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   O. Friedrich et al, 2015, Physiological Reviews CrossRef
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   Myeongjin Kim et al, 2018, Lasers Surg. Med. CrossRef
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   Akbar Ahmad et al, 2016, Pharmacological Research CrossRef
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   Akbar Ahmad et al, 2017, Burns CrossRef
6. Effect of 3-mercaptopyruvate Sulfurtransferase Deficiency on the Development of Multiorgan Failure, Inflammation, and Wound Healing in Mice Subjected to Burn Injury
   Akbar Ahmad et al, 2019 CrossRef
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   Kyle L. Flannigan et al, 2014, Proc Natl Acad Sci USA CrossRef
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   Vincenzo Brancaleone et al, 2014, J Pharmacol Exp Ther CrossRef
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   Silvana Aparecida Alves Corrêa de Noronha et al, 2014, Acta Cir. Bras. CrossRef
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    Katalin Módis et al, 2015 CrossRef
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    X Yang et al, 2017, Osteoporos Int CrossRef
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    Beomseok Son et al, 2019, Journal of Dermatological Science CrossRef
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    Mengting Xu et al, 2020, Journal of Advanced Research CrossRef
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    Yun Qian et al, 2020, Biomater. Sci. CrossRef
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    Md. Aejazur Rahman et al, 2020, Front. Cell. Infect. Microbiol. CrossRef
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    Tingting Zhang et al, 2021, Comparative Biochemistry and Physiology Part C: Toxicology & Pharmacology CrossRef
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    Sumeet Manandhar et al, 2021 CrossRef
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    Jae-Ho Lee et al, 2022, BMB Rep CrossRef
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    Andrea Domán et al, 2023, Redox Biology CrossRef
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    Annika S. Walter et al, 2023, Burns CrossRef
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    Nathalie Stummer et al, 2023, Antioxidants CrossRef
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    Patrick P.G. Mulder et al, 2023, Journal of Investigative Dermatology CrossRef
25. Immune regulation of hydrogen sulfide in children with acute lymphoblastic leukemia
    Shuxu Du et al, 2014 CrossRef
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    Xiao-Yi Liang et al, 2024, Nitric Oxide CrossRef