Tetrahydrofuran alkene Transformation

Ozonolysis of alkene 446 in the presence of acetaldehyde afforded diketone 448 through the intermediacy of 447. Ring expansion through Beckmann rearrangement took place when bis-oxime 449 was mesylated and warmed in aqueous tetrahydrofuran (THF). The bis-lactam so formed gave piperidinediol 450 on reduction with lithium aluminium hydride, and this compound was transformed into ( )-sparteine by treatment with triphenylphosphine, CCI4, and triethylamine (Scheme 105) <20050BC1557>. 

In addition to his total synthesis of pamamycin-607 (lb) (see Schemes 14-17), Kang also communicated an alternative synthesis of a larger fragment surrogate of lb [51]. Again, iodoetherifications of y-triethylsilyloxy alkenes were utilized as key transformations to control the 2,5-c/s-disubstitution of the two tetrahydrofuran moieties. However, whereas his total synthesis of lb involved a two-directional formation of both heterocycles in a single operation, the alternative route depicted in Schemes 31 and 32 is characterized by sequential... 

Adenosine analogues where the furanose ring was replaced with alternative dihydro- and tetrahydrofurans were prepared from 6-chloro-9-(4-methylenetetrahydrofuran-3-yl)-9/7-purine <2002T4865>. Of particular interest was the transformation of the exocyclic alkene on the THF ring first by dihydroxylation, then elimination to yield (4-(6-aminopurin-9-yl)-2,5-dihydrofuran-3-yl)methanol after amination of the purine ring at C-6. This A-alkenylpurine was reduced (Pd/C, H2, 25 psi, 73% yield) to provide the tetrahydrofuran-3-yl derivative. 

PCC transforms 5,6-dihydroxyalkenes into tetrahydrofurans in a highly stereoselective manner284 (see Equation below). This transformation can be explained by the initial formation of a cyclic chromate ester by reaction with the diol moiety, followed by an intramolecular oxidative addition of the chromate ester on the alkene. 

Transition-metal mediated carbene transfer from 205 to benzaldehyde generates carbonyl ylides 211 which are transformed into oxiranes 216 by 1,3-cyclization, into tetrahydrofurans 212, 213 or dihydrofurans 214 by [3 + 2] cycloaddition with electron-deficient alkenes or alkynes, and 1,3-dioxolanes 215 by [3 + 2] cycloaddition with excess carbonyl compound120 (equation 67). Related carbonyl ylide reactions have been performed with crotonaldehyde, acetone and cyclohexanone (equation 68). However, the ylide generated from cyclohexanone could not be trapped with dimethyl fumarate. Rather, the enol ether 217, probably formed by 1,4-proton shift in the ylide intermediate, was isolated in low yield120. In this respect, the carbene transfer reaction with 205 is not different from that with ethyl diazoacetate121, whereas a close analogy to diazomalonates is observed for the other carbonyl ylide reactions. 

A stereoselective synthesis of substituted tetrahydrofurans (69) via Pd-catalysed reactions of aryl and vinyl bromides with y -hydroxy terminal alkenes (68) has been described. This transformation affords trans-2,5- and frara-2,3-disubstituted tetrahydrofurans with up to >20 1 dr. This methodology also provides access to bicyclic and (g) spirocyclic tetrahydrofuran derivatives in good yield with 10-20 1 dr. The effect of... 

Dipolar cycloaddition of alkenes with carbonyl ylides generated in situ is a versatile method for tetrahydrofuran synthesis. The synthetic potential of such transformations has been reviewed <2005JOM(690)5533, 2003BMI6-253>. In addition, the stereoselective [3 + 2] annulation of allyl silanes has become a reliable protocol for the synthesis of tetrahydrofurans as demonstrated in several total syntheses . Such a [3 + 2] annulation, for example, affords the tetrahydrofuran product 11 as a single stereoisomer (Scheme 15) <2002OL2945>. Lanthanide salts serve as efficient Lewis acid catalysts in similar [3 + 2] cycloaddition reactions . 

Among the photochemical reactions of aromatic compounds, the photocycloadditions are most frequently applied to the synthesis of complex polycyclic compounds [6, 9]. The [2+3] or meta photocycloaddition of aromatic compounds and alkenes is the most prominent example [10]. This transformation also demonstrates complementarities between photochemical and ground state reactions since such reactions are almost impossible using conventional activation. A [2+2] ot ortho photocycloaddition between carbocyclic aromatic compounds and alkenes is observed as well. It is often competitive with other cycloaddition modes, in particular the [2+3] mode [11]. Many of these reactions are reversible, and photostationary equilibria are involved. This reaction was much less applied to organic synthesis. Recently, it was found that an acidic reaction medium may have an influence on the outeome of the reaction. The intramolecular photocycloaddition of resorcinol derivatives such as 1 is difficult due to its reversibility (Scheme 29.1). However, in an acidic reaction medium, the cycloadducts 2a,b are protonated at the oxygen atom of the tetrahydrofuran moiety... 

Aldol reaction of ester 253 with benzyloxyacetaldehyde gave exclusively syn aldol adduct 254 in 93% yield this was transformed into alkene 255. Subsequent transformation yielded tetrahydrofuran derivative 256. This cyclic bromoether serves as masked functionality for the labile exocyclic... 

Inspired by the synthesis of tetrahydrofurans that are imbedded in natural products, a number of groups have examined the metal-catalyzed oxidative cyclization of 1,5-dienes and/or hydroxyolefins where the alkenes in both instances are inactivated. Metals that have been shown to be capable of carrying out these transformations include Mn, Ru, Pd, Os, and Co. As is outlined in this section, these reactions have several significant advantages over other tetrahydrofuran-... 

Koskinen et al. have employed Pd-catalyzed tr-allyl cyclizations to generate tetrahydrofurans including the tetrahydrofuran present in the cytotoxic natural product pachastrissamine (Scheme 73) [79]. From Z-allyl acetate 277 they were able to generate tetrahydrofuran 278 as the major product in 59 % yield. Interestingly, they found the stereochemistry adjacent to the alkene to be an important factor in the selectivity. The use of the sy -isomer 279 resulted in the generation of tetrahydrofuran 280 in 81 % yield with 9 1 diastereoselectivity. Tetrahydrofuran 278 was subsequently transformed into pachastrissamine. 

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