2025, Dziedzic, Krzysztof, Ariyarathna, Pathumi, Szwengiel, Artur, Hęś, Marzanna, Ratajczak, Karolina, Górecka, Danuta, Sulewska, Hanna, Walkowiak, Jarosław

Background: Tartary buckwheat is a plant recognized for its resistance to various environmental stresses. Due to its valuable source of phenolic compounds, Fagopyrum tataricum is also characterized as a medicinal plant; therefore, the aim of this study was to investigate the drought stress for the levels of phenolic compounds in the morphological parts of the plant. Methods: This experiment was conducted in 7 L pots under laboratory conditions. Phenolic compounds were identified using a UHPLC–MS chromatography system. Antioxidant activity was assessed using well-known methods, including the DPPH scavenging activity and ferrous ion chelating activity. Results: In Tartary buckwheat leaves, stems, seeds, and husks, 57 phenolic compounds were identified, with a predominance of quercetin 3-rutinoside, quercetin, kaempferol-3-rutinoside, kaempferol, and derivatives of coumaric acid. It was observed that the Tartary buckwheat samples subjected to drought stress exhibited a slight decrease in the majority of individual phenolic compounds. Conclusions: The measurement of biological parameters indicated that plant regeneration after drought stress demonstrated a rapid recovery, which can be a positive response to the progression of climate changes.

2025, Ariyarathna, Pathumi, Mizera, Patryk, Walkowiak, Jarosław, Dziedzic, Krzysztof

The growing global prevalence of non-communicable diseases (NCDs) is drawing an increasing amount of attention to the health-promoting potential of whole-grain dietary fibers. Whole grains are rich sources of both soluble dietary fiber (SDF) and insoluble dietary fiber (IDF), contributing distinct physicochemical properties and playing vital roles in promoting human health. This review provides a comprehensive analysis of the dietary fiber compositions of various whole grains, including wheat, oats, barley, rye, corn, sorghum, and rice, highlighting their structural characteristics, physiochemical properties, and associated health benefits. The physicochemical properties of dietary fibers, such as solubility, water- and oil-holding capacity, viscosity, swelling ability, and bile-acid-binding capacity, contribute significantly to their technological applications and potential health benefits, particularly in the prevention of NCDs. Although there is growing evidence supporting their health benefits, global whole-grain intake remains below recommended levels. Therefore, promoting whole-grain intake and developing fiber-rich functional foods are essential for enhancing public health and preventing chronic diseases. Future research should focus on enhancing the bioavailability and functionality of whole-grain dietary fibers, optimizing the methods by which they are extracted, and exploring their potential applications in the food and pharmaceutical industries.