3 research outputs found
Effect of fermentation on content, molecule weight distribution and viscosity of Ī²-glucans in oat sourdough
This study investigated the effect of fermentation on the physicochemical properties of Ī²-glucans in oat sourdough. Sourdoughs were produced from oat using homo-fermentative lactic acid bacteria, Lactobacillus plantarum 22134. The contents of total Ī²-glucan and soluble Ī²-glucan, the molecular weight (MW) of Ī²-glucan and the viscosity of the extracted Ī²-glucans were determined at 0, 4, 8, 10 and 12 h of fermentation. The total Ī²-glucan content decreased from 4.89% to 4.23% after 12 h of fermentation. The soluble Ī²-glucan concentration increased from 1.89% to 2.18% and then decreased to 1.97% after 8 h of fermentation. The content of Ī²-glucans with MW > 105 decreased from 0 to 4 h of fermentation, followed by an increase and then a decrease after 8 h. The oat sourdough fermented for 8 h had high viscosity, which could be more beneficial for health and bread texture quality, especially for gluten-free breads. International Journal of Food Science and Technology</p
The Physiological Mechanism of Melatonin Enhancing the Tolerance of Oat Seedlings under SalineāAlkali Stress
Exogenous melatonin (MT) regulates plant growth and mitigates stress in response to stress. To analyze the machinery of exogenous melatonin, which improves salt and alkaline tolerance in oats, MTās function was identified in the oat seed germination stage in our previous study. In this study, morphogenesis, photosynthetic physiology, hormone levels, and ion homeostasis were evaluated using the same MT treatment concentration. The results revealed that compared to the S45 treatment, the 100 Ī¼molĀ·Lā1 MT treatment efficiently increased the seedling height and main root length of oat seedlings; promoted secondary root development; enhanced the root volume and root surface area; maintained a higher photosynthetic pigment content (carotenoids; chlorophyll a; chlorophyll b); raised the leaf photosynthetic rate (Pn), intercellular CO2 concentration (Ci), conductance to H2O (Gs), and transpiration rate (Tr); enhanced the light energy absorption and conversion of leaves; increased the leaf GA3, Tryptamine (TAM), and IAA contents; and decreased ABA levels. Hierarchical cluster analysis revealed that MT treatment also increased the contents of P, K, Ca, Mn, Cu, Mg, Fe, Zn, Mo, Cd, Al, Se, Ni, Co, and Ti; decreased the Na/K ratio; and maintained cellular ionic homeostasis in oat seedlings under salineāalkali stress, as compared with the untreated group. These findings showed that MT treatment enhanced the adaptation of oat to salineāalkali stress through regulating the physiological process of seedling growth. This suggests that MT plays a different role in improving salineāalkali tolerance in the germination and seedling stages of oat