Acetal formation ethers

The formation of derivatives of this type by free-radical attack has been mentioned previously (see section E above). The most common route to vinylogous halo ketones is by halogenation of dienol acetates or ethers. Both free halogen and A -halo compounds may be employed, and this approach has frequently been used to obtain 6 (axial) halo compounds ... 

With 11/3-hydroxy steroids, 11/3, 19-ether formation competes with hemi-acetal formation.This is a consequence of steric hindrance of the 11/5-oxygen by the C-18 and C-19 iodomethyl groups which reduces the rate of hypoiodite formation [(3) (5)] even though the conformation of the... 

Hydrogenation of carbonyls, or incipient carbonyls such as phenols (86), in lower alcohol solvents may result in the formation of ethers. The ether arises through formation of acetals or ketals with subsequent hydrogenolysis. The reaction has been made the basis of certain ether syntheses (45,97). Reaction of alcohols with carbonyls may be promoted by trace contamination, such as iron in platinum oxide (22,53), but it is also a property of the hydrogenation catalyst itself. So strong is the tendency of palladium-hydrogen to promote acetal formation that acetals may form even in basic media (61). 

On reacting aldehydes such as benzaldehyde or cyclohexanecarboxaldehyde 720 with silylated alcohols such as 718 or 721, or with triethylsilane 84b in the presence of TMSOTf 20 at low temperatures, acetal formation and reduction is achieved in one step to afford ethers 719 and 722 in high yields [215] (Scheme 5.74). 

Such esterifications and acetal formations are achieved through enzyme catalyses. However, such reactions are relatively rare in aqueous conditions chemically. This is because the reversed reactions, hydrolysis, are much more favorable entropically. Kobayashi and co-workers found that the same surfactant (DBSA) that can catalyze the ether formation in water (5.2 above) can also catalyze the esterification and acetal formations reactions in water.52 Thus, various alkanecarboxylic acids can be converted to the esters with alcohols under the DBSA-catalyzed conditions in water (Eq. 5.6). Carboxylic acid with a longer alkyl chain afforded the corresponding ester better than one with a shorter chain at equilibrium. Selective esterification between two carboxylic acids with different alkyl chain lengths is therefore possible. 

Halide ions will also act as nucleophiles towards aldehydes under acid catalysis, but the resultant, for example, 1,1-hydroxychloro compound (35) is highly unstable, the equilibrium lying over in favour of starting material. With HC1 in solution in an alcohol, ROH, the equilibrium is more favourable, and 1,1-alkoxychloro compounds may be prepared, e.g. 1-chloro-l-methoxymethane (36, a-chloromethyl ether ) from CH20 and MeOH (cf. acetal formation, p. 209), provided the reaction mixture is neutralised before isolation is attempted ... 

Fnchs, B. Nelson, A. Star, A. Stoddart, J. E Vidal, S. Amplification of dynamic chiral crown ether complexes dnring cyclic acetal formation. Angew. Chem. Int. Ed. 2003,42, 4220 224. 

Birch reduction of the norgetrel intermediate 5 oil owed by hydrolysis of the enol ether gives the enone oxidation of the alcohol at 17 leads to dione 7. Fermentation of that intermediate in the presence of the mold PeniciIlium raistricky serves to introduce a hydroxyl group at the 15 position W. Acetal formation with neopentyl glycol affords the protected ketone which consists of a mixture of the A and A isomers (2 ) hindrance at position 17 ensures selective reaction of the 3 ketone. The... 

Compound Name Ethylene Diamine Tetracetic Acid Ethylene Oxide Ethyl Acetate Ethyl Ether Ethyl Formate Ethyl Formate Ethylhexaldehyde Ethylhexaldehyde Ethylhexaldehyde 2-Ethyl Hexanol 2-Ethyl Hexanol 2-Ethyl-3-Propylacbolein 2-Ethylhexyl Acrylate, Inhibited 2-Ethyl Hexanol 2-Ethylhexyl Acrylate, Inhibited Ethyl Hexyl Tallate 2,4,5-T(esters)... 

Meso-tartrate is joined to glucuronic acid in glycosidic linkage and by acetal formation to the aldehyde gly-oxylic acid, HOOC—CHO, which is also joined in an ether linkage to the next repeating unit.130 Similar open acetal linkages join monosaccharide units in some bacterial lipopolysaccharides and may occur more widely.1303... 

The transition metal complex-catalyzed formation of 1,3-dioxepanes from vinyl ethers has also been described. For example, reaction of allyl vinyl ether 157 with a nonhydridic ruthenium complex at higher temperatures and without any solvent produced 1,3-dioxepane 159 whereas, the use of a hydridic ruthenium complex resulted in the formation of vinyl ether 158 by double-bond isomerization (Scheme 43). It was suggested that cyclic acetal formation proceeds via a 7i-allyl-hydrido transient complex, which undergoes nucleophilic attack of the OH group at the coordinated Jt-allyl <2004SL1203>. 

Artemisinin (1) can be selectively reduced with NaBH4 to afford dihydroartemisinin (175, DHQHS), which has been shown to be roughly ten times as potent as parent material 1. The lactol DHQHS (175) was converted to various ethers by treatment in alcohols with boron trifluoride (acetal formation conditions). Notably artemether (144) and arteether (145) were prepared in this manner. Alternatively, DHQHS can be acylated to yield esters or carbonates, as shown for sodium artesunate (146) as an example. 

A moderate yield of this reaction may be due to side reactions like dimethyl acetal formation at the hydroxymethylene group. 9 Alkylating reagents like dimethyl sulfate or diazomethane6d have been employed as well to furnish the enol ether moiety in 1 but proved to give lower yields. 

Substituted pipecolic acid derivatives can be accessed from a suitably protected allylglycine derivative by first use of a palladium-catalyzed N, O-acetal formation followed by RCM.43 Treatment of 19 with boron trifluoride etherate followed by a variety of nucleophiles formed the corresponding substituted products 20 and 21 (Scheme 28.12). 

The alternative to this 0,0-acetal formation is the sequence of addition and El reaction. As a matter of fact, this is familiar from the transformation of alcohols with carbonyl compounds, but only occurs in some (very rare) cases. This is illustrated by Figure 9.31 using acid-catalyzed transformations of ethanol with two /3-diketones as an example. Here, enol ethers, namely 3-ethoxy-2-cyclopentene-l-one and 3-ethoxy-2-cyclohexene-l-one, respectively, are... 

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.)... 

Experiments on the bromination of equilibrated ketone-acetal systems in methanol were also recently performed for substituted acetophenones (El-Alaoui, 1979 Toullec and El-Alaoui, 1979). Lyonium catalytic constants fit (57), but for most of the substituents the (fcA)m term is negligible and cannot be obtained with accuracy. However, the relative partial rates for the bromination of equilibrated ketone-acetal systems can be estimated. For a given water concentration, it was observed that the enol path is more important for 3-nitroacetophenone than for 4-methoxyacetophenone. In fact, the smaller the proportion of free ketone at equilibrium, the more the enol path is followed. From these results, it can be seen that the enol-ether path is predominant even if the acetal form is of minor importance. The proportions of the two competing routes must only depend on (i) the relative stabilities of the hydroxy-and alkyoxycarbenium ions, (ii) the relative reactivities of these two ions yielding enol and enol ether, respectively, and (iii) the ratio of alcohol and water concentrations which determines the relative concentrations of the ions at equilibrium. Since acetal formation is a dead-end in the mechanism, the amount of acetal has no bearing on the relative rates. Bromination, isotope exchange or another reaction can occur via the enol ether even in secondary and tertiary alcohols, i.e. when the acetal is not stable at all because of steric hindrance. 

Acetal formation by the solvent occurs during the aminomethylation of isobutyr-aldehydc (see 8, 9 in Sec. A.l), and a transestcrification accompanies the reaction of dithiobutyric esters with methylolamine ethers (Fig. 59). Thus, Mannich bases 172, in which the thioester bond has been converted into O-ester bond, are obtained in good yields.- ... 

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