Amine compounds intramolecular cycloadditions

Sha et al. (45) reported an intramolecular cycloaddition of an alkyl azide with an enone in an approach to a cephalotaxine analogue (Scheme 9.45). Treatment of the bromide 205 with NaN3 in refluxing methanol enabled the isolation of compounds 213 and 214 in 24 and 63% yields, respectively. The azide intermediate 206 underwent 1,3-dipolar cycloaddition to produce the unstable triazoline 207. On thermolysis of 207 coupled with rearrangement and extrusion of nitrogen, compounds 213 and 214 were formed. The lactam 214 was subsequently converted to the tert-butoxycarbonyl (t-Boc)-protected sprrocyclic amine 215. The exocyclic double bond in compound 215 was cleaved by ozonolysis to give the spirocyclic ketone 216, which was used for the synthesis of the cephalotaxine analogue 217. 

Diazomethane and its simple analogs undergo cycloaddition to unsaturated compounds both directly and after conversion to carbenes. The direct cycloadditions are 1,3-dipolar for the most part and provide access to pyrazolines and pyrazoles. Intramolecular cyclizations were recognized as early as 1965 95 The two main methods used in generation of diazo compounds for subsequent intramolecular cycloaddition include thermolysis of tosylhydrazone salts and thermolysis of iminoaziridines. Decomposition of nitros-amines has also been employed. 

The simplest ylide generation method among the deprotonation route (Section II,D) consists of the condensation of N-substituted a-amino esters with carbonyl compounds. This procedure must be especially useful for utilization in intramolecular cycloadditions because the substrates for the cycloadditions are simply prepared in situ by reacting the carbonyl compounds (or secondary amines) bearing a trapping chain with secondary amines (or carbonyl compounds). 

Several ring-fused tetrazole compounds have been reported. 2-Methyl-3-cyanopyridines were converted into their corresponding 2-azidomethyl derivatives, which underwent intramolecular cycloaddition reactions to give 3-(tetrazol-5-yl)pyridines 186 <04TL9127>. Fused tetrazole derivatives 187 were obtained via tandem cycloaddition and yV-allylation reactions <04JOC1346>. Expeditive synthesis of homochiral fused tetrazole piperazines 188 from 3-amino alcohols has been reported <04TL3725>. A novel Ugi-five-center-four-component reaction (U-5C-4CR) of aldehydes, primary amines, trimethylsilyl azide and 2-isocyanoethyl tosylate afforded tetrazolopiperazine type compounds <04TL6421>. 

An efficient synthesis of rigid tricyclic (5 5 5) nitrogen heterocycles 64 has been achieved via sequential and tandem Ugi/intramolecular Diels-Alder (IMDA) cycloaddition of pyrrole derivatives <2004JOC1207> and the trienes 477 were prepared by the acylaton of amines 475 with the anhydride 476. The amines 475 were in turn prepared starting from pyrrole-2-carbaldehyde. The triene 477 on heating in toluene at 80 °C for 15 h underwent the IMDA to afford the tricyclic compound 64 as a single diastereomer in quantitative yield. The sterically bulky N-substitutent on the triene 477 promoted cycloaddition under milder condition at 65 °C in toluene to provide the tricyclic compound 64 in quantitative yield (Scheme 108). 

Scheme 1.64). The Ag(I)-mediated cyclization afforded dipole 306 for 1,3-dipolar cycloaddition with methyl vinyl ketone to yield adducts 307 and the C(2) epimer as a 1 1 mixture (48%). Hydrogenolytic N—O cleavage and simultaneous intramolecular reductive amination of the pendant ketone of the former dipolarophile afforded a mixture of alcohol 308 and the C(6) epimer. Oxidation to a single ketone was followed by carbonyl removal by conversion to the dithiolane and desulfurization with Raney nickel to afford the target compound 305 (299). By this methodology, a seven-membered nitrone (309) was prepared for a dipolar cycloaddition reaction with Al-methyl maleimide or styrene (301). 

Assembly of Diels-Mder reaction components using a Ugi reaction Furfural and related compounds (293) can serve as diene building blocks in intramolecular and intermolecular cycloadditions, as they can be attached to resin-bound amines by reductive amination [306]. Particularly versatile is the use of furfural derivatives in 4-component Ugi reactions, where the diene and the dienophile component can be present. However, in the reaction set-up the electronic characteristics of the building blocks such as HOMO/LUMO energy or electron demand have to be considered to receive high yields. In the study presented by Schreiber et al., an acrylic acid served as dienophile (Scheme 64) [307]. 

Furans are also useful 4ji components for tandem Ugi condensation/intra-molecular Diels-Alder cascade reactions. For example, stirring a methanolic mixture of compounds 127-129 and benzylamine at rt provided the Ugi condensation product 130 that underwent a subsequent intramolecular Diels-Alder cycloaddition to furnish 131 in 70-90% yield (Scheme 23) (99TL1851). This methodology also allowed for a solid phase synthesis by using an ArgoGel-Rink resin as the amine component, providing cycloadducts 131 (after cleavage from the resin) in ca. 90-95% yields. 

Using the N-(co-alkynyl)-N-alkyl-a-isocyanoacetamide 41 as a polyfunctional substrate, three-component synthesis of the azaindoline 42 was developed. By simply heating a toluene solution of 41, a primary amine and an aldehyde afforded tricyclic compound 42 in good to excellent yield [32]. A possible reaction sequence that accounted for the formation of 42 is depicted in Scheme 5.13. The sequence involved (a) a three-component synthesis of oxazole 43, (b) intramolecular D-A cycloaddition... 

The catalytic [2 + 2 + 1]-cycloaddition reaction of two carbon—carbon multiple bonds with carbon monoxide has become a general synthetic method for five-membered cyclic carbonyl compounds. In particular, the Pauson-Khand reaction has been widely investigated and established as a powerful tool to synthesize cyclopentenone derivatives.110 Various kinds of transition metals, such as cobalt, titanium, ruthenium, rhodium, and iridium, are used as a catalyst for the Pauson-Khand reaction. The intramolecular Pauson-Khand reaction of the allyl propargyl ether and amine 91 produces the bicyclic ketones 93, which bear a heterocyclic ring as shown in Scheme 31. The reaction proceeds through formation of the bicyclic metallacyclopentene intermediate 92, which subsequently undergoes insertion of CO to give 93. 

Enders described a fascinating organocatalytic one-pot asymmetric synthesis of tricyclic compounds using a triple-cascade/Diels-Alder reaction sequence. Combination of dieneal 110 with enal 111 and nitro alkene 112 in the presence of a chiral amine catalyst results in a Michael/Michael/aldol condensation sequence to yield cycloaddition precursor 113. Cooling the reaction mixture and addition of a Lewis acid promotes the desired intramolecular Diels-Alder reaction to selectively afford the highly functionalized tricyclic target 114. ... 

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