Anionic cycloaddition/intramolecular

A slightly modified synthesis of dihydrobenzo[c]furan was achieved, in which the key reaction involved the exposure of a dibromide to dry alumina and one equivalent of water in toluene instead of in hexanes <07TL3039>. Another synthesis of dihydrobenzo[c]furans was reported by Hashmi and Teles <07SL1747> and an example is depicted below. Base-promoted cycloaddition of 1-aryl- or l-aryl-7-substituted-4-oxahepta-1,6-diynes in DMSO were found to involve an anionic intramolecular Diels-Alder reaction, and also resulted in the formation of dihydrobenzo[c]furans <07JA4939>. 

Some straightforward, efficient cyclopentanellation procedures were developed recently. Addition of a malonic ester anion to a cyclopropane-1,1-dicarboxylic ester followed by a Dieckmann condensation (S. Danishefsky, 1974) or addition of iJ-ketoester anions to a (l-phenylthiocyclopropyl)phosphonium cation followed by intramolecular Wittig reaction (J.P, Marino. 1975) produced cyclopentanones. Another procedure starts with a (2 + 21-cycloaddition of dichloroketene to alkenes followed by regioselective ring expansion with diazomethane. The resulting 2,2-dichlorocyclopentanones can be converted to a large variety of cyclopentane derivatives (A.E. Greene. 1979 J.-P. Deprds, 1980). 

The TT-allylpalladium complexes 241 formed from the ally carbonates 240 bearing an anion-stabilizing EWG are converted into the Pd complexes of TMM (trimethylenemethane) as reactive, dipolar intermediates 242 by intramolecular deprotonation with the alkoxide anion, and undergo [3 + 2] cycloaddition to give five-membered ring compounds 244 by Michael addition to an electron-deficient double bond and subsequent intramolecular allylation of the generated carbanion 243. This cycloaddition proceeds under neutral conditions, yielding the functionalized methylenecyclopentanes 244[148], The syn-... 

Intramolecular cycloaddition between an azide and an unsaturated ester (see 300) was the key step in the synthesis of triazole carboxylic acids 302 a, b, prospective anionic sugar mimics (Eq. 33) [79]. 

Strategies based on two consecutive specific reactions or the so-called "tandem methodologies" very useful for the synthesis of polycyclic compounds. Classical examples of such a strategy are the "Robinson annulation" which involves the "tandem Michael/aldol condensation" [32] and the "tandem cyclobutene electrocyclic opening/Diels-Alder addition" [33] so useful in the synthesis of steroids. To cite a few new methodologies developed more recently we may refer to the stereoselective "tandem Mannich/Michael reaction" for the synthesis of piperidine alkaloids [34], the "tandem cycloaddition/radical cyclisation" [35] which allows a quick assembly of a variety of ring systems in a completely intramolecular manner or the "tandem anionic cyclisation approach" of polycarbocyclic compounds [36]. 

Recently it has been shown that radical anionic cyclization of olefinic enones effectively compete with intramolecular [2 -I- 2]-cycloaddition to form spirocy-clic compounds [205, 206], 3-Alkenyloxy- and 3-alkenyl-2-cyclohexenones 235 are irradiated in the presence of triethylamine. As depicted in Scheme 46 two reaction pathways may operate. Both involve electron transfer steps, either to the starting material (resulting in a direct cyclization) or to the preformed cyclobutane derivative 239, which undergoes reductive cleavage. The second... 

This section is devoted to cyclizations and cycloadditions of ion-radicals. It is common knowledge that cyclization is an intramolecular reaction in which one new bond is generated. Cycloaddition consists of the generation of two new bonds and can proceed either intra- or intermolecularly. For instance, the transformation of 1,5-hexadiene cation-radical into 1,4-cyclohexadienyl cation-radical (Guo et al. 1988) is a cyclization reaction, whereas Diels-Alder reaction is a cycloaddition reaction. In line with the consideration within this book, ring closure reactions are divided according to their cation- or anion-radical mechanisms. 

If the mesomeric stabilization is provided by a double bond, the lithiated species is a homoenolate synthon, as shown in Scheme 44a. Reaction with an electrophile typically occurs at the y-position, yielding an enamine, which can then be hydrolyzed to a carbonyl compound. An important application of this approach is to incorporate a chiral auxiliary into the nitrogen substituents so as to effect an asymmetric synthesis. 2-AzaaUyl anions (Scheme 44b), which are generated by tin-lithium exchange, can be useful reagents for inter- and intramolecular cycloaddition reactions. ... 

Nitrogen heterocycles continue to be valuable reagents and provide new synthetic approaches such as NITRONES FOR INTRAMOLECULAR -1,3 - DIPOLAR CYCLOADDITIONS HEXAHYDRO-1,3,3,6-TETRAMETHYL-2,l-BENZISOX AZOLINE. Substituting on a pyrrolidine can be accomplished by using NUCLEOPHILIC a - sec - AM IN O ALKYL ATION 2-(DI-PHENYLHYDROXYMETHYL)PYRROLIDINE. Arene oxides have considerable importance for cancer studies, and the example ARENE OXIDE SYNTHESIS PHENANTHRENE 9,10-OXIDE has been included. An aromatic reaction illustrates RADICAL ANION ARYLATION DIETHYL PHENYLPHOSPHONATE. 

O-Quinodimethanes. A recent simple synthesis of Al") 5(lu)-estratriene-l 7-one (5)2 is based on the fact that on pyrolysis substances such as 1 lose sulfur dioxide with generation of o-quinodimethanes.1 The anion of 1 is generated most satisfactorily with KH (1.1 equivalent) in DMF. at 0°. It can be converted predominately to monoalkylated products, particularly if an excess of the anion is used. Thus reaction of the anion of 1 with 2 results in the diastereoisomers 3 and 4. After deketalization, the corresponding ketones are heated at 210" for 8 hours. The o-quinodimethane (a) is formed and undergoes intramolecular cycloaddition to form 5. 

MI1), which can formally be derived from the isoconjugated indenyl anion 1. As they are compounds with an o-quinodimethane structural element 3, they are especially suited for inter- and intramolecular cycloadditions. 

This cycloaddition can be performed with either the amino acid, the aldehyde, or the electron-poor alkene linked to the support. Intramolecular azaallyl anion cycloadditions have been used to prepare polycyclic systems on solid phase (Entries 5 and 7, Table 15.5). 

Azaallyl anion cycloadditions. Imines bearing one or more aryl groups are converted by LDA into 2-azaallyl anions. These anions undergo cycloaddition not only with activated alkenes,2 but can also undergo intramolecular cycloaddition with a double bond to form as-fused bicyclic pyrrolidines.3... 

Ethyl-2-(sulfonylmethyl)- and 2-(cyanomethyl)-allyl carbonates133 as well as (methoxycarbo-nyl)methylallyl carbonates136 serve as substrates for the [3 + 2] cycloaddition. Oxidative addition into the allylic C—O bond of the carbonate, followed by decarboxylation, gives a 2-substituted allylpalladium al-koxide. The alkoxide then deprotonates the C—H a to the electron-withdrawing substituent at the 2-position of the allyl. This anion then undergoes a Michael addition to an a,(3-unsaturated ketone or ester, followed by intramolecular allylation of the anion of the Michael product (Scheme 2). 

Bicyclic cyclotrigermanes, thermolysis, 3, 793 Bicyclic imidazoles, via intramolecular C-H functionalizations, 10, 138 Bicyclic siloxanes, rational synthesis, 3, 655 Bicycloctasilane dianion, preparation, 3, 466468 Bicyclo[5.3.0]decadiene, via [5+2]-cycloadditions, 10, 613 Bicyclo[5,3,0]-decanes, via Pauson-Khand reaction, 11, 361 Bicyclononasilane anions, preparation, 3, 466-468 Bicyclo[3.3.0]-octanones, via carbonylative carbocyclization, 11, 427... 

The intramolecular anionic cycloaddition proceeded rapidly at — 78°C after transmetallation with n-BuLi. The resulting A-lithiopyrrolidine was A-alkylated with methyl iodide to give a 1 5 mixture of 13 and 14 in which 14 predominated. Without purification, the isopropylidene group was cleaved from the unpurified mixture of 13 and 14, and the resulting... 

The Pearson syntheses of (—)-augustamine and (—)-amabiline by a common strategy are very noteworthy. They brilliantly show how the awesome power of intramolecular 2-azaallyl anion-olefin cycloadditions can be marshalled for the rapid assembly of complex pyrrolidine alkaloids with excellent efficiency and atom economy. 

We shall end this section with a beautiful illustration of an intramolecular 1,3-dipolar cycloaddition of a nitrile oxide that was used in the synthesis ofthe vitamin biotin. Starting at the beginning of the synthesis will allow you to revise some reactions from earlier chapters. The starting material is a simple cyclic allylic bromide that undergoes an efficient 5 2 reaction with a sulfur nucleophile. In fact, we don t know (or care ) whether this is an 5 2 or S 2 reaction as the product of both reactions is the same. This sort of chemistry was discussed in Chapter 23 if you need to check up on it. Notice that it is the sulfur atom that does the attack—it is the soft end of the nucleophile and better at Sn2 reactions. The next step is the hydrolysis ofthe ester group to reveal the thiolate anion. 

Twofold inter- and intramolecular PKRs have found interesting applications in synthesis of ansa-zirconocenes. An early example illustrated the use of this approach for the synthesis of cyclopentadiene anellated[2,2]para-cyclophanes 157-158. The reaction of several paracyclophanedienes (155) with alkynes gave the corresponding twofold cycloaddition products 156, which were transformed into cyclopentadienyl anions orthogonally attached to the bridges of the paracyclophane (Scheme 46) [158]. 

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