Recent developments in encapsulation of α-lipoic acid for enhanced bioavailability and stability

In the present study, the oxidative stability and antioxidant activity of seed oils were investigated in three Iranian pomegranate cultivars, Shirin Khafr, Torsh Sabz, and Rabab, along with the sesame (Sesamum indicume L. cv Dezful) seed oil. Punicic acid was the primary fatty acid in the pomegranate seed oils, with contents ranging from 75.5 to 80.9% (w/w). The tocopherol levels in pomegranate seed oils ranged from 1439 to 2053 mg/kg, whereas the phenolics ranged from 130 to 199.3 mg/kg, respectively. Comparatively, in the seed oil of sesame “Dezful,” these substances' contents were 1053 and 79 mg/kg, respectively. Contrary to common perception, the seed oil of the three pomegranate cultivars cultivated in Iran had high oxidative stability and antioxidative activity during the 32 h of thermal processing at 170°C. The oxidation stability assayed by peroxide value, p‐anisidine value, and TOTOX index revealed that the pomegranate seed oils had a much higher resistance to the oxidation process than the sesame oil. The content of tocopherols increased during thermal processing due to the regeneration phenomenon. Tocopherols are not always free and may form a matrix with themselves or other compounds. Changes in the antioxidant activity during the thermal processing assessed by DPPH free radical scavenging power and by the FRAP test were consistent with those for the antioxidants. Therefore, these oils can be added to other edible oils as a natural antioxidant to improve their oxidative stability.

Section: Introductionmentioning

confidence: 99%

Thermal processing of pomegranate seed oils underscores their antioxidant stability and nutritional value: Comparison of pomegranate seed oil with sesame seed oil

Tavakoli,

Ghorbani,

Hematian Sourki

et al. 2024

“…The effects of different carriers on the physicochemical properties of powders obtained from protein hydrolysates have been investigated in various studies (Nurhadi et al., 2022 ; Qadri et al., 2022 / Choudhary et al., 2023 ). For example, the physicochemical stability and shelf life of microcapsules increased with spray‐drying of buffalo WPC‐hydrolysates with a blend of gum arabic‐maltodextrin carriers in a ratio of 70:30 compared to free hydrolysate; it also improved the techno‐functional parameters of the resulting microcapsule powders (Giroldi et al., 2022 ).…”

Section: Introductionmentioning

confidence: 99%

Incorporation of spray‐dried encapsulated bioactive peptides from coconut (Cocos nucifera L.) meal by‐product in bread formulation

Sarabandi,

Dashipour,

Akbarbaglu

et al. 2024

This study aimed to stabilize and mask the bitterness of peptides obtained from the enzymatic hydrolysis of coconut‐meal protein with maltodextrin (MD) and maltodextrin‐pectin (MD‐P) as carriers via spray‐drying. Essential (~35%), hydrophobic (~32%), antioxidant (~15%), and bitter (~45%) amino acids comprised a significant fraction of the peptide composition (with a degree of hydrolysis of 33%). The results indicated that the peptide's production efficiency, physical and functional properties, and hygroscopicity improved after spray‐drying. Morphological features of free peptides (fragile and porous structures), spray‐dried with MD (wrinkled with indented structures), and MD‐P combination (relatively spherical particles with smooth surfaces) were influenced by the process type and feed composition. Adding free and microencapsulated peptides to the bread formula (2% W/W) caused changes in moisture content (35%–43%), water activity (0.89–0.94), textural properties (1–1.6 N), specific volume (5.5–6 cm3/g), porosity (18%–27%), and color indices of the fortified product. MD‐P encapsulated peptides in bread fortification resulted in thermal stability and increased antioxidant activity (DPPH and ABTS+ radical scavenging: 4.5%–39.4% and 31.6%–46.8%, respectively). MD‐P (as a carrier) could maintain sensory characteristics and mask the bitterness of peptides in the fortified bread. The results of this research can be used to produce functional food and diet formulations.

“…The oxidation of oils and fats is one of the greatest challenges that can lead to food spoilage and generate unpleasant smells, tastes, and inappropriate colors while reducing the nutritional value and undermining consumption safety (Azizi et al, 2021 ; Chailangka et al, 2023 ; Lee et al, 2021 ; Ugarte‐Espinoza et al, 2021 ). Oxidation products, such as hydroperoxides, hydroxyl radicals, and monovalent oxygen are harmful to human health and cause damage to biological cells (Amiri et al, 2021 ; Choudhary et al, 2023 ; Gonzalles et al, 2021 ). In turn, the damage to biological cells causes cardiovascular and neurological complications and diseases related to premature aging (Iqbal & Bhanger, 2007 ; Mohdaly et al, 2010 ).…”

Section: Introductionmentioning

confidence: 99%

Enhancing canola oil's shelf life with nano‐encapsulated Mentha aquatica extract for optimal antioxidant performance

Tavakoli,

Abbasi,

Gashtasebi

et al. 2023

Incorporation of antioxidants, such as phenolic compounds into edible oils has limitations such as rapid release of phenolic compounds, low solubility, low penetration, low accessibility, and rapid degradation by environmental compounds. To solve this problem, the nano‐encapsulation process is offering promising opportunities. In this research, for the first time, the phenolic extract of Mentha aquatica was nano‐encapsulated in nano‐emulsions coated with chitosan, Lepidium perfoliatum gum (LPG), and complex of chitosan and LPG (CCL) (1:1 ratio). Based on various tests (particle size measurement, ζ‐potential, polydispersity index, encapsulation efficiency index, and intensity curve), the LPG coating was the most optimum option for nano‐encapsulation compared to the other coatings. Thus, the LPG‐assisted nano‐encapsulated phenolic extract of M. aquatica was used to improve the oxidative stability of canola oil at three concentrations (100, 200, and 300 ppm). The results of peroxide value and anisidine index tests (as initial and secondary oxidation indicators, respectively) showed that the nano‐encapsulation improved the antioxidant effect of M. aquatica when compared with free extract in canola oil. In a comparative approach, the best sample was obtained from the LPG‐assisted nano‐encapsulated extract (200 ppm) due to the release of more phenolic compounds. The findings from this study showcase how nano‐encapsulation enhances the efficacy of antioxidants in edible oils.