Chemical diversity of secondary metabolites provides a considerable variety of pharmacological actions with a significant extension due to their combinations in plant extracts. Production of plant‐derived medicinal products in cell cultures has advantages because of the efficient use of different biotic and abiotic elicitors and better control of the developmental processes. Using PASS software, we predicted biological activity spectra for phytoconstituents identified in cell cultures of Panax japonicus (12 molecules), Tribulus terrestris (4 molecules), and Dioscorea deltoidea (3 molecules). Mechanisms of action associated with the antihypoxic effect were predicted for the majority of molecules. PharmaExpert software allowed analyzing possible synergistic or additive effects of the combinations of phytoconstituents associated with the antihypoxic action. Experimental studies of the antihypoxic effect of the plants′ extracts in water and ethanol have been performed in 3 animal models: Acute asphyctic hypoxia (AAH), Acute haemic hypoxia (AHeH), and Acute histotoxic hypoxia (AHtH). Effects of Panax japonicus and Tribulus terrestris preparations exceeded the activity of the reference drug Mexidol in the AHtH model. In the AHeH model, all preparations demonstrated moderate activity; the most potent has been observed for Dioscorea deltoidea. Thus, we found that experimental studies in animal models have confirmed the in silico prediction.
Background: Polyherbal mixtures called “medical species” are part of traditional and officinal medicine in Russia. This review aimed to analyze medical species used in Russia for the treatment of diabetes and related disorders. The information relevant to medical species, diabetes, and obesity was collected from local libraries, the online service E-library.ru, and Google Scholar. The prediction of the antidiabetic activity for the principal compounds identified in plants was performed using the free web resource PASS Online.Results: We collected and analyzed information about the compositions, specificities of use, and posology of 227 medical species. The medical species represent mixtures of 2–15 plants, while the most frequently mentioned in the literature are species comprising 3–6 plants. The top 10 plants among the 158 mentioned in the literature include Vaccinium myrtillus L., Phaseolus vulgaris L., Taraxacum campylodes G.E. Haglund., Urtica dioica L., Rosa spp., Hypericum spp., Galega officinalis L., Mentha × piperita L., Arctium spp, and Fragaria vesca L. The leading binary combination found in medical species comprises the leaves of V. myrtillus and pericarp of P. vulgaris; leaves of V. myrtillus and leaves of U. dioica; and leaves of V. myrtillus and aerial parts of G. officinalis. In triple combinations, in addition to the above-mentioned components, the roots of T. campylodes are often used. These combinations can be regarded as basic mixtures. Other plants are added to improve the efficacy, treat associated disorders, improve gastrointestinal function, prevent allergic reactions, etc. Meanwhile, an increase in plants in the mixture necessitates advanced techniques for quality control. A feature of medical species in Russia is the addition of fresh juices, birch sap, seaweeds, and adaptogenic plants. Modern studies of the mechanisms of action and predicted activities of the principal compounds from medicinal plants support the rationality of polyherbal mixtures. Nevertheless, the mechanisms are not well studied and reported due to the limited number of compounds. Further investigations with calculations of synergistic or additive indices are important for strengthening the scientific fundamentals for the wider use of medical species in the therapy of diabetes. Two medical species, “Arfazetin” (7 medicinal plants) and “Myrphasinum” (12 medicinal plants), are approved for use in officinal medicine. The efficacy of these species was confirmed in several in vivo experiments and clinical trials. According to modern regulatory rules, additional experiments and clinical trials are required for more detailed investigations of the mechanisms of action and confirmation of efficacy.Conclusion: We believe that the scientifically based utilization of rich plant resources and knowledge of Russian herbal medicine can significantly contribute to the local economy as well as to the sectors seeking natural healing products.
In the present study, we explored the therapeutic potential of bioreactor-grown cell cultures of the medicinal plant species Dioscorea deltoidea, Tribulus terrestris and Panax japonicus to treat carbohydrate metabolism disorders (CMDs) in laboratory rats. In the adrenaline model of hyperglycemia, aqueous suspensions of cell biomass pre-administered at a dose of 100 mg dry biomass/kg significantly reduced glucose level in animal blood 1–2.5 h (D. deltoidea and T. terrestris) or 1 h (P. japonicus) after adrenaline hydrochloride administration. In a streptozotocin-induced model of type 2 diabetes mellitus, the cell biomass of D. deltoidea and T. terrestris acted towards normalization of carbohydrate and lipid metabolism, as evidenced by a significant reduction of daily diuresis (by 39–57%), blood-glucose level (by 46–51%), blood content in urine (by 78–80%) and total cholesterol (25–36%) compared to animals without treatment. Bioactive secondary metabolites identified in the cell cultures and potentially responsible for their actions were deltoside, 25(S)-protodioscin and protodioscin in D. deltoidea; furostanol-type steroidal glycosides and quinic acid derivatives in T. terrestris; and ginsenosides and malonyl-ginsenosides in P. japonicus. These results evidenced for high potential of bioreactor-grown cell suspensions of these species for prevention and treatment of CMD, which requires further investigation.
Introduction. Today, innovative technologies are widely used in pharmacology (in particular, in the production of herbal preparations), in cosmetology (obtaining various extracts and oils, complex preparations), as well as in the food industry (as natural dyes, etc.). Plant extracts with a high level of risk do not have a harmful effect on the human body, except that they provide environmental safety, which creates a special interest for the pharmaceutical industry . vibrocavitation and supercritical fluid CO2 extraction.Aim. The choice of the optimal level of extraction to obtain a high level of fenugreek seeds.Materials and methods. Obtaining a vibrocavitation extract with an experimental vibration-explosive installation made at the Department of Processes and Apparatus of the St. Petersburg State Technology Institute. Extracts at a temperature of 60±2 ºС. The frequency of revolutions of the homogenizer ranged from 1000 to 5000 rpm. Ultrasonic impact using ultrasound unit I100-6/4 Ultrasonic effect on solid plant material with an intensity of 22 kHz for 60 minutes. The time of extraction in a vibro-cavitation extractor-homogenizer was studied for optimal values.Supercritical fluid CO2-extraction is obtained in two versions with the use of extragent (96% ethanol in the presence of carbon dioxide: ethanol 9:1) and without it. Extraction of the sound of a supercritical fluid extraction system with a 1-liter vessel. SFE1000-2-BASE with a kit for upgrading the SFE1000-2-BASE system to an SFE1000M1-2-FMC50 system (Waters, USA). The flow rate of the extractant was 60 g/min. Emergency listening for one hour and pressure 200, 300 and 400 bar. Extraction is observed three times. The obtained extracts indicate the amount of extractive substances according to article of Russian state pharmacopoeia 1.5.3.0006.15 «Determination of the content of extractive substances in plant raw materials and medicinal plant preparations». Quantitative determination of the saponin complex of parasitic seed seeds on an Agilent QTOF-6530 chromatograph with two ESI and APCI ionization sources according to Gravel et al.Results and discussion. Studies have allowed to determine the amount of extractives in the seeds and choose the most promising method. Conclusion. As a result of our research, it was found that the most promising extraction method for extracting seeds is a parasitic with vibration extraction at frequent revolutions of the homogenizer of 5000 rpm and an extraction time of 60 minutes.
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