BioVin® French Red Grapes Extract

Common Name

Grape Pomace Extract


Top Benefits of BioVin®

Supports healthy aging *

Supports mitochondrial health *

Supports cellular responses and antioxidant defenses *

Supports maintenance of healthy brain function *

Supports healthy gut microbiota *


What is BioVin®?

BioVin® is made from the juice, seeds, and skins of French red grapes. It provides a full spectrum of grape’s health-promoting compounds (grapes contain thousands of compounds). Grape skins and seeds contain small amounts of trans-resveratrol. This compound has been the subject of hundreds of pre-clinical and clinical research studies. While trans-resveratrol has received a great deal of research attention, grapes are more than one compound: They contain resveratrol derivatives (e.g., viniferins, polydatin) and polyphenol compounds (e.g., oligomeric proanthocyanidins, quercetin, gallic acids, catechins). These compounds have complementarity with trans-resveratrol. We think it makes sense to use a full spectrum extract to capture these complementary activities.*


Neurohacker’s BioVin® Sourcing

BioVin® is a full spectrum French red grape extract. Made from grape juice, seeds, and skins of Vitis vinifera, whole red grapes.

Standardized to contain 5% trans-resveratrol and not less than 40% grape oligomeric proanthocyanidins.

BioVin® is from grapes responsibly grown and harvested in the Rhone Valley region of France.

BioVin® is non-GMO and vegan.

BioVin® Advanced is a registered trademark of Cyvex Nutrition, Inc dba Bioriginal.


BioVin® Formulating Principles and Rationale

When thinking about the serving of BioVin® there’s a few things to keep in mind. This grape extract has been standardized to contain 5% trans-resveratrol and not less than 40% oligomeric proanthocyanidins. The extract also has other compounds that naturally occur in grape juice, seeds, and skin. While trans-resveratrol may be part of the reason we use this extract, it’s the complementarity of all of grape’s phytonutrients that is the story. Focusing only on resveratrol misses the big picture. That said, we don’t view resveratrol as a more is better compound—some studies have used resveratrol alone in amounts as low as 10 mg [1–4]. So, resveratrol might be better thought of as a hormetic substance; something that in low to moderate amounts supports an adaptive response to stress (see Neurohacker Dosing Principles).* Our goal with BioVin®, as with all ingredient choices, is to select an appropriate serving in the context of other ingredient complementarities. Depending on the product, the amount of Biovin® included will supply 2.5-10 mg of resveratrol and 20-80 mg of grape oligomeric proanthocyanidins. To get this amount of resveratrol would require drinking somewhere between 1-30 liters of red wine (red wine can vary quite a bit in resveratrol content).


BioVin® Key Mechanisms 

Grape extract and proanthocyanidins

Supports mitochondrial structure and function*

Supports transcription factors associated with mitochondrial biogenesis (PGC-1α, NRF1, NRF2, TFAM)* [5–12]

Supports mitochondrial structure* [8]

Supports mitochondrial electron transport chain function* [13–18]

Supports the activities of TCA cycle enzymes* [17]

Supports β-oxidation* [15]

Supports the NAD+ pool* [19]


Supports brain function and cognition*

Supports cognitive function* [20–28]

Supports healthy sleep* [29]

Supports brain metabolism* [29]

Supports BDNF levels* [22,23,26,30–32]

Supports synaptic plasticity and long-term potentiation* [21,24,26,33] 

Supports neuroprotective functions* [24,27,28,34]

Supports neuronal mitochondrial function* [6,25]

Counters brain oxidative stress* [21,23,25,27,35] 


Supports a healthy mood and stress response*

Supports positive affect* [20,22,29,32]

Supports a calm mood* [20–23,25,29,35,36]

Influences stress hormone levels* [22,25,35]


Supports skin health* 

Influences melanin production* [37–39]

Supports healthy dermal ECM structure* [40,41] 

Supports skin Nrf2 signaling and phase II detox enzymes* [40]  

Supports healthy immune/cytokine signaling* [42] 

Supports skin in adapting to environmental stress* [40,42]


Supports a healthy gut microbiota*

Supports healthy gut microbiota* [43–48]

Supports gut barrier function* [47,49,50]

Counters gut oxidative stress* [50,51]


Promotes general health, healthy aging, and longevity* 

Supports maintenance of healthy vascular function and blood pressure* [29,52,52,53] Supports maintenance of muscle mass* [29]

Supports the insulin signaling pathway* [54]

Supports maintenance of healthy lipid metabolism* [13–15,54] 

Supports antioxidant defenses* [6–9,11,13,54]

Counters reactive oxygen species (ROS) levels and oxidative stress* [8,13,14,16,18,54]

Supports UCP1 and brown adipose tissue levels* [5]

Supports AMPK signaling* [7–9,11,15,54–56]

Supports SIRT1 levels* [6–9,19]

Counters mTOR signaling* [55]

Supports healthy circadian rhythms* [57,58]


Complementary ingredients*

Pomegranate fruit extract in supporting skin health* [59]


Resveratrol

Supports mitochondrial structure and function*

Supports healthy mitochondrial structure* [60–62]

Supports healthy mitochondrial function* [61,63,64]

Supports transcription factors associated with mitochondrial biogenesis (PGC-1α, NRF1, NRF2, TFAM)* [61–68]

Supports mitochondrial metabolic pathways of cell energy production* [61,63,65,67–69]

Supports NAD+ pool* [63,64,69]


Supports brain function*

Supports cognitive function in older adults* [70–78] 

Supports healthy cerebrovascular function* [70,77,79,80]

Supports neuroplasticity mechanisms* [81–83]

Supports brain-derived neurotrophic factor (BDNF) levels* [73–75,83–91]

Supports neuroendocrine signaling* [89,91]

Supports neuroprotective functions* [86,91–94]

Supports healthy neuroimmune and microglial function* [95–103]


Supports healthy immune function*

Supports innate immunity* [104–117]

Supports adaptive immunity* [117–123]

Supports immune signaling* [118,124–131]

Supports immune tolerance* [117–122,132–138]


Supports a healthy gut microbiota*

Supports healthy gut microbiota* [139–159]

Supports gut barrier function* [142]

Supports mucosal immunity* [160–162]

Supports healthy gut immune signaling* [145]


Supports skin health*

Supports healthy dermal ECM structure (collagen, elastin)* [40,163,164]  

Influences melanin production* [165–167]

Supports skin antioxidant defenses* [163,164,168,169] 

Supports skin Nrf2 signaling and phase II defenses* [40,168,170]  

Supports healthy skin immune signaling* [163,164,171]

Supports skin in adapting to environmental stress* [172–179]

Influences skin autophagy* [180]


Promotes healthy aging and longevity*

Supports Nrf2 signaling and antioxidant defenses* [94,181–192]

Supports stem cell function* [193–205]

Supports telomerase activity* [193–195,206,207]

Supports anti-senescence functions* [194,195,200,207]

Supports AMPK signaling* [2,62–65,67–69,208]

Supports SIRT1* [2,63,65,66,68,209–211]

Supports mitochondrial uncoupling and thermogenesis* [61,64]

Supports clock gene expression and circadian rhythms* [212–215]


Complementary ingredients*

Apigenin - resveratrol is an apigenin bioenhancer* [216]

Piperine as a bioenhancer [133,217–220] and for cognitive function* [221]

Hawthorn for heart function support* [222]


*These statements have not been evaluated by the Food and Drug Administration. This product is not intended to diagnose, treat, cure, or prevent any disease.


REFERENCES 

[1]K. Magyar, R. Halmosi, A. Palfi, G. Feher, L. Czopf, A. Fulop, I. Battyany, B. Sumegi, K. Toth, E. Szabados, Clin. Hemorheol. Microcirc. 50 (2012) 179–187.

[2]K.P. Goh, H.Y. Lee, D.P. Lau, W. Supaat, Y.H. Chan, A.F.Y. Koh, Int. J. Sport Nutr. Exerc. Metab. 24 (2014) 2–13.

[3]C.W. Zhu, H. Grossman, J. Neugroschl, S. Parker, A. Burden, X. Luo, M. Sano, Alzheimer’s & Dementia: Translational Research & Clinical Interventions 4 (2018) 609–616.

[4]W. Zhu, W. Qin, K. Zhang, G.E. Rottinghaus, Y.-C. Chen, B. Kliethermes, E.R. Sauter, Nutrition and Cancer 64 (2012) 393–400.

[5]C. Rodriguez Lanzi, D.J. Perdicaro, M.S. Landa, A. Fontana, A. Antoniolli, R.M. Miatello, P.I. Oteiza, M.A. Vazquez Prieto, J. Nutr. Biochem. 56 (2018) 224–233.

[6]H. Asseburg, C. Schäfer, M. Müller, S. Hagl, M. Pohland, D. Berressem, M. Borchiellini, C. Plank, G.P. Eckert, Neuromolecular Med. 18 (2016) 378–395.

[7]L. Bao, X. Cai, X. Dai, Y. Ding, Y. Jiang, Y. Li, Z. Zhang, Y. Li, Food Funct. 5 (2014) 1872–1880.

[8]X. Cai, L. Bao, J. Ren, Y. Li, Z. Zhang, Food Funct. 7 (2016) 805–815.

[9]L. Bao, X. Cai, Z. Zhang, Y. Li, Br. J. Nutr. 113 (2015) 35–44.

[10]I. Pokkunuri, Q. Ali, M. Asghar, Oxid. Med. Cell. Longev. 2016 (2016) 6135319.

[11]J. Lu, H. Jiang, B. Liu, R. Baiyun, S. Li, Y. Lv, D. Li, S. Qiao, X. Tan, Z. Zhang, Food Chem. Toxicol. 116 (2018) 59–69.

[12]S.G. Li, Y.S. Ding, Q. Niu, S.Z. Xu, L.J. Pang, R.L. Ma, M.X. Jing, G.L. Feng, J.M. Liu, S.X. Guo, Biomed. Environ. Sci. 28 (2015) 272–280.

[13]M. El Ayed, S. Kadri, M. Mabrouk, E. Aouani, S. Elkahoui, Lipids Health Dis. 17 (2018) 109.

[14]D. Leonetti, R. Soleti, N. Clere, L. Vergori, C. Jacques, L. Duluc, C. Dourguia, M.C. Martínez, R. Andriantsitohaina, Front. Pharmacol. 9 (2018) 406.

[15]M. Yin, P. Zhang, F. Yu, Z. Zhang, Q. Cai, W. Lu, B. Li, W. Qin, M. Cheng, H. Wang, H. Gao, Mol. Med. Rep. 16 (2017) 2844–2850.

[16]N.F.F. de Sales, L. Silva da Costa, T.I.A. Carneiro, D.A. Minuzzo, F.L. Oliveira, L.M.C. Cabral, A.G. Torres, T. El-Bacha, Molecules 23 (2018).

[17]S. Miltonprabu, Nazimabashir, V. Manoharan, Toxicol Rep 3 (2016) 63–77.

[18]J. Long, H. Gao, L. Sun, J. Liu, X. Zhao-Wilson, Rejuvenation Res. 12 (2009) 321–331.

[19]G. Aragonès, M. Suárez, A. Ardid-Ruiz, M. Vinaixa, M.A. Rodríguez, X. Correig, L. Arola, C. Bladé, Sci. Rep. 6 (2016) 24977.

[20]G. Calapai, F. Bonina, A. Bonina, L. Rizza, C. Mannucci, V. Arcoraci, G. Laganà, A. Alibrandi, C. Pollicino, S. Inferrera, U. Alecci, Front. Pharmacol. 8 (2017) 776.

[21]G. Patki, F.H. Allam, F. Atrooz, A.T. Dao, N. Solanki, G. Chugh, M. Asghar, F. Jafri, R. Bohat, K.A. Alkadhi, S. Salim, PLoS One 8 (2013) e74522.

[22]N. Solanki, I. Alkadhi, F. Atrooz, G. Patki, S. Salim, Nutr. Res. 35 (2015) 65–75.

[23]F. Allam, A.T. Dao, G. Chugh, R. Bohat, F. Jafri, G. Patki, C. Mowrey, M. Asghar, K.A. Alkadhi, S. Salim, J. Nutr. 143 (2013) 835–842.

[24]A. Sarkaki, M. Rafieirad, S.E. Hossini, Y. Farbood, F. Motamedi, S.M.T. Mansouri, B. Naghizadeh, Iran. J. Basic Med. Sci. 16 (2013) 1004–1010.

[25]N. Solanki, A. Salvi, G. Patki, S. Salim, Int. J. Neuropsychopharmacol. 20 (2017) 550–561.

[26]L. Ma, H. Xiao, J. Wen, Z. Liu, Y. He, F. Yuan, Lipids Health Dis. 17 (2018) 152.

[27]I.H. Borai, M.K. Ezz, M.Z. Rizk, H.F. Aly, M. El-Sherbiny, A.A. Matloub, G.I. Fouad, Biomed. Pharmacother. 93 (2017) 837–851.

[28]D. Rapaka, V.R. Bitra, T.C. Vishala, A. Akula, J. Ayurveda Integr. Med. 10 (2019) 241–247.

[29]M. Terauchi, N. Horiguchi, A. Kajiyama, M. Akiyoshi, Y. Owa, K. Kato, T. Kubota, Menopause 21 (2014) 990–996.

[30]C. Dani, A.C. Andreazza, C.A. Gonçalves, F. Kapizinski, J.A.P. Henriques, M. Salvador, An. Acad. Bras. Cienc. 89 (2017) 155–161.

[31]H. Liao, L.-M. Chou, Y.-W. Chien, C.-H. Wu, J.-S. Chang, C.-I. Lin, S.-H. Lin, J. Nutr. Biochem. 43 (2017) 132–140.

[32]C. Jiang, E. Sakakibara, W.-J. Lin, J. Wang, G.M. Pasinetti, S.R. Salton, Ann. N. Y. Acad. Sci. 1455 (2019) 196–205.

[33]J. Wang, C. Tang, M.G. Ferruzzi, B. Gong, B.J. Song, E.M. Janle, T.-Y. Chen, B. Cooper, M. Varghese, A. Cheng, D. Freire, A. Bilski, J. Roman, T. Nguyen, L. Ho, S.T. Talcott, J.E. Simon, Q. Wu, G.M. Pasinetti, Mol. Nutr. Food Res. 57 (2013) 2091–2102.

[34]K. Narita, M. Hisamoto, T. Okuda, S. Takeda, PLoS One 6 (2011) e14575.

[35]G. Patki, Q. Ali, I. Pokkunuri, M. Asghar, S. Salim, Nutr. Res. 35 (2015) 504–511.

[36]Z. Alrefaie, Int. J. Vitam. Nutr. Res. 85 (2015) 282–291.

[37]J. Yamakoshi, A. Sano, S. Tokutake, M. Saito, M. Kikuchi, Y. Kubota, Y. Kawachi, F. Otsuka, Phytother. Res. 18 (2004) 895–899.

[38]J. Yamakoshi, F. Otsuka, A. Sano, S. Tokutake, M. Saito, M. Kikuchi, Y. Kubota, Pigment Cell Res. 16 (2003) 629–638.

[39]Y.-S. Lin, H.-J. Chen, J.-P. Huang, P.-C. Lee, C.-R. Tsai, T.-F. Hsu, W.-Y. Huang, Biomed Res. Int. 2017 (2017) 5232680.

[40]J. Kim, J. Oh, J.N. Averilla, H.J. Kim, J.-S. Kim, J.-S. Kim, J. Food Sci. 84 (2019) 1600–1608.

[41]J. Wittenauer, S. Mäckle, D. Sußmann, U. Schweiggert-Weisz, R. Carle, Fitoterapia 101 (2015) 179–187.

[42]H.P. Decean, I.C. Brie, C.B. Tatomir, M. Perde-Schrepler, E. Fischer-Fodor, P. Virag, J. Environ. Pathol. Toxicol. Oncol. 37 (2018) 261–272.

[43]V. Nash, C.S. Ranadheera, E.N. Georgousopoulou, D.D. Mellor, D.B. Panagiotakos, A.J. McKune, J. Kellett, N. Naumovski, Food Res. Int. 113 (2018) 277–287.

[44]S. Chacar, M. Tarighi, N. Fares, J.-F. Faivre, N. Louka, R.G. Maroun, Antioxidants (Basel) 7 (2018).

[45]À. Casanova-Martí, J. Serrano, K.J. Portune, Y. Sanz, M.T. Blay, X. Terra, A. Ardévol, M. Pinent, Food Funct. 9 (2018) 1672–1682.

[46]S. Chacar, T. Itani, J. Hajal, Y. Saliba, N. Louka, J.-F. Faivre, R. Maroun, N. Fares, J. Food Sci. 83 (2018) 246–251.

[47]M. Van Hul, L. Geurts, H. Plovier, C. Druart, A. Everard, M. Ståhlman, M. Rhimi, K. Chira, P.-L. Teissedre, N.M. Delzenne, E. Maguin, A. Guilbot, A. Brochot, P. Gérard, F. Bäckhed, P.D. Cani, Am. J. Physiol. Endocrinol. Metab. 314 (2018) E334–E352.

[48]W. Liu, S. Zhao, J. Wang, J. Shi, Y. Sun, W. Wang, G. Ning, J. Hong, R. Liu, Mol. Nutr. Food Res. 61 (2017).

[49]K. Gil-Cardoso, I. Ginés, M. Pinent, A. Ardévol, M. Blay, X. Terra, J. Nutr. Biochem. 62 (2018) 35–42.

[50]K. Gil-Cardoso, I. Ginés, M. Pinent, A. Ardévol, L. Arola, M. Blay, X. Terra, Mol. Nutr. Food Res. 61 (2017).

[51]P. Kuhn, H.M. Kalariya, A. Poulev, D.M. Ribnicky, A. Jaja-Chimedza, D.E. Roopchand, I. Raskin, PLoS One 13 (2018) e0198716.

[52]J.-K. Kim, K.-A. Kim, H.-M. Choi, S.-K. Park, C.L. Stebbins, J. Med. Food 21 (2018) 445–453.

[53]F. Felice, Y. Zambito, G. Di Colo, C. D’Onofrio, C. Fausto, A. Balbarini, R. Di Stefano, Eur. J. Pharm. Biopharm. 80 (2012) 176–184.

[54]G.F. da Costa, I.B. Santos, G.F. de Bem, V.S.C. Cordeiro, C.A. da Costa, L.C.R.M. de Carvalho, D.T. Ognibene, A.C. Resende, R.S. de Moura, Phytother. Res. 31 (2017) 1621–1632.

[55]L. Castillo-Pichardo, S.F. Dharmawardhane, Nutr. Cancer 64 (2012) 1058–1069.

[56]E. Casanova, L. Baselga-Escudero, A. Ribas-Latre, L. Cedó, A. Arola-Arnal, M. Pinent, C. Bladé, L. Arola, M.J. Salvadó, J. Nutr. Biochem. 25 (2014) 1003–1010.

[57]A. Ribas-Latre, L. Baselga-Escudero, E. Casanova, A. Arola-Arnal, M.-J. Salvadó, C. Bladé, L. Arola, Sci. Rep. 5 (2015) 10954.

[58]A. Ribas-Latre, J.M. Del Bas, L. Baselga-Escudero, E. Casanova, A. Arola-Arnal, M.-J. Salvadó, L. Arola, C. Bladé, Mol. Nutr. Food Res. 59 (2015) 865–878.

[59]D. Buonocore, A. Lazzeretti, P. Tocabens, V. Nobile, E. Cestone, G. Santin, M.G. Bottone, F. Marzatico, Clin. Cosmet. Investig. Dermatol. 5 (2012) 159–165.

[60]R.M. Pollack, N. Barzilai, V. Anghel, A.S. Kulkarni, A. Golden, P. O’Broin, D.A. Sinclair, M.S. Bonkowski, A.J. Coleville, D. Powell, S. Kim, R. Moaddel, D. Stein, K. Zhang, M. Hawkins, J.P. Crandall, J. Gerontol. A Biol. Sci. Med. Sci. 72 (2017) 1703–1709.

[61]M. Lagouge, C. Argmann, Z. Gerhart-Hines, H. Meziane, C. Lerin, F. Daussin, N. Messadeq, J. Milne, P. Lambert, P. Elliott, B. Geny, M. Laakso, P. Puigserver, J. Auwerx, Cell 127 (2006) 1109–1122.

[62]J.A. Baur, K.J. Pearson, N.L. Price, H.A. Jamieson, C. Lerin, A. Kalra, V.V. Prabhu, J.S. Allard, G. Lopez-Lluch, K. Lewis, P.J. Pistell, S. Poosala, K.G. Becker, O. Boss, D. Gwinn, M. Wang, S. Ramaswamy, K.W. Fishbein, R.G. Spencer, E.G. Lakatta, D. Le Couteur, R.J. Shaw, P. Navas, P. Puigserver, D.K. Ingram, R. de Cabo, D.A. Sinclair, Nature 444 (2006) 337–342.

[63]N.L. Price, A.P. Gomes, A.J.Y. Ling, F.V. Duarte, A. Martin-Montalvo, B.J. North, B. Agarwal, L. Ye, G. Ramadori, J.S. Teodoro, B.P. Hubbard, A.T. Varela, J.G. Davis, B. Varamini, A. Hafner, R. Moaddel, A.P. Rolo, R. Coppari, C.M. Palmeira, R. de Cabo, J.A. Baur, D.A. Sinclair, Cell Metab. 15 (2012) 675–690.

[64]J.-H. Um, S.-J. Park, H. Kang, S. Yang, M. Foretz, M.W. McBurney, M.K. Kim, B. Viollet, J.H. Chung, Diabetes 59 (2010) 554–563.

[65]S. Timmers, E. Konings, L. Bilet, R.H. Houtkooper, T. van de Weijer, G.H. Goossens, J. Hoeks, S. van der Krieken, D. Ryu, S. Kersten, E. Moonen-Kornips, M.K.C. Hesselink, I. Kunz, V.B. Schrauwen-Hinderling, E. Blaak, J. Auwerx, P. Schrauwen, Cell Metab. 14 (2011) 612–622.

[66]T.D. Scribbans, J.K. Ma, B.A. Edgett, K.A. Vorobej, A.S. Mitchell, J.G.E. Zelt, C.A. Simpson, J. Quadrilatero, B.J. Gurd, Appl. Physiol. Nutr. Metab. 39 (2014) 1305–1313.

[67]B. Dasgupta, J. Milbrandt, Proc. Natl. Acad. Sci. U. S. A. 104 (2007) 7217–7222.

[68]J.M. Ajmo, X. Liang, C.Q. Rogers, B. Pennock, M. You, Am. J. Physiol. Gastrointest. Liver Physiol. 295 (2008) G833–42.

[69]S.-J. Park, F. Ahmad, A. Philp, K. Baar, T. Williams, H. Luo, H. Ke, H. Rehmann, R. Taussig, A.L. Brown, M.K. Kim, M.A. Beaven, A.B. Burgin, V. Manganiello, J.H. Chung, Cell 148 (2012) 421–433.

[70]R.H.X. Wong, D. Raederstorff, P.R.C. Howe, Nutrients 8 (2016).

[71]S.D. Anton, N. Ebner, J.M. Dzierzewski, Z.Z. Zlatar, M.J. Gurka, V.M. Dotson, J. Kirton, R.T. Mankowski, M. Marsiske, T.M. Manini, J. Altern. Complement. Med. 24 (2018) 725–732.

[72]Y. Yazir, T. Utkan, N. Gacar, F. Aricioglu, Physiol. Behav. 138 (2015) 297–304.

[73]J.-F. Ge, Y.-Y. Xu, N. Li, Y. Zhang, G.-L. Qiu, C.-H. Chu, C.-Y. Wang, G. Qin, F.-H. Chen, Endocrine Journal 62 (2015) 927–938.

[74]Y.-N. Zhao, W.-F. Li, F. Li, Z. Zhang, Y.-D. Dai, A.-L. Xu, C. Qi, J.-M. Gao, J. Gao, Biochem. Biophys. Res. Commun. 435 (2013) 597–602.

[75]J. Shen, L. Xu, C. Qu, H. Sun, J. Zhang, Behav. Brain Res. 349 (2018) 1–7.

[76]J.J. Thaung Zaw, P.R. Howe, R.H. Wong, Clin. Nutr. 40 (2021) 820–829.

[77]H.M. Evans, P.R.C. Howe, R.H.X. Wong, Nutrients 9 (2017).

[78]A.V. Witte, L. Kerti, D.S. Margulies, A. Flöel, J. Neurosci. 34 (2014) 7862–7870.

[79]D.O. Kennedy, E.L. Wightman, J.L. Reay, G. Lietz, E.J. Okello, A. Wilde, C.F. Haskell, Am. J. Clin. Nutr. 91 (2010) 1590–1597.

[80]E.L. Wightman, C.F. Haskell-Ramsay, J.L. Reay, G. Williamson, T. Dew, W. Zhang, D.O. Kennedy, Br. J. Nutr. 114 (2015) 1427–1437.

[81]L. Xu, Y. Yang, L. Gao, J. Zhao, Y. Cai, J. Huang, S. Jing, X. Bao, Y. Wang, J. Gao, H. Xu, X. Fan, Biochim. Biophys. Acta 1852 (2015) 1298–1310.

[82]N.B. Bottari, M.R.C. Schetinger, M.M. Pillat, T.V. Palma, H. Ulrich, M.S. Alves, V.M. Morsch, C. Melazzo, L.D. de Barros, J.L. Garcia, A.S. Da Silva, Mol. Neurobiol. 56 (2019) 2328–2338.

[83]S. Madhyastha, S. Sekhar, G. Rao, Int. J. Dev. Neurosci. 31 (2013) 580–585.

[84]M. Wiciński, M. Socha, M. Walczak, E. Wódkiewicz, B. Malinowski, S. Rewerski, K. Górski, K. Pawlak-Osińska, Nutrients 10 (2018).

[85]M. Rahvar, M. Nikseresht, S.M. Shafiee, F. Naghibalhossaini, M. Rasti, M.R. Panjehshahin, A.A. Owji, Neurochem. Res. 36 (2011) 761–765.

[86]L. Ge, L. Liu, H. Liu, S. Liu, H. Xue, X. Wang, L. Yuan, Z. Wang, D. Liu, Eur. J. Pharmacol. 768 (2015) 49–57.

[87]G. Li, G. Wang, J. Shi, X. Xie, N. Fei, L. Chen, N. Liu, M. Yang, J. Pan, W. Huang, Y. Xu, Neuropharmacology 133 (2018) 181–188.

[88]X.-H. Yang, S.-Q. Song, Y. Xu, Neuropsychiatr. Dis. Treat. 13 (2017) 2727–2736.

[89]S.H. Ali, R.M. Madhana, A. K V., E.R. Kasala, L.N. Bodduluru, S. Pitta, J.R. Mahareddy, M. Lahkar, Steroids 101 (2015) 37–42.

[90]J. Song, S.Y. Cheon, W. Jung, W.T. Lee, J.E. Lee, Int. J. Mol. Sci. 15 (2014) 15512–15529.

[91]C. Pang, L. Cao, F. Wu, L. Wang, G. Wang, Y. Yu, M. Zhang, L. Chen, W. Wang, W. Lv, L. Chen, J. Zhu, J. Pan, H. Zhang, Y. Xu, L. Ding, Neuropharmacology 97 (2015) 447–456.

[92]G. Wang, L. Chen, X. Pan, J. Chen, L. Wang, W. Wang, R. Cheng, F. Wu, X. Feng, Y. Yu, H.-T. Zhang, J.M. O’Donnell, Y. Xu, Oncotarget 7 (2016).

[93]Q. Zhang, X. Wang, X. Bai, Y. Xie, T. Zhang, S. Bo, X. Chen, Mol. Med. Rep. 16 (2017) 2095–2100.

[94]R. Moldzio, K. Radad, C. Krewenka, B. Kranner, J.C. Duvigneau, W.-D. Rausch, J. Neural Transm. 120 (2013) 1271–1280.

[95]S. Ma, L. Fan, J. Li, B. Zhang, Z. Yan, Int. J. Neurosci. 130 (2020) 817–825.

[96]L. Feng, L. Zhang, DNA Cell Biol. 38 (2019) 874–879.

[97]B. Qi, C. Shi, J. Meng, S. Xu, J. Liu, Int. J. Biochem. Cell Biol. 103 (2018) 56–64.

[98]J. Wiedemann, K. Rashid, T. Langmann, Biochem. Biophys. Res. Commun. 501 (2018) 239–245.

[99]X. Zhang, Q. Wu, Q. Zhang, Y. Lu, J. Liu, W. Li, S. Lv, M. Zhou, X. Zhang, C. Hang, Front. Neurosci. 11 (2017) 611.

[100]L.-L. Wang, D.-L. Shi, H.-Y. Gu, M.-Z. Zheng, J. Hu, X.-H. Song, Y.-L. Shen, Y.-Y. Chen, Mol. Med. Rep. 13 (2016) 4051–4057.

[101]L. Tao, Q. Ding, C. Gao, X. Sun, Int. Immunopharmacol. 34 (2016) 165–172.

[102]M. Kodali, V.K. Parihar, B. Hattiangady, V. Mishra, B. Shuai, A.K. Shetty, Sci. Rep. 5 (2015) 8075.

[103]J. Abraham, R.W. Johnson, Rejuvenation Res. 12 (2009) 445–453.

[104]J. Li, B. Wang, Y. Luo, Q. Zhang, Y. Bian, R. Wang, Mol. Immunol. 122 (2020) 156–162.

[105]Y.-F. Zhang, Q.-M. Liu, Y.-Y. Gao, B. Liu, H. Liu, M.-J. Cao, X.-W. Yang, G.-M. Liu, Food Funct. 10 (2019) 2030–2039.

[106]S.-Y. Han, J.-Y. Bae, S.-H. Park, Y.-H. Kim, J.H.Y. Park, Y.-H. Kang, J. Nutr. 143 (2013) 632–639.

[107]D.M. André, M.C. Calixto, C. Sollon, E.C. Alexandre, L.O. Leiria, N. Tobar, G.F. Anhê, E. Antunes, Int. Immunopharmacol. 38 (2016) 298–305.

[108]K. Bozdemir, E. Şahin, N. Altintoprak, N.B. Muluk, B.P. Cengiz, M. Acar, C. Cingi, Clin. Invest. Med. 39 (2016) E63–72.

[109]J. Chen, H. Zhou, J. Wang, B. Zhang, F. Liu, J. Huang, J. Li, J. Lin, J. Bai, R. Liu, Int. Immunopharmacol. 25 (2015) 43–48.

[110]Y. Nakagami, S. Suzuki, J.L. Espinoza, L. Vu Quang, M. Enomoto, S. Takasugi, A. Nakamura, T. Nakayama, H. Tani, I. Hanamura, A. Takami, Nutrients 11 (2019).

[111]S. Liu, Y. Du, K. Shi, Y. Yang, Z. Yang, Am. J. Transl. Res. 11 (2019) 5212–5226.

[112]C. Leischner, M. Burkard, M.M. Pfeiffer, U.M. Lauer, C. Busch, S. Venturelli, Nutr. J. 15 (2016) 47.

[113]Q. Li, T. Huyan, L.-J. Ye, J. Li, J.-L. Shi, Q.-S. Huang, J. Agric. Food Chem. 62 (2014) 10928–10935.

[114]T. Li, G.-X. Fan, W. Wang, T. Li, Y.-K. Yuan, Int. Immunopharmacol. 7 (2007) 1221–1231.

[115]R. Falchetti, M.P. Fuggetta, G. Lanzilli, M. Tricarico, G. Ravagnan, Life Sci. 70 (2001) 81–96.

[116]T.-H. Huang, C.-C. Chen, H.-M. Liu, T.-Y. Lee, S.-H. Shieh, Sci. Rep. 7 (2017) 2705.

[117]M. Shabani, A. Sadeghi, H. Hosseini, M. Teimouri, R. Babaei Khorzoughi, P. Pasalar, R. Meshkani, Sci. Rep. 10 (2020) 3791.

[118]J.L. Espinoza, L.Q. Trung, P.T. Inaoka, K. Yamada, D.T. An, S. Mizuno, S. Nakao, A. Takami, Oxid. Med. Cell. Longev. 2017 (2017) 6781872.

[119]N.-H. Guo, X. Fu, F.-M. Zi, Y. Song, S. Wang, J. Cheng, Int. Immunopharmacol. 73 (2019) 181–192.

[120]B.B.-C. Weng, W.-S. Lin, J.-C. Chang, R.Y.-Y. Chiou, Int. J. Mol. Med. 38 (2016) 1895–1904.

[121]H. Yang, A. Zhang, Y. Zhang, S. Ma, C. Wang, J. Stroke Cerebrovasc. Dis. 25 (2016) 1914–1921.

[122]J. Yao, C. Wei, J.-Y. Wang, R. Zhang, Y.-X. Li, L.-S. Wang, World J. Gastroenterol. 21 (2015) 6572–6581.

[123]J. Yuan, L. Lu, Z. Zhang, S. Zhang, Rejuvenation Res. 15 (2012) 507–515.

[124]H. Ghanim, C.L. Sia, S. Abuaysheh, K. Korzeniewski, P. Patnaik, A. Marumganti, A. Chaudhuri, P. Dandona, J. Clin. Endocrinol. Metab. 95 (2010) E1–8.

[125]J. Tomé-Carneiro, M. Gonzálvez, M. Larrosa, M.J. Yáñez-Gascón, F.J. García-Almagro, J.A. Ruiz-Ros, M.T. García-Conesa, F.A. Tomás-Barberán, J.C. Espín, Am. J. Cardiol. 110 (2012) 356–363.

[126]R.C.S. Macedo, A. Vieira, D.P. Marin, R. Otton, Chem. Biol. Interact. 227 (2015) 89–95.

[127]H.S. Zahedi, S. Jazayeri, R. Ghiasvand, M. Djalali, M.R. Eshraghian, Int. J. Prev. Med. 4 (2013) S1–4.

[128]E. Jo, R. Bartosh, A.T. Auslander, D. Directo, A. Osmond, M.W. Wong, Sports (Basel) 7 (2019).

[129]S. Bo, V. Ponzo, G. Ciccone, A. Evangelista, F. Saba, I. Goitre, M. Procopio, G.F. Pagano, M. Cassader, R. Gambino, Pharmacol. Res. 111 (2016) 896–905.

[130]A.Z. Javid, R. Hormoznejad, H.A. Yousefimanesh, M.H. Haghighi-Zadeh, M. Zakerkish, Diabetes Metab. Syndr. 13 (2019) 2769–2774.

[131]S. Bo, G. Ciccone, A. Castiglione, R. Gambino, F. De Michieli, P. Villois, M. Durazzo, P. Cavallo-Perin, M. Cassader, Curr. Med. Chem. 20 (2013) 1323–1331.

[132]A.L. de B. Oliveira, V.V.S. Monteiro, K.C. Navegantes-Lima, J.F. Reis, R. de S. Gomes, D.V.S. Rodrigues, S.L. de F. Gaspar, M.C. Monteiro, Nutrients 9 (2017).

[133]N. Pannu, A. Bhatnagar, Inflammopharmacology 28 (2020) 719–735.

[134]K.A.O. Gandy, J. Zhang, P. Nagarkatti, M. Nagarkatti, J. Neuroimmune Pharmacol. 14 (2019) 462–477.

[135]Z.-L. Wang, X.-F. Luo, M.-T. Li, D. Xu, S. Zhou, H.-Z. Chen, N. Gao, Z. Chen, L.-L. Zhang, X.-F. Zeng, PLoS One 9 (2014) e114792.

[136]Z. Fonseca-Kelly, M. Nassrallah, J. Uribe, R.S. Khan, K. Dine, M. Dutt, K.S. Shindler, Front. Neurol. 3 (2012) 84.

[137]K.S. Shindler, E. Ventura, M. Dutt, P. Elliott, D.C. Fitzgerald, A. Rostami, J. Neuroophthalmol. 30 (2010) 328–339.

[138]Z. Wenbin, G. Guojun, West Indian Med. J. 63 (2014) 20–25.

[139]Y.-L. Tain, W.-C. Lee, K.L.H. Wu, S. Leu, J.Y.H. Chan, Mol. Nutr. Food Res. (2018) e1800066.

[140]Y. Zheng, W. Wu, G. Hu, L. Qiu, S. Meng, C. Song, L. Fan, Z. Zhao, X. Bing, J. Chen, Fish Shellfish Immunol. 77 (2018) 200–207.

[141]L. Zhao, Q. Zhang, W. Ma, F. Tian, H. Shen, M. Zhou, Food Funct. 8 (2017) 4644–4656.

[142]J.K. Bird, D. Raederstorff, P. Weber, R.E. Steinert, Adv. Nutr. 8 (2017) 839–849.

[143]A.S. Korsholm, T.N. Kjær, M.J. Ornstrup, S.B. Pedersen, Int. J. Mol. Sci. 18 (2017).

[144]M.M. Sung, T.T. Kim, E. Denou, C.-L.M. Soltys, S.M. Hamza, N.J. Byrne, G. Masson, H. Park, D.S. Wishart, K.L. Madsen, J.D. Schertzer, J.R.B. Dyck, Diabetes 66 (2017) 418–425.

[145]M. Larrosa, M.J. Yañéz-Gascón, M.V. Selma, A. González-Sarrías, S. Toti, J.J. Cerón, F. Tomás-Barberán, P. Dolara, J.C. Espín, J. Agric. Food Chem. 57 (2009) 2211–2220.

[146]J.M. Walker, P. Eckardt, J.O. Aleman, J.C. da Rosa, Y. Liang, T. Iizumi, S. Etheve, M.J. Blaser, J. L Breslow, P.R. Holt, Transl. Res. 4 (2019) 122–135.

[147]P. Wang, J. Wang, D. Li, W. Ke, F. Chen, X. Hu, J. Nutr. Biochem. 81 (2020) 108363.

[148]H.R. Alrafas, P.B. Busbee, K.N. Chitrala, M. Nagarkatti, P. Nagarkatti, J. Clin. Med. Res. 9 (2020).

[149]K. Chen, H. Zhao, L. Shu, H. Xing, C. Wang, C. Lu, G. Song, Int. J. Food Sci. Nutr. (2020) 1–14.

[150]P. Wang, J. Gao, W. Ke, J. Wang, D. Li, R. Liu, Y. Jia, X. Wang, X. Chen, F. Chen, X. Hu, Free Radic. Biol. Med. 156 (2020) 83–98.

[151]S. Hui, Y. Liu, L. Huang, L. Zheng, M. Zhou, H. Lang, X. Wang, L. Yi, M. Mi, Int. J. Obes. 44 (2020) 1678–1690.

[152]Y. Ma, S. Liu, H. Shu, J. Crawford, Y. Xing, F. Tao, Brain Behav. Immun. 87 (2020) 455–464.

[153]F. Li, Y. Han, X. Cai, M. Gu, J. Sun, C. Qi, T. Goulette, M. Song, Z. Li, H. Xiao, Food Funct. 11 (2020) 1063–1073.

[154]N. Sreng, S. Champion, J.-C. Martin, S. Khelaifia, J.E. Christensen, R. Padmanabhan, V. Azalbert, V. Blasco-Baque, P. Loubieres, L. Pechere, J.-F. Landrier, R. Burcelin, E. Sérée, J. Nutr. Biochem. 72 (2019) 108218.

[155]H.R. Alrafas, P.B. Busbee, M. Nagarkatti, P.S. Nagarkatti, J. Leukoc. Biol. 106 (2019) 467–480.

[156]J.D. Jaimes, V. Jarosova, O. Vesely, C. Mekadim, J. Mrazek, P. Marsik, J. Killer, K. Smejkal, P. Kloucek, J. Havlik, Molecules 24 (2019).

[157]P. Wang, D. Li, W. Ke, D. Liang, X. Hu, F. Chen, Int. J. Obes. 44 (2020) 213–225.

[158]C.L. Campbell, R. Yu, F. Li, Q. Zhou, D. Chen, C. Qi, Y. Yin, J. Sun, Diabetes Metab. Syndr. Obes. 12 (2019) 97–107.

[159]W. Liao, X. Yin, Q. Li, H. Zhang, Z. Liu, X. Zheng, L. Zheng, X. Feng, Molecules 23 (2018).

[160]Z. Gan, W. Wei, Y. Li, J. Wu, Y. Zhao, L. Zhang, T. Wang, X. Zhong, Molecules 24 (2019).

[161]J. Al Azzaz, A. Rieu, V. Aires, D. Delmas, J. Chluba, P. Winckler, M.-A. Bringer, J. Lamarche, D. Vervandier-Fasseur, F. Dalle, P. Lapaquette, J. Guzzo, Front. Immunol. 9 (2018) 3149.

[162]Y. Mayangsari, T. Suzuki, J. Agric. Food Chem. 66 (2018) 12666–12674.

[163]E.D. Lephart, M.B. Andrus, Exp. Biol. Med. 242 (2017) 1482–1489.

[164]E.D. Lephart, J.M. Sommerfeldt, M.B. Andrus, J. Funct. Foods 10 (2014) 377–384.

[165]T.H. Lee, J.O. Seo, S.-H. Baek, S.Y. Kim, Biomol. Ther. 22 (2014) 35–40.

[166]Q. Liu, C. Kim, Y.H. Jo, S.B. Kim, B.Y. Hwang, M.K. Lee, Molecules 20 (2015) 16933–16945.

[167]R.A. Newton, A.L. Cook, D.W. Roberts, J.H. Leonard, R.A. Sturm, J. Invest. Dermatol. 127 (2007) 2216–2227.

[168]J. Soeur, J. Eilstein, G. Léreaux, C. Jones, L. Marrot, Free Radic. Biol. Med. 78 (2015) 213–223.

[169]Y. Ido, A. Duranton, F. Lan, K.A. Weikel, L. Breton, N.B. Ruderman, PLoS One 10 (2015) e0115341.

[170]Y. Liu, F. Chan, H. Sun, J. Yan, D. Fan, D. Zhao, J. An, D. Zhou, Eur. J. Pharmacol. 650 (2011) 130–137.

[171]X. Zhu, Q. Liu, M. Wang, M. Liang, X. Yang, X. Xu, H. Zou, J. Qiu, PLoS One 6 (2011) e27081.

[172]K. Park, J.-H. Lee, Oncol. Rep. 19 (2008) 413–417.

[173]F. Zhou, X. Huang, Y. Pan, D. Cao, C. Liu, Y. Liu, A. Chen, Biochem. Biophys. Res. Commun. 499 (2018) 662–668.

[174]S. Reagan-Shaw, F. Afaq, M.H. Aziz, N. Ahmad, Oncogene 23 (2004) 5151–5160.

[175]M.A. Choi, J.K. Seok, J.W. Lee, S.Y. Lee, Y.M. Kim, Y.C. Boo, J. Soc. Cosmet. Sci. Korea 44 (2018) 249–258.

[176]M.-H. Tsai, L.-F. Hsu, C.-W. Lee, Y.-C. Chiang, M.-H. Lee, J.-M. How, C.-M. Wu, C.-L. Huang, I.-T. Lee, Int. J. Biochem. Cell Biol. 88 (2017) 113–123.

[177]J.-W. Shin, H.-S. Lee, J.-I. Na, C.-H. Huh, K.-C. Park, H.-R. Choi, Int. J. Mol. Sci. 21 (2020).

[178]C. Sticozzi, G. Belmonte, F. Cervellati, X.M. Muresan, F. Pessina, Y. Lim, H.J. Forman, G. Valacchi, Free Radic. Biol. Med. 69 (2014) 50–57.

[179]C. Sticozzi, F. Cervellati, X.M. Muresan, C. Cervellati, G. Valacchi, Food Funct. 5 (2014) 2348–2356.

[180]D.K. Mostafa, S.I. Omar, A.A. Abdellatif, O.A. Sorour, O.A. Nayel, M.R.A. Al Obaidi, Curr. Mol. Pharmacol. (2020).

[181]S. Seyyedebrahimi, H. Khodabandehloo, E. Nasli Esfahani, R. Meshkani, Acta Diabetol. 55 (2018) 341–353.

[182]T. Farkhondeh, S.L. Folgado, A.M. Pourbagher-Shahri, M. Ashrafizadeh, S. Samarghandian, Biomed. Pharmacother. 127 (2020) 110234.

[183]X. Wang, H. Fang, G. Xu, Y. Yang, R. Xu, Q. Liu, X. Xue, J. Liu, H. Wang, Diabetes Metab. Syndr. Obes. 13 (2020) 1061–1075.

[184]M. Sami-Ur-Rasheed, M.K. Tripathi, D.K. Patel, M.P. Singh, Protein Pept. Lett. (2020).

[185]H. Hosseini, M. Teimouri, M. Shabani, M. Koushki, R. Babaei Khorzoughi, F. Namvarjah, P. Izadi, R. Meshkani, Int. J. Biochem. Cell Biol. 119 (2020) 105667.

[186]N. Lian, S. Zhang, J. Huang, T. Lin, Q. Lin, Lung 198 (2020) 323–331.

[187]G. Wang, X. Xie, L. Yuan, J. Qiu, W. Duan, B. Xu, X. Chen, Biofactors 46 (2020) 441–453.

[188]A.A. Javkhedkar, Y. Quiroz, B. Rodriguez-Iturbe, N.D. Vaziri, M.F. Lokhandwala, A.A. Banday, Am. J. Physiol. Regul. Integr. Comp. Physiol. 308 (2015) R840–6.

[189]B. Wang, J. Sun, L. Li, J. Zheng, Y. Shi, G. Le, Food Funct. 5 (2014) 1452–1463.

[190]P. Brasnyó, G.A. Molnár, M. Mohás, L. Markó, B. Laczy, J. Cseh, E. Mikolás, I.A. Szijártó, A. Mérei, R. Halmai, L.G. Mészáros, B. Sümegi, I. Wittmann, Br. J. Nutr. 106 (2011) 383–389.

[191]Y.K. Gupta, S. Briyal, G. Chaudhary, Pharmacol. Biochem. Behav. 71 (2002) 245–249.

[192]S.S. Leonard, C. Xia, B.-H. Jiang, B. Stinefelt, H. Klandorf, G.K. Harris, X. Shi, Biochem. Biophys. Res. Commun. 309 (2003) 1017–1026.

[193]V.P. Pearce, J. Sherrell, Z. Lou, L. Kopelovich, W.E. Wright, J.W. Shay, Oncogene 27 (2008) 2365–2374.

[194]L. Xia, X.X. Wang, X.S. Hu, X.G. Guo, Y.P. Shang, H.J. Chen, C.L. Zeng, F.R. Zhang, J.Z. Chen, Br. J. Pharmacol. 155 (2008) 387–394.

[195]X.-B. Wang, L. Zhu, J. Huang, Y.-G. Yin, X.-Q. Kong, Q.-F. Rong, A.-W. Shi, K.-J. Cao, Chin. Med. J. 124 (2011) 4310–4315.

[196]M.L. Balestrieri, C. Schiano, F. Felice, A. Casamassimi, A. Balestrieri, L. Milone, L. Servillo, C. Napoli, J. Biochem. 143 (2008) 179–186.

[197]L. Ling, S. Gu, Y. Cheng, Mol. Med. Rep. 15 (2017) 1188–1194.

[198]X.-H. Chen, Z.-G. Shi, H.-B. Lin, F. Wu, F. Zheng, C.-F. Wu, M.-W. Huang, Eur. Rev. Med. Pharmacol. Sci. 23 (2019) 6352–6359.

[199]H. Zhang, Z. Zhai, Y. Wang, J. Zhang, H. Wu, Y. Wang, C. Li, D. Li, L. Lu, X. Wang, J. Chang, Q. Hou, Z. Ju, D. Zhou, A. Meng, Free Radic. Biol. Med. 54 (2013) 40–50.

[200]Y.-J. Lv, Y. Yang, B.-D. Sui, C.-H. Hu, P. Zhao, L. Liao, J. Chen, L.-Q. Zhang, T.-T. Yang, S.-F. Zhang, Y. Jin, Theranostics 8 (2018) 2387–2406.

[201]H. Liu, S. Zhang, L. Zhao, Y. Zhang, Q. Li, X. Chai, Y. Zhang, Stem Cells Int. 2016 (2016) 2524092.

[202]I.I. Suvorova, A.R. Knyazeva, A.V. Petukhov, N.D. Aksenov, V.A. Pospelov, Cell Death Discov 5 (2019) 61.

[203]Y.-J. Wang, P. Zhao, B.-D. Sui, N. Liu, C.-H. Hu, J. Chen, C.-X. Zheng, A.-Q. Liu, K. Xuan, Y.-P. Pan, Y. Jin, Exp. Mol. Med. 50 (2018) 1–15.

[204]T.-S. Chen, C.-H. Kuo, C.H. Day, L.-F. Pan, R.-J. Chen, B.-C. Chen, V.V. Padma, Y.-M. Lin, C.-Y. Huang, J. Cell. Physiol. 234 (2019) 20443–20452.

[205]Z. Safaeinejad, M. Nabiuni, M. Peymani, K. Ghaedi, M.H. Nasr-Esfahani, H. Baharvand, Eur. J. Cell Biol. 96 (2017) 665–672.

[206]F. Uchiumi, T. Watanabe, S. Hasegawa, T. Hoshi, Y. Higami, S.-I. Tanuma, Curr. Aging Sci. 4 (2011) 1–7.

[207]J. Li, C.-X. Zhang, Y.-M. Liu, K.-L. Chen, G. Chen, Oncotarget 8 (2017) 65717–65729.

[208]C.E. Park, M.-J. Kim, J.H. Lee, B.-I. Min, H. Bae, W. Choe, S.-S. Kim, J. Ha, Exp. Mol. Med. 39 (2007) 222–229.

[209]P. Zhang, Y. Li, Y. Du, G. Li, L. Wang, F. Zhou, Transplant. Proc. 48 (2016) 3378–3386.

[210]K.T. Howitz, K.J. Bitterman, H.Y. Cohen, D.W. Lamming, S. Lavu, J.G. Wood, R.E. Zipkin, P. Chung, A. Kisielewski, L.-L. Zhang, B. Scherer, D.A. Sinclair, Nature 425 (2003) 191–196.

[211]S.-C. Hsu, S.-M. Huang, A. Chen, C.-Y. Sun, S.-H. Lin, J.-S. Chen, S.-T. Liu, Y.-J. Hsu, Int. J. Biochem. Cell Biol. 53 (2014) 361–371.

[212]J. Miranda, M.P. Portillo, J.A. Madrid, N. Arias, M.T. Macarulla, M. Garaulet, Br. J. Nutr. 110 (2013) 1421–1428.

[213]F. Pifferi, A. Dal-Pan, S. Languille, F. Aujard, Oxid. Med. Cell. Longev. 2013 (2013) 187301.

[214]J.R. Leheste, G. Torres, Front. Mol. Neurosci. 8 (2015) 61.

[215]L. Sun, Y. Wang, Y. Song, X.-R. Cheng, S. Xia, M.R.T. Rahman, Y. Shi, G. Le, Biochem. Biophys. Res. Commun. 458 (2015) 86–91.

[216]J.-A. Lee, S.K. Ha, E. Cho, I. Choi, Nutrients 7 (2015) 9650–9661.

[217]J.J. Johnson, M. Nihal, I.A. Siddiqui, C.O. Scarlett, H.H. Bailey, H. Mukhtar, N. Ahmad, Mol. Nutr. Food Res. 55 (2011) 1169–1176.

[218]K.R. Polley, N. Jenkins, P. O’Connor, K. McCully, Appl. Physiol. Nutr. Metab. 41 (2016) 26–32.

[219]W. Huang, Z. Chen, Q. Wang, M. Lin, S. Wu, Q. Yan, F. Wu, X. Yu, X. Xie, G. Li, Y. Xu, J. Pan, Metab. Brain Dis. 28 (2013) 585–595.

[220]Y. Xu, C. Zhang, F. Wu, X. Xu, G. Wang, M. Lin, Y. Yu, Y. An, J. Pan, Metab. Brain Dis. 31 (2016) 837–848.

[221]E.L. Wightman, J.L. Reay, C.F. Haskell, G. Williamson, T.P. Dew, D.O. Kennedy, Br. J. Nutr. 112 (2014) 203–213.

[222]Y. Zhu, B. Feng, S. He, Z. Su, G. Zheng, Phytomedicine 40 (2018) 20–26.