| 1 |
Investigation of the effects of safranal on the experimentally created rheumatoid arthritis model in rats |
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| Mustafa Cellat, Cafer T. Isler, Tuncer Kutlu, Müslüm Kuzu, Muhammed Etyemez, Halil Alakus, Mehmet Güvenç |
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| Journal of Biochemical and Molecular Toxicology. 2022; |
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| [Pubmed] [Google Scholar] [DOI] |
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| 2 |
Effects of thymoquinone on scopolamine-induced spatial and echoic memory changes through regulation of lipid peroxidation and cholinergic impairment |
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| Deniz Kantar, Alev Duygu Acun, Betül Danisman |
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| Behavioural Brain Research. 2022; 431: 113972 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 3 |
Molecular Mechanisms behind Safranal’s Toxicity to HepG2 Cells from Dual Omics |
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| David Roy Nelson, Ala’a Al Hrout, Amnah Salem Alzahmi, Amphun Chaiboonchoe, Amr Amin, Kourosh Salehi-Ashtiani |
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| Antioxidants. 2022; 11(6): 1125 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 4 |
The role of Safranal and saffron stigma extracts in oxidative stress, diseases and photoaging: A systematic review |
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| Sanju Nanda, Kumud Madan |
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| Heliyon. 2021; 7(2): e06117 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 5 |
Saffron for “toning down” COVID-19-related cytokine storm: Hype or hope? A mini-review of current evidence |
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| Alexios-Fotios A. Mentis, Maria Dalamaga, Cuncun Lu, Moschos G. Polissiou |
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| Metabolism Open. 2021; 11: 100111 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 6 |
Flavonoids Activation of the Transcription Factor Nrf2 as a Hypothesis Approach for the Prevention and Modulation of SARS-CoV-2 Infection Severity |
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| Patricia Mendonca, Karam F. A. Soliman |
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| Antioxidants. 2020; 9(8): 659 |
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| 7 |
Safrana l Prevents Prostate Cancer Recurrence by Blocking the Re-activation of Quiescent Cancer Cells via Downregulation of S-Phase Kinase-Associated Protein 2 |
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| Xue Jiang, Yang Li, Ji-ling Feng, Wan Najbah Nik Nabil, Rong Wu, Yue Lu, Hua Liu, Zhi-chao Xi, Hong-xi Xu |
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| Frontiers in Cell and Developmental Biology. 2020; 8 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 8 |
Thymoquinone-induced antitumor and apoptosis in human lung adenocarcinoma cells |
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| Saeed Samarghandian, Mohsen Azimi-Nezhad, Tahereh Farkhondeh |
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| Journal of Cellular Physiology. 2019; 234(7): 10421 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 9 |
A comprehensive review of the pharmacological potential of Crocus sativus and its bioactive apocarotenoids |
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| Syed Imran Bukhari, Mahreen Manzoor, M.K. Dhar |
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| Biomedicine & Pharmacotherapy. 2018; 98: 733 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 10 |
Response surface optimization of Safranal and Crocin extraction from Crocus sativus L. via supercritical fluid technology |
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| M. Ghorbandoust Goleroudbary,S.M. Ghoreishi |
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| The Journal of Supercritical Fluids. 2016; 108: 136 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 11 |
In-Silico Study on the Interaction of Saffron Ligands and Beta-Lactoglobulin by Molecular Dynamics and Molecular Docking Approach |
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| Mehdi Sahihi |
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| Journal of Macromolecular Science, Part B. 2016; 55(1): 73 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 12 |
Saffron: a natural product with potential pharmaceutical applications |
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| Eirini Christodoulou,Nikolaos PE Kadoglou,Nikolaos Kostomitsopoulos,Georgia Valsami |
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| Journal of Pharmacy and Pharmacology. 2015; 67(12): 1634 |
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| [Pubmed] [Google Scholar] [DOI] |
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| 13 |
Safranal as a novel anti-tubulin binding agent with potential use in cancer therapy: An in vitro study |
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| Ali Naghshineh,Ali Dadras,Behafarid Ghalandari,Gholam Hossein Riazi,Seyed Mohamad Sadegh Modaresi,Ali Afrasiabi,Mahsa Kiani Aslani |
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| Chemico-Biological Interactions. 2015; 238: 151 |
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