1-iodo-1-alkenes

For example, Piers and Marais demonstrated that keto iodo alkene 32 can be converted to bicyclic keto alkene 35 in one pot21 (see Scheme 7). In this interesting methylenecyclopentane annulation method, it is presumed that intermediate 33, produced by sequential oxidative addition and deprotonation reactions, undergoes conver-... 

Cyanogen Iodide (ICN) has been used extensively for the cyanation of alkenes and aromatic compounds [12], iodination of aromatic compounds [13], formation of disulfide bonds in peptides [14], conversion of dithioacetals to cyanothioacetals [15], formation of trans-olefins from dialkylvinylboranes [16], lactonization of alkene esters [17], formation of guanidines [18], lactamization [19], formation of a-thioethter nitriles [20], iodocyanation of alkenes [21], conversion of alkynes to alkyl-iodo alkenes [22], cyanation/iodination of P-diketones [23], and formation of alkynyl iodides [24]. The products obtained from the reaction of ICN with MFA in refluxing chloroform were rrans-16-iodo-17-cyanomarcfortine A (14)... 

Fig. 16.20. Alkenylation of isomeric alkenylboronic acid esters with isomeric iodo-alkenes stereoselective synthesis of isomeric 1,3-dienes.

A series of aryl radical cyclizations were reported by a group at Novartis [10], and some of these processes were also compared with bond formation by Pd-mediated Heck cyclization of the same substrates. The tributyltin hydride-mediated reaction of iodo alkenes 7 (Scheme 3), immobilized on polystyrene resin through a linker, gave dihydrobenzofurans 8 [11]. It was also possible to perform a tandem cyclization using allyltributyltin to give the allylated product 9, although the yields were less satisfactory. The radical cyclization onto enol ethers was demonstrated [12] by the conversion of 10 to 11. For best results, the tributyltin hydride and AIBN were added portionwise every 5-8 h. The impressive 95% yield was in fact higher than that for the solid-phase Heck cyclization of 10. Similarly, cyclization of anilide 12 afforded the phenanthridine 13. 

The synthesis of polyfunctionalized cyclohexanes by d-exo-free radical cydization have been reported.In this way iodo-alkene 18 and bromo acetate 19, on treatment with tributyltin l dride and AIBN, afford products 20 and 21, respectively. In addition, 21a was formed as a minor product... 

Solvents play a pivotal role in the Negishi coupling, as demonstrated in the coupling of alkenyl zinc reagents with iodo alkenes. In this case, DMF is superior to THF, one of the standard solvents (Scheme 5-77). 

The alkenyl moiety, rather than the aryl moiety, in the aryl(alkenyl)iodo-nium salt 152 reacts smoothly with alkenes under mild conditions[121]. 

In the presence of a double bond at a suitable position, the CO insertion is followed by alkene insertion. In the intramolecular reaction of 552, different products, 553 and 554, are obtained by the use of diflerent catalytic spe-cies[408,409]. Pd(dba)2 in the absence of Ph,P affords 554. PdCl2(Ph3P)3 affords the spiro p-keto ester 553. The carbonylation of o-methallylbenzyl chloride (555) produced the benzoannulated enol lactone 556 by CO, alkene. and CO insertions. In addition, the cyclobutanone derivative 558 was obtained as a byproduct via the cycloaddition of the ketene intermediate 557[4I0]. Another type of intramolecular enone formation is used for the formation of the heterocyclic compounds 559[4l I]. The carbonylation of the I-iodo-1,4-diene 560 produces the cyclopentenone 561 by CO. alkene. and CO insertions[409,4l2]. 

The first example of a cyclization of fluorine-containing 5-hexenyl radicals was the study of the radical-iniOated cyclodimenzation reaction of 3,3,4,4-tetra-fluoro-4-iodo-1-butene. In this reaction, the intermediate free radical adds either to more of the butene or to an added unsaturated species [54, 55] (equation 56). Electron-deficient alkenes are not as effective trapping agents as electron-nch alkenes and alkynes [55]. 

The Simmons-Smith reaction (Section 14.12) Methylene transfer from iodo-methylzinc iodide converts alkenes to cyclopropanes. The reaction is a stereospecific syn addition of a CH2 group to the double bond. 

Accordingly, cyclic nitronates can be a useful synthetic equivalent of functionalized nitrile oxides, while reaction examples are quite limited. Thus, 2-isoxazoline N-oxide and 5,6-dihydro-4H-l,2-oxazine N-oxide, as five- and six-membered cyclic nitronates, were generated in-situ by dehydroiodination of 3-iodo-l-nitropropane and 4-iodo-l-nitrobutane with triethylamine and trapped with monosubstituted alkenes to give 5-substituted 3-(2-hydroxyethyl)isoxazolines and 2-phenylperhydro-l,2-oxazino[2,3-fe]isoxazole, respectively (Scheme 7.26) [72b]. Upon treatment with a catalytic amount of trifluoroacetic acid, the perhydro-l,2-oxazino[2,3-fe]isoxazole was quantitatively converted into the corresponding 2-isoxazoline. Since a method for catalyzed enantioselective nitrone cycloadditions was established and cyclic nitronates should behave like cyclic nitrones in reactivity, there would be a good chance to attain catalyzed enantioselective formation of 2-isoxazolines via nitronate cycloadditions. 

The adjacent iodine and lactone groupings in 16 constitute the structural prerequisite, or retron, for the iodolactonization transform.15 It was anticipated that the action of iodine on unsaturated carboxylic acid 17 would induce iodolactonization16 to give iodo-lactone 16. The cis C20-C21 double bond in 17 provides a convenient opportunity for molecular simplification. In the synthetic direction, a Wittig reaction17 between the nonstabilized phosphorous ylide derived from 19 and aldehyde 18 could result in the formation of cis alkene 17. Enantiomerically pure (/ )-citronellic acid (20) and (+)-/ -hydroxyisobutyric acid (11) are readily available sources of chirality that could be converted in a straightforward manner into optically active building blocks 18 and 19, respectively. 

The mechanism of oxidation probably involves in most cases the initial formation of a glycol (15-35) or cyclic ester,and then further oxidation as in 19-7. In line with the electrophilic attack on the alkene, triple-bonds are more resistant to oxidation than double bonds. Terminal triple-bond compounds can be cleaved to carboxylic acids (RC=CHRCOOH) with thallium(III) nitrate or with [bis(trifluoroacetoxy)iodo]pentafluorobenzene, that is, C6F5l(OCOCF3)2, among other reagents. 

Alkenes have also been converted to more highly oxidized products. Examples are (1) Treatment with KMn04 in aqueous acetone containing acetic acid gives a-hydroxy ketones. (2) 1,2-Disubstituted and trisubstituted alkenes give a-chloro ketones when oxidized with chromyl chloride in acetone RCH=CR R"—> RCOCCIR R". (3) a-Iodo ketones can be prepared by treating alkenes with... 

Halogenation of 106 with triphenylphosphine, iodine, and imidazole provided the iodo derivative 109. On treatment with lithium aluminum hydride, 109 was converted into two endocyclic alkenes, 110 and di-O-isopro-pylidenecyclohexanetetrol, in the ratio of 2 1. Oxidation of 110 with dimethyl sulfoxide - oxalyl chloride afforded the enone 111.1,4-Addition of ethyl 2-lithio-l,3-dithiane-2-carboxylate provided compound 112. Reduction of 112 with lithium aluminum hydride, and shortening of the side-chain, gave compound 113, which was converted into 114 by deprotection. ... 

An interesting approach to the pyrrolizidine skeleton was devised wherein pyrrole-2-carboxaldehyde (70) underwent A-allylation under basic conditions and subsequent olefmation with ethyl p-tolylsulfinylmethanephosphonate to produce the pyrrolyl alkene 71 <00TL1983>. Intramolecular Heck reaction of the iodo species then produced the 1 -p-tolylsulfinyl-1,3-diene 72. 

A novel and highly efficient synthesis of 1,1-diiodo-, 1,1-dibromo-, and mixed (Z)- or ( )-1-iodo-l-bromo-l-alkenes using the 1,1-heterobimetallic reagents obtained by hydrozirconation of stannylacetylenes has also been described [155], The hydrozirconation and halo-genolysis steps were carried out at room temperature in THF under a nitrogen atmosphere. It is noteworthy that the developed route is compatible with various functionalities... 

A synthesis of potentially useful 1-iodo-l-bromo-l-alkenes has thus been developed that offers complete stereocontrol. These methods have also proven to be highly efficient for the preparation of 1,1-diiodo-l-alkenes and 1,1-dibromo-l-alkenes, which are very useful synthetic intermediates (Scheme 7.26) [155]. 

Allyltitanium complexes derived from a chiral acetal have been reacted with carbonyl compounds and imines [63], While the chiral induction proved to be low with carbonyl compounds, high induction was observed with imines. This complex represents the first chiral homoenolate equivalent that reacts efficiently with imines. Finally, the reactions with electrophiles other than carbonyl compounds and imines, namely a proton source, NCS, and I2, furnished the corresponding alkene, chloro, and iodo derivatives in good yields [64]. 

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