In organic chemistry, a hemiacetal is a functional group the general formula, where is a hydrogen atom or an organic substituent. They generally result from the nucleophilic addition of an alcohol (a compound with at least one hydroxy group) to an aldehyde or a ketone under acidic conditions. The addition of an alcohol to a ketone is more commonly referred to as a hemiketal. Common examples of hemiacetals include cyclic monosaccharides. Hemiacetals have use as a protecting group and in synthesizing oxygenated heterocycles like tetrahydrofurans.
According to the IUPAC definition of a hemiacetal, the R1 and R2 groups may or may not be hydrogen. In a hemiketal, both of these R-groups must not be hydrogen. Thus, hemiketals are regarded as a subclass of hemiacetals. The prefix hemi, meaning half, refers to the one alcohol added to the carbonyl group. This is half of the required alcohols to form acetals or ketals.[1] Cyclic hemiacetals can sometimes be referred to as lactols.[2]
Hemiacetals form in the reaction between alcohols and aldehydes or ketones. Using an acid catalyst, the reaction proceeds via nucleophilic attack of the carbonyl group by the alcohol.[3] A subsequent nucleophilic attack of the hemiacetal by the alcohol results in an acetal. Solutions of simple aldehydes in alcohols mainly consist of the hemiacetal. The equilibrium is dynamic and can be easily reversed via hydrolysis. The equilibrium is sensitive to steric effects.[4]
| center | + Acetalization of aldehydes and ketones | ||
| Carbonyl compound | alcohol solvent | %hemiacetal | |
|---|---|---|---|
| acetaldehyde | methanol | 97 | |
| acetaldehyde | ethanol | 91 | |
| propionaldehyde | methanol | 95 | |
| bromoacetone | methanol | 47 |
Hemiacetals commonly exist in nature as aldoses such as glucose, and hemiketals commonly exist in nature as ketoses such as fructose. The favorability of the formation of a strain-free six-membered ring and the electrophilicity of an aldehyde combine to strongly favor the acetal form[6] .
Hemiacetals can be strategically used as a protecting group for carbonyls in organic synthesis to prevent unwanted reactions from occurring. A carbonyl can be converted to its hemiacetal form to decrease its reactivity. The desired reaction with the target functional group can then be carried out, and the hemiacetal can later be converted back to a carbonyl via hydrolysis.
Tetrahydrofurans can be synthesized from nucleophilic addition to hemiacetals with high stereoselectivity, which can be further used to form polymers such as lignans.
Hemiacetals can also undergo acid-catalyzed spirocyclization or metal-catalyzed addition/elimination to afford spiroacetals. These reactions are moderately stereoselective, although the thermodynamically-favoured isomer is often produced. Drug discovery programs synthesize spiroacetal scaffolds to generate libraries of spiroacetal-containing molecules. These spiroacetal derivatives have potential use in treating diseases such as CLL leukemia.
One method of producing linear hemiacetal esters is through the condensation of stabilized hemiacetals by anhydrides; this creates a stable hemiketal intermediate that subsequently undergoes acetylation into the hemiacetal ester. Hemiacetal esters are primarily used in polymer chemistry as a polymerization initiator and as a protecting group for carboxylic acids.[7]