Di Santo M, Tarozzi N, Nadalini M, et al. Human sperm cryopreservation: update on techniques, effect on DNA integrity, and implications for ART. Adv Urol (in eng). 2012;2012:854837.
Sanger WG, Olson JH, Sherman JK. Semen cryobanking for men with cancer–criteria change. Fertil Steril (in eng). 1992;58(5):1024–7.
He Y, Zheng H, Du H, et al. Delayed frozen embryo transfer failed to improve live birth rate and neonatal outcomes in patients requiring whole embryo freezing. Reprod Biol Endocrinol (in eng). 2020;18(1):1.
Hosseini A, Khalili MA, Talebi AR, et al. Cryopreservation of low number of human spermatozoa; which is better: vapor phase or direct submerging in liquid nitrogen? Hum Fertil (Camb) (in eng). 2019;22(2):126–32.
Hezavehei M, Sharafi M, Kouchesfahani HM, et al. Sperm cryopreservation: a review on current molecular cryobiology and advanced approaches. Reprod Biomed Online (in eng). 2018;37(3):327–39.
Ladeira C, Koppen G, Scavone F, et al. The comet assay for human biomonitoring: effect of cryopreservation on DNA damage in different blood cell preparations. Mutat Res Genet Toxicol Environ Mutagen (in eng). 2019;843:11–7.
Long J, Liu C, Sun L, et al. Neuronal mitochondrial toxicity of malondialdehyde: inhibitory effects on respiratory function and enzyme activities in rat brain mitochondria. Neurochem Res (in eng). 2009;34(4):786–94.
Lasso JL, Noiles EE, Alvarez JG, et al. Mechanism of superoxide dismutase loss from human sperm cells during cryopreservation. J Androl (in eng). 1994;15(3):255–65.
Bahmyari R, Zare M, Sharma R, et al. The efficacy of antioxidants in sperm parameters and production of reactive oxygen species levels during the freeze-thaw process: a systematic review and meta-analysis. Andrologia (in eng). 2020;52(3):e13514.
Luño V, Gil L, Olaciregui M, et al. Rosmarinic acid improves function and in vitro fertilising ability of boar sperm after cryopreservation. Cryobiology (in eng). 2014;69(1):157–62.
Vieira JIT, da Silva TA, Barbosa WMP, et al. Effect of green tea extract (Camellia sinensis) on the spermatic parameters of Wistar rats submitted or not to testicular heat shock. Anim Reprod (in eng). 2020;17(2):e20190049.
Milani S, Calabrò A. Role of growth factors and their receptors in gastric ulcer healing. Microsc Res Tech (in eng). 2001;53(5):360–71.
Tang YL, Chan SW. A review of the pharmacological effects of piceatannol on cardiovascular diseases. Phytother Res (in eng). 2014;28(11):1581–8.
Liu J, Mai P, Yang Z, et al. Piceatannol protects PC-12 cells against oxidative damage and mitochondrial dysfunction by inhibiting autophagy via SIRT3 pathway. Nutrients (in eng). 2023;15(13):2973.
Cuadrado A, Rojo AI, Wells G, et al. Therapeutic targeting of the NRF2 and KEAP1 partnership in chronic diseases. Nat Rev Drug Discov (in eng). 2019;18(4):295–317.
Thimmulappa RK, Lee H, Rangasamy T, et al. Nrf2 is a critical regulator of the innate immune response and survival during experimental sepsis. J Clin Invest (in eng). 2006;116(4):984–95.
Sadeghiani G, Khanehzad M, Sadighi Gilani MA, et al. Evaluation of Nrf2/ARE signaling pathway in the presence of pentoxifylline as a cryoprotectant in mouse spermatogonial stem cells. Biopreserv Biobank (in eng). 2023;21(3):294–307.
Zhu X, He L, Gao W, et al. Neuroprotective investigation of tanshinone in the cerebral infarction model in the Keap1-Nrf2/ARE pathway. Cell Cycle (in eng). 2023;22(4):390–402.
Wang L, Guo Y, Ye J, et al. Protective effect of piceatannol against cerebral ischaemia-reperfusion injury via regulating Nrf2/HO-1 pathway in vivo and vitro. Neurochem Res (in eng). 2021;46(7):1869–80.
Shi X, Fu L. Piceatannol inhibits oxidative stress through modification of Nrf2-signaling pathway in testes and attenuates spermatogenesis and steroidogenesis in rats exposed to cadmium during adulthood. Drug Des Devel Ther (in eng). 2019;13:2811–24.
Björndahl L, Apolikhin O, Baldi E, et al. WHO laboratory manual for the examination and processing of human semen. 6th edition. Geneva: World Health Organization; 2021. pp.155–160.
Liu Y, Xiao Y, Zhao D, et al. Direct fumigation for freeze-thawing of human sperm: an experimental study. Natl J Androl. 2012;18(03):227–30.
Baldi E, Gallagher MT, Krasnyak S, et al. Extended semen examinations in the sixth edition of the WHO laboratory manual for the examination and processing of human semen: contributing to the understanding of the function of the male reproductive system. Fertil Steril (in eng). 2022;117(2):252–7.
Lopes F, Pinto-Pinho P, Gaivão I, et al. Sperm DNA damage and seminal antioxidant activity in subfertile men. Andrologia (in eng). 2021;53:5 e14027.
Thomson LK, Fleming SD, Aitken RJ, et al. Cryopreservation-induced human sperm DNA damage is predominantly mediated by oxidative stress rather than apoptosis. Hum Reprod (in eng). 2009;24(9):2061–70.
Karimfar MH, Niazvand F, Haghani K, et al. The protective effects of melatonin against cryopreservation-induced oxidative stress in human sperm. Int J Immunopathol Pharmacol (in eng). 2015;28(1):69–76.
Johnson LA, Weitze KF, Fiser P, et al. Storage of boar semen. Anim Reprod Sci (in eng). 2000;62(1–3):143–72.
Halliwell B. Establishing the significance and optimal intake of dietary antioxidants: the biomarker concept. Nutr Rev (in eng). 1999;57(4):104–13.
Walters JLH, De Iuliis GN, Nixon B, et al. Oxidative stress in the male germline: a review of novel strategies to reduce 4-hydroxynonenal production. Antioxidants (Basel) (in eng). 2018;7(10):132.
Kensler TW, Wakabayashi N, Biswal S. Cell survival responses to environmental stresses via the Keap1-Nrf2-ARE pathway. Annu Rev Pharmacol Toxicol (in eng). 2007;47:89–116.
David JA, Rifkin WJ, Rabbani PS, et al. The Nrf2/Keap1/ARE pathway and oxidative stress as a therapeutic target in type II diabetes mellitus. J Diabetes Res (in eng). 2017;2017:4826724.
Hosoda R, Hamada H, Uesugi D, et al. Different antioxidative and antiapoptotic effects of piceatannol and resveratrol. J Pharmacol Exp Ther (in eng). 2021;376(3):385–96.
Xiong L, Xiang D, Yuan F, et al. Piceatannol-3’-O-β-D-glucopyranoside attenuates colistin-induced neurotoxicity by suppressing oxidative stress via the NRF2/HO-1 pathway. Biomed Pharmacother (in eng). 2023;161:114419.
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