The material was originally isolated from an aqueous extract of Asparagus officinalis, a spring vegetable. It is a derivative of the cyclic disulfide organic compound 1,2-dithiolane with a carboxylic acid functional group bound to carbon-4 of the heterocycle. Biosynthetic studies revealed that asparagusic acid is derived from isobutyric acid. Asparagusic acid is a colorless solid with a melting point of 75.7–76.5 °C, higher than that of the corresponding dithiol, dihydroasparagusic acid, at 59.5–60.5 °C.
Laboratory synthesis
A convenient synthesis of asparagusic acid has been developed from a commercially available diethyl malonate derivative starting material, improving on the prior method of Jansen. Diethyl bismalonate is treated with hydroiodic acid to yield β,β'-diiodoisobutyric acid after decarboxylation and ester hydrolysis. Dihydroasparagusic acid, the reduced form of asparagusic acid, is produced by sequential reaction with sodium trithiocarbonate and sulfuric acid; subsequent oxidation with hot dimethyl sulfoxide yields asparagusic acid.
Effect on urine
Observations that eating asparagus results in a detectable change in the odour of urine have been recorded over time. In 1702, Louis Lémery noted "a powerful and disagreeable smell in the urine", whilst John Arbuthnot noted that "asparagus... affects the urine with a smell." Benjamin Franklin described the odour as "disagreable" in Fart Proudly, his essay on flatulence whilst Marcel Proust claimed that asparagus "transforms my chamber-pot into a flask of perfume." As early as 1891, Marceli Nencki had attributed the smell to methanethiol which is also a component of flatus and bad breath. More recent research has attributed the odour to a mixture of sulfur-containing metabolites of asparagusic acid which have been detected in urine; these include methanethiol and span at least seven distinct functional groups, as shown in the table below. Most of the metabolites are volatile organic compounds with a high vapour pressure, meaning that they readily enter the gaseous state and spread through the air at room temperature and hence are available for detection by the olfactory system.
Asparagus has been eaten and cultivated for at least two millennia but the association between odorous urine and asparagus consumption was not observed until the late 17th century when sulfur-rich fertilisers become common in agriculture. Small-scale studies noted that the "asparagus urine" odour was not produced by all individuals and estimates as to the proportion of the population who are excretors has ranged from about 40% to as high as 79% In a 91 subject population study 82 participants reported "asparagus urine" odour. When excretors are exposed to non-excretor urine after asparagus consumption, however, the characteristic asparagus urine odour is usually reported. More recent work has confirmed that a small proportion of individuals do not produce asparagus urine, and amongst those that do, some cannot detect the odour due to a single-nucleotide polymorphism within a cluster of olfactory receptors. of α-lipoic acid, an organic compound essential for aerobic metabolism Recent research is consistent with attributing the origin of asparagus urine to asparagusic acid, a substance unique to this vegetable. Most studies of the compounds responsible for the odour of asparagus urine have correlated the appearance of the compounds above with asparagus consumption; they appear as little as 15 minutes after consumption. However, this does not provide information on the biochemical processes which lead to their formation. Asparagusic acid and lipoic acid are similar in that both possess a 1,2-dithiolane ring with a carboxylic acid tethered to it; indeed, it has been reported that asparagusic acid can substitute for lipoic acid in α-keto-acid oxidation systems such as the citric acid cycle. The --enantiomer of α-lipoic acid is a cofactor in the pyruvate dehydrogenase complex and is essential for aerobic metabolism. The degradation pathway of lipoic acid has been well studied and includes evidence of reduction of the disulfide bridge, S-methylation, and oxidation to produce sulfoxides. Similar transformations of asparagusic acid would lead to metabolites like this detected in asparagus urine. Synthetic work has confirmed the relative ease of oxidation of asparagusic acid to yield S-oxides of the dithiolane ring. The rate of degradation appears highly variably between subjects; the typical half-life for odour disappearance is around 4 h with a between subject variability of 43.4%. In the small minority of people who do not produce these metabolites after consuming asparagus, the reason may be as simple as asparagusic acid not being taken into the body from the digestive tract or that these individuals metabolise it in such a way as to minimise the release of volatile sulfur-containing products.
