Tetrahydropyranyl ether, from alcohols

Enol ethers (15) and mixed acetals (16) are readily obtained from secondary but not from tertiary alcohols, whereas tetrahydropyranyl ethers can be formed even from tertiary alcohols. This is a result of the greater steric requirements of the reagents (17) and (18) as compared to (19). 

The 21-hydroxyl group in the corticosteroid series can be protected as the base stable triphenylmethyl ether and tetrahydropyranyl ether. " " Mixed acetals from 21-alcohols are extremely acid sensitive compounds. ... 

Although alcohols are oxidized by tetra-n-butylammonium persulphate when the reaction is conducted in dichloromethane, tetrahydropyranyl ethers have been produced (>90%) when attempts to oxidize the alcohol are conducted in tetrahydro-pyran (see Chapter 10) [ 19], Tetrahydrofuranyl ethers have been prepared by an analogous method [20,21 ]. Base-mediated elimination of halo acids from P-halo alcohols under phase-transfer catalysed conditions produce oxiranes in high yield (70-85%). The reaction has particular use in the synthesis of epihalohydrins from p,y-dihalo alcohols [22],... 

Tetrahydropyranyl ethers are readily prepared from the alcohol and 2,3-tetrahydropyran in the presence of acid, and the reaction is widely used as a method of protection of hydroxyl groups. Preparative procedures and the methods of deprotection are given in Section 5.4.6, p. 551). 

A recently published full account of another synthesis [69] of the same alkaloid starting from the /rans-cinnamic ester 264 represented a different approach (ACD -> ACDB) to ( )-lycorine (Scheme 42). An intramolecular Diels-Alder reaction of 264 in o-dichlorobenzene furnished the two diastereomeric lactones 265 (86%) and 266 (5%) involving the endo and exo modes of addition respectively. The transposition of the carbonyl group of 265 to 267 was achieved by reduction with lithium aluminium hydride, followed by treatment of the resulting diol with Fetizon s reagent, which selectively oxidised the less substituted alcohol to give isomeric 5-lactone 267. On exposure to iodine in alkaline medium 267 underwent iodolactonisation to afford the iodo-hydroxy y-lactone 268. The derived tetrahydropyranyl ether... 

The mechanism of the formation of the tetrahydropyranyl ether (see Figure 23.1) is an acid-catalyzed addition of the alcohol to the double bond of the dihydropyran and is quite similar to the acid-catalyzed hydration of an alkene described in Section 11.3. Dihydropyran is especially reactive toward such an addition because the oxygen helps stabilize the carbocation that is initially produced in the reaction. The tetrahydropyranyl ether is inert toward bases and nucleophiles and serves to protect the alcohol from reagents with these properties. Although normal ethers are difficult to cleave, a tetrahydropyranyl ether is actually an acetal, and as such, it is readily cleaved under acidic conditions. (The mechanism for this cleavage is the reverse of that for acetal formation, shown in Figure 18.5 on page 776.)... 

The structure of baloxine (236) has been confirmed by partial synthesis from vindolinine,110 which has previously been converted into 19-hydroxytabersonine (237). The tetrahydropyranyl ether (238) of the (19.S)-epimer, on hydroboration-oxidation, gave a mixture of C-14 epimeric alcohols (239) on oxidation and removal of the tetrahydropyranyl ether grouping, these gave baloxine (236) (Scheme 34). Its formulation as (19S)-hydroxy-14-oxovincadifformine is thus confirmed. 

A similar reaction occurs when enol ethers react with alcohols in acid solution and in the absence of water, but now we are starting in the middle of the acetal hydrolysis mechanism and going the other way, in the direction of the acetal A useful example is the formation of THP (= TetraHydroPyranyl) derivatives of alcohols from the enol ether dihydropyran. You will see THP derivatives of alcohols being used as protecting groups in Chapter 24. 

On reaction of lithium dimethylcuprate with a vinylic halide which also contained a tetrahydropyranyl ether-protected allylic alcohol function (152), the product of coupling, (XVI), was obtained in poor yield (30%) and was accompanied by a 60% total yield of three other compounds [Eq. (103)]. The most significant of these represent products arising from the splitting off of the THP group, perhaps because of its allylic nature, by attack of the dimethylcuprate species and by an intermediate copper(III) compound on (XVI) or its precursor. 

The combination of triphenylphosphine with esters of trihaloacetic acids provides a reagent system for the stereo- and regio-selective conversion of alcohols into alkyl halides.The bromine-triphenylphosphine adduct has been used at low temperatures (-50 C in dichloromethane) for the removal of the tetrahydropyranyl protecting group from tetrahydropyranyl ethers derived from secondary and tertiary alcohols.The reactions of tertiary phosphines (and other trivalent phosphorus compounds) with iodine in aprotic solvents have received further study, a range of species being identified.The first reported study of the reactions of trivalent phosphorus compounds with monopositive astatine has led to the identification of stable complexes with triphenylphosphine, trioctylphosphine, and triethylphosphite. 

Allenic alcohols. Landor et alhave developed a new method for the preparation of allenic alcohols from prop-l-yne-3-ols, for example (1). This is converted into the tetrahydropyranyl ether (2) and then treated with ethylmagnesium... 

A second problem with Sarett oxidation is the difficulty in isolating the products from a pyridine solution. An advantage of the technique, as mentioned above, is that alkenes, ketals, sulfides, and tetrahydropyranyl ethers are oxidized much slower than alcohols and rarely give competitive side reactions. Oxidation of secondary alcohols proceeds in good yield, but oxidation of primary aliphatic alcohols often gives low yields of the aldehyde. 2 Benzylic and allylic alcohols give good yields, however. 

A second new synthesis of squalene utilizes the observation that selenium dioxide oxidation of gem-dimethyl olefins or cis- and truns-allylic alcohols yields stereospecifically traus-aj3-unsaturated aldehydes. The olefin (4) or a mixture of cis- and truus-diols (5) were transformed by use of selenium dioxide, followed by reduction, into the truns-allylic diol (6). The corresponding bromide (7) was used to alkylate two moles of the ylide from trans-geranyltributylphosphonium bromide leading eventually to all-traus-squalene in 46% yield [from the diol (6)]. Protection of one of the p-alcohol groups of (6) as the tetrahydropyranyl ether opens the possibilities of unsymmetrical coupling and the introduction of specifically labelled fragments. 

The corresponding reaction of but-3-yn-l-ols or pent-4-yn-l-ols with primary or secondary alcohols in the presence of catalytic amounts of Ph3PAuBF4 and p-TsOH afforded tetrahydrofuranyl ethers (Scheme 4-76). This tandem 5-endo-cycloisomerization/hydroalkoxylation proceeds via 2,3-dihydrofurans, which then undergo an intermolecular Bronsted acid-catalyzed addition of the external alcohol. The transformation is not restricted to internal alkynols but can be applied to terminal acetylenes as well. Application of the method to the s thesis of bicyclic heterocycles with a P-lactam structure was reported recently.Under the same conditions, epoxyalkynes undergo a sequence of epoxide opening, 6-exo-cycloisomerization, and nucleophilic addition to afford tetrahydropyranyl ethers. In a closely related transformation, cyclic acetals were obtained from alk-2-ynoates bearing a hydroxy group in 6- or 7-position by treatment with AuCU and MeOH. ... 

Alcohols and phenols were tetrahydropyrai rlated in the presence of H PMOgV O J in good to excellent yields in acetonitrile and under solvent-free reaction conations. A mild and convenient method for the formation and deprotection of ethers (tetrahydropyranyl (THP) ethers) is described. The formation of THP ethers from the corresponding alcohols was accomplished in the presence of acid-sensitive fimctional groups [106] (Scheme 3.47). 

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