1. Assembly of Self-Cleaning Electrode Surface for the Development of Refreshable Biosensors
    Xiaoli Zhu et al, 2017, Anal. Chem. CrossRef
  2. Improving In Vivo Efficacy of Bioactive Molecules: An Overview of Potentially Antitumor Phytochemicals and Currently Available Lipid-Based Delivery Systems
    Lamia Mouhid et al, 2017, Journal of Oncology CrossRef
  3. Biosynthesis of amino deoxy-sugar-conjugated flavonol glycosides by engineered Escherichia coli
    Ramesh Prasad Pandey et al, 2015, Biochemical Engineering Journal CrossRef
  4. Quercetin inhibits angiogenesis through thrombospondin-1 upregulation to antagonize human prostate cancer PC-3 cell growth in vitro and in vivo
    FEIYA YANG et al, 2016 CrossRef
  5. Flavonoids from persimmon ( Diospyros kaki L.) leaves inhibit proliferation and induce apoptosis in PC-3 cells by activation of oxidative stress and mitochondrial apoptosis
    Yan Ding et al, 2017, Chemico-Biological Interactions CrossRef
  6. Designing food structure and composition to enhance nutraceutical bioactivity to support cancer inhibition
    David Julian McClements et al, 2017, Seminars in Cancer Biology CrossRef
  7. Intake of Individual Flavonoids and Risk of Carcinogenesis: Overview of Epidemiological Evidence
    Katrin Sak, 2017, Nutrition and Cancer CrossRef
  8. Anticancer effect of docetaxel induces apoptosis of prostate cancer via the cofilin-1 and paxillin signaling pathway
    PAN XIAO et al, 2016 CrossRef
  9. Stability of dietary polyphenols: It's never too late to mend?
    Jianbo Xiao, 2018, Food and Chemical Toxicology CrossRef
  10. BIOLOGICALLY ACTIVE COMPOUNDS OF KNOTWEED (Reynoutria spp.)
    Jiří Patočka et al, 2017, MMSL CrossRef
  11. Antitumor and immunomodulatory activities of total flavonoids extract from persimmon leaves in H22 liver tumor-bearing mice
    Li Chen et al, 2018, Sci Rep CrossRef
  12. null
    Corina T. Madreiter-Sokolowski et al, 2018 CrossRef
  13. null
    Krishnendu Sinha et al, 2018 CrossRef
  14. Modern analytical methods for consideration of natural biological activity
    Sagandykova N. Gulyaim et al, 2018, TrAC Trends in Analytical Chemistry CrossRef
  15. null
    Farrukh Aqil et al, 2019 CrossRef
  16. Nitrogen-Containing Derivatives of O-Tetramethylquercetin: Synthesis and Biological Profiles in Prostate Cancer Cell Models
    Pravien Rajaram et al, 2019, Bioorganic Chemistry CrossRef
  17. Aerobic Decomposition of Trialkylquercetins: Structure Characterization and Antiproliferative Effect
    Sami M.R. Al-Jabban et al, 2016, Natural Product Communications CrossRef
  18. Concise Synthesis of 2-Methoxyestradiol from 17β-Estradiol through the C(sp2)-H Hydroxylation
    Meng-Yu Ba et al, 2019, Steroids CrossRef
  19. Quercetin augments apoptosis of canine osteosarcoma cells by disrupting mitochondria membrane potential and regulating PKB and MAPK signal transduction
    Soomin Ryu et al, 2019, J Cell Biochem CrossRef
  20. Phytochemicals in Prostate Cancer: From Bioactive Molecules to Upcoming Therapeutic Agents
    null Salehi et al, 2019, Nutrients CrossRef
  21. Prospect of natural products in glioma: A novel avenue in glioma management
    Moumita Kundu et al, 2019, Phytotherapy Research CrossRef
  22. Quercetin: A flavonol with multifaceted therapeutic applications?
    Gabriele D'Andrea, 2015, Fitoterapia CrossRef
  23. Quercetin-6-C-β-d-glucopyranoside, natural analog of quercetin exhibits anti-prostate cancer activity by inhibiting Akt-mTOR pathway via aryl hydrocarbon receptor
    null Hamidullah et al, 2015, Biochimie CrossRef
  24. Quercetin-induced inactivation and conformational alterations of alpha-2-macroglobulin: multi-spectroscopic and calorimetric study
    Tooba Siddiqui et al, 2019, Journal of Biomolecular Structure and Dynamics CrossRef
  25. A minireview of quercetin: from its metabolism to possible mechanisms of its biological activities
    Hande Gül Ulusoy et al, 2019, Critical Reviews in Food Science and Nutrition CrossRef
  26. Looking for New Antifungal Drugs from Flavonoids: Impact of the Genetic Diversity of Candida albicans on the in-vitro Response
    Maria Rosa Felice et al, 2019, CMC CrossRef

  27. Quercetin Inhibits Epithelial-to-Mesenchymal Transition (EMT) Process and Promotes Apoptosis in Prostate Cancer via Downregulating lncRNA MALAT1


    Xinxing Lu et al, 2020, CMAR CrossRef
  28. Prostate cancer management: long-term beliefs, epidemic developments in the early twenty-first century and 3PM dimensional solutions
    Radek Kucera et al, 2020, EPMA Journal CrossRef
  29. Quercetin reverses the doxorubicin resistance of prostate cancer cells by downregulating the expression of c-met.
    Yan Shu et al, 0 CrossRef
  30. Quercetin‑3‑O‑β‑D‑glucoside decreases the bioavailability of cyclosporin A through regulation of drug metabolizing enzymes, transporters and nuclear receptors in rats
    Tingyu Yang et al, 2018, Mol Med Report CrossRef
  31. Concise synthesis of 2-methoxyestradiol through C(sp2)-H methoxylation
    Mo-Ran Sun et al, 2020, Steroids CrossRef
  32. Inhibiting CDK6 Activity by Quercetin Is an Attractive Strategy for Cancer Therapy
    Mohd Yousuf et al, 2020, ACS Omega CrossRef
  33. Flavonoids Induce Migration Arrest and Apoptosis in Detroit 562 Oropharynx Squamous Cell Carcinoma Cells
    Arkadiusz Dziedzic et al, 2021, Processes CrossRef
  34. Phytochemicals With Anti 5-alpha-reductase Activity: A Prospective For Prostate Cancer Treatment
    Aziemah Azizi et al, 2021, F1000Res CrossRef
  35. Quercetin Inhibits Invasion and Angiogenesis of Esophageal Cancer Cells
    Yue Liu et al, 2021, Pathology - Research and Practice CrossRef
  36. Traditional uses, phytochemistry and pharmacology of Bauhinia racemosa Lam.: a comprehensive review
    S. Prabhu et al, 2021, Futur J Pharm Sci CrossRef
  37. Potential of natural products as radioprotectors and radiosensitizers: opportunities and challenges
    Juanjuan Yi et al, 2021, Food Funct. CrossRef
  38. Phytochemicals With Anti 5-alpha-reductase Activity: A Prospective For Prostate Cancer Treatment
    Aziemah Azizi et al, 2021, F1000Res CrossRef
  39. Influence of Filipendula ulmaria (L.) Maxim. Extract on Lewis Lung Carcinoma Development and Cytostatic Therapy Effectiveness in Mice
    E. N. Amosova et al, 2019, Pharm Chem J CrossRef
  40. New approaches and procedures for cancer treatment: Current perspectives
    Dejene Tolossa Debela et al, 2021, SAGE Open Medicine CrossRef
  41. Combination of quercetin and 2-methoxyestradiol inhibits epithelial–mesenchymal transition in PC-3 cell line via Wnt signaling pathway
    Neeti Sharma et al, 2021, Future Science OA CrossRef
  42. Bax/Bcl-2 Cascade Is Regulated by the EGFR Pathway: Therapeutic Targeting of Non-Small Cell Lung Cancer
    Manzar Alam et al, 2022, Front. Oncol. CrossRef
  43. Immunomodulatory effect of mushrooms and their bioactive compounds in cancer: A comprehensive review
    Manash Pratim Pathak et al, 2022, Biomedicine & Pharmacotherapy CrossRef
  44. Free Radical Properties, Source and Targets, Antioxidant Consumption and Health
    Giovanni Martemucci et al, 2022, Oxygen CrossRef
  45. Phytochemical Constitution, Anti-Inflammation, Anti-Androgen, and Hair Growth-Promoting Potential of Shallot (Allium ascalonicum L.) Extract
    Warintorn Ruksiriwanich et al, 2022, Plants CrossRef
  46. Liposomes: An Emerging Approach for the Treatment of Cancer
    Keerti Mishra et al, 2021, CPD CrossRef
  47. Deciphering the enigmatic crosstalk between prostate cancer and Alzheimer's disease: A current update on molecular mechanisms and combination therapy
    Nitesh Kumar Poddar et al, 2022, Biochimica et Biophysica Acta (BBA) - Molecular Basis of Disease CrossRef
  48. Quercetin induces autophagy-associated death in HL-60 cells through CaMKKβ/AMPK/mTOR signal pathway
    Jie Xiao et al, 2022, ABBS CrossRef
  49. Tandem cyclocondensation of 1,3-bis-sulfonylpropan-2-ones with arylaldehydes. One-pot synthesis of tris-sulfonyl 3-arylphenols
    Nai-Chen Hsueh et al, 2022, Org. Biomol. Chem. CrossRef
  50. Recent Insights into Therapeutic Potential of Plant-Derived Flavonoids against Cancer
    Roohi Mohi-ud-din et al, 2022, ACAMC CrossRef
  51. Identification of natural products and FDA-approved drugs for targeting cancer stem cell (CSC) propagation
    Gloria Bonuccelli et al, 2022, Aging CrossRef
  52. Guava (Psidium guajava L.) Leaf Extract as Bioactive Substances for Anti-Androgen and Antioxidant Activities
    Warintorn Ruksiriwanich et al, 2022, Plants CrossRef
  53. null
    Fatimah Fatimah et al, 2023 CrossRef
  54. The potential anti-cancer effects of quercetin on blood, prostate and lung cancers: An update
    Noushin Lotfi et al, 2023, Front. Immunol. CrossRef
  55. Anti-cancer potential of synergistic phytochemical combinations is influenced by the genetic profile of prostate cancer cell lines
    Carol A. Gano et al, 2023, Front. Nutr. CrossRef
  56. Improving Whole Tomato Transformation for Prostate Health: Benign Prostate Hypertrophy as an Exploratory Model
    Pier Giorgio Natali et al, 2023, IJMS CrossRef
  57. Knoevenagel Condensation of Acetonedicarboxylates with Aldehydes
    Meng-Yang Chang et al, 2023, Journal of Molecular Structure CrossRef
  58. A Critical Review on Quercetin Bioflavonoid and its Derivatives: Scope, Synthesis, and Biological Applications with Future Prospects
    R. Udaya Rajesh et al, 2023, Arabian Journal of Chemistry CrossRef
  59. Apoptotic and anti‐Warburg effect of Morusin via ROS mediated inhibition of FOXM1/c‐Myc signaling in prostate cancer cells
    Ja Il Koo et al, 2023, Phytotherapy Research CrossRef
  60. The Effect of Natural Substances Contained in Bee Products on Prostate Cancer in In Vitro Studies
    Przemysław Woźniak et al, 2023, Molecules CrossRef
  61. Nano Drug Delivery Strategies for an Oral Bioenhanced Quercetin Formulation
    Esha S. Attar et al, 2023, Eur J Drug Metab Pharmacokinet CrossRef
  62. A Review of Nutraceuticals in Cancer Cachexia
    Lucas Caeiro et al, 2023, Cancers CrossRef