Dipolarophiles synthesis

Additional examples of supported dipolarophile synthesis of isoxazolines are shown in Table 2. 

A versatile method for the synthesis of a variety of five-membered heterocycles and their ring-fused analogs involves the reaction of a neutral 47r-electron-3-atom system with a 27T-electron system, the dipolarophile, which is usually electron deficient in nature. Available evidence, e.g. retention of dipolarophile stereochemistry in the product and solvent polarity exerting only a moderate influence on the reaction, indicates that the cycloaddition proceeds via a concerted mechanism 63AG(E)565, 63AG(E)633, 68JOC2291) and may be represented in general terms by the expression in Scheme 8. 

Use of mesoionic ring systems for the synthesis of five-membered heterocycles with two or more heteroatoms is relatively restricted because of the few readily accessible systems containing two heteroatoms in the 1,3-dipole. They are particularly suited for the unambiguous synthesis of pyrazoles as the azomethine imine is contained as a masked 1,3-dipole in the sydnone system. An attractive feature of their use is that the precursor to the mesoionic system may be used in the presence of the cyclodehydration agent and the dipolarophile, avoiding the necessity for isolating the mesoionic system. 

Small unsaturated rings are usually very reactive undergoing ring opening in a number of ways, and this characteristic has been utilized in heterocyclic synthesis. In their role as dienophiles or dipolarophiles, the initial cycloaddition is usually followed by a valence tautomerism resulting in a six-membered or larger ring system. Several examples exist, however, where this does not occur, and these are described below. 

The photocycloaddition of arylazirines with a variety of multiple bonds proceeds in high yield and provides a convenient route for the synthesis of five-membered heterocyclic rings. Some of the dipolarophiles include azodicarboxylates, acid chlorides, vinylphosphonium salts and p-quinones. 

An interesting perspective for synthesis is offered by the reaction sequence cycloaddition/cycloreversion. It often does not lead to the initial reactants, but to a different pair of dipole and dipolarophile instead ... 

The importance of the 1,3-dipolar cycloaddition reaction for the synthesis of five-membered heterocycles arises from the many possible dipole/dipolarophile combinations. Five-membered heterocycles are often found as structural subunits of natural products. Furthermore an intramolecular variant makes possible the formation of more complex structures from relatively simple starting materials. For example the tricyclic compound 10 is formed from 9 by an intramolecular cycloaddition in 80% yield ... 

The class of 1,3-dipolar cycloadditions embraces a variety of reactions that can accomplish the synthesis of a diverse array of polyfunctional and stereochemically complex five-membered rings.3 The first report of a 1,3-dipolar cycloaddition of a nitrone (a 1,3-dipole) to phenyl isocyanate (a dipolarophile) came from Beckmann s laboratory in 1890,4 and a full 70 years elapsed before several investigators simultaneously reported examples of nitrone-olefin [3+2] cycloadditions.5 The pioneering and brilliant investigations of Huisgen and his coworkers6 have deepened our under-... 

Another example of a microwave-assisted 1,3-dipolar cycloaddition using azomethine ylides and a dipolarophile was the intramolecular reaction reported for the synthesis of hexahydrochromeno[4,3-fo]pyrrolidine 105 [70]. It was the first example of a solvent-free microwave-assisted intramoleciflar 1,3-dipolar cycloaddition of azomethine ylides, obtained from aromatic aldehyde 102 and IM-substituted glycinate 103 (Scheme 36). The dipole was generated in situ (independently from the presence of a base like TEA) and reacted directly with the dipolarophile present within the same molecifle. The intramolecu-... 

In addition to nitrones, azomethine ylides are also valuable 1,3-dipoles for five-membered heterocycles [415], which have found useful applications in the synthesis of for example, alkaloids [416]. Again, the groups of both Grigg [417] and Risch [418] have contributed to this field. As reported by the latter group, the treatment of secondary amines 2-824 with benzaldehyde and an appropriate dipolarophile leads to the formation of either substituted pyrrolidines 2-823, 2-825 and 2-826 or oxa-zolidines 2-828 with the 1,3-dipole 2-827 as intermediate (Scheme 2.184). However, the yields and the diastereoselectivities are not always satisfactory. 

Clearly, the nitroalkene dipolarophile oxidoisoquinolinium betaine 123 is nonideal for the synthesis of the hetisine alkaloids, as mass throughput for the needed cycloadduct would be low, and conversion of the tertiary nitro group to carbon-based functionality, as would be required in the latter stages of the synthesis, could be problematic. On the other hand, an ene-nitrile dipolarophile has several potential advantages over nitroalkene dipolarophile. Most importantly, the ene-nitrile cycloadduct has carbon functionality installed at the C-10 position. Second, the conjugate addition byproduct pathway that occurs so readily for the nitroalkene oxidoisoquinolinium betaine 123 system (see Scheme 1.13) should be much slower... 

In contrast to the failure of Diels-Alder reactions, dipolar cycloadditions of indoles are much more successful, and the Boger group has reported a fascinating [4+2]/l,3-dipolar cycloaddition cascade involving indole as the dipolarophile in their impressive synthesis of vindoline (Scheme 4.8) [26]. After the initial... 

The synthesis of biologically significant fluorinated heterocyclic compounds has been accomplished by 1,3-dipolar cycloaddition of nitrones to fluorinated dipolarophiles [51], This reaction was noticeably improved under solvent-free conditions and using microwave irradiation (Eq. (8) and Tab. 3.5). 

A systematic exploration of the intramolecular [4+2]/[3+2] cycloaddition cascade of 1,3,4-oxadiazoles was described. The studies permit the use of unsymmetrical dienophiles, dipolarophiles, and oxadiazoles as well as to control the cycloaddition regioselectivity and diastereoselectivity. The scope and utility of the reaction were defined <2006JA10589>. The tandem intramolecular [4+2]/[3+2] cycloaddition cascade reaction of 1,3,4-oxadiazole was applied to the syntheses of a series of natural products including a total synthesis of (-)- and ent-(+)-vindoline <2006JA10596>. 

Type G syntheses are typified by the 1,3-dipolar cycloaddition reactions of nitrile sulfides with nitriles. Nitrile sulfides are reactive 1,3-dipoles and they are prepared as intermediates by the thermolysis of 5-substituted-l,3,4-oxathiazol-2-ones 102. The use of nitriles as dipolarophiles has resulted in a general method for the synthesis of 3,5-disubstituted-l,2,4-thiadiazoles 103 (Scheme 11). The thermolysis is performed at 190°C with an excess of the nitrile. The yields are moderate, but are satisfactory when aromatic nitrile sulfides interact with electrophilic nitriles. A common side reaction results from the decomposition of the nitrile sulfide to give a nitrile and sulfur. This nitrile then reacts with the nitrile sulfide to yield symmetrical 1,2,4-thiadiazoles <2004HOU277>. Excellent yields have been obtained when tosyl cyanide has been used as the acceptor molecule <1993JHC357>. 

Macrocycles containing isoxazoline or isoxazole ring systems, potential receptors in host—guest chemistry, have been prepared by multiple (double, triple or quadruple) 1,3-dipolar cycloadditions of nitrile oxides, (prepared in situ from hydroxamoyl chlorides) to bifunctional calixarenes, ethylene glycols, or silanes containing unsaturated ester or alkene moieties (453). This one-pot synthetic method has been readily extended to the preparation of different types of macrocycles such as cyclophanes, bis-calix[4]arenes and sila-macrocycles. The ring size of macrocycles can be controlled by appropriate choices of the nitrile oxide precursors and the bifunctional dipolarophiles. Multiple cycloadditive macrocy-clization is a potentially useful method for the synthesis of macrocycles. 

Dipolarophiles D3. 1,3-Dipolar cycloadditions of suitably functionalized cyclic nitrones with terminal alkenes, which have potential leaving groups X at the end of the alkane chain -(CHo),- (D3), were successfully used for the synthesis of pyrrolozidine, indolizidine and quinolizidine alkaloids, such as (+ )-and (—)-lentiginosine, a potent amyloglucosidase inhibitor (Scheme 2.243) (742). Reductive cleavage of the N-0 bond in the cycloadduct is important for the subsequent cyclization to pyrrolozidines, indolizidines, and quinolizidines. 

Recently, dipolarophile 1)13 (fumaronitrile) (777) has been used in the synthesis of indolizine lactone (677). Both, intermolecular and intramolecular cycloadditions were studied. Intermolecular 1,3-cycloaddition of nitrone (671) to D13 led to the formation of isoxazolidine (672). Subsequent deprotection and esterification of the obtained alcohol (673) with (674) gave isoxazolidine (675) in 65% yield. Ester (675), when refluxed in xylene for 10 min, after elimination of fumaronitrile by cyclo-reversion, underwent spontaneously intramolecular cycloaddition to give the tricyclic cycloadduct (676) in 84% yield (Scheme 2.291). 

Dipolarophiles D14. The 1,3-dipolar cycloaddition of nitrones to dimethyl maleate and dimethyl fumarate is widely used in the synthesis of polyhydroxy alkaloid derivatives of dihydroindolizidinone (81), pyrrolizidine (119), (—)-codonopsinine, and (+ )-hyacinthacines Ai and A2 (312). In cases of unstable nitrones, syntheses of cycloadducts are performed in situ (81). 

The asymmetric synthesis of six-membered cyclic nitronates with the use of dipolarophiles containing auxiliaries was studied in more detail. Chiral vinyl ethers are most commonly used for this purpose. This process is schematically shown in Scheme 3.182. 

The general method, that has been widely used for the synthesis of perhydropyrrolo[1,2-6]isoxazoles, is based on a cycloaddition reaction of cyclic nitrones with dipolarophiles. The nitrone is easily available by oxidation of the corresponding hydroxylamine with mercuric chloride. The cycloaddition of nitrone to dipolarophiles is highly regioselective and stereoselective and have been often applied in the total synthesis of natural products <20010L1367, 2004BML3967, 2005JOC3157>. As one representative example of dipolar cycloaddition, reaction... 

Other approaches including 1,3-dipolar cycloadditions of azomethine ylides or nitroxides to alkene or alkyne dipolarophiles have been applied to the synthesis of these ring systems. 

Various chiral dipolarophiles have been used in the asymmetric synthesis of hexahydro-isoxazolo[2,3- ]pyridines. Examples include // / -2-methylcnc-l, 3-dithiolane 1,3-dioxide 83 <1998JOC3481>, chiral vinyl sulfoxide 85 <1997TA109>, or chiral dioxolanes <2001TA1747> (Scheme 27). 

This methodology has been applied to the diastereoselective synthesis of the pyrrolizidine alkaloid 196 from 194 via 195 (Scheme 15.62) [123], Furthermore, the diastereoselectivity of these reactions for different dipolarophiles has been investigated in detail [124] and could be extended to a ring closure to seven-membered nitrogen heterocycles [125,126]. 

---