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  • 原金丝桃素

    Protohypericin

    原金丝桃素
    产品编号 CFN93055
    CAS编号 548-03-8
    分子式 = 分子量 C30H18O8 = 506.46
    产品纯度 >=98%
    物理属性 Powder
    化合物类型 Quinones
    植物来源 The herbs of Hypericum perforatum L.
    ChemFaces的产品在影响因子大于5的优秀和顶级科学期刊中被引用
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    原金丝桃素 CFN93055 548-03-8 1mg QQ客服:2159513211
    原金丝桃素 CFN93055 548-03-8 5mg QQ客服:2159513211
    原金丝桃素 CFN93055 548-03-8 10mg QQ客服:2159513211
    原金丝桃素 CFN93055 548-03-8 20mg QQ客服:2159513211
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    ChemFaces的产品在许多优秀和顶级科学期刊中被引用

    Cell. 2018 Jan 11;172(1-2):249-261.e12.
    doi: 10.1016/j.cell.2017.12.019.
    IF=36.216(2019)

    PMID: 29328914

    Cell Metab. 2020 Mar 3;31(3):534-548.e5.
    doi: 10.1016/j.cmet.2020.01.002.
    IF=22.415(2019)

    PMID: 32004475

    Mol Cell. 2017 Nov 16;68(4):673-685.e6.
    doi: 10.1016/j.molcel.2017.10.022.
    IF=14.548(2019)

    PMID: 29149595

    ACS Nano. 2018 Apr 24;12(4): 3385-3396.
    doi: 10.1021/acsnano.7b08969.
    IF=13.903(2019)

    PMID: 29553709

    Nature Plants. 2016 Dec 22;3: 16206.
    doi: 10.1038/nplants.2016.205.
    IF=13.297(2019)

    PMID: 28005066

    Sci Adv. 2018 Oct 24;4(10): eaat6994.
    doi: 10.1126/sciadv.aat6994.
    IF=12.804(2019)

    PMID: 30417089
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  • 国外学术期刊发表的引用ChemFaces产品的部分文献
  • Metabolites.2020, 10(12):497.
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  • Oncotarget.2017, 8(64):108006-108019
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  • Nutrients.2021, 13(3):978.
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  • Int J Vitam Nutr Res.2022, doi: 10.1024.
  • ...
  • 生物活性
    Description: Protohypericin exhibits photocytotoxicity.
    In vitro:
    Planta Med. 1999 Dec;65(8):719-22.
    Photocytotoxicity of protohypericin after photoconversion to hypericin.[Pubmed: 10630113]
    In the present study, Protohypericin was synthesised in order to compare its intrinsic photocytotoxicity with that of hypericin.
    METHODS AND RESULTS:
    The experimental work was performed in specific filtered light conditions that prevented both an unintended photoconversion of Protohypericin and photosensitization of the cells. Assessing the photocytotoxicity as a function of irradiation time, it was found that the photocytotoxicity of both compounds converged after a long irradiation time (i.e., 15 min), while the difference between the photocytotoxicities was maximal after a short irradiation time (i.e., 1 min).
    CONCLUSIONS:
    Since this could not be accounted for by a redistribution of Protohypericin during irradiation, and the different irradiation times corresponded to different degrees of photoconversion of Protohypericin into hypericin, the results clearly suggest that Protohypericin exhibits intrinsically a dramatically lower photoactivity as compared to hypericin.
    J AOAC Int. 2005 Nov-Dec;88(6):1607-12.
    Simultaneous determination of protopseudohypericin, pseudohypericin, protohypericin, and hypericin without light exposure.[Pubmed: 16526439 ]
    St. John's wort products are commonly standardized to total naphthodianthrones and hyperforin. Determination of these marker compounds is complicated because of the photochemistry of the naphthodianthrones pseudohypericin and hypericin and the instability of hyperforin in solution.
    METHODS AND RESULTS:
    Protopseudohypericin and Protohypericin have been identified as naturally occurring naphthodianthrones and, when exposed to light, they are converted into pseudohypericin and hypericin, respectively. However, exposure to light and the resulting naphthodianthrone free-radical reactions oxidize hyperforin. A mathematical relationship between the response of the proto compound and the resulting naphthodianthrone can be established by comparing the analytical response of the proto compound in a solution protected from light with the increase in the analytical response of naphthodianthrone in the same solution after exposure to light. By mathematically converting the proto compounds to their respective products, exposure to light can be avoided while still including proto compounds in a single assay.
    CONCLUSIONS:
    The method presented here details the reporting of all significant naphthodianthrones, including protopseudohypericin and Protohypericin, without exposure to light. This approach includes the benefits of improved naphthodianthrone precision and protection of hyperforin from oxidation.
    In vivo:
    J Drug Target. 2015 Jun;23(5):417-26.
    Radiopharmaceutical evaluation of (131)I-protohypericin as a necrosis avid compound.[Pubmed: 25655506 ]
    Hypericin is a necrosis avid agent useful for nuclear imaging and tumor therapy. Protohypericin, with a similar structure to hypericin except poorer planarity, is the precursor of hypericin.
    METHODS AND RESULTS:
    In this study, we aimed to investigate the impact of this structural difference on self-assembly, and evaluate the necrosis affinity and metabolism in the rat model of reperfused hepatic infarction. Protohypericin appeared less aggregative in solution compared with hypericin by fluorescence analysis. Biodistribution data of (131)I-Protohypericin showed the percentage of injected dose per gram of tissues (%ID/g) increased with time and reached to the maximum of 7.03 at 24 h in necrotic liver by gamma counting. The maximum ratio of target/non-target tissues was 11.7-fold in necrotic liver at 72 h. Pharmacokinetic parameters revealed that the half-life of (131)I-Protohypericin was 14.9 h, enabling a long blood circulation and constant retention in necrotic regions. SPECT-CT, autoradiography, and histological staining showed high uptake of (131)I-Protohypericin in necrotic tissues.
    CONCLUSIONS:
    These results suggest that (131)I-Protohypericin is a promising necrosis avid compound with a weaker aggregation tendency compared with hypericin and it may have a broad application in imaging and oncotherapy.
    制备储备液(仅供参考)
    1 mg 5 mg 10 mg 20 mg 25 mg
    1 mM 1.9745 mL 9.8724 mL 19.7449 mL 39.4898 mL 49.3622 mL
    5 mM 0.3949 mL 1.9745 mL 3.949 mL 7.898 mL 9.8724 mL
    10 mM 0.1974 mL 0.9872 mL 1.9745 mL 3.949 mL 4.9362 mL
    50 mM 0.0395 mL 0.1974 mL 0.3949 mL 0.7898 mL 0.9872 mL
    100 mM 0.0197 mL 0.0987 mL 0.1974 mL 0.3949 mL 0.4936 mL
    * Note: If you are in the process of experiment, it's need to make the dilution ratios of the samples. The dilution data of the sheet for your reference. Normally, it's can get a better solubility within lower of Concentrations.
    部分图片展示
    产品名称 产品编号 CAS编号 分子式 = 分子量 位单 联系QQ
    番泻苷C; Sennoside C CFN99905 37271-16-2 C42H40O19 = 848.76 10mg QQ客服:1457312923
    番泻苷D; Sennoside D CFN99906 37271-17-3 C42H40O19 = 848.76 5mg QQ客服:2056216494
    1,5,7'-联大黄素甲醚; Floribundone 1 CFN97845 118555-84-3 C32H22O10 = 566.52 5mg QQ客服:3257982914
    原金丝桃素; Protohypericin CFN93055 548-03-8 C30H18O8 = 506.46 5mg QQ客服:1413575084
    金丝桃素; Hypericin CFN99188 548-04-9 C30H16O8 = 504.45 20mg QQ客服:2159513211
    伪金丝桃素; Pseudohypericin CFN99591 55954-61-5 C30H16O9 = 520.44 5mg QQ客服:1457312923
    原伪金丝桃素; Protopseudohypericin CFN90677 54328-09-5 C30H18O9 = 522.46 10mg QQ客服:2056216494
    番泻苷元A; Sennidin A CFN99597 641-12-3 C30H18O10 = 538.46 5mg QQ客服:3257982914
    番泻苷元B; Sennidin B CFN99598 517-44-2 C30H18O10 = 538.46 5mg QQ客服:2056216494
    番泻苷A; Sennoside A CFN99903 81-27-6 C42H38O20 = 862.74 20mg QQ客服:2056216494

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