Effects of enzyme-assisted extraction on the profile and bioaccessibility of isoflavones from soybean flour

Green and chemical-free pretreatment of flavonoids in tea plant seed husk using ultrasound-cold isostatic pressure synergistic extraction

A new method was established to extract flavonoids from tea plant seed husk: ultrasonic-cold isostatic pressure synergistic extraction. The effects of pressure, ethanol concentration, tea plant seed husk addition and treatment time on the extraction of flavonoids were investigated. The optimal extraction process was determined as follows: applied pressure 468.440 MPa, 31.169 g of tea plant seed husk, ethanol concentration 69.067 %, and processing time 10.916 min. Characterization experiments demonstrated that ultrasonic synergistic cold isostatic pressure extraction could effectively destroy the plant structure and promote the efflux of active ingredients. Then, the flavonoid extracts were analyzed qualitatively and quantitatively by LC-MS/MS, and three flavonoids were identified and found to be higher in the ultrasonic-cold isostatic pressure synergistic extraction group. Finally, the antioxidant, anti-inflammatory and bacteriostatic tests revealed that the activity of the extract was higher in the ultrasonic-cold isostatic pressure synergistic extraction group and did not destroy the activity of extraction.

An overview on the potential application of nanotechnology in enhancing the therapeutic efficacy of phytoestrogens

Phytoestrogens, derived from plants possesses structural similarity with 17 β-estradiol found in mammals. It is abundantly present in soybean along with red clove, alfalfa as well as other legumes, nuts, vegetables and seeds. It is used as hormone replacement therapy and exhibits both anti-estrogenic and estrogenic properties that linked to therapeutic benefits as well as plays active role in sports nutrition. Despite the potential benefits of phytoestrogens, their low solubility, bioavailability, and stability make it challenging to target them effectively. Recent advancements in nanotechnology have paved in facilitating target delivery. Scaling at nano level offered greater surface area, improved solubility, and bioavailability of phytoestrogens which has ultimately reduced the required medication dosage, and enhanced cost-effectiveness, particularly for expensive bioactive substances where precise dosages are recommended. The present article discussed about the potential application of nanotechnology in enhancing therapeutic benefits of phytoestrogens while minimizing their potential side effects.

Methods of Analysis of Phytoestrogenic Compounds: An Up-to-Date of the Present State

Phytoestrogens, natural compounds with structural similarity to 17-β-estradiol, are known to have potential health benefits, including in hormone-dependent malignancies. The therapeutic interest and some safety concerns observed triggered the need to develop accurate methods to assess their level in different matrices. This narrative review examines the existing analytical methods used to isolate, quantify, and characterize phytoestrogens and their metabolites in plants, foods, and biological samples. Different conventional and modern extraction techniques, such as ultrasonication-assisted extraction, supercritical fluid extraction, or enzyme-assisted extraction, were presented and compared. The advantages and limitations of the existing analytical methods, such as high-performance liquid chromatography using different sensitive detectors, gas chromatography often coupled with mass spectrometry, and immunoassay methods, are highlighted, along with the need for ongoing research to improve the sensitivity and selectivity of the analysis.

Bioaccessibility Evaluation of Soymilk Isoflavones with Biotransformation Processing

Soy isoflavones are considered important sources of bioactive compounds, but they are poorly absorbable, due to their large hydrophilic structures. Some biotransformation strategies have been used to convert the glycosidic form into aglycones, making them available for absorption. This study evaluated the potential of enzymatic and/or microbial fermentation combined bioprocesses in a soymilk extract before and after gastrointestinal in vitro digestion. Commercial β-glucosidase (ET) and a mix of commercial probiotics (F) containing Lactobacillus acidophilus, Lactobacillus casei, Lactococcus lactis, Bifidobacterium bifidum, and Bifidobacterium lactis were used to biotransform the soymilk phenolic extract. An isoflavone profile was identified using HPLC-DAD, total phenolic content was identified using the Folin-Ciocalteu test, and antioxidant capacity was identified using ORAC and FRAP. Soymilk enzymatically treated (ET) followed by microbial fermentation (ET + T) resulted in better conversion of glycosylated isoflavones (6-fold lower than control for daidzin and 2-fold for genistin) to aglycones (18-fold greater than control for dadzein and genistein). The total phenolic content was increased (3.48 mg/mL for control and 4.48 mg/mL for ET + T) and the antioxidant capacity was improved with treatments of ET + T (120 mg/mL for control and 151 mg/mL with ORAC) and with FRAP (285 µL/mL for control and 317 µL/mL). After the in vitro digestion, ET + T samples resulted in a higher content of genistein (two-fold higher than control); also, increases in the total phenolic content (2.81 mg/mL for control and 4.03 mg/mL for ET + T) and antioxidant capacity measured with ORAC were greater compared to undigested samples. In addition, the isolated microbial fermentation process also resulted in positive effects, but the combination of both treatments presented a synergistic effect on soy-based products.

Biscuits Prepared with Enzymatically-Processed Soybean Meal Are Rich in Isoflavone Aglycones, Sensorially Well-Accepted and Stable during Storage for Six Months

Soybean meal (SBM) is a co-product of the soybean oil industry that is rich in bioactive compounds, such as isoflavones. We aimed to study the effects of processing SBM by fermentation (Saccharomyces cerevisiae) (FSBM) and enzymatic hydrolysis (CelluMax C, a commercial cellulase) (ESBM) on its chemical composition, with emphasis on isoflavones. Fermentation increased protein content by 9%, ash content by 7%, dietary fiber by 11% and minerals by up to 38%, except for iron, which decreased by 26%. Fermentation completely removed oligosaccharides from SBM, while enzymatic processing decreased oligosaccharides by 45% in SBM. Both processes converted glycosylated isoflavones into the corresponding aglycones, the content of which increased by up to 7.7-fold. Biscuits containing SBM, FSBM and ESBM could be labeled as dietary sources of dietary fibers, potassium, phosphorous, calcium and zinc, as well as high in proteins, copper, iron, manganese and magnesium. While FSBM biscuits had lower sensory scores compared to SBM biscuits, ESBM biscuits had equivalent scores. During storage for 180 days at room temperature, the isoflavone profile of all biscuits remained stable. Moreover, storage did not impair microbiological and sensory qualities of any biscuits. Altogether, ESBM biscuits show great marketing potential.

From a Single-Stage to a Two-Stage Countercurrent Extraction of Lipids and Proteins from Full-Fat Chickpea Flour: Maximizing Process Extractability and Economic Feasibility

The mainstream adoption of chickpea proteins and lipids requires a thorough understanding of the impact of critical extraction parameters (enzyme use, reaction time, and solids-to-liquid ratio—SLR) and modes of extraction (single-stage extraction—SSE and countercurrent extraction—CCE) on the simultaneous extraction of lipids and proteins from full-fat chickpea flour and economic process feasibility. A kinetics study revealed that 68.5% oil and 87% protein extraction yields can be achieved using 0.5% protease at pH 9.0, 50 °C, 60 min, and 1:10 SLR, highlighting the role of proteolysis and an adequate incubation time on overall extractability. An increased gradient concentration between the matrix and aqueous media solutes at a lower SLR (1:15), and reduced slurry viscosity increased oil and protein extractability to 80 and 91%, respectively. The high-water usage in the SSE was addressed by the development of a two-stage CCE that reduced water usage by 47% while increasing oil and protein extractability to ~96%. Higher extractability and reduced water usage in the two-stage CCE resulted in a higher net gross profit, thus outweighing its higher operating costs. The results presented herein further widen the scope of bioprocessing standards for full-fat chickpea flour and add to the elucidation of the impact of key processing conditions on the extractability and economic feasibility of the production of chickpea ingredients for subsequent food/nutraceutical applications.