1. Oxidative stress and cellular pathways of asthma and inflammation: Therapeutic strategies and pharmacological targets.
   Vikas Mishra et al, 2018, Pharmacol Ther CrossRef
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   Rong Jun Wan et al, 2017 CrossRef
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   Zhongjie Wang et al, 2018, Renal Failure CrossRef
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   Juan Antonio Moreno et al, 2018, Expert Opin Investig Drugs CrossRef
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   Yingying Wang et al, 2018, Front. Pharmacol. CrossRef
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   Ning Liu et al, 2019, Mediators Inflamm CrossRef
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   Shinichi Harada et al, 2017, J Pharm Pharmacol CrossRef
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   Lu Gao et al, 2017, Mol Cell Biochem CrossRef
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    Dalia Mahmoud Abdelmonem Elsherbini et al, 2020, Anat Cell Biol CrossRef
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    Zhi Chang et al, 2020, Phytotherapy Research CrossRef
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    Khouchlaa Aya et al, 2020 CrossRef
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    Gang Gong et al, 2020, Biomed Pharmacother CrossRef
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    Dorin Dragoș et al, 2020, Journal of Diabetes Research CrossRef
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    Damini Kothari et al, 2020, Antioxidants CrossRef
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    Chunli Piao et al, 2020, Evidence-Based Complementary and Alternative Medicine CrossRef
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    Chaima Mouffouk et al, 2021, Eur J Pharmacol CrossRef
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    Marwa Matboli et al, 2021, Epigenomics CrossRef
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    Weie Zhou et al, 2021, Journal of Diabetes Research CrossRef
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    Shanshan Ding et al, 2021, Evidence-Based Complementary and Alternative Medicine CrossRef
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    Youzi Dong et al, 2021, Sci Rep CrossRef
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    Feten Zar Kalai et al, 2022, IJMS CrossRef
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    Feten Zar Kalai et al, 2022, International Journal of Food Properties CrossRef
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    Jinjun Li et al, 2022, Front. Nutr. CrossRef
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    Marwa Matboli et al, 2024, Front. Endocrinol. CrossRef
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    Partha Biswas et al, 2024, Biomedicine & Pharmacotherapy CrossRef
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