posted on 2024-11-06, 15:23authored byPeiqing Yang, Nuno Basílio, Xiaojun Liao, Zhenzhen Xu, Olivier Dangles, Fernando Pina
In
this work, the thermodynamics and kinetics of the
reversible
and irreversible processes of cyanidin 3,5-O-diglucoside
and cyanidin 3-O-(2-O-glucosyl,
6-O-sinapoyl)glucoside-2-O-glucoside,
5-O-glucoside were studied by covering all pH range
(holistic approach). The acylation (i) decreases the mole fraction
of the colorless hemiketal in acidic medium and increases that of
the colored quinoidal base, (ii) expands the pH domain of the flavylium
cation, and (iii) moderately decreases the rate of tautomerization
and isomerization of the neutral and monoanionic species. Degradation
of cyanidin-3,5-O-diglucoside in a basic medium occurs
in two distinct stages. After the formation of the anionic quinoidal
bases (double proton loss from flavylium cation), a fast kinetic step,
only observed by stopped flow, gives rise to the B4n– hydroxide adducts (n = 2,3) in equilibrium with the respective quinoidal bases An– (n = 1,2), leading
to a first transient state. The quinoidal bases and B4n– adducts disappear completely from
the first to a second transient state by means of two parallel reactions:
(i) one reversible, giving the anionic cis- and trans-chalcones, (ii) the other irreversible, giving degradation
products and exhibiting a pH-dependent bell-shaped mole fraction with
maximum around pH = 12. From the second transient state, the anionic
chalcones disappear completely in a few days. Acylation prevents formation
of the first transient state. All of these effects are compatible
with anthocyanidin–acyl π-stacking interactions (intramolecular
copigmentation).