Study of the Interactions Occurring During the Encapsulation of Sesamol within Casein Micelles Reformed from Sodium Caseinate Solutions

Abstract A casein micelle is a natural structure found in milk, based on the association between individual caseins and colloidal calcium phosphate, which can be used as vehicle for the encapsulation of hydrophobic compounds. In this project the capacity of micelles to encapsulate sesamol, a powerful antioxidant present in roasted sesame seeds, was evaluated. The micelles were reformed from sodium caseinate solutions at 2% or 5% (w/v) concentration, and then 1 or 2 mg/mL sesamol were added. A significant increase on the encapsulation efficiency was observed as caseinate concentration increased, going from 28% to 35% of sesamol encapsulated, while the encapsulation yield was greater in all cases for micelles from solutions with lower caseinate concentration. The average size of micelles ranged from 150 to 165 nm with an average zeta potential of −27.3 ± 1.86 mV. FTIR and fluorescence analysis confirm interactions within the casein chains and sesamol molecules with a bathochromic shift which suggests a predominant hydrophilic nature of such interactions. Differential scanning calorimetry thermograms showed that denaturation enthalpy tended to decrease as sesamol concentration increased, suggesting that sesamol molecules may be displacing the water molecules associated with the casein chains, reinforcing the idea of predominant hydrophilic interactions. Based on the results from encapsulation efficiency, it is estimated that about 7 g of casein micelles reformed from 2% (w/v) caseinate solutions with 2 mg/mL of added sesamol may provide the recommended daily dose and may be useful for the development of new functional food products. Practical Applications The development of a nanodelivery system for different bioactives will allow the enrichment of foods and drinks to develop new functional products that will satisfy consumers’ demands. Additionally, the study of interactions between these molecules will allow us to understand how sesamol is being incorporated within the reformed micelles and how this process can even be improved.