Rheological properties of mixed oleogels: lecithin, sucrose ester, and monoacylglycerol interactions toward high-oleic sunflower oil structuring

Ana Nathália Fernandez da  Cruz; Maria Aliciane Fontenele  Domingues; Gustavo das Graças Pereira; Kivia Mislaine  Albano

doi:10.4025/actascitechnol.v48i1.74063

Autores

Ana Nathália Fernandez da Cruz Universidade Federal de São Carlos https://orcid.org/0009-0009-3000-5543
Maria Aliciane Fontenele Domingues Universidade Federal de São Carlos https://orcid.org/0000-0002-1944-7895
Gustavo das Graças Pereira Universidade Federal de São Carlos https://orcid.org/0000-0003-2672-2565
Kivia Mislaine Albano Universidade Federal de São Carlos https://orcid.org/0000-0003-2298-3880

DOI:

https://doi.org/10.4025/actascitechnol.v48i1.74063

Palavras-chave:

lipid structurants; ternary interactions; binary interactions; mechanical properties; viscosity; thixotropy of oleogel

Resumo

This study aimed to understand how oleogels are formed from a combination of monoacylglycerol (MAG), soy lecithin (SL), and sucrose fatty ester (SE) in high-oleic sunflower oil (HOSO). In this study, thirteen tests were conducted with binary (no SL) and ternary (SE + SL + MAG) mixture designs. To create the oleogels, the HOSO was heated to 70°C, and the structuring agents were added until completely melted. The samples were then kept at 5°C for 24 hours in a controlled environment to structure and stabilize the gel network. Afterward, the temperature was raised to 25°C for another 24 hours. The mechanical properties were analyzed using the backward extrusion method. Flow curves were obtained from ramps downward and upward at 25°C. Gap assessment, apparent viscosity curves, and thixotropic area assessment were also obtained. The results indicated that lecithin had a significant influence on the mechanical properties of oleogels in ternary interactions. All samples showed similar behavior: at high shear rates on the downward ramp, they were more structured, but with continued shear, they had Newtonian behavior. On the upward ramp, they had pseudoplastic behavior and thixotropy, as evidenced by the apparent viscosity curves, indicating a change in structure due to the alignment of the long chains of macromolecules decreasing resistance to flow. In conclusion, samples with higher SE contents in ternary interactions resulted in more structured materials, minimizing changes in apparent viscosity, with the most structured sample having intermediate SL values.

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Rheological properties of mixed oleogels: lecithin, sucrose ester, and monoacylglycerol interactions toward high-oleic sunflower oil structuring

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