Food Antioxidants and Aging: Theory, Current Evidence and Perspectives

The concept of food and aging is of great concern to humans. So far, more than 300 theories of aging have been suggested, and approaches based on these principles have been investigated. It has been reported that antioxidants in foods might play a role in human aging. To clarify the current recognition and positioning of the relationship between these food antioxidants and aging, this review is presented in the following order: (1) aging theories, (2) food and aging, and (3) individual food antioxidants and aging. Clarifying the significance of food antioxidants in the field of aging will lead to the development of strategies to achieve healthy human aging

Current Use of Fenton Reaction in Drugs and Food

Iron is the most abundant mineral in the human body and plays essential roles in sustaining life, such as the transport of oxygen to systemic organs. The Fenton reaction is the reaction between iron and hydrogen peroxide, generating hydroxyl radical, which is highly reactive and highly toxic to living cells. “Ferroptosis”, a programmed cell death in which the Fenton reaction is closely involved, has recently received much attention. Furthermore, various applications of the Fenton reaction have been reported in the medical and nutritional fields, such as cancer treatment or sterilization. Here, this review summarizes the recent growing interest in the usefulness of iron and its biological relevance through basic and practical information of the Fenton reaction and recent reports

Microgreens—A Comprehensive Review of Bioactive Molecules and Health Benefits

Microgreens, a hypothesized term used for the emerging food product that is developed from various commercial food crops, such as vegetables, grains, and herbs, consist of developed cotyledons along with partially expanded true leaves. These immature plants are harvested between 7–21 days (depending on variety). They are treasured for their densely packed nutrients, concentrated flavors, immaculate and tender texture as well as for their vibrant colors. In recent years, microgreens are on demand from high-end restaurant chefs and nutritional researchers due to their potent flavors, appealing sensory qualities, functionality, abundance in vitamins, minerals, and other bioactive compounds, such as ascorbic acid, tocopherol, carotenoids, folate, tocotrienols, phylloquinones, anthocyanins, glucosinolates, etc. These qualities attracted research attention for use in the field of human health and nutrition. Increasing public concern regarding health has prompted humans to turn to microgreens which show potential in the prevention of malnutrition, inflammation, and other chronic ailments. This article focuses on the applications of microgreens in the prevention of the non-communicable diseases that prevails in the current generation, which emerged due to sedentary lifestyles, thus laying a theoretical foundation for the people creating awareness to switch to the recently introduced category of vegetable and providing great value for the development of health-promoting diets with microgreens

Theaflavins inhibit glucose transport across Caco-2 cells through the downregulation of the Ca^<2+>/AMP-activated protein kinase-mediated glucose transporter SGLT1

The study investigated the effects of theaflavins, which are intestinally non-absorbable compounds, on intestinal glucose transport in Caco-2 cells. ^C_6-Glucose transport experiments clearly revealed that glucose transport across Caco-2 cells was significantly (p -release and CaMKK β. These findings demonstrated for the first time that theaflavins can inhibit glucose transport across Caco-2 cell monolayers through the suppression of SGLT1 expression partly via the activation of the intracellular Ca^/CaMKK β/AMPK signaling pathway.Highlights / •Theaflavins exhibit anti-hyperglycemic potential via inhibition of glucose transport in Caco-2 cells. / •Theaflavins suppress sodium-dependent glucose transporter 1, but not glucose transporter 2 expression. / •Upregulated Ca2+/CaMKK β/AMPK signaling pathway is involved in the inhibition of glucose transport