Recent advances in chemistry and bioactivity of Sargentodoxa cuneata.
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Xiaochi Ma | Wen Zhang | Wen-Yu Zhao | Chengpeng Sun | B. Fang | Shuang Zhou | Juan-Juan Yan | Jing Yi | Lin Wang | Lingli Sheng | Tiantian Liu
[1] Sargentodoxa cuneata , 2022, CABI Compendium.
[2] M. Rosales-Hernández,et al. Neuroprotective Effects of Apocynin and Galantamine During the Chronic Administration of Scopolamine in an Alzheimer’s Disease Model , 2019, Journal of Molecular Neuroscience.
[3] Guan-Jhong Huang,et al. Four New Iridoid Metabolites Have Been Isolated from the Stems of Neonauclea reticulata (Havil.) Merr. with Anti-Inflammatory Activities on LPS-Induced RAW264.7 Cells , 2019, Molecules.
[4] K. Patel,et al. Isorhapontigenin, a resveratrol analogue selectively inhibits ADP-stimulated platelet activation. , 2019, European journal of pharmacology.
[5] Chian-Jiun Liou,et al. Maslinic acid protects against obesity‐induced nonalcoholic fatty liver disease in mice through regulation of the Sirt1/AMPK signaling pathway , 2019, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.
[6] Z. Dong,et al. Salidroside prevents tumor necrosis factor-α-induced vascular inflammation by blocking mitogen-activated protein kinase and NF-κB signaling activation. , 2019, Experimental and therapeutic medicine.
[7] Xiaofang Li,et al. Chrysophanol: a review of its pharmacology, toxicity and pharmacokinetics , 2019, The Journal of pharmacy and pharmacology.
[8] Naihong Chen,et al. Physcion and physcion 8-O-β-glucopyranoside: A review of their pharmacology, toxicities and pharmacokinetics. , 2019, Chemico-biological interactions.
[9] H. Aisa,et al. Phenolic glycosides from Nitraria sibirica leaves and their in vitro biological activities , 2019, Natural product research.
[10] Shukun Zhang,et al. Treatment with 3,4-dihydroxyphenylethyl alcohol glycoside ameliorates sepsis-induced ALI in mice by reducing inflammation and regulating M1 polarization. , 2019, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.
[11] Sung Chul Park,et al. Anti-inflammatory effects of apocynin on dextran sulfate sodium-induced mouse colitis model , 2019, PloS one.
[12] Hyung-Sik Kang,et al. Daucosterol suppresses dextran sulfate sodium (DSS)-induced colitis in mice. , 2019, International immunopharmacology.
[13] P. Gao,et al. Daucosterol induces autophagic-dependent apoptosis in prostate cancer via JNK activation. , 2019, Bioscience trends.
[14] Shukun Zhang,et al. Purification of 3, 4-dihydroxyphenylethyl alcohol glycoside from Sargentodoxa cuneata (Oliv.) Rehd. et Wils. and its protective effects against DSS-induced colitis , 2019, Scientific Reports.
[15] Bao-song Liu,et al. Effect of Sargentodoxa cuneata total phenolic acids on focal cerebral ischemia reperfusion injury rats model , 2018, Saudi journal of biological sciences.
[16] Huifang Sun,et al. Anti‐Inflammatory Activities and Related Mechanism of Polysaccharides Isolated from Sargentodoxa cuneata , 2018, Chemistry & biodiversity.
[17] Tingting Nie,et al. Studies on the Mechanism of Chlorogenic Acid Inhibiting Inflammation in Collagen-Induced Rheumatoid Arthritis , 2018, Journal of Biomaterials and Tissue Engineering.
[18] Jing Zhang,et al. Frontline Science: Reprogramming COX‐2, 5‐LOX, and CYP4A‐mediated arachidonic acid metabolism in macrophages by salidroside alleviates gouty arthritis , 2018, Journal of leukocyte biology.
[19] H. Rotsztejn,et al. Antioxidant Properties of Ferulic Acid and Its Possible Application , 2018, Skin Pharmacology and Physiology.
[20] G. Haenen,et al. The chemical reactivity of (‐)‐epicatechin quinone mainly resides in its B‐ring , 2018, Free radical biology & medicine.
[21] M. Rateb,et al. Epigenetic Modifiers Induce Bioactive Phenolic Metabolites in the Marine-Derived Fungus Penicillium brevicompactum , 2018, Marine drugs.
[22] Xiukun Lin,et al. Maslinic acid as an effective anticancer agent. , 2018, Cellular and molecular biology.
[23] Ziyan Guo,et al. Protocatechuic acid inhibits the growth of ovarian cancer cells by inducing apoptosis and autophagy , 2018, Phytotherapy research : PTR.
[24] Heonyong Park,et al. Pinosylvin enhances leukemia cell death via down‐regulation of AMPKα expression , 2018, Phytotherapy research : PTR.
[25] Ling Zhang,et al. Protective Effect of Rosamultin against H2O2-Induced Oxidative Stress and Apoptosis in H9c2 Cardiomyocytes , 2018, Oxidative medicine and cellular longevity.
[26] Feng Yan,et al. Salidroside improves brain ischemic injury by activating PI3K/Akt pathway and reduces complications induced by delayed tPA treatment , 2018, European journal of pharmacology.
[27] W. Yap,et al. Maslinic acid modulates secreted phospholipase A2-IIA (sPLA2-IIA)-mediated inflammatory effects in macrophage foam cells formation , 2018, Journal of Biosciences.
[28] Heonyong Park,et al. Pinosylvin exacerbates LPS-induced apoptosis via ALOX 15 upregulation in leukocytes , 2018, BMB reports.
[29] E. Kumolosasi,et al. Immunomodulatory effects of Tinospora crispa extract and its major compounds on the immune functions of RAW 264.7 macrophages , 2018, International immunopharmacology.
[30] J. Bernatonienė,et al. The Role of Catechins in Cellular Responses to Oxidative Stress , 2018, Molecules.
[31] Lin Gui,et al. Salidroside Inhibits HMGB1 Acetylation and Release through Upregulation of SirT1 during Inflammation , 2017, Oxidative medicine and cellular longevity.
[32] Y. Joo,et al. Chlorogenic acid suppresses lipopolysaccharide‑induced nitric oxide and interleukin‑1β expression by inhibiting JAK2/STAT3 activation in RAW264.7 cells. , 2017, Molecular medicine reports.
[33] Shukun Zhang,et al. Protective role of liriodendrin in mice with dextran sulphate sodium‐induced ulcerative colitis , 2017, International immunopharmacology.
[34] Sang-Hyun Kim,et al. Tyrosol attenuates lipopolysaccharide-induced acute lung injury by inhibiting the inflammatory response and maintaining the alveolar capillary barrier. , 2017, Food and chemical toxicology : an international journal published for the British Industrial Biological Research Association.
[35] M. Rasool,et al. p‐Coumaric acid, a dietary polyphenol ameliorates inflammation and curtails cartilage and bone erosion in the rheumatoid arthritis rat model , 2017, BioFactors.
[36] D. Mirowska-Guzel,et al. Pharmacological effects of protocatechuic acid and its therapeutic potential in neurodegenerative diseases: Review on the basis of in vitro and in vivo studies in rodents and humans , 2017, Nutritional neuroscience.
[37] Zhen Liu,et al. Microbial transformation of the anti-diabetic agent corosolic acid by Cunninghamella echinulata , 2017, Journal of Asian natural products research.
[38] P. Barnes,et al. Isorhapontigenin, a bioavailable dietary polyphenol, suppresses airway epithelial cell inflammation through a corticosteroid‐independent mechanism , 2017, British journal of pharmacology.
[39] H. Saito,et al. Protective Effects of Tormentic Acid, a Major Component of Suspension Cultures of Eriobotrya japonica Cells, on Acetaminophen-Induced Hepatotoxicity in Mice , 2017, Molecules.
[40] L. Cisneros-Zevallos,et al. Chlorogenic Acid: Recent Advances on Its Dual Role as a Food Additive and a Nutraceutical against Metabolic Syndrome , 2017, Molecules.
[41] Hui Zhang,et al. A Theoretical Study on the Antioxidant Activity of Piceatannol and Isorhapontigenin Scavenging Nitric Oxide and Nitrogen Dioxide Radicals , 2017, PloS one.
[42] Hong Chen,et al. Anti-thrombotic and anti-tumor effect of water extract of caulis of Sargentodoxa cuneata (Oliv) Rehd et Wils (Lardizabalaceae) in animal models , 2016 .
[43] Shailesh J. Wadher,et al. In silico PASS analysis and determination of antimycobacterial, antifungal, and antioxidant efficacies of maslinic acid in an extract rich in pentacyclic triterpenoids , 2016, International journal of mycobacteriology.
[44] Jin-Young Park,et al. Apocynin Suppresses Lipopolysaccharide‐Induced Inflammatory Responses Through the Inhibition of MAP Kinase Signaling Pathway in RAW264.7 Cells , 2016, Drug development research.
[45] Ying Zhang,et al. Tormentic acid inhibits H2O2-induced oxidative stress and inflammation in rat vascular smooth muscle cells via inhibition of the NF-κB signaling pathway , 2016, Molecular medicine reports.
[46] M. Yamaguchi. The botanical molecule p-hydroxycinnamic acid as a new osteogenic agent: insight into the treatment of cancer bone metastases , 2016, Molecular and Cellular Biochemistry.
[47] Dihua Li,et al. Protective Role of Liriodendrin in Sepsis-Induced Acute Lung Injury , 2016, Inflammation.
[48] Dan Zhang,et al. Two new phenylpropanoid glycosides from the aerial parts of Lespedeza cuneata , 2016, Acta pharmaceutica Sinica. B.
[49] Jian Ni,et al. Emodin: A Review of its Pharmacology, Toxicity and Pharmacokinetics , 2016, Phytotherapy research : PTR.
[50] D. Załuski,et al. HPTLC-profiling of eleutherosides, mechanism of antioxidative action of eleutheroside E1, the PAMPA test with LC/MS detection and the structure–activity relationship , 2016, Saudi journal of biological sciences.
[51] M. S. Bin Sayeed,et al. Beta-Sitosterol: A Promising but Orphan Nutraceutical to Fight Against Cancer , 2015, Nutrition and cancer.
[52] T. Murata,et al. The flavonoid p-hydroxycinnamic acid mediates anticancer effects on MDA-MB-231 human breast cancer cells in vitro: Implications for suppression of bone metastases. , 2015, International journal of oncology.
[53] K. Shimizu,et al. In vitro Cytotoxic Activities and Molecular Mechanisms of Angelica shikokiana Extract and its Isolated Compounds , 2015, Pharmacognosy magazine.
[54] Baomei Xia,et al. Daucosterol protects neurons against oxygen–glucose deprivation/reperfusion-mediated injury by activating IGF1 signaling pathway , 2015, The Journal of Steroid Biochemistry and Molecular Biology.
[55] Hee-kyoung Kang,et al. Chemical constituents of the Annona glabra fruit and their cytotoxic activity , 2015, Pharmaceutical biology.
[56] Hong Wang,et al. Protocatechuic Acid Inhibits Inflammatory Responses in LPS-Stimulated BV2 Microglia via NF-κB and MAPKs Signaling Pathways , 2015, Neurochemical Research.
[57] Hui-Chun Wang,et al. Sassarandainol: a new neolignan and anti-inflammatory constituents from the stem of Sassafras randaiense , 2015, Natural product research.
[58] Douglas E. Soltis,et al. Repeated range expansions and inter-/postglacial recolonization routes of Sargentodoxa cuneata (Oliv.) Rehd. et Wils. (Lardizabalaceae) in subtropical China revealed by chloroplast phylogeography. , 2015, Molecular phylogenetics and evolution.
[59] Lubna,et al. Cytotoxic and antioxidant properties of phenolic compounds from Tagetes patula flower , 2015, Pharmaceutical biology.
[60] Jingzhao Zhang,et al. Antimicrobial and cytotoxic phenolics and phenolic glycosides from Sargentodoxa cuneata. , 2015, Fitoterapia.
[61] T. Hayakawa,et al. Hepatoprotective triterpenes from traditional Tibetan medicine Potentilla anserina. , 2014, Phytochemistry.
[62] P. Gentili,et al. Synthesis and DPPH radical scavenging activity of novel compounds obtained from tyrosol and cinnamic acid derivatives , 2014 .
[63] Qiaoling He,et al. Lyoniresinol 3α-O-β-D-Glucopyranoside-Mediated Hypoglycaemia and Its Influence on Apoptosis-Regulatory Protein Expression in the Injured Kidneys of Streptozotocin-Induced Mice , 2013, PloS one.
[64] Zhi-min Wang,et al. [A new lignan from stems of Sargentodoxa cuneata]. , 2013, Zhongguo Zhong yao za zhi = Zhongguo zhongyao zazhi = China journal of Chinese materia medica.
[65] Xue-Ru Wu,et al. Cyclin D1 Downregulation Contributes to Anticancer Effect of Isorhapontigenin on Human Bladder Cancer Cells , 2013, Molecular Cancer Therapeutics.
[66] M. Matsumoto,et al. Antioxidative and Melanogenesis‐Inhibitory Activities of Caffeoylquinic Acids and Other Compounds from Moxa , 2013, Chemistry & biodiversity.
[67] Guan-Jhong Huang,et al. Antioxidant, Antinociceptive, and Anti-Inflammatory Activities from Actinidia callosa var. callosa In Vitro and In Vivo , 2012, Evidence-based complementary and alternative medicine : eCAM.
[68] T. Perečko,et al. The natural stilbenoid pinosylvin and activated neutrophils: effects on oxidative burst, protein kinase C, apoptosis and efficiency in adjuvant arthritis , 2012, Acta Pharmacologica Sinica.
[69] M. Ouyang,et al. A new seco-neolignan glycoside from the root bark of Ailanthus altissima , 2012, Natural product research.
[70] Zhen Ouyang,et al. Chemical constituents from the water-soluble fraction of wild Sargentodoxa cuneata , 2012 .
[71] K. Wertz,et al. Hydroxytyrosol is the major anti-inflammatory compound in aqueous olive extracts and impairs cytokine and chemokine production in macrophages. , 2011, Planta medica.
[72] J. Um,et al. Vanillic acid inhibits inflammatory mediators by suppressing NF-κB in lipopolysaccharide-stimulated mouse peritoneal macrophages , 2011, Immunopharmacology and immunotoxicology.
[73] Guo-lin Zhang,et al. A new triterpene and an antiarrhythmic liriodendrin from Pittosporum brevicalyx , 2010, Archives of pharmacal research.
[74] G. Du,et al. In vitro anti-influenza viral activities of stilbenoids from the lianas of Gnetum pendulum. , 2010, Planta medica.
[75] Hui Ming,et al. Isolation and identification of antioxidant and hyaluronidase inhibitory compounds from Ficus microcarpa L. fil. bark , 2010, Journal of enzyme inhibition and medicinal chemistry.
[76] Shuifeng Qiu,et al. A preliminary study: the anti-proliferation effect of salidroside on different human cancer cell lines , 2010, Cell Biology and Toxicology.
[77] Tie-jun Zhang,et al. A new macrolide and glycosides from the stem of Sargentodoxa cuneata , 2009 .
[78] Dinghua Yi,et al. Cardioprotection of salidroside from ischemia/reperfusion injury by increasing N-acetylglucosamine linkage to cellular proteins. , 2009, European journal of pharmacology.
[79] Ze-xin Jin,et al. [Contents of secondary metabolites and anti-bacterial activity of compound Caulis Sargentodoxae decoction]. , 2008, Zhejiang da xue xue bao. Yi xue ban = Journal of Zhejiang University. Medical sciences.
[80] Yanling Zhao,et al. Microcalorimetric studies of the action on four organic acids in Radix isatidis on the growth of microorganisms. , 2008, Sheng wu gong cheng xue bao = Chinese journal of biotechnology.
[81] R. Liu,et al. Triterpenoids isolated from apple peels have potent antiproliferative activity and may be partially responsible for apple's anticancer activity. , 2007, Journal of agricultural and food chemistry.
[82] M. Glória,et al. Antibacterial activity of coffee extracts and selected coffee chemical compounds against enterobacteria. , 2006, Journal of agricultural and food chemistry.
[83] C. Kwik-Uribe,et al. Inhibitory Effects of Procyanidin B2 Dimer on Lipid-laden Macrophage Formation , 2006, Journal of cardiovascular pharmacology.
[84] J. Garssen,et al. Oral administration of the NADPH-oxidase inhibitor apocynin partially restores diminished cartilage proteoglycan synthesis and reduces inflammation in mice. , 2006, European journal of pharmacology.
[85] Ryan J. Case,et al. Phenolic glycosides and ionone glycoside from the stem of Sargentodoxa cuneata. , 2005, Phytochemistry.
[86] G. S. Pope,et al. Oestrogenic activity of p‐hydroxybenzoic acid (common metabolite of paraben esters) and methylparaben in human breast cancer cell lines , 2005, Journal of applied toxicology : JAT.
[87] Jun-xing Dong,et al. [Phenolics from traditional Chinese medicine Sargentodoxa cuneata]. , 2005, Yao xue xue bao = Acta pharmaceutica Sinica.
[88] E. Park,et al. Antibacterial and antifungal activity of pinosylvin, a constituent of pine. , 2005, Fitoterapia.
[89] K. Chopra,et al. Delineation of antimutagenic activity of catechin, epicatechin and green tea extract. , 2004, Mutation research.
[90] W. Ye,et al. Antioxidative phenylethanoid and phenolic glycosides from Picrorhiza scrophulariiflora. , 2004, Chemical & pharmaceutical bulletin.
[91] P. Kuo,et al. Chemical constituents of the stem of Sargentodoxa cuneata , 2003 .
[92] J. Ha,et al. In vivo Anti-Inflammatory and Antinociceptive Effects of Liriodendrin Isolated from the Stem Bark of Acanthopanax senticosus , 2003, Planta medica.
[93] A. Kamimura,et al. Procyanidin B‐2, extracted from apples, promotes hair growth: a laboratory study , 2002, The British journal of dermatology.
[94] H. Kwon,et al. Inhibition of NFkappaB by methyl chlorogenate from Eriobotrya japonica. , 2000, Molecules and cells.
[95] G. Rücker,et al. Triterpensaponine aus der chinesischen Droge Daxueteng (Caulis Sargentodoxae) , 1991 .
[96] Qu Shi-zeng,et al. A NEW SPECIES OF SARGENTODOXA FROM SHAANXI , 1986 .
[97] J. Skvarla,et al. POLLEN MORPHOLOGY AND THE RELATIONSHIPS OF CIRCAEASTER, OF KINGDONIA, AND OF SARGENTODOXA TO THE RANUNCULALES , 1982 .
[98] M. Dianat,et al. Does p-coumaric acid improve cardiac injury following LPS-induced lung inflammation through miRNA-146a activity? , 2020, Avicenna journal of phytomedicine.
[99] J. Zhou,et al. ANTI -INFLAMMATORY AND ANTI -NOCICEPTIVE ACTIVITIES OF THE EXTRACTS OF SARGENTODOXA CUNEATA AND ITS EFFECTS ON THE MODEL RATS WITH PELVIC INFLAMMATION , 2012 .
[100] Y. Fu. INFLUENCE OF CAULIS SARGENTODOXAC ON SERUM LEVEL OF TNF-α、IL-6 IN ADJUVANT ARTHRITIS RAT , 2007 .
[101] Guo Cheng. Reproductive Biology of Sargentodoxa cuneata(Sargentodoxaceae) , 2007 .
[102] M. Shui. Phenolic compounds from Sargentodoxa cuneata (Oliv.) Rehd.et Wils.and their antitumor activities , 2004 .
[103] J. Marrugat,et al. Bioavailability of tyrosol, an antioxidant phenolic compound present in wine and olive oil, in humans. , 2003, Drugs under experimental and clinical research.
[104] Liu Jun-mi. Anti-microbial Activity of Sargentodoxa Cuneata Leafblades Extracts Treated with Different Organic Solvents , 2002 .
[105] Z. Jing. Clinical Study on "Winter-Cherry and Sargentgloryvine Tablets" in Treatment of Acute Biliary Infection , 2002 .
[106] Hwang Sb,et al. The investigation of lignans from Sargentodoxa cuneata (Oliv) Rehd et Wils , 1986 .