Manganese-mediated radical addition

Because disconnection of a-alkoxy-y-amino acid 28 calls for (3-alkoxyhydra-zone 30, the potential for (3-elimination of the alkoxy group from the hydrazone precursor 30 (Scheme 7) makes non-basic conditions critical. In fact, treatment of 30 with TBAF in THF led to just such a (3-elimination (Marie, University of Iowa, unpublished). However, the manganese-mediated radical addition of isopropyl iodide proceeded in 77% yield, without any evidence of (3-elimination, to afford 31 as a single diastereomer. Reductive removal of the chiral auxiliary and oxidation to the carboxylic acid gave 28 in good overall yield [103]. 

Phenylacetaldehyde /V-acylhydrazone 32 served as the radical acceptor for assembly of y-amino acid 29 (Scheme 8), employing difunctional iodide 33 in the manganese-mediated radical addition (56% yield, single diastereomer) [103]. As with 31 (shown above), this radical adduct 34 was converted through the same four-step sequence to y-amino acid 29. 

Although the aforementioned routes provided the desired y-amino acids, it was desirable to develop a synthesis which incorporates the carboxylic acid oxidation state prior to coupling. We hypothesized that manganese-mediated radical addition would accomplish this objective, and therefore initiated a study of manganese-mediated coupling of alkyl iodides with y-hydrazonoesters [104]. We had already shown that the manganese-mediated radical addition conditions offer excellent chemoselectivity, but it remained to be seen whether the stereocontrol model would be disrupted would an additional Lewis basic ester function in the hydra-zone interfere with the role of In(III) in two-point binding and rotamer control ... 

Fig. 49 Electrochemically mediated manganese-catalyzed radical additions...

To date, several protocols for Knoevenagel additions to protected carbohydrates or carbohydrate-derived molecules have been reported in the literature [36]. For a manganese(III)- or cerium(IV)-mediated radical addition of malonates to protected carbohydrates, see Reference 37. For early reactions of protected carbohydrates with malonic acid in basic medium (pyridine), see Reference 6j. 

An efficient modification of the manganese(III) mediated malonate radical addition to styrene has been examined. Use of cerium(IV) nitrate in methanol at room temperature results in the direct formation of the butyrolactone 17 in low yield along with other byproducts [95JCS(P1)1881]. Other intermolecular single electron processes for the formation of lactones have been reported [95JOC458] [95BCSF843],... 

The simple piperidine alkaloid coniine (for selected asymmetric syntheses of coniine see [22, 81-85]) offered a preliminary test case for hybrid radical-ionic annulation in alkaloid synthesis. From butyraldehyde hydrazone and 4-chloro-iodobutane (Scheme 4), manganese-mediated photolysis afforded the acyclic adduct in 66% yield (dr 95 5) the cyclization did not occur in situ [69, 70]. Nevertheless, Finkelstein conditions afforded the piperidine, and reductive removal of the auxiliary afforded coniine in 34% overall yield for four steps. This reaction sequence enables a direct comparison between radical- and carbanion-based syntheses using the same retrosynthetic disconnection an alternative carbanion approach required nine to ten steps [81, 85]. The potential for improved efficiency through novel radical addition strategies becomes quite evident in such comparisons where multifunctional precursors are employed. 

Prototypical radical additions were examined under manganese-mediated photolysis conditions with InCp as the Lewis acid, coupling isopropyl iodide with a variety of y-hydrazonoesters 35a-35d (Table 6) bearing varied substitution at the position a to the ester. The a-methyl, a,a-dimethyl, and a-benzyloxy substituents appeared to have little effect on reaction efficiency and selectivity, as all provided the isopropyl adducts with consistently high diastereoselectivities and excellent yields (91-98%). Surprisingly, the selectivity was only slightly... 

Despite the development of various intermolecular radical addition methods, those studies have rarely accommodated additional functionality, our discovery of the manganese-mediated photolysis conditions notwithstanding. Prior to that discovery, we began to elaborate an alternative strategy which employs temporary tethers ([115, 116] reviews of silicon-tethered reactions [117-120]) (silyl ether or acetal linkages) linking radical and acceptor. In this scenario the C-C bond is constructed via cyclization, in which internal conformational constraints can control diaster-eoselectivity. The tether itself would be converted to useful functionality upon cleavage, and once the tether is cleaved the net result may be considered as formal acyclic stereocontrol. ... 

A combination of radical and electron transfer steps mediated by manganese triacetate has been used in the synthesis of 5-acetoxyfuranones 21 through carbox-ymethyl radical addition to mono- and disubstituted alkynes 20, followed by oxidative cyclization of the resulting vinyl radicals 22 (Scheme 2.4). The cyclic intermediate 24 is transformed into the furanone 21 through stepwise one-electron oxidation and capture of the resulting aUyl cation 26 by acetate. 

Manganese(III)-mediated radical reactions have become a valuable method for the formation of carbon-carbon bonds over the past thirty years since the oxidative addition of acetic acid (1) to alkenes to give y-butyrolactones 6 (Scheme 1) was first reported by Heiba and Dessau [1] and Bush and Finkbeiner [2] in 1968. This method differs from most radical reactions in that it is carried out under oxidative, rather than reductive, conditions leading to more highly functionalized products from simple precursors. Mn(III)-based oxidative free-radical cyclizations have been extensively developed since they were first reported in 1984-1985 [3-5] and extended to tandem, triple and quadruple cyclizations. Since these additions and cyclizations have been exhaustively reviewed recently [6-11], this chapter will present an overview with an emphasis on the recent literature. 

Manganese(III) can oxidize carbonyl compounds and nitroalkanes to carboxy-methyl and nitromethyl radicals [186]. With Mn(III) as mediator, a tandem reaction consisting of an intermolecular radical addition followed by an intramolecular electrophilic aromatic substitution can be accomplished [186, 187). Further Mn(III)-mediated anodic additions of 1,3-dicarbonyl and l-keto-3-nitroalkyl compounds to alkenes and alkynes are reported in [110, 111, 188). Sorbic acid precursors have been obtained in larger scale and high current efficiency by a Mn(III)-mediated oxidation of acetic acid acetic anhydride in the presence of butadiene [189]. Also the nitromethylation of benzene can be performed in 78% yield with Mn(III) as electrocatalyst [190]. A N03 radical, generated by oxidation of a nitrate anion, can induce the 1,4-addition of aldehydes to activated olefins. NOj abstracts a hydrogen from the aldehyde to form an acyl radical, which undergoes addition to the olefin to afford a 1,4-diketone in 34-58% yield [191]. 

In 2009, Chiba s group reported a manganese-mediated synthesis of pyridines from cyclopropanols with vinyl azides [70]. In the presence of 1.7 equivalents of Mn(AcAc)3, a variety of pyridine derivatives have been prepared in good yields at room temperature. In their further studies, they realized this transformation in a catalytic manner [71]. In their mechanistic studies, they found the reactions were initiated by a radical addition of /3-carbonyl radicals, generated by the one-electron oxidation of cyclopropanols with Mn(III), to vinyl azides to give imi-nyl radicals, which cyclized with the intramolecular carbonyl groups. Additionally, the application of this newly developed methodology in the synthesis of quaternary indole alkaloid, melinonine-E, was accomplished as well (Scheme 3.33). 

Friestad, G.K. and Qin, J., Intermolecular alkyl radical addition to chiral N-acylhydrazones mediated by manganese carbonyl,/. Am. Chem. Soc., 123, 9922, 2001. 

In addition to catalyzing the oxidation of many compounds, LiP is also able to catalyze reductive reactions in the presence of electron donors such as EDTAor oxalate (Fig. 7) (6, 77). Veratryl alcohol is a free radical mediator in these reactions. The electron donors appear to be oxidized by a LiP generated veratryl alcohol cation radical. The resulting anion radical can catalyze the reduction of good electron acceptors such as cytochrome c, nitroblue tetrazolium, and oxygen. Evolution of CO2 from EDTA or oxalate effectively drives the reductive reactions. Similar reactions have also been observed with the manganese dependent peroxidases in the presence of quinones (20). Early work performed in our laboratory showed that these reductive mechanisms are not involved in TNT reduction. However, these reactions may be involved in other steps in TNT metabolism. 

Radical reaction of [60]fullerene (459) with phosphites or phosphine oxide (460) mediated by manganese(III) acetate dihydrate in chlorobenzene under three dilferent reaction conditions afforded three different types of phosphorylated fullerenes hydrophosphorylated fullerenes (461), singly bonded fullerene dimers (462), and acetoxylated fullerene derivatives (463) (Scheme 114). In addition, interconversions among the three types of phosphorylated fullerene derivatives have also been investigated. ... 

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