Aldol reaction allyl rearrangement

Treatment of 2,4,6-triphenylpyrylium perchlorate with 3-benzo[i>]-thienylmethylmagnesium bromide affords the 4//-pyran (155),460 which undergoes allylic rearrangement in diethylene glycol in the presence of sodium to give the 2//-pyran (156).461 Under the same reaction conditions 156 is further converted by an intramolecular aldol condensation into 3-(2,4,6-triphenylphenyl)benzo[6]thiophene. 

The reaction is very slow in acetic acid alone, and accelerated as acetate by the addition of bases [59]. These two isomers undergo Pd-catalysed allylic rearrangement with each other. 3-Acetoxy-l,7-octadiene (139) is converted to the allylic alcohol 157 and to the enone 158, which is used as a bisannulation reagent [60], Thus Michael addition of 158 to 2-methylcyclopentanedione (159) and aldol condensation give 160. The terminal alkene is oxidized using PdCl2/CuCl/02 to the methyl ketone 161. After reduction of the double bond in 161, aldol condensation affords the tricyclic system 162. 

Lanthanide Lewis acids catalyze many of the reactions catalyzed by other Lewis acids, for example, the Mukaiyama-aldol reaction [14], Diels-Alder reactions [15], epoxide opening by TMSCN and thiols [14,10], and the cyanosilylation of aldehydes and ketones [17]. For most of these reactions, however, lanthanide Lewis acids have no advantages over other Lewis acids. The enantioselective hetero Diels-Alder reactions reported by Danishefsky et al. exploited one of the characteristic properties of lanthanides—mild Lewis acidity. This mildness enables the use of substrates unstable to common Lewis acids, for example Danishefsky s diene. It was recently reported by Shull and Koreeda that Eu(fod)3 catalyzed the allylic 1,3-transposition of methoxyace-tates (Table 7) [18]. This rearrangement did not proceed with acetates or benzoates, and seemed selective to a-alkoxyacetates. This suggested that the methoxy group could act as an additional coordination site for the Eu catalyst, and that this stabilized the complex of the Eu catalyst and the ester. The reaction proceeded even when the substrate contained an alkynyl group (entry 7), or when proximal alkenyl carbons of the allylic acetate were fully substituted (entries 10, 11 and 13). In these cases, the Pd(II) catalyzed allylic 1,3-transposition of allylic acetates was not efficient. 

There are two main synthetic applications where the reaction of an allyl system with electrophiles is accompanied by an allylic rearrangement. One consists of the use of heteroatom-substituted allylic anions as homoenolate anion equivalents and the other represents a synthetically valuable alternative to the aldol reaction by addition of allyl metal compounds to aldehydes. 

Prior chapters have covered the use of transition metals in asymmetric hydrogenations ( 6.2 and 7.1), hydroborations ( 7.3), hydrosilylations and hydro-cyanations ( 6.3, 6.4, 7.4 and 7.5), cyclopropanations ( 7.19), aldol reactions ( 6.11), allylations of carbanions ( 5.3.2), and some sigmatropic rearrangements ( 10.3). This chapter covers other reactions catalyzed by transition metal complexes including coupling of organometallic reagents with vinyl, aryl or allyl derivatives, Heck reactions allylamine isomerizations, some allylation reactions, car-bene insertions into C-H bonds and Pauson-Khand reactions. 

There is a change in the regiochemical course for Claisen rearrangement" of a letrahydropyridyl allyl ether by BFj-OEtj. The problem in stereocontrol of the aldol reaction involving cyclic ketones and aldehydes can be solved by way of the rearrangement of hydroxyalkyl epoxides." Ultimately, it rests on the proper choice of the haloalkenes. 

In 1998, Kawahara and Nagumo reported the first total synthesis of a member of the TAN1251 series [63] and five years later both authors revisited the TAN1251A alkaloid by means of a new enantioselective synthesis (see Section 5.6). The retro synthetic analysis of TAN 1251A is outlined in Scheme 37. The target compound could be obtained by aldol reaction of tricyclic lactam 119, whose disconnection at the amide bond led to the bicyclic amino acid 120, which could be prepared from azaspirocyclic compound 121 by means of alkylation of the secondary amine and Mitsunobu-type chemistry. Azabicycle 121 may be prepared by an intramolecular alkylation of 122, which in turn could be available from allyl derivative 123. The latter can be prepared from carboxylic acid 124 by alkylation and subsequent Curtius rearrangement. 

These amidines have been extensively applied to dehydrohalogenation in organic synthesis and in some cases DBU (1) is more effective than DBN (2) [5]. A double bond can be also introduced into organic molecules by elimination of sulfonate ester instead of the halogen atom (i.e. dehydrosulfonation in addition to dehydrohalogenation). Furthermore, these amidines can be applied to the Wittig reaction [6], aldol condensation [6], 1,3-allyl rearrangement [7] and epimerization of the (3-lactam skeleton (at Ce of the penicillic acid derivatives). Sterically hindered phenols (e.g. 2,6-di(ferf-butyl)-4-fluorophenol) are (9-acetylated with DBU (1), which is superior to sodium hydroxide in the synthesis [8]. 

With 41 in hand, a two-step nitro reduction and protection, followed by partial reduction of the lactam and resulting cyclization furnished aminal 42. Further treatment with cyanogen azide generated Wcyanoamidine 43. Hydrolysis and amide protection followed by alkylation with allyl iodide yielded olefin 44 as a single diastereomer. Conversion of 44 to aldehyde 45 was the followed reaction of the mesylate with azide, a cross-aldol reaction with acetone, lactam reprotection with Boc, and trimethylphosphine-mediated reductive rearrangement to provide spiro-y-lactam 46. Methyllithium addition to lactam 46 and similar chemistry as reported by Qin et al. gave communesin F (17) (Scheme 6). 

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