Allylstannanes

Similar reactions give functionally-substituted allylstannanes, for example 6 

Various ally lie halides have also been cross-coupled with tributyltin chloride or tin tetrachloride under the action of ultrasound in the presence of a metal to give the corresponding allyltributylstannane or tetraallylstannane in excellent yield this procedure avoids the formation of biallyl which is sometimes a problem in making the Grignard reagent.7 

Optically active allylstannanes, R3SnC HR (CH=CHR ), are formed from active secondary propargyl phosphates from the sequence of reactions shown in equation 9-4,8 using the Ti(OPr1)4/Pr1MgBr reagent.9 Presumably the titanium/tin transmetallation involves an Sn2 process. 

Organotin Chemistry, Second Edition. Alwyn G. Davies Copyright 2004 Wiley-VCH Verlag GmbH Co. KGaA. ISBN 3-527-31023-1 

The allylation of an aldehyde can be carried out by the direct reaction of tin with an allyl bromide in aqueous ethanol or in water,10 or in the absence of any solvent.11 Allylation can also be achieved by generating the allylstannane reagent in situ from tin(II) chloride and the appropriate allyl bromide.12 13 The reaction can be carried out with the more accessible but less reactive allyl chloride if sodium iodide is added, which converts the chloride into the iodide.14 

Since the discovery of thermally promoted allylation of aldehydes [9], allylstannanes have been widely used in organic synthesis as stable and stereodefined reagents for C-C bond formation. Although it had been reported that activated aldehydes [10] or allylstannanes with chloride on the tin [11] could be used for allylation, remarkably innovative technology for allylation was advanced by Naruta and by Sakurai and Hosomi [12]. They disclosed that allylation was promoted by addition of a Lewis acid this substantially expanded the versatihty of the aUylstaimane procedure. Because many allylation reactions have already been documented [1], the most recent progress in this field will be described after brief description of fundamental aspects. 

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Aryl halides react with a wide variety of aryl-, alkenyl- and alkylstan-nanes[548-550]. Coupling of an aryl tritlate with an arylstannane is a good preparative method for diaryls such as 688. The coupling of alkenylstannanes with alkenyl halides proceeds stereospecifically to give conjugated dienes 689. The allylstannane 690 is used for allylation[397,546,551-553]. Aryl and enol triflates react with organostannanes smoothly in the presence of LiCl[554]. 

The a-bromo-7-lactone 901 undergoes smooth coupling with the acetonyltin reagent 902 to afford the o-acetonyl-7-butyrolactone 903[763j. The o-chloro ether 904, which has no possibility of //-elimination after oxidative addition, reacts with vinylstannane to give the allyl ether 905, The o -bromo ether 906 is also used for the intramolecular alkyne insertion and transmetallation with allylstannane to give 907[764],... 

The allylstannane 474 is prepared by the reaction of allylic acetates or phosphates with tributyltin chloride and Sml2[286,308] or electroreduction[309]. Bu-iSnAlEt2 prepared in situ is used for the preparation of the allylstannane 475. These reactions correspond to inversion of an allyl cation to an allyl anion[3l0. 311], The reaction has been applied to the reductive cyclization of the alkenyl bromide in 476 with the allylic acetate to yield 477[312]. Intramolecular coupling of the allylic acetate in 478 with aryl bromide proceeds using BuiSnAlEti (479) by in situ formation of the allylstannane 480 and its reaction with the aryl bromide via transmetallation. (Another mechanistic possibility is the formation of an arylstannane and its coupling with allylic... 

Allylsilanes and allylstannanes are also reactive toward electrophiles and usually undergo a concerted elimination of the silyl substituent. Several examples are shown below. 

Stereocontrolled synthesis of polycyclic ethers and related heterocycles via intramolecular reactions of allylstannanes 97YGK619. 

Evans developed a new method for the synthesis of [(-C-allylglycosides, based on BusSnOTf-mediated ring-opening of glycal epoxides with allylstannanes as nucleophiles [81a], This methodology has been efficiently used in the (3-stereoselective introduction of the side chain (C44-C51) of spongistatin 2 (Scheme 8.43) [81b,c]. 

Lewis acid catalyzed carbonyl addition of allylsilanes (Section D.l.3.3.3.5.) and allylstannanes (Section D.l.3.3.3.6.) usually proceed with clean allylic inversion (Section D.l.3.3.1.2.). Since these compounds are prepared by several routes and are also stable enough to be purified, each regioisomer can be approached. 

Since the double-bond configuration is established in the final elimination step from a /t-silicon-(or tin-) substituted carbenium ion in a conformation of lowest energy, often high E selectivity is observed. In reactions of allylstannanes, catalyzed by tin(TV) chloride or titanium(IV) chloride, occasionally a metal exchange occurs, followed by the pericyclic addition pathway leading to the iwti-diastereomers17 19. A more detailed discussion is given in Section D.1.3.3.3.5. 

Allylsilanes or allylstannanes in the presence of a bidentate Lewis acid such as tin(IV) chloride, titanium(IV) chloride, zinc chloride, and magnesium bromide as well as diallylzinc, are promising choices (Table 1). 

I.3.3.3.6.I. Unsubstituted and Alkyl- and Aryl-Substituted Allylstannanes and Allyltin Halides... 

Symmetric allylstannanes are readily available by stannylation of allylmetal reagents3,4. 

Allylstannanes can be prepared by treatment of allyl halides with trialkyl- or triaryltin lithium reagents. Displacement of primary allyl halides tends to be regioselective for formation of the less substituted allylstannane, and takes place with useful retention of double-bond geometry14-16. 

Displacement of secondary allyl halides is satisfactory for the formation of symmetric allylstannanes, e.g., ( )-tributyl(l-mcthyl-2-butcnyl)stannane17, but can give 1,3-rearranged products in other cases, e.g., from 3-chlorobutene and trimethyltin reagents14 lS. Allylic cyclohexenyl chlorides react with triphenyltin lithium with clean inversion and little 1,3-transformation19,20. 

A useful synthesis of allylstannanes from primary alcohols involves conversion of the alcohols into their O-substituted 5-methyl carbonodithioates, thermolysis to effect [3,3] rearrangement to the corresponding 5-substituted 5-methyl carbonodithioates, and treatment with a trialkyl-tin hydride under free-radical conditions to form the allylstannane21. This procedure has been applied to the synthesis of functionalized allylstannanes including (5)-( )-4-(benzyloxy)-2-pen-tenyl(tributyl)stannane22. 

Allylstannanes are also available from allyl sulfoncs24 and sulfides25 by treatment with tri-alkyltin hydrides under free-radical conditions. Of some interest is the stereocontrol exercised by a neighboring hydroxy group, possibly because of interaction with the tin26. 

Unsymmetric allylstannanes in which the tin substituent is at the more substituted end of the allyl fragment have been obtained by oxidative elimination of primary alkyl aryl selenides which are available from the corresponding primary alcohols. This procedure was satisfactory for allylstannanes unsubstituted at the 3-position, but elimination of secondary aryl selenides gave mixtures of regioisomers33. 

Hydrolysis of 1-boronylallylstannanes, available by stannylation of alkenyl and allyl boranes. gives (Z)-allylstannanes stereoselectively34. 

Finally, the in situ formation and thermolysis of trialkyltin ethers derived from tertiary homoal-lylic alcohols has been developed into a useful allylstannane synthesis39,40. This fragmentation is the reverse of the addition of an allylstannane to a ketone41. 

Two approaches for the synthesis of allyl(alkyl)- and allyl(aryl)tin halides are thermolysis of halo(alkyl)tin ethers derived from tertiary homoallylic alcohols, and transmetalation of other allylstannanes. For example, dibutyl(-2-propenyl)tin chloride has been prepared by healing dibutyl(di-2-propenyl)stannane with dibutyltin dichloride42, and by thermolysis of mixtures of 2,3-dimethyl-5-hexen-3-ol or 2-methyl-4-penten-2-ol and tetrabutyl-l,3-dichlorodistannox-ane39. Alternatively dibutyltin dichloride and (dibutyl)(dimethoxy)tin were mixed to provide (dibutyl)(methoxy)tin chloride which was heated with 2,2,3-trimethyl-5-hexen-3-ol40. 

Both allylstannane transmetalation and thermolysis of homoallyl stannoxanes have been used to prepare 2-butenyltin halides as (E)j(Z) mixtures44-45. The reaction between 2-butenyl-(tributyl)stannane and dibutyltin dichloride initially provides dibutyl(l-methyl-2-propenyl)tin chloride as the kinetic product by an SE2 process, but this isomerizes under the reaction conditions to give a mixture containing the (Z)- and (E)-2-butenyl isomers46. 

The stereoselectivity of the boron trifluoride induced reactions was initially discussed in terms of open-chain, antiperiplanar transition states66. However studies of Lewis acid induced intramolecular allylstannane-aldehyde reactions are supportive of a synclinal process56,67. 

Analogous reactions of more complex allylstannanes have been applied to natural product synthesis72, although /(,/i-dialkylated aldehydes appear not to react, possibly due to deactivation of the aldehyde towards nucleophilic attack72. 

In contrast to this generally high preference for. tyn-products for boron trifluoride mediated reactions between 3-a//c v/-Substituted allylstannanes and aldehydes, //-products are preferred for reactions involving 3-p/ cn>7-substituted allylstannanes. This stereoselectivity was observed for a range of aldehydes, and was explained in terms of the increased propensity for the tin-allylie carbon bond to be polarized when the -substituent is able to stabilize a positive charge so favoring a cyclic transition state73. 

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