Antioxidants in Oak (Quercus sp.): Potential Application to Reduce Oxidative Rancidity in Foods.

This review explores the antioxidant properties of oak (Quercus sp.) extracts and their potential application in preventing oxidative rancidity in food products. Oxidative rancidity negatively impacts food quality, causing changes in color, odor, and flavor and reducing the shelf life of products. The use of natural antioxidants from plant sources, such as oak extracts, has gained increasing interest due to potential health concerns associated with synthetic antioxidants. Oak extracts contain various antioxidant compounds, including phenolic acids, flavonoids, and tannins, which contribute to their antioxidative capacity. This review discusses the chemical composition of oak extracts, their antioxidative activity in different food systems, and the safety and potential challenges related to their application in food preservation. The potential benefits and limitations of using oak extracts as an alternative to synthetic antioxidants are highlighted, and future research directions to optimize their application and determine their safety for human consumption are suggested.

Lesser-Consumed Tropical Fruits and Their by-Products: Phytochemical Content and Their Antioxidant and Anti-Inflammatory Potential.

Açaí, lychee, mamey, passion fruit and jackfruit are some lesser-consumed tropical fruits due to their low commercial production. In 2018, approximately 6.8 million tons of these fruits were harvested, representing about 6.35% of the total world production of tropical fruits. The present work reviews the nutritional content, profile of bioactive compounds, antioxidant and anti-inflammatory capacity of these fruits and their by-products, and their ability to modulate oxidative stress due to the content of phenolic compounds, carotenoids and dietary fiber. Açaí pulp is an excellent source of anthocyanins (587 mg cyanidin-3-glucoside equivalents/100 g dry weight, dw), mamey pulp is rich in carotenoids (36.12 mg ß-carotene/100 g fresh weight, fw), passion fruit peel is rich in dietary fiber (61.16 g/100 dw). At the same time, jackfruit contains unique compounds such as moracin C, artocarpesin, norartocarpetin and oxyresveratrol. These molecules play an important role in the regulation of inflammation via activation of mitogen-activated protein kinases (including p38, ERK and JNK) and nuclear factor κB pathways. The properties of the bioactive compounds found in these fruits make them a good source for use as food ingredients for nutritional purposes or alternative therapies. Research is needed to confirm their health benefits that can increase their marketability, which can benefit the primary producers, processing industries (particularly smaller ones) and the final consumer, while an integral use of their by-products will allow their incorporation into the circular bioeconomy.

Propiedades bioactivas de frutas tropicales exóticas y sus beneficios a la salud / Bioactive properties of exotic tropical fruits and their health benefits

Las frutas exóticas se encuentran dentro del grupo de las frutas tropicales y su carácter perecedero limita su exportación a mercados distantes. En general, su consumo es local, son subutilizadas o poco valoradas tanto en el hogar como industrialmente; sin embargo, debido su alto valor nutricional, su consumo se ha incrementado significativamente en los últimos años. Estas frutas son fuente de compuestos bioactivos como fibra, vitamina C, carotenoides, ácidos fenólicos y polifenoles, los cuales han sido asociados a la reducción de los riesgos de enfermedades crónicas causadas por el estrés oxidativo. Estos compuestos bioactivos han demostrado que poseen varias actividades biológicas in vitro e in vivo incluyendo actividad antioxidante, antimicrobiana, antiinflamatoria, antiedad, neuroprotectora y antiviral entre otras. Por lo tanto, la obtención de ingredientes funcionales a partir de las frutas tropicales consideradas exóticas resulta viable; así como su utilización para el desarrollo de alimentos funcionales y nutracéuticos, para elaboración de productos de la industria farmacéutica y la conservación de alimentos. En la presente revisión se discute la información más relevante publicada en el período 2010-2020 de las principales bases de datos científicas, incluyendo Scopus, Science Direct, PubMed, Medline y Scielo, sobre los compuestos fenólicos y las bioactividades reportadas de las frutas tropicales exóticas como acai (Euterpe oleraceae), acerola (Malpighia emarginata), buruti (Mauritia flexuosa) caqui (Diospyros kaki), chicozapote (Manilkara zapota), litchi (Litchi chinensis), maracuyá (Passiflora edulis), noni (Morinda citrifolia) rambután (Nephelium lappaceum), pitaya blanca (Hylocereus undatus), pitaya roja (Hylocereus polyrhizus) y su relación con sus potenciales efectos benéficos en la salud(AU)

Exotic fruits are found in the group of tropical fruits and their perishable nature limits their export to distant markets. In general, their consumption is local; they are underutilized or little valued both at home and industrially; however, its consumption has increased significantly in recent years due to its high nutritional value. These fruits are a source of bioactive compounds such as fiber, vitamin C, carotenoids, phenolic acids and polyphenols, which have been associated with reducing the risks of chronic diseases caused by oxidative stress. These bioactive compounds have been shown to possess various in vitro and in vivo biological activities, including antioxidant, antimicrobial, antiviral, anti-inflammatory, anti-aging, neuroprotective, and among others. Therefore, obtaining functional ingredients from tropical fruits considered exotic is viable and used to develop functional and nutraceutical foods, prepare products for the pharmaceutical industry and food preservation. This review discusses the most relevant information published in the 2010-2020 period from the main scientific databases, including Scopus, Science Direct, PubMed, Medline and Scielo, on phenolic compounds and reported bioactivities of exotic tropical fruits such as acai (Euterpe oleraceae), acerola (Malpighia emarginata), persimmon (Diospyros kaki), chicozapote (Manilkara zapota), litchi (Litchi chinensis), passion fruit (Passiflora edulis) noni (Morinda citrifolia), rambutan (Nephelium lappaceum), white pitaya (Hylocereus undatus) and red pitaya (Hylocereus polyrhizus) and their relationship with their potential beneficial effects on health(AU)

Phase II-inducing, polyphenols content and antioxidant capacity of corn (Zea mays L.) from phenotypes of white, blue, red and purple colors processed into masa and tortillas.

White, blue, red and purple corns (Zea mays L.) were lime-cooked to obtain masa for tortillas. The total phenolics and anthocyanins content, antioxidant activity expressed as total reducing power (TRP), peroxyl radical bleaching (PRAC), total antioxidant activity (TAA) and quinone reductase (QR) induction in the murine hepatoma (Hepa 1 c1c7 cell line) as a biological marker for phase II detoxification enzymes were investigated. Among the extracts prepared from raw corn varieties the highest concentration of total phenolics, anthocyanins, antioxidant index and induction of QR-inducing activity were found in the Veracruz 42 (Ver 42) genotype. The nixtamalization process (masa) reduced total phenolics, anthocyanins and antioxidant activities and the ability for QR induction when was compared to raw grain. Processing masa into tortillas also negatively affected total phenolics, anthocyanin concentration, antioxidant activities, and QR induction in the colored corn varieties. The blue variety and its corresponding masa and tortillas did not induce QR. Ver 42 genotype and their products (masa and tortilla) showed the greatest antioxidant activity and capacity to induce QR.