Carbon cyclic ketal

In an analogous approach explored by Dixneuf et al., a conjugated enynyl carbonate is converted into an oxolenone or a bicyclic lactone in significant yields via double carbonylation in the presence of methanol (Scheme 22) [128]. When a neighboring carbonyl group is present in the substrate, it can also participate in palladium-catalyzed cyclization-carbonylation. Indeed, 4-yn-l-ones lead to cyclic ketals that can be easily converted into 2-cyclopentenone carboxylates in an acidic medium (Scheme 22) [129]. 

Reaction of Cyclic Ketals with Carbon Dioxide... 

This section deals only with solvents whose reduction products are insoluble in the presence of lithium ions. The list includes open chain ethers such as diethyl ether, dimethoxy ethane, and other polyethers of the glyme family cyclic ethers such as THF, 2Me-THF, and 1,4-dioxane cyclic ketals such as 1,3-dioxolane and 1,3-dioxane, esters such as y-butyrolactone and methyl formate and alkyl carbonates such as PC, EC, DMC, and ethylmethyl carbonate. This list excludes the esters, ethyl and methyl acetates, and diethyl carbonate, whose reduction products are soluble in them (in spite of the presence of Li ions). Solutions of solvents such as acetonitrile and dimethyl formamide are also not included in this section for the same reasons. Figure 6 presents typical steady state voltammo-grams obtained with gold, platinum, and silver electrodes in Li salt solutions in which solvent reduction products are formed and precipitate at potentials above that of lithium metal deposition. These voltammograms are typical of the above-mentioned solvent groups and are characterized by the following features ... 

The rat can convert glucose cycloacetoacetate to ascorbic add, although this does not appear to be a physiological route of synthesis. The conversion is blocked by pantothenic acid deficiency (T6). This interesting compound is a cyclic ketal in which carbons 2 and 3 of acetoacetate are condensed with carbons 1 and 2 of glucose. 

Cyclic carbonates and cyclic boronates have also found considerable use as protective groups. In contrast to most acetals and ketals the carbonates are cleaved with strong base and sterically unencumbered boronates are readily cleaved by water. 

Catechols can be protected as diethers or diesters by methods that have been described to protect phenols. However, formation of cyclic acetals and ketals (e.g., methylenedioxy, acetonide, cyclohexylidenedioxy, diphenylmethylenedioxy derivatives) or cyclic esters (e.g., borates or carbonates) selectively protects the two adjacent hydroxyl groups in the presence of isolated phenol groups. 

Just as certain pyranose sugars can give rise to bis-acetal or bis-ketal derivatives which constitute linearly fused 5 6 6 systems (cf. Section 12.17.2.1.7), another set of bis-acetals and bis-ketals - in many cases derived from the same sugars - correspond to angularly fused 5 6 6 systems. These, like their linearly fused analogues, serve to protect, selectively, four hydroxyl groups of the parent sugars, and cyclic carbonates (l,3-dioxolan-2-ones) may fulfill similar functions. 

This ketal protective group is resistant to basic and nucleophilic reagents but is readily removed by aqueous acid. Formaldehyde, acetaldehyde, and benzaldehyde can also used as the carbonyl component in the formation of cyclic acetals. They function in the same manner as acetone. A disadvantage in the case of acetaldehyde and benzaldehyde is the possibility of forming a mixture of diastereomers, because of the new stereogenic center at the acetal carbon. 

Satoh and coworkers further investigated this reaction and found that, in some cases, magnesium /3-oxido carbenoids gave better results. Trapping of the enolate intermediates with several electrophiles was successfully carried out and a new method for the synthesis of one-carbon expanded cyclic a,a-disubstituted ketones from lower cyclic ketones was realized. An example using 1,4-cyclohexanedione mono ethylene ketal (195) as a representative cyclic ketone is shown in Table 15. ... 

We saw in the previous chapter that aldehydes react with alcohols to form hemi-acetals, and hemiacetals react with another alcohol to afford acetals. Well, the intramolecular reaction of the aldehyde carbon of an aldose monosaccharide with one of the hydroxyl groups in the same molecule affords a cyclic hemiac-etal. An mferaiolecular reaction of this hemiacetal with the hydroxyl group of another sugar molecule provides an acetal functional group. This kind of acetal linkage connects monosaccharides into polysaccharides. Biochemists refer to these acetal (and ketal) bonds as glycoside bonds. 

In connection with the total synthesis of grandisol, an asymmetric addition of ethylene on chiral heterocyclic aminals and ketals was examined (Scheme 23). The selectivity can be high, with a preferred approach of ethylene from the less hindered side, especially when chiral pyrrolidone 97 or furanones 100 were used in place of cyclic enones [70]. The diastereoisomeric excess of 101 or 102 remains modest with 5-menthyloxy furanone, even if the dark addition of nucleophiles or radicals on 100 occurs with a total facial selectivity. From a detailed analysis of the dependence of the product ratio with temperature and substituents, it was proposed that a pyramidalization of the (3-carbon in the relaxed of the... 

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