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Paridis Rhizoma possesses the functions of clearing heat and detoxifying, alleviating swelling and relieving pain, cooling the liver and calming the convulsion. Saponins are the main active components of Paridis Rhizoma. Studies have shown that total saponins in Paridis Rhizoma have obvious inhibitory effect on solid tumors such as breast cancer, lung cancer, gastric cancer, and liver cancer and non-solid tumors such as leukemia. The saponins may exert the anti-tumor effects by inhibiting the proliferation, migration, and invasion of tumor cells, regulating cell cycle, inducing apoptotic and non-apoptotic death pathways, and regulating metabolism and tumor microenvironment. Furthermore, total saponins in Paridis Rhizoma showed anti-inflammatory, antioxidant, antimicrobial, hemostatic, and uterus-contracting activities. At the same time, they may induce apoptosis of normal cells, inflammation and oxidative stress, and metabolic disorders. In recent years, the reports of liver injury, reproductive injury, gastrointestinal injury, hemolysis, and other adverse reactions caused by total saponins in Paridis Rhizoma have been increasing. Pharmacokinetic studies have shown that there are significant differences in the metabolism of total saponins in Paridis Rhizoma administrated in different ways. Injection has a fast clearance rate, while oral administration may have hepatoenteric circulation. Meanwhile, due to the low solubility and activation of P-glycoprotein (P-gp) molecular pump, the prototype absorption, intestinal permeability, and recovery rate of total saponins in Paridis Rhizoma are poor, which affects the bioavailability. The bioavailability can be improved to some extent by preparing new dosage forms or new drug delivery systems with advanced technology. This paper reviews the pharmacological effect, pharmacokinetics, and adverse reactions of Rhizoma Paridis total saponins by searching the China National Knowledge Infrastructure (CNKI), VIP, and Web of Science with ''Rhizoma Paridis total saponins'' as the keywords, hoping to provide references for the research, development, and clinical application of such components.
Résumé
Ferroptosis, a new form of programmed cell death different from apoptosis, necrosis, and autophagy, is closely associated with a variety of physiological and pathological processes. Iron-mediated accumulation of reactive oxygen species is the main inducement of ferroptosis, the mechanism of which is related to intracellular lipid metabolism, iron metabolism, and antioxidant defense pathways. Multiple signaling axes and regulators jointly regulate the occurrence and disruption of ferroptosis. Studies have demonstrated that ferroptosis regulates the growth and proliferation of tumor cells. Inducing ferroptosis in tumor cells can control the growth, metastasis, and multi-drug resistance of tumors. Therefore, the effect and mechanism of ferroptosis on tumor cells have become a hot topic in anti-cancer research. As the research advances, a variety of ferroptosis inducers has been used in the clinical chemotherapy for cancers and demonstrate significant efficacy. Accordingly, the development of ferroptosis-inducing anticancer drugs has become a new research direction for tumor treatment. Some active ingredients such as lycorine, oleanolic acid, dihydroartemisinin, pseudolaric acid B, and ophiopogonin B of Chinese medicines can induce ferroptosis in tumor cells via lipid metabolism, iron metabolism, system Xc-, and GPX4/GSH to regulate the development of tumors, demonstrating a promising prospect in clinical treatment. Based on the theory of the mechanism of ferroptosis, this paper reviews the research progress in ferroptosis induced by active ingredients of Chinese medicines in tumor cells and describes the metabolic regulatory network of ferroptosis from signaling pathways and regulatory factors, providing new strategies for applying active ingredients of Chinese medicines in the treatment of tumors.
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As a rare Chinese medicinal material, Paridis Rhizoma is mainly distributed in Yunnan, Guangxi, and Guizhou in southwestern China, with the effect of clearing heat and detoxifying, alleviating edema and relieving pain, cooling liver and tranquilizing mind. It is particularly effective for injuries from falls, fractures, contusions and strains, snake bites, cold wind-induced convulsion, and other diseases, which has been used for more than 2 000 years. According to modern research, polyphyllin Ⅱ, one of the main active components of Paridis Rhizoma, belongs to diosgenin in structure. It has the anti-tumor, anti-inflammatory, antiviral, antibacterial, immune-regulating, antioxidant, and multidrug resistance-reversing activities, showing good application prospect. Especially, the anti-tumor effect of polyphyllin Ⅱ has attracted wide attention, and the mechanism is inhibiting proliferation, migration, and invasion of tumor cells, inducing cell cycle arrest, apoptosis, and autophagy, suppressing angiogenesis, and modulating tumor microenvironment. However, the pharmacokinetic results show that polyphyllin Ⅱ has low bioavailability in vivo due to the low solubility, poor absorption, unsatisfactory distribution, and slow metabolism, which limit the clinical application. In recent years, there has been an explosion of research on the adverse reactions of polyphyllin Ⅱ, such as the strong hemolytic activity and obvious cytotoxicity to liver, kidney, myocardium and cardiovascular cells. Thus, papers were retrieved from "CNKI", "VIP", "Wanfang Data", "PubMed", "Web of Science", and "Elsevier SD" with "Paris saponin Ⅱ", "Polyphyllin Ⅱ" as the main keywords, and the pharmacological activities and mechanisms, pharmacokinetics, and adverse reactions were summarized. The findings are expected to serve as a reference for the in-depth research, development, and utilization of polyphyllin Ⅱ.
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Objective To establish an HPLC method for simultaneous determination of Quercetin , Luteolin, pigenin in Matricaria Chamomila L.. Methods HPLC analysis was performed on Agilent Zorbox SB-C18 column (4.6 mm×250 mm, 5 μm) with the methanol and phosphoric acid as mobile phase in equal degree model, and the column temperature was set at 25 ℃, and the flow rate was 1.0 ml.min-1 and the detecting wave length was at 350 nm. Results The linear response ranges were from 0.25-4.04 μg of Quercetin (r=1.000, n=6) and from 0.25-3.98 μg of Luteolin (r=1.000, n=6) and 0.25-4.02 μg of Apigenin (r=1.000, n=6);and the recoveries, the precision and the stability RSD of Quercetin, Luteolin and Apigenin meet the requirements. The average recovery rate of quercetin, luteolin and apigenin was 93.64%, 95.85% and 95.40%, respectively. Conclusions All 3 samples in Matricaria Chamomila.L were determined by HPLC. The method is simple, rapid, and reproducible. It can be used as reference for the quality control of Matricaria Chamomila L..
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Objective To investigate the anti-inflammatory activity of the main active ingredients in the dried stem bark of Daphne giraldii Nitsche.Methods Severialchemical compounds like vladinol D, pinoresinol, daphneticin, daphnoretin, daphnetin, giraloid A and giraldoid B were isolated from the stem barks. The CCK-8 experiemnts were analyzed for the cytotoxicity study. The cells were divided into the control group, the model group and the treatment group according to random number table method. The control group and the model group were added with 50μl culture medium. Moreover, treatment group was added with different concentrations (50.00, 25.00, 12.50, 6.25, 3.12μg/ml) of the solutions of giraloid A, giraldoid B and daphneticin. Then, RAW264.7 cells were treated with 50μl LPS (4μg/ml) for 24 h in the model group and treatment group. Griess reagent was used to determine the amount of NO release, and the secretion of TNF-α was detected by ELISA kit.Results Cytotoxicity test indicated that giraldoid A (50.00μg/ml), giraldoid B (50.00μg/ml) and daphneticin (50.00μg/ml) showed noobvious cytotoxicity. Giraldoid B (12.50, 25.00, 50.00μg/ml) could inhibit the production of NO (271.86% ± 20.92%, 256.48% ± 20.92%, 199.31% ± 15.16%vs.358.62% ± 28.64%) and TNF-α (647.87% ±115.79%, 618.42% ± 87.52%, 588.33% ± 87.94%vs. 1035.06% ± 58.29%) in RAW264.7 induced by LPS compared with the model group. Giraldoid A (25, 50μg/ml) could inhibit the production of NO (234.99% ± 34.28%, 167.36% ± 25.76% vs.358.62%±28.64%) and TNF-α (691.76% ± 60.37%, 534.01% ± 41.60% vs. 1035.06% ± 58.29%) in RAW264.7 induced by LPS compared with the model group. Daphneticin (12.5, 25, 50μg/ml) could inhibit the production of NO (283.89% ± 36.69%, 243.08% ± 48.19%, 225.92% ± 33.67% vs.358.62% ± 28.64%) and TNF-α (713.77% ± 121.96%, 670.62% ± 18.70% vs. 1035.06% ± 58.29%) in RAW264.7 induced by LPS compared with the model group.Conclusions Giraldoid A, giraldoid B and daphneticin exhi bited anti-inflammatory effect through inhibiting the release of NO and the production of TNF-α in RAW264.7 induced by LPS.