Ketone titanium

TABLE 7. Stereoselective aldol reactions with titanium ketone enolates... 

Perkins and coworkers reported on stereoselective aldol reactions with boron and titanium ketone enolates (equations 30 and 31) for the construction of a spiroacetal-dihydropyrone (108) related to natural products auripyrone A and Both are cytotoxic... 

Syn selective aldol additions of titanated aldehyde hydrazones and ketone hydrazones have been reported by Reetz. The observed syn selectivity parallels the syn selectivity seen in titanium ketone eno-iates, and the intermediate titanium aldehyde hydrazone derivatives were seen to have ( )c—c geometry (equation 17). 

Cp2Zr(Me)Cl, respectively. Their NMR spectra clearly reveal that the O-bond character of the enolate, indicated by the carbon-carbon double bond, is maintained in solution (Scheme 3.8) [53]. Crystal structures were also obtained for O-bound zirconium acetophenone enolate 21 [55], titanium ketone enolate 22, derived from/) r -methylacetophenone, and amide enolate 23 [56]. Whereas the latter readily added to benzaldehyde, the ketone enolate 22 (X = Ph) failed to undergo an aldol addition. This difference in reactivity was explained - based on a computational study - by a higher electron density at the methylene carbon atom in the amide compared to the ketone enolate [56]. 

Stereoselectivities of 99% are also obtained by Mukaiyama type aldol reactions (cf. p. 58) of the titanium enolate of Masamune s chired a-silyloxy ketone with aldehydes. An excess of titanium reagent (s 2 mol) must be used to prevent interference by the lithium salt formed, when the titanium enolate is generated via the lithium enolate (C. Siegel, 1989). The mechanism and the stereochemistry are the same as with the boron enolate. 

Addition compounds form with those organics that contain a donor atom, eg, ketonic oxygen, nitrogen, and sulfur. Thus, adducts form with amides, amines, and A/-heterocycles, as well as acid chlorides and ethers. Addition compounds also form with a number of inorganic compounds, eg, POCl (6,120). In many cases, the addition compounds are dimeric, eg, with ethyl acetate, in titanium tetrachloride-rich systems. By using ammonia, a series of amidodichlorides, Ti(NH2) Cl4, is formed (133). 

Reactions of titanium alkyls with aldehydes and ketones are generally more stereospecific and selective than the corresponding Grignard reactions (416). 

Owing to their particular interest two individual reactions will now be discussed separately. The reaction of methoxycarbonylhydrazine and 3-bromo-2,4-pentanedione affords, in addition to the expected pyrazole (608), a pyrazolium salt (609), the structure of which was established by X-ray crystallography (74TL1987). Aryldiazonium salts have been used instead of arylhydrazines in the synthesis of pyrazolines (610) and pyrazoles (611) (82JOC81). These compounds are formed by free radical decomposition of diazonium salts by titanium(n) chloride in the presence of a,/3-ethylenic ketones. 

Formation o( oleltns by coupling or cross coupling of ketones, mediated by low valent titanium Also coupling ol enol ethers of 1,3-dicarbonyl compounds. 

Titanium tetrakis(diethylamide) selectively adds to aldehydes in the presence of ketones and to the least hindered ketone in compounds containing more than one ketone. The protection is in situ, which thus avoids the usual protection-deprotec-tion sequence. Selective aldol and Grignard additions are readily performed employing this protection methodology. ... 

Titanium(IV) is a powerful but selective Lewis acid which can promote the coupling of allylsilanes with carbonyl compounds and derivatives In the presence of titanium tetrachlonde, benzalacetone reacts with allyltnmethylsilane by 1,4-addition to give 4-PHENYL-6-HEPTEN-2-ONE. Similarly, the enol silyl ether of cyclopentanone is coupled with f-pentyl chloride using titanium tetrachlonde to give 2-(tert-PENTYL)CYCLOPENTANONE, an example of a-tert-alkylation of ketones. 

A reagent more reactive than tris(dimethylamino)arsine employed by Weingarten and White 39) was tetrakis(dimethylamino)titanium (145). With this compound it was possible to prepare N,N-dimethyl(l-isopropyl-2-methylpropcnyl)amine (147) from diisopropyl ketone. Weingarten and White 39) have suggested a possible mechanism for this reaction (see p. 88). If benzaldehyde 39,111), formaldehyde 111), or acetaldehyde 39) is used, the corresponding gem diamine or aminal (143) is formed. 

They found that a stoichiometric mixture of titanium tetrachloride, secondary amine, and aldehyde or ketone produeed enamines directly and rapidly [Eq. (11)]. 

The yields ranged from 55% for the mixture of enamines formed from morpholine and methylisopropyl ketone to 94% for the enamine formed from dimethylamine and methyl t-butyl ketone. The hindered ketone 2,5-dimethylcyclopentanone could be converted to an enamine, but the more hindered ketone, 2,6-di-t-butylcyclohexanone, was inert. White and Weingarten 43) attribute the effectiveness of titanium tetrachloride in this reaction to its ability to scavenge water and to polarize the carbonyl bond. 

Chelation control of the intramolecular reaction between an allylsilane and an aldehyde or ketone has been carefully investigated. Excellent stereoselectivity was found for cyclization of B-oxo esters using titanium(IV) chloride as the Lewis acid, less good selectivity for cyclization of /l-diketones70. 

Alkene R1 Ketone Titanium Reagent Temp. (°C) d.r. (anti/syn) Yield (%) Ref... 

Only few allyltitanium reagents bearing a removable chiral auxiliary at the allylic residue are known. The outstanding example is a metalated 1-alkyl-2-imidazolinone14, derived from (—)-ephedrine, representing a valuable homoenolate reagent. After deprotonation by butyllithium, metal exchange with chlorotris(diethylamino)titanium, and aldehyde or ketone addition, the homoaldol adducts are formed with 94 to 98% diastereoselectivity. 

A solution of 0.11 mol of 1.5M butyllithium in hexane is added to 30 mL of THF under a layer of argon or nitrogen at —78 C, followed by 0.10 mol of (4S,5/ )-1-allyl-3,4-dimcthyl-5-phenyl-2-imidazolidinone in 75 mL of THF. After 25 min, a solution of 0.11 mol of chlorotris(diethylamino)titanium in 30 mL of THF is introduced. The mixture is stirred at — 20 °C for 45 min, then 0.11 mol of the aldehyde or ketone in 10 mL of THF is added. After 2 h. 20 mL of water and 200 mL of diethyl ether are added. The ethereal solution is separated, washed with 20 mL of 10% aq NaHS03 followed by 20 mL of water, dried over Na2S04 and concentrated, whereupon the product crystallizes. Diastereomerically pure samples are prepared by recrystallization from hexane or hexane/ethyl acetate. 

Very high levels of induced diastereoselectivity are also achieved in the reaction of aldehydes with the titanium enolate of (5)-l-rerr-butyldimethylsiloxy-1-cyclohexyl-2-butanone47. This chiral ketone reagent is deprotonated with lithium diisopropylamide, transmetalated by the addition of triisopropyloxytitunium chloride, and finally added to an aldehyde. High diastereoselectivities are obtained when excess of the titanium reagent (> 2 mol equiv) is used which prevents interference by the lithium salt formed in the transmetalation procedure. Under carefully optimized conditions, diastereomeric ratios of the adducts range from 70 1 to >100 1. 

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