Cinnamyl derivatives alkylation with

Unstabilized enolates react with allylic carbonates in the presence of metalacyclic iridium-phosphoramidite catalysts. Although ketones and aldehydes have not yet been used directly as pronucleophiles with this catalyst system, silyl enol ethers [80] and enamines [81] react with linear allylic carbonates to form, after workup, p-branched, y-8 unsaturated ketones (Scheme 13). Both methods form products in high yield, branched selectivity, and enantioselectivity for a range of cinnamyl and alkyl-substituted allylic carbonates. However, the silyl enol ethers derived from aliphatic ketones reacted in lower yields than enamines derived from the same ketones. 

The ready formation of esters of P amino acids by reduction of the correspond ing imines/enamines (Table 4.6, entries 12 14), which in turn can be prepared from the readily available P keto esters, allowed an expedient synthesis of SCH48461 (56), a potent, orally active inhibitor of cholesterol absorption [22]. Enamine 36n (Scheme 4.6) was reduced (via imine lOn) with ChSiH in the presence of Sigamide (35) to afford the P amino ester ISn (80% isolated yield, 88% ee), whose treatment with methylmagnesium bromide (acting as a base) produced p lactam 55 (92%). Enolization of the latter derivative with LDA followed by alkylation with cinnamyl bromide and catalytic hydrogenation afforded 56 in 77% overall yield for the last two steps (S. Stoncius, A.V. Malkov, and P. Kocovsky, unpublished results). 

A phosphonate is an activating group. Asymmetric allylation of the chiral racemic a-acetamido-jS-keto phosphonate 159 with cinnamyl acetate (41) was carried out at —30°C to afford a-alkyl-a-aminophosphonic acid derivative 160 with 88 % ee in 78% yield when (/ )-BINAP was used as a chiral ligand [56]. 

Thia-[2,3]-Wittig sigmatropic rearrangement of lithiated carbanions 47, obtained by deprotonation of the S-allylic sulfides 46, affords the thiols 48 or their alkylated derivatives 49. The corresponding sulfonium ylides 51, prepared by deprotonation of the sulfonium salts 50 also undergoes a [2,3]-sigmatropic shift leading to the same sulfides 49 [36,38] (Scheme 13). As far as stereochemistry is concerned, with crotyl (R R =H,R =Me) and cinnamyl (R, R =H,R =Ph) derivatives, it has been shown that the diastereoselectivity depends on the nature of the R substituent and on the use of a carbanion or an ylide as intermediate. 

The phosphoramidite ligands that are the focus of the remainder of this chapter have prompted the investigation of ligands containing related structures. Iridium complexes of aspartic acid-derived P-chirogenic diaminophosphine oxides (DlAPHOXs) catalyze the amination [62] and alkylation [63] of aUyhc carbonates (Scheme 6). With BSA as base and catalytic amounts of NaPFs as additive, branched amination and alkylation products were obtained from cinnamyl carbonates in excellent yields and enantioselectivities. However, the yields and enantios-electivities were lower for the reactions of alkyl-substituted aUyhc carbonates. Added LiOAc increased the enantioselectivities of aUyhc alkylation products. 

Here we report the synthesis and catalytic application of a new porous clay heterostructure material derived from synthetic saponite as the layered host. Saponite is a tetrahedrally charged smectite clay wherein the aluminum substitutes for silicon in the tetrahedral sheet of the 2 1 layer lattice structure. In alumina - pillared form saponite is an effective solid acid catalyst [8-10], but its catalytic utility is limited in part by a pore structure in the micropore domain. The PCH form of saponite should be much more accessible for large molecule catalysis. Accordingly, Friedel-Crafts alkylation of bulky 2, 4-di-tert-butylphenol (DBP) (molecular size (A) 9.5x6.1x4.4) with cinnamyl alcohol to produce 6,8-di-tert-butyl-2, 3-dihydro[4H] benzopyran (molecular size (A) 13.5x7.9x 4.9) was used as a probe reaction for SAP-PCH. This large substrate reaction also was selected in part because only mesoporous molecular sieves are known to provide the accessible acid sites for catalysis [11]. Conventional zeolites and pillared clays are poor catalysts for this reaction because the reagents cannot readily access the small micropores. 

An exciting development has come from work with an iridium catalyst. The use of the complex derived from phosphinoaryloxazoline ligand 149 leads to an efficient alkylation of E-cinnamyl acetate (Eq. 8E.32) [217], It is of note that electron-withdrawing substituents on the phosphorus atom, which are known to be required to give a good regioselectivity in general [218], also increased the enantioselectivity dramatically. 

Because of the low reactivity of the tertiary alcohol, alkylation of the 014-hydroxyl with alkyl halides such as propyl or isoamyl halides was unsuccessful [Schmidhammer H, unpublished observations]. Therefore, allylic halides were employed to introduce 14-O-alkenyl substituents using similar conditions as described above [ 43—461. Catalytic hydrogenation afforded the corresponding 14-O-alkyl derivatives [43 -5]. Thus, 14-hydroxy-5-methylcodeinone (20) was treated with 3,3-dimethylallyl bromide in DMF in the presence of NaH to give compound 21, which underwent catalytic hydrogenation to yield 14-O-isoamyl-substituted morphinan 24 (Scheme 5) [43]. Similarly 14-phenylpropoxymorphinans 25 and 26 were prepared from 14-hydroxycodeinone (3) and 21, respectively, via intermediates 22 and 23, which were obtained by alkenylation using cinnamyl bromide (Scheme 5) [44, 45],... 

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