1.3- Dipolar cycloaddition betaine

A variety of 1-azirines are available (40-90%) from the thermally induced extrusion (>100 °C) of triphenylphosphine oxide from oxazaphospholines (388) (or their acyclic betaine equivalents), which are accessible through 1,3-dipolar cycloaddition of nitrile oxides (389) to alkylidenephosphoranes (390) (66AG(E)1039). Frequently, the isomeric ketenimines (391) are isolated as by-products. The presence of electron withdrawing functionality in either or both of the addition components can influence the course of the reaction. For example, addition of benzonitrile oxide to the phosphorane ester (390 = C02Et) at... 

Dipolar cycloadditions of dihydropyrimidine-fused mesomeric betaines 389, 391 and 394 with different dipolarophiles afforded 6-oxo-6H-pyrido[l,2-n]pyrimidine-3-carboxylates 390, 392, 393 and 396 (97JOC3109). 

Dipolar cycloaddition of betaines 492 gave cycloadducts 493, which produced tricyclic compounds 494 on further thermolysis (Scheme 48) <1995H(41)1631>. Heating 9,9-disubstituted yr/ra-(4-hydroxy-2-oxo-2//-pyrido-[2. -//][ 1.3]thiazinium) hydroxides 495 afforded tricyclic compounds 497 as diastereomeric mixtures (Scheme 49) <1995S973>. In the case of the lower homolog (n = 0), a cycloadduct 496 could be also isolated at lower temperature. 

Dipolar cycloaddition of pyrido[2,l-A][l,3]thiazinium betaine 507 (R = Me) with 1-diethylamino-l-propyne afforded cycloadduct 508, from which quinolizin-4-one 509 formed by a rapid cheletropic extrusion of COS (Scheme 53) <1995T6651>. 1,4-Dipolar cycloaddition of 507 and 4-phenyl-l,2,4-triazoline-3,5-dione yielded 511 (via 510) <1995H(41)1631> and 512 <1995T6651>. 

The Diels-Alder cycloaddition potential of fused 4-aryldihydropyrimidine mesomeric betaines has been studied. The cross-conjugated thiazinium betaine 317 underwent 1,4-dipolar cycloaddition with electron-rich dipolaro-philes, and thus 1-diethylaminoprop-l-ine gave the pyrido[l,2-tf]pyrimidine 318 by loss of carbonyl sulfide (Equation 34). Reaction of 317b with 1,1-diethoxyethene resulted in the 8-ethoxy analogue of 318 (R = H) <1997JOC3109>. 

In general, conjugated heterocyclic mesomeric betaines are associated with 1,3-dipoles and cross-conjugated heterocyclic mesomeric betaines are associated with 1,4-dipoles. The dipolar cycloaddition reactions of both types of heterocyclic mesomeric betaines have been widely investigated and its use for the preparation of a diverse variety of heterocyclic compounds was duly covered in CHEC-II(1996) <1996CHEC-II(8)747>. 

To investigate the feasibility of employing 3-oxidopyridinium betaines as stabilized 1,3-dipoles in an intramolecular dipolar cycloaddition to construct the hetisine alkaloid core (Scheme 1.8, 77 78), a series of model cycloaddition substrates were prepared. In the first (Scheme 1.9a), an ene-nitrile substrate (i.e., 83) was selected as an activated dipolarophile functionality. Nitrile 66 was subjected to reduction with DIBAL-H, affording aldehyde 79 in 79 % yield. This was followed by reductive amination of aldehyde x with furfurylamine (80) to afford the furan amine 81 in 80 % yield. The ene-nitrile was then readily accessed via palladium-catalyzed cyanation of the enol triflate with KCN, 18-crown-6, and Pd(PPh3)4 in refluxing benzene to provide ene-nitrile 82 in 75 % yield. Finally, bromine-mediated aza-Achmatowicz reaction [44] of 82 then delivered oxidopyridinium betaine 83 in 65 % yield. 

Each of the 3-oxidopyridinium betaine substrates 83, 91, and 98 were extensively investigated for their potential to engage in intramolecular dipolar cycloaddition (Scheme 1.10). Heating a solution of ene-nitrile 83 in variety of solvents failed to effect the desired intramolecular [3+2] dipolar cycloaddition to form the bridged pyrrolidine 100, as tricyclic oxidopyridinium betaine 103 was the only... 

Despite the lack of success in the attempts at intramolecular cycloaddition with substrates 83 and 91, a moderately promising outcome was observed for the nitroalkene substrate (98, Scheme 1.10c). Heating a dilute solution of oxido-pyridinium betaine 98 in toluene to 120 °C produced a 20 % conversion to a 4 1 mixture of two cycloadducts (110 and 112), in which the major cycloadduct was identified as 110. While initially very encouraging, it became apparent that the dipolar cycloaddition reaction proceeded to no greater than 20 % conversion, an outcome independent of choice of reaction solvent. Further investigation, however, revealed that the reaction had reached thermodynamic equilibrium at 20 % conversion, a fact verified by resubmission of the purified major cycloadduct 110 to the reaction conditions to reestablish the same equilibrium mixture at 20 % conversion. 

Scheme 1.13 Intramolecular dipolar cycloaddition of nitroalkene oxidoisoquinolinium betaine 123...

Scheme 1.15 Intramolecular dipolar cycloaddition of ene-nitrile oxidoisoquinolinium betaine 131...

The ring expansion reaction of diaryl cyclopropenones and cyclopropene thiones occurring with pyridinium, sulfonium, and phosphonium enolate betaine 427268-270) is related to 1,3-dipolar cycloadditions. This process results in formation of 2-pyrones 428 by loss of pyridine (or sulfide or phosphine) and insertion of the remaining fragment C=C-0 to the C1(2)/C3 bond of the cyclopropenone ... 

The betainic imidazo[l,2- 7][l,2,4]triazinium-olate 107 was found to react as a 1,3-dipole in 1,3-dipolar cycloaddition with ynamines to yield a bridged skeletone 108 <1999T13703> as shown in Scheme 15. This cycloadduct 108 underwent subsequent rearrangement upon heating, and resulted in formation of a fused eight-membered heterocycle 109. With acetylenes other than ynamines, the transformation was found to proceed slowly and in bad yields. The fact that ynamines were used successfully, as well as theoretical considerations (cf. Section 11.17.2) in this chapter, indicated that these Diels-Alder reactions are of inverse electron demand. 

Mechanisms that are probably associated, respectively, with these processes are (i) the formation of betaine intermediates (306) (Fig. 3) 103,143,149,197,200 homolysis or heterolysis of the X—Z bond (304) or the X—Z bond (305) giving diradicsd (307) or dipolar (308) intermediates, (iv) 1,3-dipolar cycloaddition yielding intermediate adducts (e.g, 309), The base-catalyzed rearrangements (ii) present very interesting mechanistic problems suitable for speculation and experimental enquiry. 

The formation of various 1 1 adducts from dehydrodithizone 413, R = R = Ph, and various 1,3-dipolarophiles has been reported. Thus, dimethyl acetylenedicarboxylate yields 419, X = COOMe, tetra-cyanoethylene yields 420, and e oxycarbonylmethylenetriphenylphos-phorane yields the betaine 421. These transformations have been considered as 1,3-dipolar cycloaddition reactions of a novel type. It seems to us rather unlikely that these transformations are concerted 1,3-dipolar cycloadditions the alternative that they are reactions involving dipolar intermediates (e.g., 422, 423, and 424) should also be considered. The... 

The structural requirements of the mesomeric betaines described in Section III endow these molecules with reactive -electron systems whose orbital symmetries are suitable for participation in a variety of pericyclic reactions. In particular, many betaines undergo 1,3-dipolar cycloaddition reactions giving stable adducts. Since these reactions are moderately exothermic, the transition state can be expected to occur early in the reaction and the magnitude of the frontier orbital interactions, as 1,3-dipole and 1,3-dipolarophile approach, can be expected to influence the energy of the transition state—and therefore the reaction rate and the structure of the product. This is the essence of frontier molecular orbital (EMO) theory, several accounts of which have been published. 16.317 application of the FMO method to the pericyclic reactions of mesomeric betaines has met with considerable success. The following section describes how the reactivity, electroselectivity, and regioselectivity of these molecules have been rationalized. 

Fig. 7. Exemplifying two distinct modes of symmetry allowed cycloaddition of mesomeric-betaines (a) conventional 1,3-dipolar cycloaddition (b) addition across peri positions.

Dipolar cycloaddition of anhydro pyrido[2,l-b][l,3]thiazinium hydroxides (128) with aryl isocyanates and dimethyl acetylenedicarboxylate gave pyrido[l,2]pyrimidines (129) and quinolizine-l,2-dicarboxylates (130), respectively (76CB3668). 1,4-Dipolar cycloaddition of pyrido[2,l-h][l,3]thi-azinium betaine (131, R = Me) with 1-diethylamino-l-propyne afforded cycloadduct 132, from which quinolizin-4-one 133 formed by a rapid cheletropic extrusion of carbonyl sulfide (93TL5405 95T6651). 1,4-Dipolar cycloaddition of anhydro 4-hydroxyl-2-oxo-6,7,8,9-tetrahydro-2//-pyrido-[2,l-b][l,3]thiazinium hydroxides (131) and 4-phenyl-l,2,4-triazoline-3,5-dione yielded 135 via 134 [94H(39)219 95H(41)1631] and 136 (95T6651). 

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