Dihydropyrans preparation

Dehydration Alumina (see also Dihydropyrane, preparation). Boric acid. Boron triSuoride. N-Bromoacetamide-Pyridine-SOj. Dicyclohexylcarbodiimide. Diketene. Dimethylform-amide-Thionyl chloride. Dimethyl sulfoxide. Ethylene chlorophosphite. Florisil. Girard s reagent. Hydrobromic acid. Iodine. Mesyl chloride-Sulfur dioxide. Methyl chlorosulfite. Methylketene diethylacetal. Naphthalene-d-sulfonic acid. Oxalic acid. Phenyl isocyanate. Phosgene. Phosphorus pentoxide. Phosphoryl chloride. Phthalic anhydride. Potassium bisulfate. Pyridine. Thionyi chloride. Thoria. p-Toluenesulfonic acid. p-Toluenesulfonyl chloride. Triphenylphosphine dibromide. 

To a mixture of 300 mL 85% phosphoric acid and 25 mL 95% ethanol was added 10.0 g cyano dihydropyran prepared from l,4-dibromo-l,4-dibenzoylbutane and sodium cyanide. The solution was stirred for 18 h at room temperature and then refluxed for 8 h. When the solution was cooled down, it was diluted to a volume of 1800 mL in a 2-L... 

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. 

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. 

The tetrahydropyranyl ether, prepared from a phenol and dihydropyran (HCl/ EtOAc, 25°, 24 h), is cleaved by aqueous oxalic acid (MeOH, 50-90°, 1-2 h). ... 

The THP derivative of the imidazole nitrogen in purines has been prepared by treatment with dihydropyran (TsOH, 55°, 1.5 h, 50-85% yield). It is cleaved by acid hydrolysis. ... 

Tetrahydropyranyl ethers are prepared by reaction with 2,3-dihydropyran, and a catalyst such as hydrochloric acid, " phosphorous oxychloride or p-toluenesulfonic acid at room temperature. 3iS-Hydroxy-5-enes " also form pyranyl ethers by distillation of a solution of the steroid and dihy-dropyran in ether without a catalyst. 

The tetrahydropyranyl ether, prepared from a phenol and dihydropyran (HCl/EtOAc, 25°, 24 h) is cleaved by aqueous oxalic acid (MeOH, 50-90°, 1-2 h). Tonsil, Mexican Bentonite earth, HSZ Zeolite, and H3[PW,204o] have also been used for the tetrahydropyranylation of phenols. The use of [Ru(ACN)3(triphos)](OTf)2 in acetone selectively removes the THP group from a phenol in the presence of an alkyl THP group. Ketals of acetophenones are also cleaved. ... 

The tetrahydropyranyl cyanohydrin was prepared from a steroid cyanohydrin (dihydropyran, TsOH, reflux, 1.5 h) and cleaved by hydrolysis (cat. coned. HCl, acetone, reflux, 15 min, followed by aq. pyridine, reflux, 1 h). ... 

Cyelohydration of alkoxylvinylaeetylenie aleohols 180 (prepared from methoxy-butenyne by the Favorsky reaetion) leads to dihydropyran-4-ones 181-183 under eonditions of the Kueherov reaetion (75MI1 88MI1 93MI2). 

The [ 2 + 4]-cycloaddition reaction of aldehydes and ketones with 1,3-dienes is a well-established synthetic procedure for the preparation of dihydropyrans which are attractive substrates for the synthesis of carbohydrates and other natural products [2]. Carbonyl compounds are usually of limited reactivity in cycloaddition reactions with dienes, because only electron-deficient carbonyl groups, as in glyoxy-lates, chloral, ketomalonate, 1,2,3-triketones, and related compounds, react with dienes which have electron-donating groups. The use of Lewis acids as catalysts for cycloaddition reactions of carbonyl compounds has, however, led to a new era for this class of reactions in synthetic organic chemistry. In particular, the application of chiral Lewis acid catalysts has provided new opportunities for enantioselec-tive cycloadditions of carbonyl compounds. 

The 6-substituted 1,4-dioxocins can be used to prepare other 6-substituted derivatives by simple functional group transformations.4,8,9 Especially interesting is the synthesis of the 4/7-4-oxo-2,3-dihydropyran-2-yl-substituted derivative 16 from l,4-dioxocin-6-carbaldehyde (15) by a cyclocondcnsation with Danishefsky s diene.9 Dehydrogenation of 16 yields 2 which can be isomerized to the corresponding isomeric. sr/i-benzene dioxide 3 (X = 4/f-4-oxopyran-2-yl), which is identical with and proved the structure of the naturally occurring antibiotic LL-Z 1220.10... 

Dihydro-2f/-pyran-2-one has been prepared by reductive cycliza-tion of 5-hydroxy-2-pentynoic acid [2-Pentynoic acid, 5-hydroxy-], which is obtained in two steps from acetylene [Ethyne] and ethylene oxide [Oxirane] 3 and by the reaction of dihydropyran [277-Pyran, 3,4-dihydro-] with singlet oxygen [Oxygen, singlet].4,5 2ff-Pyran-2-one has been prepared by pyrolysis of heavy metal salts of coumalic acid [2//-Pyran-5-carboxylic acid, 2-oxo-],8 by pyrolysis of a-pyrone-6-carboxylic acid [211 - Pyran-6-carboxyl ic acid, 2-oxo-] over copper,7 and by pyrolysis of coumalic acid over copper (66-70% yield).8... 

The first total synthesis of the marine dolabellane diterpene (+)-4,5-deoxy-neodolabelline (70) was accomplished by D. R. Williams et al. [58]. The trans-disubstituted dihydropyran moiety in key intermediate 69 was efficiently prepared from mixed acetal 66 by RCM with second-generation catalyst C and subsequent Lewis acid-catalyzed allylation of ethyl glycosides 67 with allylsi-lane 68 (Scheme 12) [59]. 

Dihydropyrans [71] and 4-dihydropyranones [72] have been prepared by BF3 or Me2AlCl catalyzed Diels-Alder reactions of alkyl and aryl aldehydes with dienes 72 and 73 (Equations 3.20 and 3.21). Allylic bis-silanes are useful building blocks for synthesizing molecules of biological interest [73], 4-Pyra-nones have been obtained by cerium ammonium nitrate (CAN) oxidation of the cycloadducts. 

Lewis-acid catalyzed inverse electron-demand Diels-Alder reactions between conjugated carbonyl compounds and simple alkenes and enolethers also allow dihydropyranes to be prepared. SnCU-Catalyzed cycloaddition of... 

Substituted 3,4-dihydropyranes were also prepared by Diels-Alder reactions between (E)-4-oxobutenoate 80 and vinylethers [80] under iron(III) 2-ethylhex-aonate, a mild and economical catalyst (Equation 3.26). Diastereomeric excess as high as 98 % was observed. Cycloadducts with a 2,4-cw-configuration were preferred. 

Dihydropyran (DHP) linker 45 is a common handle that couples an alcohol to a solid support with subsequent release upon mild TFA conditions (Fig. 12) [54]. An alternative approach is to prepare an active carbonate linker. TV,TV -Disuccinimidyl carbonate (DSC), a valuable reagent for converting hydroxymethyl-based supports to their corresponding carbonates, was reacted with 4-hydroxymethylpolystyrene 46 and 4-nitrobenzamido (Nbb) 47 resins to anchor alcohols and phenols (Scheme 17) [55]. The final products were released from the solid support by HF and photolysis, respectively. 

Preparation of the requisite side chain starts by alkylation of ethyl acetoacetate with 1,3-dibromopen-tane the initially formed bromoketone (shown as the enol 97) undergoes O-alkylation under the reaction conditions to give the dihydropyran 98. Reaction of that masked hydroxy ketone derivative with hydrogen... 

An additional example of an oxonium ion generated via the acid catalyzed rearrangement has been used to prepare a dihydropyran <06TL6149>. The oxonium ion 54 generated by the reaction of an epoxide with ZrCl4 can be trapped by a nucleophile such as butynol to prepare dihydropyran 55. A variety of mono- and disubstituted epoxides have been used in this reaction. 

Tetrahydropyrane has been prepared by hydrogenation of dihydropyrane using a platinum black catalyst 1 by heating pen-tamethylene bromide with water 2 3 or with water and zinc oxide in a sealed tube 4 or by heating pentamethylene glycol with three volumes of 60 per cent sulfuric acid in a pressure tube.5... 

Aside from alcohols, other oxygen nucleophiles have also participated in hydroalkoxylation reactions with alkynes. The most common of these are 1,3-dicarbonyl compounds, whose enol oxygens are readily available to add to alkynes. Cyclization reactions of this type have been carried out under Pd(0) catalysis with various aryl or vinyl iodides or triflates, often in the presence of CO, affording the corresponding furan derivatives (Equation (95)).337-340 A similar approach employing cyclic 1,3-diketones has also been reported to prepare THFs and dihydropyrans under Pd, Pt, or W catalysis.341 Simple l-alkyn-5-ones have also been isomerized to furans under the influence of Hg(OTf)2.342... 

The protocol mentioned above for the preparation of dihydropyrans was also applied to the amidopalladation of allenes 8 and the subsequent RCM of N,0-acetal intermediates 216. This method leads to the expected five-, six- and seven-membered nitrogen-containing heterocycles 217 with good efficiency (Scheme 8.53) [118a],... 

Similarly, 5-lactols and 5-lactones are obtainable from the corresponding homo allylic alcohols. With dehydration, the corresponding dihydropyrans are prepared. Spirocyclic y-butyrolactones of this type and the corresponding 5-lactones are widespread in nature and play a key role as synthetic intermediates. 

An outstandingly reactive diene is l-methoxy-3-(trimethylsilyloxy)-l,3-butadiene ( Danishefsky s diene ) 4, prepared by the action of trimethylsilyl chloride on the ketone 3 in the presence of zinc chloride/triethylamine (equation 7)6. The reaction of diethyl mesoxalate with Danishefsky s diene gives the dihydropyran 5 with the (trimethylsily-loxy)dienes 6 and 7, mixtures of dihydropyrans are obtained, in which the meta-isomers predominate (equations 8 and 9)7. 

Disubstituted dihydrofurans and dihydropyrans were prepared via allylic etherification [68] in a similar manner to dihydropyrroles (cf Section 9.4.6). Thus, diaste-reoisomeric ethers were generated by the reaction of cinnamyl tert-butyl carbonate with the copper alkoxide prepared from (Rj-l-octen-3-ol, depending on which enantiomer of the phosphoramidite ligand was used (Scheme 9.39). Good yields and excellent selectivities were obtained. RCM in a standard manner gave cis- and trans-dihydrofuran derivatives in good yield, and the same method was used for the preparation of dihydropyrans. 

The preparation of dibenzo-18-crown-6 polyether directly from catechol and bis(2-chloroethyl) ether has been reported previously. The present procedure is an improvement of this method. Although dibenzo-18-crown-6 polyether can be obtained in 80% yield from bis-[2-(o-hydroxyphenoxy)-ethyl] ether and bis(2-chloroethyl) ether, the former intermediate has to be synthesized by a method involving several steps. One of the hydroxyl groups of catechol must be protected against alkali by reaction with a molecule of dihydropyran or chloromethylm ethyl ether. Then the intermediate is treated with bis(2-chloroethyl) ether in the presence of alkali and, finally, converted into the desired intermediate by acid hydrolysis. The yield of bis[2-(o-hydroxyphenoxy)-ethyl] ether was less than 40% so that the overall yield of dibenzo-18-crown-6 polyether never approached 39-48%, the yield of the present direct method. 

Recently, the first examples of catalytic enantioselective preparations of chiral a-substituted allylic boronates have appeared. Cyclic dihydropyranylboronate 76 (Fig. 6) is prepared in very high enantiomeric purity by an inverse electron-demand hetero-Diels-Alder reaction between 3-boronoacrolein pinacolate (87) and ethyl vinyl ether catalyzed by chiral Cr(lll) complex 88 (Eq. 64). The resulting boronate 76 adds stereoselectively to aldehydes to give 2-hydroxyalkyl dihydropyran products 90 in a one-pot process.The diastereoselectiv-ity of the addition is explained by invoking transition structure 89. Key to this process is the fact that the possible self-allylboration between 76 and 87 does not take place at room temperature. Several applications of this three-component reaction to the synthesis of complex natural products have been described (see section on Applications to the Synthesis of Natural Products ). 

McDonald et al. applied their dihydropyran formation to the oligosaccharide synthesis featuring reiterative alkynol cycloisomerization [19c-f]. Dihydropyran 49 was prepared by the method described above and then NIS-promoted glycosyla-tion with the acyclic alkynol 50 followed by Ph3SnH-promoted dehalogenation and... 

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