Furans transformation

Diketones are readily transformed to cycHc derivatives, such as cyclopentanones and furans. In this manner, the fragrance dihydrojasmone (3-meth5l-2-pentyl-2-cyclopenten-l-one) is prepared by the base-catalyzed aldol condensation of 2,5-undecanedione. 2,5-Undecanedione is itself prepared from heptanal and methyl vinyl ketone in the presence of thiazoHum salts (329). i7j -Jasmone can be similarly prepared (330,331). 

Transformation of pyridazine 1-oxides and their methyl derivatives into cyclopropyl ketones and/or substituted furans can also occur (Scheme 14). 

Recently, many transformations of various heterocycles into pyridazines have been reported. From the synthetic point of view it appears that furan derivatives are the most valuable. 

Similar transformations are based upon 1,2-thiazine 2,2-dioxides (5-sultones), easily obtained by treating a,/3- or /3,y-unsaturated ketones with acetic anhydride and sulfuric acid. These compounds can be converted subsequently into furans, thiophenes or pyrroles (Scheme 115). 

Several modifications of the Feist-Benary furan synthesis have been reported and fall into two general classes 1) reactions that yield furan products 2) reactions that yield dihydrofuran products. One variant that furnishes dihydrofiirans uses substrates identical to the traditional Feist-Benary furan synthesis with a slight modification of the reaction conditions. The other transformations covered in this section involve the combination of P-dicarbonyls with reagents that are not simple a-halocarbonyls. Several reactions incorporate a-halocarbonyl derivatives while others rely on completely different compounds. 

A different procedure provides access to 2,3,5-trisubstituted furans. Deslongchamps discovered that simply heating a mixture of glyceraldehyde (41) and methyl acetoacetate (42) in DMF provides a high yield of furan 43. Subsequent transformations enable selective substitution at the 2-position of the product. 

R] KOnig, B. Product Class 9 Furans. In Science of Synthesis Houben-Weyl Methods of Molecular Transformations, Maas, G., Ed. Georg Thieme Verlag New York, 2001 Cat. 2, Vol. 9, 183-278. 

In a series of papers in late 1884 and early 1885, Paal and Knorr demonstrated that several 1,4-dicarbonyls could be transformed into furans, pyrroles, and thiophenes. Paal first discovered this transformation and used it to prepare di-, tri-, and tetrasubstituted furans. For example, dicarbonyl 3 yielded disubstituted furan 4 upon treatment with weak acid. 

Photoinduced transformations of photochromes (spiropyrans, furan-derived fulgides, dithienylethenes) in polymers 98PAC2157. 

Synthesis of multisubstituted furan rings using silyl protection 99CSR209. Synthetic applications of furan Diels-Alder chemistry 97T14179. Transformation of furans to N-heterocycles by aza-Achmatovicz reaction 98SL105. 

Two sequential pericyclic reactions are involved in the following furan synthesis. Identify them, and propose a mechanism for the transformation. 

It would be expected that a few straightforward steps could accomplish the transformation of alkyl bromide 14 into phosphorus ylide 12 (Scheme 2b). On the other hand, the evolution of 14 from substituted aromatic furan ring 15 may not be obvious. It is, in fact, conceivable that the action of ethylene glycol on substituted furan... 

IV. The Transformation of Poly(vinylalcohol) into Furan Polymers. .. 85... 

In this section some systems are briefly described which make use of furan derivatives as starting materials for chemical transformations which eventually lead to polymeric products. However, with the exception of Section (c), these final products bear little resemblance to the original furan compounds used and are, therefore, only marginally relevant to the context of the present review. 

Of course, these conclusions do not rule out completely the occurrence of other reactions such as those listed above, but their contribution to the overall mechanism must be very small in the production of the oligomers. The dark colour of these products was attributed to hydride transfer reactions, similar in nature to those encountered in the cationic polymerization of 2-vinyl furan [see Section III-B-l-c)]. The subsequent process which transforms these oligomers into cross-linked resins was not investigated. 

The potential of these transformations has not been fully exploited. The method is certainly valuable both for the purpose of studying the structure of furan polymers which might be of interest but cannot be prepared easily by conventional techniques and for preparing polymers in which a certain proportion of the hydroxyl groups of poly(vinylalcohol) are substituted with a furan moiety which gives the new product some special property. 

A high endo selectivity is observed in the reaction of (phenylsulfonyl)allene (112) with furan (157) (equation 113)108. The endo adduct 158 can be readily transformed into highly substituted cyclohexenol 160 upon treatment with n-butyllithium after hydrogenation of the ring double bond (equation 114)108. 

The insertion of alkynes into a chromium-carbon double bond is not restricted to Fischer alkenylcarbene complexes. Numerous transformations of this kind have been performed with simple alkylcarbene complexes, from which unstable a,/J-unsaturated carbene complexes were formed in situ, and in turn underwent further reactions in several different ways. For example, reaction of the 1-me-thoxyethylidene complex 6a with the conjugated enyne-ketimines and -ketones 131 afforded pyrrole [92] and furan 134 derivatives [93], respectively. The alkyne-inserted intermediate 132 apparently undergoes 671-electrocyclization and reductive elimination to afford enol ether 133, which yields the cycloaddition product 134 via a subsequent hydrolysis (Scheme 28). This transformation also demonstrates that Fischer carbene complexes are highly selective in their reactivity toward alkynes in the presence of other multiple bonds (Table 6). 

Aromatic bromine compounds can be formed and transformed during various thermal processes, like aromatic chlorine compounds (ref. 22). Brominated dibenzodioxins and -furans and mixed brominated/chlorinated compounds have been detected in trace levels in the fly ash of a municipal waste incinerator (ref. 23).Chlorine is generally abundant compared to the bromine of typical municipal waste the chlorine vs. bromine ratio is in the range of 250 1. 

These results show the fate of aromatic bromine compounds during municipal waste incineration bromine is exchanged by chlorine on the surface of fly ash at the electrostatic precipitator at 250-3(X)°C. But the toxic potential at brominated dibenzodioxins and furans is not reduced by these transformations. The increase of PCDD/F concentration in MWI by adding bromine compounds has been pointed out by Lahl and coworkers (ref. 26). 

The reaction of crotonaldehyde and methyl vinyl ketone with thiophenol in the presence of anhydrous hydrogen chloride effects conjugate addition of thiophenol as well as acetal formation. The resulting j3-phenylthio thioacetals are converted to 1-phenylthio-and 2-phenylthio-1,3-butadiene, respectively, upon reaction with 2 equivalents of copper(I) trifluoromethanesulfonate (Table I). The copper(I)-induced heterolysis of carbon-sulfur bonds has also been used to effect pinacol-type rearrangements of bis(phenyl-thio)methyl carbinols. Thus the addition of bis(phenyl-thio)methyllithium to ketones and aldehydes followed by copper(I)-induced rearrangement results in a one-carbon ring expansion or chain-insertion transformation which gives a-phenylthio ketones. Monothioketals of 1,4-diketones are cyclized to 2,5-disubstituted furans by the action of copper(I) trifluoromethanesulfonate. ... 

As we found that furan and thiophene substituted oximes can be used as substrates for the INOC reactions (Eq. 5) [29b] similarly, furan substituted nitro alkane 134 is also a good substrate for INOC reactions (Eq. 13) [40]. The furfuryl derivative 134, prepared via Michael addition of furfuryl alcohol to 4-methoxy- -nitrostyrene, was subsequently transformed without isolation of the intermediate nitrile oxide 135 to the triheterocyclic isoxazoline 136 as a 5 1 mixture of isomers in high yield. 

Attempts to prepare the corresponding tetrameric para-PAM from 62 were unsuccessful. Dehydrobromination in furan afforded a symanti mixture of cycloadducts 65, that were subsequently transformed to the known dibenzodiyne (66). Formation of 65 is likely to arise from stepwise elimination/cycloaddition rather than to involve the intermediacy of the highly strained tetrameric PAM. 

Synthesis of 2-alkyl- or 2-aryl-substituted benzo[b]furans has been reported, involving a CuITMEDA complex which catalyzes the transformation of readily available ketone derivatives into the corresponding benzofurans in good-to-excellent yields in water (Eq. 6.13).29... 

A number of the bicyclic ozonides 12 were prepared in good yield (45-65 %) by diimide reduction of furan singlet oxygenates (Eq. 9) 23>. Again, low temperature were essential because the furan endoperoxides readily transform into 1,2-diacyl-ethylenes. Of course, the bicyclic ozonides 12 can alternatively be prepared via ozonolysis of the appropriate 1,2-disubstituted cyclobutene 24). 

Selective transformations Selective styrene ring opening [103] One-pot domino process for regioselective synthesis of a-carbonyl furans [104] Tandem process for synthesis of quinoxalines [105] Atmospheric oxidation of toluene [106] Cyclohexane oxidation [107] Synthesis of imines from alcohols [108] Synthesis of 2-aminodiphenylamine [109] 9H-Fluorene oxidation [110] Dehydrogenation of ethane in the presence of C02 [111] Decomposition of methane [112] Carbon monoxide oxidation [113]... 

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