium catalysts enolates

Scheme 2.9 gives some examples of use of enantioselective catalysts. Entries 1 to 4 are cases of the use of the oxazaborolidinone-type of catalyst with silyl enol ethers and silyl ketene acetals. Entries 5 and 6 are examples of the use of BEMOL-titanium catalysts, and Entry 7 illustrates the use of Sn(OTf)2 in conjunction with a chiral amine ligand. The enantioselectivity in each of these cases is determined entirely by the catalyst because there are no stereocenters adjacent to the reaction sites in the reactants. 

Mikami et al. [18] demonstrated that under Lewis acid catalysis silyl enol ethers, bearing at least one hydrogen atom in the allylic position, form carbonyl-ene products. They succeeded in using the titanium catalyst 32 for the asymmetric catalysis of this reaction (Scheme 11b). If the aldehyde contains an activating substituent, as in the case of the glyoxolate 62, an excess of the enecompound is not necessary. For example, the reaction of 62 with the silyl enol ether 27 to the carbonyl-ene adduct 63 still proceedes with good stereoselectivity, but yields drop to a moderate value. 

A newer approach toward the enantioselective electrophilic fluorination of jS-ketoesters is based on enolization of the substrate under neutral conditions by coordination to a chiral titanium catalyst [211]. The catalyst, a chiral titanium TADDOLato complex (TADDOL = a,a,a, a -tetraaryl-2,2-dimethyl-1,3-dioxolan-4,5-dimethanol) [212, 213], coordinates to the -ketoester, enolizes it, and thus renders it susceptible to electrophilic fluorination (Scheme 2.95). One face of the prochiral enolate substructure is covered by a bulky naphthyl substituent from the TADDOL ligand, impeding electrophilic attack of F-TEDA. 

The reaction can be applied to silyl enol esters as well. Good asymmetric induction can be achieved in the Mukaiyama aldol reaction. The reaction of silyl enol thioether 246 and nonanal, for example, gave 247 in 60% yield and in 93% ee when the (/ )-BINOL-titanium catalyst shown was used. In this work, the reaction was also done in supercritical fluoroform and in supercritical carbon dioxide. A similar reaction was reported using catalysts closely related to 244 and dichloromethane as the solvent.Chiral oxazaborolidine catalysts have also been shown to be effective for enantioselective Mukaiyama aldol reactions. 

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. 

A chiral titanium(IV) complex has also been used by Wada et al. for the intermole-cular cycloaddition of ( )-2-oxo-l-phenylsulfonyl-3-alkenes 45 with enol ethers 46 using the TADDOL-TiX2 (X=C1, Br) complexes 48 as catalysts in an enantioselective reaction giving the dihydropyrans 47 as shown in Scheme 4.32 [47]. The reaction depends on the anion of the catalyst and the best yield and enantioselectivity were found for the TADDOL-TiBr2 up to 97% ee of the dihydropyrans 47 was obtained. 

The pharmaceutical interest in the tricyclic structure of dibenz[6,/]oxepins with various side chains in position 10(11) stimulated a search for a convenient method for the introduction of functional groups into this position. It has been shown that nucleophilic attack at the carbonyl group in the 10-position of the dibenzoxepin structure renders the system susceptible to water elimination. Formally, the hydroxy group in the enol form is replaced by nucleophiles such as amines or thiols. The Lewis acids boron trifluoride-diethyl ether complex and titanium(IV) chloride have been used as catalysts. 

Summary of Facial Stereoselectivity in Aldol and Mukaiyama Reactions. The examples provided in this section show that there are several approaches to controlling the facial selectivity of aldol additions and related reactions. The E- or Z-configuration of the enolate and the open, cyclic, or chelated nature of the TS are the departure points for prediction and analysis of stereoselectivity. The Lewis acid catalyst and the donor strength of potentially chelating ligands affect the structure of the TS. Whereas dialkyl boron enolates and BF3 complexes are tetracoordinate, titanium and tin can be... 

As is the case for aldol addition, chiral auxiliaries and catalysts can be used to control stereoselectivity in conjugate addition reactions. Oxazolidinone chiral auxiliaries have been used in both the nucleophilic and electrophilic components under Lewis acid-catalyzed conditions. (V-Acyloxazolidinones can be converted to nucleophilic titanium enolates with TiCl3(0-/-Pr).320... 

Various transition metals have been used in redox processes. For example, tandem sequences of cyclization have been initiated from malonate enolates by electron-transfer-induced oxidation with ferricenium ion Cp2pe+ (51) followed by cyclization and either radical or cationic termination (Scheme 41). ° Titanium, in the form of Cp2TiPh, has been used to initiate reductive radical cyclizations to give y- and 5-cyano esters in a 5- or 6-exo manner, respectively (Scheme 42). The Ti(III) reagent coordinates both to the C=0 and CN groups and cyclization proceeds irreversibly without formation of iminyl radical intermediates.The oxidation of benzylic and allylic alcohols in a two-phase system in the presence of r-butyl hydroperoxide, a copper catalyst, and a phase-transfer catalyst has been examined. The reactions were shown to proceed via a heterolytic mechanism however, the oxidations of related active methylene compounds (without the alcohol functionality) were determined to be free-radical processes. 

BINOL-derived titanium complex was found to serve as an efficient catalyst for the Mukaiyama-type aldol reaction of ketone silyl enol ethers with good control of both absolute and relative stereochemistry (Scheme 8C.24) [57]. It is surprising, however, that the aldol products were obtained in the silyl enol ether (ene product) form, with high syn-diastereoselec-tivity from either geometrical isomer of the starting silyl enol ethers. 

This procedure illustrates a general method for the preparation of crossed aldols. The aldol reaction between various silyl enol ethers and carbonyl compounds proceeds smoothly according to the same procedure (see Table I). Sllyl enol ethers react with aldehydes at -78°C, and with ketones near 0°C. Note that the aldol reaction of sllyl enol ethers with ketones affords good yields of crossed aldols which are generally difficult to prepare using lithium or boron enolates. Lewis acids such as tin tetrachloride and boron trifluoride etherate also promote the reaction however, titanium tetrachloride is generally the most effective catalyst. 

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... 

The catalyst used was TiCU and the complex 21 cyclises in a conrotatory fashion so that the two Hs end up trans in the intermediate 22. Cyclisation to the activated para position of the benzene ring that is already attached to the bottom face of the five-membered ring gives the titanium enolate 23 and protonation puts the ethyl group in the more favourable down position, anti to the nearer methyl group.4... 

Additional advantages of the formamide condensation protocol were observed performing the reaction in the presence of catalysts which decompose formamide to formaldehyde. Formaldeyde is the most important pre-biotic precursor of sugars through a series of enolization and aldol-like condensation processes catalyzed under acidic or basic conditions, known as the formose reaction [100]. When formamide was heated at 160 °C in the presence of titanium dioxide (a catalyst able to degrade amides to aldehydes) [101] a complex mixture of nucleobase derivatives was obtained including adenine 1, purine 12, cytosine 17, N9-formylpurine 28, N9, N6-diformyladenine 29, 5-hydroxymethyluracil 30, thymine 31 and three novel... 

Three reactions, which were known from the literature to be catalyzed by Lewis acids were selected as test reactions. A, was the Reetz alkylation of silyl enol ethers with -butyl chloride for which titanium tetrachloride is known to be useful [52]. B, was the Diels-Alder reaction between furan and acetylenedicarboxylic ester for which aluminium trichloride is a good catalyst [53]. C, was a Friedel-Crafts acylation for which aluminium trichloride is the preferred catalyst [54]. The reactions are summarized in Scheme 6. 

Phenylthioalkylation of silyl enol ethers. Silyl enol ethers of ketones, aldehydes, esters, and lactones can be alkylated regiospecifically by a -chloroalkyl phenyl sulfides in fhe presence of a Lewis acid. Zinc bromide and titanium(IV) chloride are the most effective catalysts. The former is more satisfactory for enol ethers derived from esters and lactongs. ZnBr2 and TiCL are about equally satisfactory for enol ethers of ketones. The combination of TiCL and Ti(0-f-Pr)4 is more satisfactory for enol ethers of aldehydes. Since the products can be desulfurized by Raney nickel, this reaction also provides a method for alkylation of carbonyl compounds. Of more interest, sulfoxide elimination provides a useful route to a,B-unsaturated carbonyl compounds. 

The acid-catalyzed reaction of enol silyl ethers of cyclic ketones with optically active methyl 4-methylphenylsulfinate has been reported as a very efficient method for the synthesis of chiral a-sulfinyl cycloalkanones 212. Boron trifluoride-diethyl ether, titanium tetrachloride and tin(IV) chloride may all be used as catalysts, however, the reproducibility of this procedure has recently been questioned71. 

Mukaiyama Aldol Condensation. The BINOL-derived titanium complex BINOL-T1CI2 is an efficient catalyst for the Mukaiyama-type aldol reaction. Not only ketone silyl enol ether (eq 25), but also ketene silyl acetals (eq 26) can be used to give the aldol-type products with control of absolute and relative stereochemistry. 

Mukaiyama Aldol Condensation. As expected, the chiral titanium complex is also effective for a variety of carbon-carbon bond forming processes such as the aldol and the Diels-Alder reactions. The aldol process constitutes one of the most fundamental bond constructions in organic synthesis. Therefore the development of chiral catalysts that promote asymmetic aldol reactions in a highly stereocontrolled and truly catalytic fashion has attracted much attention, for which the silyl enol ethers of ketones or esters have been used as a storable enolate component (Mukaiyama aldol condensation). The BINOL-derived titanium complex BINOL-TiCl2 can be used as an efficient catalyst for the Mukaiyama-ty pe aldol reaction of not only ketone si ly 1 enol ethers but also ester silyl enol ethers with control of absolute and relative stereochemistry (eq 11). ... 

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