Allylation Lewis base catalysts

The first use of chiral sulfoxides as Lewis-base catalysts in the allylation of aldehydes with allyltrichlorosilane was reported in 2003. The formation of the... 

Keywords Allylation, Allylsilanes, Allylstannanes, Carbonyl compounds, Chiral Lewis acid catalysts, Chiral Lewis base catalysts... 

Catalytic asymmetric allylations of aldehydes or ketones are roughly classified into two methods, namely, those using chiral Lewis acid catalysts and those using chiral Lewis base catalysts. The former method uses less reactive allylsilanes or allylstannanes as the allyl source. The latter method requires allyltrichlorosi-lane or more reactive allylmetals. Both processes are applicable to the reactions with substituted allylmetal compounds or propargylation. 

Many noticeable examples of chiral Lewis base catalyzed allylation of carbonyl compounds have also appeared. Iseki and coworkers published a full paper on enantioselective addition of allyl- and crotyltrichlorosilanes to aliphatic aldehydes catalyzed by a chiral formamide 28 in the presence of HMPA as an additive [41]. This method was further applied to asymmetric allenylation of aliphatic aldehydes with propargyltrichlorosilane [40]. Nakajima and Hashi-moto have demonstrated the effectiveness of (S)-3,3 -dimethyl-2,2 -biquinoline N,AT-dioxide (29) as a chiral Lewis base catalyst for the allylation of aldehydes [42]. In the reaction of (fs)-enriched crotyltrichlorosilane (54 , E Z=97 3) with benzaldehyde (48), y-allylated anfi-homoallylic alcohol 55 was obtained exclusively with high ee while the corresponding syn-adduct was formed from its Z isomer 54Z (fs Z= 1 99) (Scheme 6). Catalytic amounts of chiral urea 30 also promote the asymmetric reaction in the presence of a silver(I) salt, although the enantioselectivity is low [43]. 

Chiral bidentate imidodiphosphoric tetramide 33 [46], chiral 2,2 -bipyrid-ine-type N-monoxide (PINDOX) 34 [47], and chiral 3,3 -bis(hydroxymethyl)-6,6 -diphenyl-2,2 -bipyridine N,N -dioxide (35) [48] have been also developed as efficient chiral Lewis base catalysts for the asymmetric allylation of aldehydes with allyltrichlorosilane. 

Catalytic enantioselective allylations of aldehydes already published can be classified into two methods carried out under the influence of chiral Lewis acid catalysts and chiral Lewis base catalysts. The process by chiral Lewis acid catalysts generally uses allyltrimethylsilane or allyltrialkylstannane as an allylating agent, both of which show low reactivity toward aldehydes without these catalysts. The process by chiral Lewis base catalysts employs allyltrichlorosilane or allylmetals possessing relatively higher reactivity. Both processes can be successfully applied to various substituted allylmetal compounds or allenylmetal compounds. 

Iseki et al. later improved the catalytic process and showed that chiral phos-phoramides 15,16, and 17, prepared from (S)-proHne, are suitable to catalyze the asymmetric allylation of aromatic aldehydes to give chiral homoallylic alcohols 34 with up to 88% ee (Scheme 13) [36,37]. The same group has also developed a chiral formamide 18 as a chiral Lewis base catalyst [38]. This catalyst is convenient for the allylation of aUphatic aldehydes with high enantioselectivity. A typical aromatic aldehyde, benzaldehyde, gives a low enantiomeric excess (Scheme 13). 

Allylation. Silver tosylate is used in combination with urea, a Lewis base catalyst, to promote allylation of aldehydes with allyltrichlorosilane. 

Figure 21.3 Selected mono-JV-oxides as Lewis-base catalysts. The enantioselectiv-ities attained in the allylation of PhCHO with 21.5a are shown in parentheses.

Despite steady progress in the development of new efficient Lewis-base catalysts for asymmetric allylation, only a few of them proved their worth in the target synthesis of pharmaceutically relevant compounds and natural products. 

As a Carbon Nucleophile in Lewis Base-catalyzed Reactions. Allylation of alkyl iodides with allyltrimethylsilane proceeds in the presence of phosphazenium fluoride. Tetra-butylammonium triphenyldifluorosilicate (TBAT) is useful for allylation of aldehydes, ketones, imines, and alkyl halides with allyltrimethylsilane (eq 63). 55 Similarly, TBAHF2 is an effective catalyst for allylation of aldehydes. The homoallylamines are synthesized from allyltrimethylsilane and imines with a catalytic amount of TBAF (eq 64). The reactions of thioketones as well as sulfines with allyltrimethylsilane can be mediated by TBAF to give allylic sulfides and allyl sulfoxides, respectively. Besides fluoride ion, 2,8,9-triisopropyl-2,5,8,9-tetra-aza-1-phosphabi-cyclo[3.3.3]undecane promotes the allylation of aldehydes with allyltrimethylsilane as a Lewis base catalyst (eq 65). ... 

SCHEME 10.43. Asymmetric allylation and crotylation using Lewis base catalysts. 

The formed methylcyclohexane carbocation eliminates a proton, yielding 3-methylcyclohexene. 3-Methylcyclohexene can either dehydrogenate over the platinum surface or form a new carbocation by losing H over the acid catalyst surface. This step is fast, because an allylic car-bonium ion is formed. Losing a proton on a Lewis base site produces methyl cyclohexadiene. This sequence of carbocation formation, followed by loss of a proton, continues till the final formation of toluene. 

The directive effect of allylic hydroxy groups can be used in conjunction with chiral catalysts to achieve enantioselective cyclopropanation. The chiral ligand used is a boronate ester derived from the (VjA jA N -tetramethyl amide of tartaric acid.186 Similar results are obtained using the potassium alkoxide, again indicating the Lewis base character of the directive effect. 

As an alternative approach, chiral Lewis base has been tested for catalytic allylation. Compound 139, reported by Iseki et al.,88 was the first example of a chiral Lewis base that effectively serves as a catalyst in asymmetric allylation in combination with HMPA. Allylation of aliphatic aldehydes with allyl- and crotyltrichlorosilanes in the presence of 139 provides up to 98% ee (Scheme 3-49). 

If olehn metathesis is to be conducted in solution, solvents of low Lewis-basicity will generally give the best results (CH2CI2 > toluene > THF). As discussed above, metathesis is initiated by the formation of a jt-complex between the metal and the alkene. Hence, other nucleophiles will compete with the alkene for these coordination sites and in some systems even THF can lead to complete deactivation of the catalyst [786]. Tungsten-based catalysts which can even metathesize allyl thioethers have, however, been described [787]. 

Predominantly cis-1,4-polybutadiene is produced by coordination polymerization with mixed catalysts.187,487,488 Three catalyst systems based on titanium, cobalt, or nickel are used in industrial practice. Iodine is an inevitable component in titanium-alkylaluminum sytems to get high cis content. Numerous different technologies are used 490,491 A unique process was developed by Snamprogetti employing a (Tr-allyl)uranium halide catalyst with a Lewis acid cocatalyst.492-494 This catalyst system produces poly butadiene with 1,4-ris content up to 99%. 

For a recent summary of the Lewis-base-catalyzed allylation with a main focus on phosphoramide catalysts, see S. E. Denmark, J. Fu, Chem. 

Allyl boronates react very slowly with carbonyl compounds as compared to the corresponding allyldialkylboranes, due to the presence of two oxygen atoms on boron which diminish the Lewis acidity of boron. However, the activity of the allyl boronates can be enhanced by the addition of Lewis acid catalysts. There have been two complementary approaches described for the stereoselective allylation with allyl boronates, one involving the use of chiral Lewis acid, and the other involving chiral allyl boronates in conjunction with achiral Lewis acid catalyst. Several chiral fVsymmetric-based 1,2-diols 197 have been employed in combination with SnCLj as a Lewis acid and excellent level of enantioselectivity has been observed for the allylation to furnish homoallylic alcohols 198 with high ee (Equation 8) <2006AGE2426>. 

If the latter reaction proceeds through a closed transition state (e.g., 5 in Scheme 7.2), good diastereocontrol can be expected in the case of trans- and cis-CrotylSiCl3 (2b/2c) [14, 15]. Here, the anh-diastereoisomer 3b should be obtained from trans-crotyl derivative 2b, whereas the syn-isomer 3c should result from the reaction of the cis-isomer 2c (Scheme 7.2). Furthermore, this mechanism creates an opportunity for transferring the chiral information if the Lewis base employed is chiral. Provided that the Lewis base dissociates from the silicon in the intermediate 6 at a sufficient rate, it can act as a catalyst (rather than as a stoichiometric reagent). Typical Lewis bases that promote the allylation reaction are the common dipolar aprotic solvents, such as dimethylformamide (DMF) [8,12], dimethyl sulfoxide (DMSO) [8, 9], and hexamethylphosphoramide (HMPA) [9, 16], in addition to other substances that possess a strongly Lewis basic oxygen, such as various formamides [17] (in a solution or on a solid support [7, 8, 18]), urea derivatives [19], and catecholates [10] (and their chiral modifications [5c], [20]). It should be noted that, upon coordination to a Lewis base, the silicon atom becomes more Lewis acidic (vide infra), which facilitates its coordination to the carbonyl in the cyclic transition state 5. 

The chemistry of asymmetric allylation of carbonyl compounds has further progressed since the review in Comprehensive Asymmetric Catalysis [1] and plenty of papers including reviews [2,3] on chiral catalysts for the reaction have since appeared. This chapter describes new examples of catalytic enantioselec-tive allylation of carbonyl compounds with allylmetals in the presence of a catalytic amount of chiral Lewis acid or chiral Lewis base (Scheme 1). Compounds 1-36 [4-49] shown in Fig. 1 are the chiral catalysts reported since 1998, which have been used in the asymmetric allylation or propargylation of carbonyl compounds. Chiral compounds 37-40 [50-53], which have been utilized in the stoichiometric version, are also candidates for the chiral catalyst (Fig. 2). 

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