Aluminum reductive ring opening with

When dienones such as 55 are subjected to the epoxidation conditions the electron-poorer C=C double bond is selectively epoxidized. The other C=C bond can be functionalized further, for example, it can be dihydroxylated, as shown in the synthesis of the lactone 56 (Scheme 10.11) [82]. Stannyl epoxides such as 57 (Scheme 10.11, see also Table 10.8, R1 = n-Bu3Sn) can be coupled with several electrophiles [72], reduction of chalcone epoxide 58 and ring opening with alkyl aluminum compounds provides access to, e.g., the diol 59 and to phenylpropionic acids (for example 60). Tertiary epoxy alcohols such as 61 can be obtained with excellent diastereoselectivity by addition of Grignard reagents to epoxy ketones [88, 89]. 

Nitrogen azoles are less easily reductively ring opened benzimidazole with lithium aluminum hydride simply gives 2,3-dihydrobenzimidazole. 

Hydrogenation of 2-isoxazolines over Raney nickel as catalyst and in the presence of acids often leads first to 1,3-hydroxyimines, and then, through hydrolysis, to 1,3-hydroxycarbonyl compounds. In some cases the stereochemical integrity of the starting material is maintained, but in others hydrolysis of the intermediate imines may cause scrambling of stereochemistry at the a-carbon atom. Rapid protonation of the imine function minimizes this possibility and the use of Lewis acids, such as boron trichloride or aluminum trichloride which release hydrochloric acid on contact with moist methanol, is frequently recommended. Boric acid serves a similar purpose and is effective in, for example, the stereocontrolled reductive ring opening of the 2-isoxazoline (135) en route to crispatic acid (136 Scheme 6). ... 

Access to the pharmacologically useful hexahydro-2,5-diazocines (see Section V) has been provided by reductive ring opening of imidazoisoindolones. Sulkowski and co-workers, in most of such reports, reacted o-aroylbenzoic acids with 1,2-diamines, producing compounds 46. These latter compounds were reduced with lithium aluminum hydride, aflbrding diazocines 47... 

Various aluminum hydrides have been found to induce the reductive ring opening of [2.2.1] and [3.2.1] oxabicydic compounds. Metz found that the treatment of sultone 258 with Red-Al resulted in the overall net SN2 addition of hydride and ring opening [165]. When 260 was found to also give 261 under the same reaction conditions, the mechanism postulated to account for this transformation was an initial deprotonation of the sultone 258 by Red-Al and ring opening, followed by the 1,6-delivery of hydride via aluminate 259, and stereoselective protonation, Eq. 162. 

The reductive ring opening of 330a with sodium cyanoborohydride/titanium tetrachloride in acetonitrile occurs with no ester reduction whatsoever to provide 421 in 83% yield. Subsequent conversion to the tosylate followed by reduction with lithium borohydride/lithium triethylborohydride affords in 61% yield the crystalline diol 422. Lithium aluminum hydride or sodium borohydride reduction of the tosylate of 421 fails to produce clean reductions to 422. Epoxide ring closure of 422 is achieved with two equivalents of sodium hydroxide in methanol to fiimish in 93% yield (2 S, 3i )-2-benzyloxy-3,4-epoxybutan-l-ol (423) [140] (Scheme 94). 

Aryl-4,5-dihydropyridazine-3(2//)-one undergoes ring opening when submitted to Wolff-Kishner reduction, while with lithium aluminum hydride the corresponding 2,3,4,5-tetrahydro product is obtained. 

Reductive opening of the oxirane ring of 188 with lithium aluminum hydride, and acetylation with acetic anhydride-DMAP, provided the pen-... 

Moreover, alcohol functionalities have been introduced into the polynor-bornene (PNB) backbone by copolymerization of norbornene with a few percent of 5-acetate norbornene and subsequent acetate reduction. After transformation of the pendant hydroxyl functions into diethyl aluminum alkoxides, sCL has been ring opening polymerized (Scheme 31). Owing to the controlled/ liv-ing character of both polymerization processes the isolated poly(NB- -CL) graft copolymers were characterized by well-defined composition, controlled molecular weight and branching density, and narrow MWD (PDI=1.2-1.4) [92]. 

The photochemical ring opening of chrom-3-enes (29) has been shown to produce o-quinoneallides (30). These have been trapped as the phenols (31) and (32) by their in situ reduction with lithium aluminum hydride (67JPC4045). The reverse process, thermal electrocyclic ring closure of the allide, is a facile reaction and hence any synthesis of an o -quinoneallide is effectively a synthesis of a chrom-3-ene. Many chromene syntheses are considered to proceed through the intermediacy of a quinoneallide and all of these are... 

Catalytic hydrogenolysis of 1,1-difluorocyclopropanes occurs at the C2-C3 bond with partial retention of fluorine in the cases studied [49] (equation 38) In contrast, reduction of acetoxy 1,1 difluorocytlopropanes with lithium aluminum hydride occurs with loss of fluoride to give (3-fluoroallyl alcohols, often with high stereose lectivity [50] (equation 39) A further variant involving free radical intermediates produces allylidene difluorides after ring opening [5/] (equation 40)... 

Ascarylose (94) and the (35) deuterium-labeled ascarylose were prepared starting from methyl a-L-rhamnopyranoside via the 2,3-anhydro sugar 120 (Scheme 34).204 Opening of the epoxide ring with lithium aluminum hydride in THF led selectively to the 3-deoxy derivative. If reduction was performed with lithium aluminum deuteride, the methyl (3S)-[32H]ascaryloside (3S)-[32H]119 was obtained. 

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