Pyrans rearrangement

Burger, J.F.W., H. Kolodziej, R.W. Hemingway, J.P. Steynberg, D.A. Young, and D. Ferreira Oligomeric Flavanoids. Part 15. Base-catalyzed Pyran Rearrangements of... 

Pyridazines are formed from pyrones or their thioxo analogs or from appropriate pyridones. Pyrones or pyridones react with diazonium salts to give the corresponding hydrazones (187) and (188) which are rearranged under the influence of acid or base into pyridazinones as shown in Scheme 107. On the other hand, kojic acid is transformed with hydrazine into a 1,4-dihydropyridazine and a pyrazole derivative. 4H-Pyran-4-thiones... 

Furfural — see Furan-2-oarbaldehyde, 532 Furfuryl acetate, o -(butoxycarbonyl)-anodic oxidation, 1, 424 Furfuryi acrylate polymerization, 1, 279 Furfuryl alcohol configuration, 4, 544 2-Furfuryl alcohol polyoondensation, 1, 278 reactions, 4, 70-71 Furfuryl alcohol, dihydro-pyran-4-one synthesis from, 3, 815 Furfuryl alcohol, tetrahydro-polymers, 1, 276 rearrangement, 3, 773 Furfuryl chloride reactions... 

Beckmann rearrangement, 3, 710 Pyran-4-carbaldehyde, 2,2-dimethyl-tetrahydro-Reformatsky reaction, 3, 732 4H-Pyran-4-carbaldehydes synthesis, 3, 760-761 Pyran-2-carbonitrile, 5,6-dihydro-reactions, 3, 732... 

H,3H- Pyrrolo[l, 2-c]oxazole-l, 3-dione, 5,6,7,8-tetrahydro-IR spectra, 6, 978 [2.2](2,5)Pyrrolophane, N-aryl-rearrangements, 4, 209 Pyrrolophanes natural products, 7, 764 synthesis, 7, 771 Pyrrolophanes, N-aryl-synthesis, 7, 774 (2,4)Pyrrolophanes synthesis, 7, 771 Pyrrolo[3,4-c]pyran-4-ones synthesis, 4, 288 Pyrrolopyrans synthesis, 4, 525, 526 Pyrrolopyrazines synthesis, 4, 526 Pyrrolo[l, 2-a]pyrazines synthesis, 4, 516 Pyrrolo[2,3-6]pyrazines Mannich reaction, 4, 504 Vilsmeier reaction, 4, 505 Pyrrolo[3,4-c]pyrazole, 1,3a,6,6a-tetrahydro-structure, 6, 976 synthesis, 6, 1019 Pyrrolopyrazoles synthesis, 5, 164 Pyrrolo[l,2-6]pyrazoles synthesis, 6, 1002, 1006 Pyrrolo[3,4-c]pyrazoles reactions, 6, 1034 synthesis, 6, 989, 1043 Pyrrolo[3,4-c]pyrazolones synthesis, 6, 989 Pyrfolopyridazines synthesis, 4, 517 Pyrrolo[l, 2-6]pyridazines synthesis, 4, 297 6/7-Pyrrolo[2,3-d]pyridazines synthesis, 4, 291 2/f-Pyrrolo[3,4-d]pyridazines synthesis, 4, 291 6/7-Pyrrolo[3,4-d]pyridazines synthesis, 4, 291... 

A thio-Claisen rearrangement174 was used for the regioselective synthesis of thiopyrano[2,3-b]pyran-2-ones and thieno[2,3-b]pyran-2-ones (Eq. 12.76). A convenient method for the aromatic amino-Claisen rearrangement of N-(l,l-disubstituted-allyl)anilines led to the 2-allylanilines being produced cleanly and in high yield by using a catalytic amount of p-toluenesulfonic acid in acetonitrile/water (Eq. 12.77).175... 

Dihydro-2H-pyran-2-ones (e. g., 4-195) are valuable intermediates in the synthesis of several natural products [67]. Hattori, Miyano and coworkers [68] have recently shown that these compounds can be easily obtained in high yield by a Pd2+-catalyzed [2+2] cycloaddition of ct, 3-unsaturated aldehydes 4-192 with ketene 4-193, followed by an allylic rearrangement of the intermediate 4-194 (Scheme 4.42). In this reaction the Pd2+-compound acts as a mild Lewis acid. a,(3-unsaturated ketones can also be used, but the yields are below 20%. 

A Lewis acid-induced aza-Diels-Alder reaction between the /3-lactam-imine 295 and 3,4-di hydro-2//-pyran gives the two diastereomeric pyranoquinolines 296 and 297. Under basic conditions, these products rearrange to the amino-substituted pyranoindolizinones, 298 and 299, respectively, with retention of stereochemistry (Scheme 74) <2003CEJ3415>. 

Treatment of the tetrahydropyrano[l,6]naphthyridine 303 with phosphorus oxychloride results both in closure of the imidazole ring and rearrangement of the pyran ring to give the spiro-cyclopropano compound 304 (Equation 104) <1996JHC49>. 

The cyclization of y -hydroxy ketones is useful for the formation of pyrans,306,403 both directly and via rearrangement, as illustrated in Eq. 231.153 As with their acyclic counterparts, these cyclizations also occur with the silyl ethers of the hydroxy ketones where Et3SiH/BiBr3 is used with the TBS and TES ethers.342,404 A methyl thiomethyl ether is also capable of undergoing the reductive cyclization 405 In like manner, 1,4-diols and e-hydroxy ketones provide oxepanes, with I ds Si H or PhMe2SiH/TMSOTf being especially effective (Eqs. 232 and 233).336,406 The trimethylsilyl ether of the alcohol also provides the oxepane.306... 

Tochtermann reported the addition of dichlorocarbene to the racemic glycal 52, whose cyclopropyl-allyl rearrangement leads to the 2//-pyran. The synthesis of the optically pure (+)-(2S,3R,7S) and (-)-(2f ,3S,7f )-glycal precursors has also been achieved. As pointed out, optically pure glycals are versatile precursors for carbohydrate synthesis <00EJO1741>. 

The application of RCM to dihydropyran synthesis includes a route to 2,2-disubstituted derivatives from a-hydroxycarboxylic acids. In a one-pot reaction, the hydroxy esters undergo sequential O-allylation, a Wittig rearrangement and a second O-allylation to form allyl homoallyl ethers 8. A single RCM then yields the 3,6-dihydro-2//-pyran 9. The process is readily adapted not only to variably substituted dihydropyrans but also to 2-dihydrofuranyl and 2-tetrahydrooxepinyl derivatives and to spirocycles e.g. 10 through a double RCM (Scheme 4) <00JCS(P1)2916>. 

Tetrahydropyran epoxides 12, the synthesis of which involves a RCM, undergo a base-induced rearrangement to 3,4-dihydro-2//-pyran-4-ols 13. These compounds are converted stereospecifically to 3,6-dihydropyrans 14 on treatment with allyltrimethylsilane (Scheme 6) <00EJO3145>. 

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 synthetic versatility and significance of the Zr-catalyzed kinetic resolution of exocyc-lic allylic ethers is demonstrated by the example provided in Scheme 6.9. The optically pure starting allylic ether, obtained by the aforementioned catalytic kinetic resolution, undergoes a facile Ru-catalyzed rearrangement to afford the desired chromene in >99% ee [20], Unlike the unsaturated pyrans discussed above, chiral 2-substituted chromenes are not readily resolved by the Zr-catalyzed protocol. Optically pure styrenyl ethers, such as that shown in Scheme 6.9, are obtained by means of the Zr-catalyzed kinetic resolution, allowing for the efficient and enantioselective preparation of these important chromene heterocycles by a sequential catalytic protocol. 

Apparently, the aromatization of the heterocyclic cation serves as a driving force of the Cope rearrangement in the transformation of the 3-formyl-4-allyl-4//-pyrane (481) into poly-substituted pyrylium salt 483 which presumably proceeds via 482 (equation 183)242. 

New rearrangements of 2-imino-2//-l-benzopyran-3-carboxamides under the action of anthranilic acid as an N-nucleophile have been revealed. Depending on the conditions 2-(2-oxo-2//-l-benzopyran-2-yl)-3//-quinazolin-4-ones or 2-oxo-2//-l-benzo-pyran-3-((V-2-carboxyphenyl)carboxamides were found to be the products. 

A review of Claisen rearrangements in aqueous solution has appeared. The synthesis of natural products utilizing tandem Diels-Alder additions with sigmatropic rearrangement processes has been reviewed, and a brief review of the regioselective synthesis of coumarins, quinolones and thiocoumarins with 3,4-fused pyran or furan ring systems by the Claisen rearrangement has been presented. ... 

Naphtho[2,l-( ]pyrans 291 with carbon disulfide lead to dithiones 292 (08PS1145), perhaps via a Dimroth rearrangement of possible intermediates 293 (Scheme 122). 

A Claisen rearrangement of the 1,4-dioxene 69 provided the pyran 70 asymmetrically (Equation 10) <1998JA12702>. 

Benzoxathiins 265 can be prepared by rearrangement of the 8-(2-bromoethoxy)-2,3-dihydro-2//-l-benzothio-pyran 264 in DMF at 80°C (Equation 41) <2003MI187>. 

The l,3,4-oxadiazin-6-one (240) undergoes cycloaddition followed by a remarkable rearrangement to give the triazole A(-imine 241 and an open-chain product (136). Cycloadditions have also been carried out with the following ring systems 1,2-dihydroisoquinoline (242) (137) dihydro-1,3-oxazine (243) (138,139), 2H-, 3-benzothiazine (244) (140,141), and 27/-l-pyran-2-thione (245) (142). 

Two one-pot syntheses of highly substituted pyran-2-ones have been published. One involves the reaction between t-BuNC, dialkyl acetylenedicarboxylates and bromomalonates <99JCR368>. In the other, cyclobutenediones are treated with 0-silylated cyanohydrins to yield a 4-acylcyclobutenone by a 1,4-silyl migration and cyanide displacement which rearranges to the pyranone (Scheme 18) <99JOC2145>. 

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