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Functionally substituted tetrahydropyran

Aiming at the pyranose form of sugars, normal type hetero-Diels-Alder reactions were extensively used for the synthesis of functionally substituted dihydropyran and tetrahydropyran systems (5-10) (see routes A - D in the general Scheme 1) which are also important targets in the "Chiron approach" to natural product syntheses (2.) Hetero-Diels-Alder reactions with inverse electron demand such as a, p-unsaturated carbonyl compounds (l-oxa-1,3-dienes) as heterodienes and enol ethers as hetero-dienophiles, are an attractive route for the synthesis of 3,4-dihydro-2H-pyrans (11). [Pg.183]

The structural feature of the members in this family involves a 51-carbon chain having 24 stereogenic centers, two 6,6-spiroketal moieties, two highly substituted tetrahydropyran rings, and a 42-membered lactone ring. In addition, spongistatins 1 (altohyrtin A), 4,5, and 9 contain a novel unprecedented chlorodiene functionality. [Pg.243]

Reductive lithiations of substituted tetrahydropyrans are often highly stereoselective reactions as a direct consequence of the anomeric radical intermediates involved. The mechanism involves one-electron reduction of a thiophenyl ether (or an equivalent reactive functional group) to generate an axial anomeric radical that is reduced by a second electron to form an axial a-alkoxylithium species, which can then be alkylated or protonated. Thus the high selectivities observed in reductive lithiations are a direct reflection of the axial preference for a-oxygenated radicals. [Pg.834]

Substituted tetrahydropyrans are prevalent in natural products that show interesting biological and pharmacological activities. Therefore, demand for new synthetic approaches for the construction of substituted tetrahydropyrans has recently increased. Specifically, quick and facile access to substrates, excellent stereoselectivity and yield, versatility in substrate scope, and mild reaction conditions compatible with various functional groups are highly desirable characteristics in tetrahydropyran synthesis. [Pg.9]

It was demonstrated that BINOL catalysts authorize the /3- and /-functionalizations of the allyltin reagents without lowering the enantioselectivity level [223], and such a strategy was used in the total syntheses of macrolides [224] or substituted tetrahydropyran units [225]. It was noteworthy that the BINOL-Ti catalysis was extended to the enantioselective allylation of alkyl and aromatic ketones in good yields with up to 96% ee [226]. Silver/BINAP was used as well, with a marked anti selectivity, when using crotyltins whatever is the nature, (E) or (Z) of the double bond [227]. This reaction was extended to other organometallics such as 2,4-pentadienylstannanes [228] or buta-2,3-dienylstannanes [229] (Scheme 6.26). [Pg.222]

In 2007, another departure from carbonyl-type activation was marked by Kotke and Schreiner in the organocatalytic tetrahydropyran and 2-methoxypropene protection of alcohols, phenols, and other ROH substrates [118, 145], These derivatives offered a further synthetically useful acid-free contribution to protective group chemistry [146]. The 9-catalyzed tetrahydropyranylation with 3,4-dihydro-2H-pyran (DHP) as reactant and solvent was described to be applicable to a broad spectrum of hydroxy functionalities and furnished the corresponding tetrahydro-pyranyl-substituted ethers, that is, mixed acetals, at mild conditions and with good to excellent yields. Primary and secondary alcohols can be THP-protected to afford 1-8 at room temperature and at loadings ranging from 0.001 to 1.0mol% thiourea... [Pg.162]

Unsaturated tetrahydropyran derivatives have received only cursory attention in the literature as heterocyclic monomers. 2,3-Dihydropyran and several of its substituted derivatives apparently undergo cationic polymerization in a manner typical of vinyl ethers (72MI11103), while tetrahydropyranyl esters of methacrylic acid (123) are fairly typical free radically polymerizable monomers (Scheme 35) (74MI11105). The THP group was used in this study as a protecting group for the acid functionality, and it was found that deprotection of polymers (124) could be accomplished under extremely mild conditions. [Pg.287]

Cyclobutenes possessing an angular O-functionality, obtained from a Lewis acid-mediated [2+2] cycloaddition of cyclic silyl enol ethers to ethyl propynoate and subsequent reduction and butenylation, undergo a ring-opening metathesis that produces a substituted dihydropyran that forms part of a c -diene. After desilylation, an oxy-Cope rearrangement leads to the fused tetrahydropyran 4 <03JA14901>. [Pg.407]

Pyrans, pyrones, pyrilium salts, mutual transformations of 85UK1971. 2-Pyrones, 6-substituted, synthesis and reactivity of 83MI6. Tetrahydropyrans, 2.6-disubstituted, synthesis of 83CRV379. 47/-Tetrahydropyrans, 4-functionalized, chemistry of 81AKZ728. Tetrahydropyrans, synthesis via intramolecular cyclization of unsaturated... [Pg.330]

One recognizes an oxane ring (tetrahydropyran) substituted by three secondary alcohol functions in an equatorial orientation, a side chain carrying a primary alcohol function and finally a hemiacetal hydroxyl carried by carbon 1. This intramolecular hemiacetal is derived from the addition of the oxygen carried by C-5 to an aldehyde function. [Pg.170]

For synthetic purposes cyclized radicals are preferentially trapped by chlorine [16], bromine [60], or iodine atom donors [54] to provide y9-functionalized tetrahy-drofurans, for instance halides 35-37 (Scheme 9), which serve as building blocks for subsequent ionic or free-radical reactions. This radical version of the classical halogen cyclization (Bartlett reaction [61]) is particularly useful if functionalized tetrahydrofurans can be obtained from terminal alkyl- or aryl-substituted alkenols. If these compounds are reacted for example with iodine or with A -bromosuccin-imide, tetrahydropyrans are formed from ionic cyclofunctionalizations [62], If, however, the corresponding alkenols are converted into a thiohydroxamic acid... [Pg.933]

A further variation of these functionalizations of cyanoarenes is the NOCAS process [14, 15]. As shown in Scheme 14.2, path g, this involves the addition of a nucleophile (which is often the solvent) to the donor radical cation. The thus-formed neutral radical adds to the acceptor radical anion, while rearomatization by the loss of an anion leads again to an overall ipso-substitution. AUenes could be used as the donors in these reactions, as shown recently by Arnold [50]. Accordingly, the irradiation of TCB in the presence of tetramethylaUene (15) in a 3 1 MeCN/MeOH mixture afforded 1 1 1 arene-allene-methanol adduct 16 in 48% yield (Scheme 14.9, central part). Interestingly, the addition of methanol took place exclusively at the central allene carbon, while aromatic substitution occurred through the terminal carbons. co-Alkenols, in which an O-nucleophile and an easily oxidized moiety are both present, could also be used. In the latter case, the initial ET was followed by a cyclization, yielding aryl-substituted tetra-hydrofurans or tetrahydropyrans as the final products via a tandem Ar—C, C—O bond formation [51]. [Pg.524]

The addition of alkyl radicals to vinyl sulfones to give functionalized alkenes via an addition-elimination sequence has been investigated by Russell and coworkers in some details [132, 147]. This reaction has recently been extended to unsaturated sulfimides, allowing the synthesis of styryl tetrahydrofurans and tetrahydropyrans [148]. The extension of this approach to phenylsulfonyl oxime ethers and heteroaromatic aryl sulfones (/p o-substitution) has recently been obtained with success [149, 150]. An example which comes from the work of Kim et al. is reported in equation (76) [149]. In this radical sequence, the alkyl radical generated photochemically from an alkyl iodide, in the presence of 1.2 equivalent of hexabutylditin, adds readily to the C=N bond of the oxime ether to... [Pg.345]


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Functional substitution

Substituted tetrahydropyrans

Tetrahydropyran

Tetrahydropyranation

Tetrahydropyrane

Tetrahydropyranes

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