Iodine atom transfer reactions

Triethylborane in combination with oxygen provides an efficient and useful system for iodine atom abstraction from alkyl iodide, and thus is a good initiator for iodine atom transfer reactions [13,33,34]. Indeed, the ethyl radical, issued from the reaction of triethylborane with molecular oxygen, can abstract an iodine atom from the radical precursor to produce a radical R that enters into the chain process (Scheme 13). The iodine exchange is fast and efficient when R is more stable than the ethyl radical. 

Scheme 13 Mechanism of the Et3B-mediated iodine atom transfer reaction...

Iodine atom transfer reactions between alkyl radicals and iodocarbonyls are very rapid (107 M-1 s-1 to 109 M-1 s-1).130 This means that, even when these iodides are cyclized by the tin hydride method, iodine atom transfer may supersede hydrogen transfer, and the reductively cyclized product will ultimately be derived from the reduction of a cyclic iodide. Tin hydride cyclizations of halocarbonyls also often require very low concentration to avoid reduction of the initial radical prior to cyclization. For these reasons, reductively cyclized products are best formed by atom transfer cyclization at high concentration, followed by reduction of the product in situ. In a recent full paper, we have described in detail the preparative and mechanistic features of these cyclizations,19 and Jolly and Livinghouse have reported a modification of our reaction conditions that appears to be especially useful for substrates that cyclize very slowly.131 Cyclizations of a-iodocarbonyls can also be promoted by palladium.132... 

Naito has also described analogous tandem radical addition-cyclization processes under iodine atom-transfer reaction conditions [16,32], Treatment of 186 with z-PrI (30 eq.) and triethylborane (3x3 eq.) in toluene at 100 °C gave, after cleavage from the resin, the desired lactam product 190 in 69% yield (Scheme 46). Similar reactions involving cyclohexyl iodide, cyclopentyl iodide, and butyl iodide were also reported as well as the reaction with ethyl radical from triethylborane [16,32], The relative stereochemistry of the products was not discussed. 

Triethylborane in combination with oxygen provides an efficient and useful system for iodine atom abstraction from alkyl iodides and therefore is a good initiator for iodine atom transfer reactions.6 Indeed, the ethyl radical, issuing... 

Triethylborane is also an excellent initiator for intramolecular iodine atom transfer reactions. For example, cyclisation of the propargyl a-iodoacetal depicted in Scheme 6.5 gives the corresponding bicyclic vinyl iodide in high yield.10 Allyliodoacetamides (Scheme 6.5) and allyl iodoacetates (Scheme 6.5) cyclise cleanly under Et3B-02 initiation. In the case of the ester, the reaction has to be run in refluxing benzene in order to allow Z/E-ester isomerisation prior to... 

The reaction of the iodoalkene (178) with Pd(dppe)2 in HMPA followed by reduction with tributyltin hydride gave a mixture of the 6-exo trans product (179), the 6-exo cis product (180), and the 1-endo product (181) in a ratio of 1 1 2 in combined yield of 76% (Equation (18)), identical to the result of using hexalkylditin in benzene <90TL933>. This has led Curran and Chang to propose that the low valent palladium ene-halogenocyclization should be classed as a radical chain reaction that proceeds by way of an atom transfer mechanism and that palladium(O) may be a useful substitute for ditin in other iodine atom transfer reactions. 

The kinetics of the iodine-atom transfer reaction Ar + ArT -> Arl + Ar O o) two-step process involving an intermediate [ArlAr ] (generated independently by electrolytic reduction of [Arl Ar ]) over the single-step process with [ArlAr ] as a transition state, proposed by other workers. 

Cyclizations involving iodine-atom transfers have been developed. Among the most effective examples are reactions involving the cyclization of 6-iodohexene derivatives. The 6-hexenyl radical generated by iodine-atom abstraction rapidly cyclizes to a cyclo-pentylmethyl radical. The chain is propagated by iodine-atom transfer. 

These reactions result in iodine atom transfer and introduce a potential functional group into the product. The trialkylborane method of radical generation can also be used in conjunction with either tri-n-butyl stannane or fnT-(trimethylsilyl)silane, in which case the product is formed by hydrogen atom transfer. 

Reaction conditions have been developed in which the cyclized radical can react in some manner other than hydrogen atom abstraction. One such reaction is an iodine atom transfer. The cyclization of 2-iodo-2-methyl-6-heptyne is a structurally simple example. 

The fact that the cyclization is directed toward an acetylenic group and leads to formation of an alkenyl radical is significant. Formation of a saturated iodide could lead to a more complex product mixture because the cyclized product could undergo iodine atom transfer and proceed to add to a second unsaturated center. Vinyl iodides are much less reactive and the reaction product is unreactive. Owing to the potential... 

Scheme 3.32. Products and mechanism of an iodine atom transfer radical domino reaction.

Cyclizable radical-probe experiments have been extensively used in ET versus Spj2 investigations (see Ashby, 1988, and references cited therein). Attention has, however, been recently drawn to causes of possible misinterpretation, particularly in the case of iodides, where an iodine-atom-transfer chain mechanism is able to convert most of the starting linear iodide into the cyclized iodide, even if only a minute amount of linear-chain radical is present in 7-8 2 reactions (Newcomb and Curran, 1988). Rather puzzling results were found in the reaction of (CH3)3Sn ions with secondary bromides, which should not be involved in atom-exchange chain reactions... 

By contrast, for iodide 18 having the triple bond activated by a phenyl group, conversion to the cyclic organozinc species 25 occurred effectively and the latter could be efficiently functionalized, provided that traces of moisture were excluded by pre-treatment of zinc powder with Mel. The substituted benzylidene cyclopentanes 26 and 27 were respectively obtained after iodinolysis and palladium-catalyzed cross-coupling reaction with benzoyl chloride (equation 10). However, it could not be assessed whether the formation of organozinc 25 was attributable to an anionic or a radical cyclization pathway (or both) as, had iodide 26 been produced by a radical iodine atom-transfer, it would have been converted to 25 by reaction with metallic zinc due to the presence of the activating phenyl group21. 

In the atom-transfer reactions of iodine from aryl iodides to phenyl radical, intervention of [9-1-2] aryl(phenyl)-A3-iodanyl radicals is proposed [Eq. (86)] [3]. The ab initio molecular orbital study indicates that the diaryl-A3-iodanyl radicals are transition states in the atom-transfer reactions, but not intermediates [161]. Examples obtained by ab initio molecular orbital calculations with the B3LYP/6 - 31G(d) level are shown in Fig. 2. 

Radical cyclization with iodine atom transfer of a highly functionalized propiolic ester 103 using dibenzoyl peroxide as an initiator gave the a-methylene-y-butyrolactone 104 in good yield [95T11257]. The relative stereochemistry at carbon atoms 4 and 5 are established during the reaction. The intermediate 104 has been converted to the anti-tumor agent (-)-methylenolactocin 105. 

In the presence of an alkyl iodide, selective alkyl radical addition to the C-atom of the imine generated in situ occurs, overcoming the competitive phenylation reaction (Equation 14.20) [30]. The Ph- radical, generated by decomposition of the diazonium salt, as described before, generates the alkyl radical by selective iodine atom transfer (Equation 14.21). 

Fig. 39 Pd-catalyzed iodine atom transfer cyclization reactions...

Miyabe et al. developed a tandem addition/cycUzation reaction featuring an unprecedented addition of alkoxycarbonyl-stabihzed radicals on oxime ethers [117], and leading to the diastereoselective formation of /1-amino-y-lactone derivatives [118,119]. The reaction proceeds smoothly in the absence of toxic tin hydride and heavy metals via a route involving a triethylborane-mediated iodine atom-transfer process (Scheme 37). Decisive points for the success of this reaction are (1) the differentiation of the two electrophilic radical acceptors (the acrylate and the aldoxime ether moieties) towards the nucleophilic alkyl radical and (2) the high reactivity of triethylborane as a trapping reagent toward a key intermediate aminyl radical 125. The presence of the bulky substituent R proved to be important not only for the... 

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