Pyran derivatives

By long tradition, a group of cationic pyran derivatives have trivial names, i.e. (186)-(189), which are retained by lUPAC. These names may be modified by the prefixes thio-, seleno-and telluro- for their chalcogen analogs. 

These reactions are related to the formation of pyrroles and quinolines from aminocarbonyl compounds and acetylenes (582,583) and may be contrasted with the formation of pyran derivatives by electrophilic attack on an enamine, followed by addition of an oxygen function to the imonium carbon (584-590). 

Pyran derivatives, useful intermediates in the total synthesis of many monosaccharides and other natural products, have been synthesized by hetero-Dish-Alder reaction by using carbonyl compounds as dienophiles [9, 23]. 

More functionalized 5,6-dihydro-2H-pyran-derivatives 71 and 72 have been prepared [26] by cycloaddition of 1 -methoxy-3-trialkylsilyloxy-1,3-butadienes 69 with t-butylglyoxylate (70) (Scheme 5.6). Whereas thermal reactions did not occur in good yields because of the decomposition of the cycloadducts, application of pressure (10 kbar) allowed milder conditions to be used, which markedly improved the reaction yields. The use of high pressure also gives preferentially en Jo-adduct allowing a stereocontrolled synthesis of a variety of substituted 5,6-dihydro-2H-pyran-derivatives, which are difficult to prepare by other procedures. 

The [4 + 2] cycloaddition of enones and electron-rich olefins is a well-known method for the synthesis of pyrane derivatives [45]. Methylenecyclo-alkanediones [46] have also been used extensively for this purpose. 

Ring contractions of pyran derivatives are occasionally valuable. The contraction of 3-halo-2-pyrones to 2-furoic acids under the influence of alkali has been studied and the conditions defined.58112113 The method is adaptable to the preparation of 3-furoic acid via furan-2,4-dicarboxylic acid58 and of 3,4,5-triphenylfuran-2-carboxylic acid.113 Another ring contraction involving halides is the conversion of 4-chloromethylpyrylium salts into furylmethyl ketones as indicated in Scheme 21.114 Pyridine oxides may be transformed with unexpected ease into furans through treatment with a thiol (Scheme 22).115... 

The newer reagent, pyridinium chlorochromate(VI), has the particular (though not unique) ability to transform furylcarbinols into pyran derivatives under remarkably mild conditions (dichloromethane at room temperature for 1 h).310 The conversion shown in Scheme 58b exemplifies the general... 

Scheme 150).225 227 The pyran products predominate when the ratio of triphenylphosphine to palladium catalyst exceeds two whereas the linear oligomers are the major products when this ratio is close to unity. The suggested227 mechanism (Scheme 151) includes a step of insertion of C=0 into a C—Pd palladium-catalyzed reactions leading to the formation of pyranones (see Scheme 152)228 and piperidones (see Scheme 139 in Section V,A,2).211 It is useful to note that the 2,5-divinyltetrahydropyran derivative can be transformed catalytically by ruthenium trichloride into synthetically useful 3,4-dihydro-2//-pyran derivatives (Scheme 153).229... 

Examples of the use of heterodienophiles under the action of microwave irradiation are not common. Soufiaoui [84] and Garrigues [37] used carbonyl compounds as die-nophiles. The first example employed solvent-free conditions the second is an example of the use of graphite as a susceptor. Cycloaddition of a carbonyl compound provided a 5,6-dihydro-2H-pyran derivative. These types of reaction proceed poorly with aliphatic and aromatic aldehydes and ketones unless highly reactive dienes and/or Lewis acid catalysts are used. Reaction of 2,3-dimethyl-l,3-butadiene (31) with ethyl glyoxylate (112) occurred in 75% yield in 20 min under the action of microwave irradiation. When conventional heating is used it is necessary to heat the mixture at 150 °C for 4 h in a sealed tube to obtain a satisfactory yield (Scheme 9.33). 

The conversion of anomerically linked enol ethers 29 into either the cis- or trans-substituted pyranyl ketones with high diastereoselectivity and yield involves a Lewis acid-promoted O —> C rearrangement (Scheme 19) <00JCS(P1)2385>. Under similar conditions, homoallylic ethers 30 ring open and the oxonium ions then recyclise to new pyran derivatives 31. Whilst the product is a mixture of alkene isomers, catalytic hydrogenation occurs with excellent diastereoselectivity (Scheme 20) <00JCS(P1)1829>. 

The 3,4-di-O-benzylated D-fructopyran derivative (Scheme 26) would limit the possibilities for spiro-furan and -pyran derivatives. Application of the usual two-step process afforded with a 60% overall yield a mixture of OZTs in which the spiro-furan forms predominated (2 1 ratio) over the spiro-pyran forms. After column chromatography separation, acetylation allowed isolation of each epimer either a-furan (37%) and (3-furan (35%) forms as well as a-pyran (41%) and (3-pyran (27%) forms. 

Scheme 6.62 The 3<52-pyran derivative 288 as a possible intermediate in the thermal cyclization of undeca-3,8-diyne-2,10-dione (287).

Intermediates such as 224 resulting from the nudeophilic addition of C,H-acidic compounds to allenyl ketones such as 222 do not only yield simple addition products such as 225 by proton transfer (Scheme 7.34) [259]. If the C,H-acidic compound contains at least one carbonyl group, a ring dosure is also possible to give pyran derivatives such as 226. The reaction of a similar allenyl ketone with dimethyl mal-onate, methyl acetoacetate or methyl cyanoacetate leads to a-pyrones by an analogous route however, the yields are low (20-32%) [260], The formation of oxaphos-pholenes 229 from ketones 227 and trivalent phosphorus compounds 228 can similarly be explained by nucleophilic attack at the central carbon atom of the allene followed by a second attack of the oxygen atom of the ketone at the phosphorus atom [261, 262], Treatment of the allenic ester 230 with copper(I) chloride and tributyltin hydride in N-methylpyrrolidone (NMP) affords the cephalosporin derivative 232 [263], The authors postulated a Michael addition of copper(I) hydride to the electron-... 

The reaction of Br2 with 2,2-dimethyl-3,4-hexadienol 336 afforded the pyran derivative 339(158],... 

The proposed mechanism involves the usual oxidative addition of the aryl halide to the Pd(0) complex affording a Pd(II) intermediate (Ar-Pd-Hal), subsequent coordination of allene 8 and migratory insertion of the allene into the Pd-C bond to form the jt-allylpalladium(II) species 123. A remarkable C-C bond cleavage of 123 leads by decarbopalladation to 1,3-diene 120 and a-hydroxyalkylpalladium species 124. /8-H elimination of 124 affords aldehyde 121 and the H-Pd-Hal species, which delivers Pd(0) again by reaction with base (Scheme 14.29). The originally expected cyclization of intermediate 123 by employment of the internal nucleophilic hydroxyl group to form a pyran derivative 122 was observed in a single case only (Scheme 14.29). 

Enantioselective cyclic ether is synthesized by molybdenum-catalyzed olefin metathesis. Cyclopentene derivative 85a is reacted with 5 mol% of chiral molybdenum catalyst 76 to give pyran derivative 86a in high yield and high ee... 

Scheme 34 Green methodologies for the three-component synthesis of 4//-pyran derivatives...

Balalaie S, Bararjanian M, Amani AM, Movassagh B (2006) (S)-Proline as a neutral and efficient catalyst for the one-pot synthesis of tetrahydrobenzo b pyran derivatives in aqueous media. Synlett 263-266... 

As in the synthesis of other bipyridines, several routes to 4,4 -bipyridine have been devised where one of the pyridine rings is built up from simpler components. For example, a dimer of acrolein reacts with ammonia and methanol in the presence of boron phosphate catalyst at 350°C to give a mixture of products including 4,4 -bipyridine (3.4% yield), and in a reaction akin to ones referred to with other bipyridines, 4-vinylpyridine reacts with substituted oxazoles in the presence of acid to give substituted 4,4 -bipyridines. ° ° Condensation of isonicotinaldehyde with acetaldehyde and ammonia at high temperatures in the presence of a catalyst also affords some 4,4 -bipyridine, and related processes give similar results,whereas pyran derivatives can be converted to 4,4 -bipyridine (56% conversion), for example, by reaction with ammonia and air at 350°C with a nickel-alumina catalyst. Likewise, 2,6-diphenyl-4-(4-pyridyl)pyrylium salts afford 2,6-... 

Many examples of the use of chiral Ca-symmetric bis(oxazoline) hgands have been presented here. Other examples include their use in various heteroannulations, one of which is shown in Figure 9.69. Here, the vinyl iodide, (Z)-3-iodo-2-methyl-2-propen-l-ol, 235 is condensed with 1,2-undecadiene to form the 3-methylene-2//-pyran derivative 237. " When this reaction was mn in the presence of 10 mol% of bis(oxazoline) Ugand 236 complexed with palladium(ll), 237 was produced in 70% yield with 79% ee. 

X-Ray analysis of hexahydrofuro[2,3- ]pyran derivative 39 shows that the tetrahydropyran ring assumes a chair conformation with the C(7a)-0(1) bond found in the axial position <1998T8753>. This conformation agrees with that obtained by analysis of the NMR spectrum of 39. 

Phosphorus ylides can be generated from triphenylphosphine, 3-chloro-(3//, 5//)-furan-2,4-dione, and alkynyl esters. Additional alkynyl ester, acting as a Michael acceptor, reacts with the ylides in a [4+2] cycloaddition reaction that results in the formation of furo[2,3-3]pyran derivatives (Equation 30) <2000T5221>. 

Dihydrofuran reacts with /3,7-unsaturated a-keto esters with copper or zinc complex catalysts to generate furo[2,3-/ ]pyran derivatives in good yields with high stereoselectivity. The synthesis proceeds via an inverse electron demand hetero-Diels-Alder reaction <2000CC459>. 

A solid-phase synthesis of furo[3,2-3]pyran derivatives utilizing highly functionalized sugar templates has been reported <2003JOC9406>. After incorporation of alkenes within the sugar template, such as compound 95, the solid support is introduced via formation of the acid amide. This immobilized system then allows a ruthenium-catalyzed ring-closing metathesis that leads to the formation of the fused oxacycles. 

Iodothiophene-2-carboxylic acid and terminal alkynes, in the presence of a palladium catalyst system, produce good yields of thieno[2,3-f]pyran derivatives as the major product (Equation 33) <2006TL83>. 

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