Synthesis alkenyl organometallics

Studies on the stereochemical outcome of the reaction of 2-alkenyl organometallic reagents with aldehydes have increased recently, largely because stereoselectively produced homoallylic alcohols are synthetically equivalent, by cleavage at the carbon-carbon double bond, to the type of aldol adduct stereoisomers required for macrolide antibiotic total synthesis. A new stereoselective synthesis of (Z)-2-alkenyltins (46a) or the corresponding silanes (46b) from allyl or vinyl 9-BBN derivatives has appeared (Scheme 20). The... 

The manifold chiral information readily available in customary carbohydrates provides an attractive approach to a chiral modification of metal carbenes that may be applied to either metal-mediated stereoselective organic synthesis via sugar auxiliaries or to carbohydrate synthesis via organometallic methodologies [107, 108]. The sugar moiety can be incorporated into metal carbenes by well-established procedures such as nucleophilic addition to the metal-coordinated carbene carbon atom or conjugate addition to the vinylogous position in alkenyl or alkynyl car-... 

Ketones can be prepared by trapping (transmetallation) the acyl palladium intermediate 402 with organometallic reagents. The allylic chloride 400 is car-bonylated to give the mixed diallylic ketone 403 in the presence of allyltri-butylstannane (401) in moderate yields[256]. Alkenyl- and arylstannanes are also used for ketone synthesis from allylic chlorides[257,258]. Total syntheses of dendrolasin (404)f258] and manoalide[259] have been carried out employing this reaction. Similarly, formation of the ketone 406 takes place with the alkylzinc reagent 405[260],... 

Especially in the early steps of the synthesis of a complex molecule, there are plenty of examples in which epoxides are allowed to react with organometallic reagents. In particular, treatment of enantiomerically pure terminal epoxides with alkyl-, alkenyl-, or aryl-Grignard reagents in the presence of catalytic amounts of a copper salt, corresponding cuprates, or metal acetylides via alanate chemistry, provides a general route to optically active substituted alcohols useful as valuable building blocks in complex syntheses. 

The only preparative limitation to this method is the occasional coproduction of alkenyl-boronates that presumably arise via a-elimination pathways of the ate complex generated upon addition of the organometallic reagent to the a-haloalkylboronate4,29-30. This problem is illustrated in the synthesis of 5-(rm-butyldimethylsilyloxy)-2-pentenyl-substituted dioxaborolane30. 

Jordan RF, LaPointe RE, Bradley PK, Baenziger N (1989) Synthesis and chemistry of cationic alkyl, alkenyl, and allyl complexes derived from the soluble, cationic hydride (CH4Me)2Zr(H) (THF)+. Organometallics 8 2892-2903... 

When the allylic alcohol needed for asymmetric epoxidation is unavailable from a commercial source, reasonably general synthetic routes have been developed to allylic alcohols of several different substitution patterns. Good methods are available for the preparation of 3-substituted allylic alcohols, whereas synthesis of 2-substituted allylic alcohols is more problematic. The substrates for kinetic resolution, 1-substituted allylic alcohols, frequently can be derived by addition of alkenyl or alkynyl organometallic reagents to aldehydes followed by modification of the resulting product as required. 

The stereoselective synthesis of alkenes is basically a solved problem. Nowadays, all kinds of alkenes can be synthesized irrespective of whether their double bond is isolated or conjugated with another C=C double bond, a C=C triple bond, or an aromatic ring. This state of affairs is largely due to the discovery and the development of a number of palladium-catalyzed alkenylation and arylation reactions of organometallic compounds. 

The stereodefined alkenyl halides are of prime importance due to the recent developments of di- or trisubstituted alkene synthesis by cross-coupling reactions between organometallics and alkenyl halides catalyzed by transition metal compounds 171). These alkenyl halides can be conveniently obtained from alkenylboranes or alkeneboronic acids. B-Alk enylcatecholboranes undergo rapid hydrolysis when stirred with excess water at 25 °C (Eq. 109)102). The alkeneboronic acids are usually crystalline solids of low solubility in water and can be easily isolated and handled in air without significant deterioration. 

The quasi-complex compounds, as well as the complexes discussed above, led us into a domain which was nearly terra incognita at that time, namely, the substituted (j3-chloro, j8-alkyl, )3-keto) vinyl organometallics. Thus, the simplest of metal vinyls became the objective of our work, and the vinyl, isopropenyl, propenyl, and styryl derivatives of elements such as Hg, B, Tl, Ge, Sn, Si, P, As, Sb, and Bi were studied in collaboration with Freidlina and Borisov. Apart from the procedures mentioned in Section V, vinyl-lithium and vinyl Grignard compounds were used for the synthesis. Note that the highest valence alkenyl derivatives of the type RjSb were reported by us (181-205). 

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