Thermal degradation kinetics of carotenoids: Acrocomia aculeata oil in the context of nutraceutical food and bioprocess technology

In the present study, the kinetics of beta-carotene and beta-cryptoxanthin degradation were investigated in edible oil mechanically extracted from the mesocarp of macauba fruit. The crop has a similar productive potential to African palm (Elaeis guineensis), which is among the highest oil-yielding plants in the world. The heating process was conducted under a nitrogen atmosphere, without light exposure. Heat treatments were assumed isothermal and performed at five temperatures, ranging from 110 to 150 degrees C. HPLC analyses were carried out in addition to spectrophotometric determinations to monitor the carotenoid variations over the heating time. The initial composition of the oil was also highlighted for tocols, peroxide, and trace metal contents. Thermodynamic parameters were obtained from the expression of rate constant derived from transition state theory. The results indicated that the first-order kinetic model is appropriate for describing the oxidative degradation of the compounds in the macauba oil. The carotenoid concentrations decreased for all the treatments as a function of heating time, becoming faster at higher temperatures. A definite influence of temperature on the reaction rates of beta-carotene and beta-cryptoxanthin was determined, based on the Arrhenius model. The apparent activation energy estimated for beta-cryptoxanthin (87 kJ mol(-1)) was higher as compared to beta-carotene (80 kJ mol(-1)) and the sum of beta-carotene + beta-cryptoxanthin (84 kJ mol(-1)). Correlated combinations of k(ref) and E-a indicate that the kinetic parameters estimated for overall carotenoids might predict the retention of the individual compounds with relative accuracy in the context of industrial-scale processes.

Automated summary

This study investigated the kinetics of beta-carotene and beta-cryptoxanthin degradation in edible oil from macauba fruit. The results showed that temperature has a significant influence on the degradation rates of these compounds, with the degradation rate increasing at higher temperatures. The apparent activation energy for carotenoids was also determined, highlighting the impact of temperature on the degradation process.