Yasuko Fukuda

Bio: Yasuko Fukuda is an academic researcher. The author has contributed to research in topics: Sesamolin & Sesamin. The author has an hindex of 12, co-authored 23 publications receiving 968 citations.

Contribution of lignan analogues to antioxidative activity of refined unroasted sesame seed oil

Abstract: A lignan compound, P3, having strong antioxidative activity was found to be formed in high concentration during the industrial bleaching process of unroasted sesame seed oil. P3 (named sesaminol) was identical to a minor constituent previously isolated from acetone extract of sesame seed. It was shown that sesamolin in unprocessed sesame oil is the source of seaseminol, and the formation of seasaminol was confirmed by the model experiment with corn oil to which sesamolin had been added. Sesaminol was not so greatly removed by the deodorization process that follows bleaching as was sesamol, and it was shown to be at a concentration of ca. 100 mg/100g in commercial refined unroasted seed oil. The antioxidative activity of sesaminol was foughly equal to those of sesamol and γ-tocopherol by the thiocyanate method. Therefore, it seems that the antionxidative activity of refined unroasted seed oil is mainly attributed to sesaminol.

Studies on Antioxidative Substances in Sesame Seed

Abstract: Our previous study revealed the presence of some potent antioxidative components other than γ-tocopherol and sesamol in sesame seed and oil. In the present study, the effective components were extracted from mashed sesame seed with acetone, followed by removal of triglycerides by freezing. The acetone extract showed strong antioxidative activity with the thiocyanate method and gave 4 active antioxidative substances after a series of chromatographic separations. The molecular formulae were determined to be C20H20O6 (P1), C20H20O7 (P2), C20H18O7 (P3) and C10H10O4 (P4). Compounds P1 and P4 were respectively identified as a bisepoxylignan analogue and trans-ferulic acid. Though preliminary structural data for P2 and P3 indicate them to be a sesamolin analogue and a sesamin analogue, respectively, work is currently underway to confirm this. The antioxidative activities were in the order of P3 >P2>P1 >P4. The same components were also obtained from the 80% ethanol extractable polar fraction of the sesame oil ca...

Chemical Aspects of the Antioxidative Activity of Roasted Sesame Seed Oil, and the Effect of Using the Oil for Frying

Abstract: Antioxidative constituents in roasted sesame seed oil were studied mainly by an antioxidative assay and HPLC analysis, in comparison with unroasted sesame seed oil. The main active constituent in fresh roasted seed oil was γ-tocopherol, but after heating at frying temperature for 1 ~ 2 hr, this was identified as sesamol, which was produced by hydrolysis of sesamolin that is present to a large degree in roasted sesame seed oil. This conversion of sesamolin to sesamol is catalyzed by acids.

Oil and minor components of sesame (Sesamum indicum L.) strains

Abstract: Oil and mior components of sesamin and sesamolin were studied in 42 strains ofSesamum indicum L. The oil contents of the seed ranged from 43.4 to 58.8% and varied inversely with the percentage of hull (r=−0.804, significant at the 1% level). The hull percentage was used as a criterion to predict oil content. The percentage of sesamin in the oil ranged from 0.07 to 0.61% and that of sesamolin from 0.02 to 0.48%. There was a significant positive correlation between the oil content of the seed and the sesamin content of the oil (r=0.608, significant at the 1% level); no correlation was found between the oil and sesamolin contents.

Mechanisms and Factors for Edible Oil Oxidation

Abstract: : Edible oil is oxidized during processing and storage via autoxidation and photosensitized oxidation, in which triplet oxygen (3O2) and singlet oxygen (1O2) react with the oil, respectively. Autoxidation of oils requires radical forms of acylglycerols, whereas photosensitized oxidation does not require lipid radicals since 1O2 reacts directly with double bonds. Lipid hydroperoxides formed by 3O2 are conjugated dienes, whereas 1O2 produces both conjugated and nonconjugated dienes. The hydroperoxides are decomposed to produce off-flavor compounds and the oil quality decreases. Autoxidation of oil is accelerated by the presence of free fatty acids, mono- and diacylglycerols, metals such as iron, and thermally oxidized compounds. Chlorophylls and phenolic compounds decrease the autoxidation of oil in the dark, and carotenoids, tocopherols, and phospholipids demonstrate both antioxidant and prooxidant activity depending on the oil system. In photosensitized oxidation chlorophyll acts as a photosensitizer for the formation of 1O2; however, carotenoids and tocopherols decrease the oxidation through 1O2 quenching. Temperature, light, oxygen concentration, oil processing, and fatty acid composition also affect the oxidative stability of edible oil.

Phenolics in food and nutraceuticals

Abstract: Phenolics in Food and Nutraceuticals is the first single-source compendium of essential information concerning food phenolics. This unique book reports the classification and nomenclature of phenolics, their occurrence in food and nutraceuticals, chemistry and applications, and nutritional and health effects. In addition, it describes antioxidant activity of phenolics in food and nutraceuticals as well as methods for analysis and quantification. Each chapter concludes with an extensive bibliography for further reading. Food scientists, nutritionists, chemists, biochemists, and health professionals will find this book valuable.

Antioxidants/antimutagens in food.

Abstract: Oxygen is indispensable for aerobic organisms including, of course, human beings, but it is believed that oxygen also may be responsible for undesired phenomena. In particular, oxygen species such as hydrogen peroxide, superoxide radical anion, and singlet oxygen are proposed as agents attacking polyunsaturated fatty acids in cell membranes, giving rise to lipid peroxidation. Several reports have suggested that lipid peroxidation may result in destabilization and disintegration of cell membranes, leading to liver injury and other diseases, and finally, to aging and susceptibility to cancer (4).

Handbook of Herbs and Spices

Abstract: Herbs, spices and their active components as natural antimicrobials in foods Effect of natural antioxidants in herbs and spices on shelf life of foods Ajowan Aniseed Asafoetida Allspice Capers and caperberries Caraway Celery Chervil Fennel and fennel seed Galangal Kaffir lime leaf Lavender Lemongrass Lovage Nigella Oregano Poppy Sesame Star anise Tarragon Tamarind Other significant herbs and spices.