Alkenes diastereoselective reduction

Py used a nitrone-alkene coupling in a short, asymmetric synthesis of (+ )-hyacinthacine A2 (Scheme 5.43).74 The key carbon-carbon bond-forming step in their approach involved the highly diastereoselective reductive coupling of the L-xylose-derived cyclic nitrone 66 to ethyl acrylate.74... 

Applications in Total Synthesis. Two recent examples of directed hydrogenations employing (1) in the total synthesis of complex molecules are illustrated. In eq I a simultaneous diastereoselective reduction of the trisuhstituted alkene and the a,p-unsaturated ester afforded the illustrated advanced intermediate in the asymmetric total synthesis of ionomycin. In addition, a two-directional application has been utilized in an asymmetric synthesis FK-506 (eq 2). ... 

Coupling of these two readily available precursors leads to bis-enone 413 elaborated to 414 by chemo- and stereoselective hydrogenation of the more strained, bicyclic alkene with PhSiH3 in the presence of catal)dic Mo(CO)6, and K-selectride diastereoselective reduction (O Scheme 81). 

Gallc er and co-workers devised a formal enantioselective synthesis of ( — )-3 in wduch the stereogenic center at C-6 was derived fiom Cbz-protected (S)-2-amino-4-pentenoic acid (36) (44). Acylation of 3,3-dimethoxy-pyrrolidine (37) with this acid yielded amide 38, which was converted into aldehyde 39 by cleavage of the terminal alkene vnth osmium tetroxide and sodium periodate (Scheme 5). The indolizidine nucleus was constructed from 39 by a problematic intramolecular aldol condensation, which was eventually optimized by using 2,2,6,6-tetramethylpiperidine as base followed by adsorption onto, and elution from, silica gel (45). Diastereoselective reduction of the ketone group of the aldol product 40 was accomplished in better than 95% enantiomeric excess (ee) with the Corey... 

As for the diols, the symmetric compounds have found most uses for nonsymmetric diols, a versatile synthesis via silyl ketones using the SAMP/RAMP methodology has been developedl5. Both enantiomers of the simplest symmetric diol, 2,3-butanediol (11), are often used in asymmetric synthesis, mostly for the formation of acetals and ketals with carbonyl compounds and subsequent reactions with acidic catalysts (Section D. 1.1.2.2.), Grignard reagents (Section D. 1.3.1.4.) and other carbanions (Sections D. 1.5.1., D. 1.5.2.4.), and diastereoselective reductions (Section D.2.3.3.). Precursors of chiral alkenes for cycloprotonations (Section D.1.6.1.5.) and for chiral allenes (Section B.I.), and chiral haloboronic acids (Section D. 1.1.2.1.) are other applications. The free diol has been employed as a chiral ligand in molybdenum peroxo complexes used for enantioselective epoxidation of alkenes (Section D.4.5.2.2.). 

When a ketone or aldehyde is part of a molecule bearing another stereogenic center, reduction can proceed with good diastereoselectivity. Reduction of 472 from the exo- face led to a quantitative yield of 473, in Takasu and Ihara s synthesis of culmorin. l Conjugated ketones are reduced selectivity at the alkene moiety and there is usually a preference for the product with a trans-ring juncture. 2... 

Synthesis of Alkenes by Reductive Elimination. The treatment of 2-halo-3-hydroxy esters and amides with samarium iodide leads to the corresponding di- or trisubstituted E)-a,p-unsaturated derivatives in high yields and diastereoselectivities (eqs 39 and 40). The precursors are readily accessible by condensation of the lithium enolate of a-haloesters or amides. If the substrate contains y,i5-unsaturation, the /3,y-unsaturated ester is generated in the process (eq 41). 

In an effort to identify a more stereoselective route to dihydroagarofuran (15), trimethylsilylated alkyne 17 was utilized as a substrate for radical cyclization (Scheme 2). Treatment of 17 with a catalytic amount of AIBN and tri-n-butyltin hydride (1.25 equiv) furnishes a mixture of stereoisomeric vinyl silanes 18 (72% combined yield) along with an uncyclized reduction product (13% yield). The production of stereoisomeric vinyl silanes in this cyclization is inconsequential because both are converted to the same alkene 19 upon protodesiiyiation. Finally, a diastereoselective di-imide reduction of the double bond in 19 furnishes dihydroagaro-... 

Deuterium-labeled organosilicon hydride alkene to alkane reductions, 34 disubstituted alkenes, 37-38 alkyl halide reduction, 29-31 Diastereoselectivity, ketone-alcohol reduction, 76-79... 

With the advent of enantioselective zirconocene-catalyzed alkene carbomagnesiation,27 27a 27c 28 28a chirally modified zirconocenes soon were applied to asymmetric reductive diene carbocyclization.2 a c As demonstrated by the reductive cyclization of 5a,29 highly enantioselective cyclization is enabled through the use Brintzinger s chiral, mszz-zirconocene.30 30a (For the preparation and resolution of chiral tf .szz-zirconocene 6, see Refs 30,30a.) However, moderate diastereoselectivities and yields are generally observed (Scheme 5). 

A diastereoselective dipolar cycloaddition of chiral nitrone 80 with alkene dipolarophiles afforded imidazo[ 1,2-3]-isoaxazole (Scheme 9). The conversion via N-O reduction of this ring system with Raney-Ni in methanol gave the corresponding pyrrolo[l,2-A imidazole in 66% yield. The structure has been confirmed by X-ray diffraction crystal stmcture analysis <2000SL967>. 

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