5.6- Dihydropyrans

The same observation was made by Dobbs et al., who used a similar annulating agent 119 and reacted it with various aldehydes in the presence of indium trichlor- 

Another approach towards dihydropyrans 124 and 125 was developed by Panek et al. [64] In this methodology, two enantiomerically enriched diastereoisomers, 

It was observed that the cyclization of syn-123 produced mainly the dihydropyran 124a accompanied by dihydropyran 124b as a minor diastereoisomer. In contrast, the cyclization of anti-123 provided dihydropyran 125b as the major isomer and the all-cis-substituted dihydropyran 125a as the minor product. In all cases, the diastere-oselectivity ranged from good to excellent. 

Roush and Dilley suggested [50] that the preferential formation of cis-2,6-disub-stituted dihydropyrans 127 and 132 instead of the expected trans-2,6-disubstituted 

All yields are for pure, fully characterized, products b Products129(50%) and 130(3%) are also formed 

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The 7, i5-unsaturated alcohol 99 is cyclized to 2-vinyl-5-phenyltetrahydro-furan (100) by exo cyclization in aqueous alcohol[124]. On the other hand, the dihydropyran 101 is formed by endo cyclization from a 7, (5-unsaturated alcohol substituted by two methyl groups at the i5-position. The direction of elimination of /3-hydrogen to give either enol ethers or allylic ethers can be controlled by using DMSO as a solvent and utilized in the synthesis of the tetronomycin precursor 102[125], The oxidation of the optically active 3-alkene-l,2-diol 103 affords the 2,5-dihydrofuran 104 in high ee. It should be noted that /3-OH is eliminated rather than /3-H at the end of the reac-tion[126]. 

The 1.3-allylic diacetate 135 can be used for the formation of the methy-lenecyclopentane 137 with the dianionic compound 136(86]. The cyclohexa-none-2-carboxylate 138 itself undergoes a similar annulation with the 1,3-allylic diacetate 135 to form the methylenecyclohexane derivative 139(90]. The reaction was applied as a key step in the synthesis of huperzin A[91]. On the other hand. C- and 0-allylations of simple J-dikctones or. 1-keto esters take place, yielding a dihydropyran 140(92]. 

In other work, sulfone chemistry plays an integral part of the syntheses of both -carotene and vitamin A by workers at Kuraray. In this approach, the anion of C q P-cyclogeranyl sulfone (36) is condensed with the C q aldehyde (37). The resulting P-hydroxy sulfone (38) is treated with dihydropyran followed by a double elimination to yield vitamin A acetate. Alternatively, the P-hydroxy sulfone (38) can be converted to the 5-halo sulfone (39) and a similar double elimination scheme is employed (23,24) (Fig. 8). 

A number of highly potent DHP-I stable iP-methylcarbapenems having a variety of C-2 substituents have now been described (60,66—69) including SM 7338 [96036-03-2] (42), C yH25N20 S. An acylamiao compound (66) and a iP-methoxy analogue (70) provide other variations. The pyrroHdine substituted iP-methyl-carbapenem SM 7338 (42) is being developed as a broad-spectmm parenteral antibiotic under the name meropenem the synthesis of (42) is by way of the lactone (43) derived by a novel Diels-Alder approach to dihydropyran precursors of (43) (71). 

Several procedures for making glutaric acid have been described in Organic Syntheses starting with trimethylene cyanide (28), methylene bis (malonic acid) (29), y-butyrolactone (30), and dihydropyran (31). Oxidation of cyclopentane with air at 140° and 2.7 MPa (400 psi) gives cyclopentanone and cyclopentanol, which when oxidized further with nitric acid at 65—75° gives mixtures of glutaric acid and succinic acid (32). 

Various alkylating agents are used for the preparation of pyridazinyl alkyl sulfides. Methyl and ethyl iodides, dimethyl and diethyl sulfate, a-halo acids and esters, /3-halo acids and their derivatives, a-halo ketones, benzyl halides and substituted benzyl halides and other alkyl and heteroarylmethyl halides are most commonly used for this purpose. Another method is the addition of pyridazinethiones and pyridazinethiols to unsaturated compounds, such as 2,3(4//)-dihydropyran or 2,3(4//)-dihydrothiopyran, and to compounds with activated double bonds, such as acrylonitrile, acrylates and quinones. 

H-pyran synthesis from, 3, 759 bis(trimethylsiloxy) in pyrrole synthesis, 4, 333 chromene synthesis from, 3, 750 cycloaddition reactions with isocyanates, azetidin-2-ones from, 7, 261 dihydropyran synthesis from, 3, 771 fuiyl... 

Butane, 2,3-0-isopropylidene-2,3-dihydroxy-1,4-bis(diphenylphosphino)-catalyst in homogeneous asymmetric hydrogenation, 6, 781 Butane-1,4-dioic acid, 2,2-di(indolyl)-synthesis, 4, 226 Butanenitrile, 4-hydroxy-dihydropyran synthesis from, 3, 769 Butanoic acid, -y-aryl-y-amino-synthesis, 1, 433 1-Butanol... 

Heptan-2-one, 5-hydroxy-5-methylene-dihydropyran-3-one synthesis from, 3, 843 Heptan-3-one, (-b)-(S)-4-methyl-synthesis, 1, 435 Herbicides... 

As chemists proceeded to synthesize more complicated stmctures, they developed more satisfactory protective groups and more effective methods for the formation and cleavage of protected compounds. At first a tetrahydropyranyl acetal was prepared, by an acid-catalyzed reaction with dihydropyran, to protect a hydroxyl group. The acetal is readily cleaved by mild acid hydrolysis, but formation of this acetal introduces a new stereogenic center. Formation of the 4-methoxytetrahy-dropyranyl ketal eliminates this problem. 

Reillex 425-HCl, dihydropyran, 86°, 1.5 h, 84-98% yield. The Reillex resin is a macroreticular polyvinylpyridine resin and is thus an insoluble form of the PPTS catalyst. 

Amberlyst H-15 (SO3H ion-exchange resin), dihydropyran, hexane, 1-2 h, 95% yield. ... 

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