Research Article
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Year 2023, , 220 - 233, 29.03.2023
https://doi.org/10.59313/jsr-a.1232251

Abstract

References

  • [1] WHO, (2018), Global Status Report on Alcohol and Health; World Health Organization: Geneva, Switzerland.
  • [2] Yuan, R., Tao, X., Liang, S., Pan, Y., He, L., Sun, J., Wenbo, J., Li, X., Chen, J. and Wang, C., (2018), Protective effect of acidic polysaccharide from Schisandra chinensis on acute ethanol-induced liver injury through reducing CYP2E1-dependent oxidative stress, Biomed Pharmacother, 99, 537-542.
  • [3] Qiao, J.Y., Li, H.W., Liu, F.G., Li, Y.C., Tian, S., Cao, L.H., Hu, K., Wu, X.X. and Miao, M.S., (2019), Effects of Portulaca Oleracea Extract on Acute Alcoholic Liver Injury of Rats, Molecules, 24(16), 2887.
  • [4] Pronko, P., Bardina, L., Satanovskaya, V., Kuzmich, A. and Zimatkin, S., (2002), Effect of chronic alcohol consumption on the ethanol-and acetaldehyde-metabolizing systems in the rat gastrointestinal tract, Alcohol and Alcoholism, 37(3), 229-235.
  • [5] Bode, C. and Bode, J.C., (2003), Effect of alcohol consumption on the gut, Best practice & research Clinical gastroenterology, 17(4), 575-592.
  • [6] Day, C.R. and Kempson, S.A., (2016), Betaine chemistry, roles, and potential use in liver disease, Biochimica et Biophysica Acta (BBA)-General Subjects, 1860(6), 1098-1106.
  • [7] Rosas-Rodríguez, J.A. and Valenzuela-Soto, E.M., (2021), The glycine betaine role in neurodegenerative, cardiovascular, hepatic, and renal diseases: Insights into disease and dysfunction networks, Life Sciences, 285, 119943.
  • [8] Alirezaei, M., Jelodar, G., Niknam, P., Ghayemi, Z. and Nazifi, S., (2011), Betaine prevents ethanol-induced oxidative stress and reduces total homocysteine in the rat cerebellum, Journal of physiology and biochemistry, 67, 605-612.
  • [9] Alirezaei, M., Jelodar, G. and Ghayemi, Z., (2012), Antioxidant defense of betaine against oxidative stress induced by ethanol in the rat testes, International Journal of Peptide Research and Therapeutics, 18, 239-247.
  • [10] Rehman, A. and Mehta, K.J., (2022), Betaine in ameliorating alcohol-induced hepatic steatosis, European Journal of Nutrition, 61(3), 1167-1176.
  • [11] Arumugam, M.K., Chava, S., Perumal, S.K., Paal, M.C., Rasineni, K., Ganesan, M., Donohue, T.M., Jr., Osna, N.A. and Kharbanda, K.K., (2022), Acute ethanol-induced liver injury is prevented by betaine administration, Front Physiol, 13, 940148.
  • [12] Çakır Gündoğdu, A., Kar, F. and Özbayer, C., (2022), Investigation of the Gastroprotective Effect of Betaine-Homocysteine Homeostasis on Oxidative Stress, Inflammation and Apoptosis in Ethanol-Induced Ulcer Model, Journal of Investigative Surgery, 35(11-12), 1806-1817.
  • [13] Ozlu, H., Cakir Gundogdu, A., Elmazoglu, Z., Take Kaplanoglu, G., Oktar, L. and Karasu, C., (2021), Bacopa monnieri protects the directly affected organ as well as distant organs against I/R injury by modulating anti-inflammatory and anti-nitrosative pathways in a rat model for infra-renal aortic occlusion, Journal of Investigative Surgery, 34(9), 935-946.
  • [14] Akbulut, S., Elbe, H., Eris, C., Dogan, Z., Toprak, G., Otan, E., Erdemli, E. and Turkoz, Y., (2014), Cytoprotective effects of amifostine, ascorbic acid and N-acetylcysteine against methotrexate-induced hepatotoxicity in rats, World journal of gastroenterology: WJG, 20(29), 10158-10165.
  • [15] Ewer, A.K., Al-Salti, W., Coney, A.M., Marshall, J.M., Ramani, P. and Booth, I.W., (2004), The role of platelet activating factor in a neonatal piglet model of necrotising enterocolitis, Gut, 53(2), 207-213.
  • [16] Güney, T.G., Çalışkan, A., Kar, F., Çakır Gündoğdu, A. and Özbayer, C., (2022), Sıçan böbrek dokusunda etanolün akut toksisitesi ve borik asitin koruyucu rolü, Biyolojik Çeşitlilik ve Koruma, 15(1), 107-113.
  • [17] Fernández-Solà, J., (2020), The effects of ethanol on the heart: alcoholic cardiomyopathy, Nutrients, 12(2), 572.
  • [18] Ding, Y., Wu, Y., Chen, J., Zhou, Z., Zhao, B., Zhao, R., Cui, Y., Li, Q. and Cong, Y., (2022), Protective effect of Eucommia ulmoides Oliver male flowers on ethanol‐induced DNA damage in mouse cerebellum and cerebral cortex, Food Science & Nutrition, 10(8), 2794-2803.
  • [19] Stickel, F., Hoehn, B., Schuppan, D. and Seitz, H., (2003), Nutritional therapy in alcoholic liver disease, Alimentary pharmacology & therapeutics, 18(4), 357-373.
  • [20] Ozdil, S., Bolkent, S., Yanardag, R. and Arda-Pirincci, P., (2004), Protective effects of ascorbic acid, dl-alpha-tocopherol acetate, and sodium selenate on ethanol-induced liver damage of rats, Biol Trace Elem Res, 97(2), 149-162.
  • [21] Sathiavelu, J., Senapathy, G.J., Devaraj, R. and Namasivayam, N., (2009), Hepatoprotective effect of chrysin on prooxidant-antioxidant status during ethanol-induced toxicity in female albino rats, J Pharm Pharmacol, 61(6), 809-817.
  • [22] Xiao, Q., Chen, Y.H., Pratama, S.A., Chen, Y.L., Shirakawa, H., Peng, H.C. and Yang, S.C., (2021), The Prophylactic Effects of Glutamine on Muscle Protein Synthesis and Degradation in Rats with Ethanol-Induced Liver Damage, Nutrients, 13(8), 2788.
  • [23] Zhong, W., Zhao, Y., Sun, X., Song, Z., McClain, C.J. and Zhou, Z., (2013), Dietary zinc deficiency exaggerates ethanol-induced liver injury in mice: involvement of intrahepatic and extrahepatic factors, PLoS One, 8(10), e76522.
  • [24] Bode, C. and Bode, J.C., (1997), Alcohol’s role in gastrointestinal tract disorders, Alcohol health and research world, 21(1), 76-83.
  • [25] Person, J., (1991), Alcohol and the small intestine, Scandinavian journal of gastroenterology, 26(1), 3-15.
  • [26] Persson, J., Berg, N., Sjolund, K., Stenling, R. and Magnusson, P., (1990), Morphologic changes in the small intestine after chronic alcohol consumption, Scandinavian journal of gastroenterology, 25(2), 173-184.
  • [27] Kar, F., Hacioglu, C., Kacar, S., Sahinturk, V. and Kanbak, G., (2019), Betaine suppresses cell proliferation by increasing oxidative stress–mediated apoptosis and inflammation in DU-145 human prostate cancer cell line, Cell Stress and Chaperones, 24(5), 871-881.
  • [28] Hagar, H. and Al Malki, W., (2014), Betaine supplementation protects against renal injury induced by cadmium intoxication in rats: role of oxidative stress and caspase-3, Environ Toxicol Pharmacol, 37(2), 803-811.
  • [29] Zhang, M., Zhang, H., Li, H., Lai, F., Li, X., Tang, Y., Min, T. and Wu, H., (2016), Antioxidant mechanism of betaine without free radical scavenging ability, Journal of agricultural and food chemistry, 64(42), 7921-7930.
  • [30] Ahn, M., Park, J.S., Chae, S., Kim, S., Moon, C., Hyun, J.W. and Shin, T., (2014), Hepatoprotective effects of Lycium chinense Miller fruit and its constituent betaine in CCl4-induced hepatic damage in rats, Acta histochemica, 116(6), 1104-1112.
  • [31] Kharbanda, K.K., Rogers II, D.D., Mailliard, M.E., Siford, G.L., Barak, A.J., Beckenhauer, H.C., Sorrell, M.F. and Tuma, D.J., (2005), Role of elevated S-adenosylhomocysteine in rat hepatocyte apoptosis: protection by betaine, Biochemical pharmacology, 70(12), 1883-1890.
  • [32] Ratter, F., Germer, M., Fischbach, T., Schulze-Osthoff, K., Peter, M.E., Dröge, W., Krammer, P.H. and Lehmann, V., (1996), S-adenosylhomocysteine as a physiological modulator of Apo-1-mediated apoptosis, International immunology, 8(7), 1139-1147.
  • [33] Bellas, R.E., Harrington, E.O., Sheahan, K.L., Newton, J., Marcus, C. and Rounds, S., (2002), FAK blunts adenosine-homocysteine-induced endothelial cell apoptosis: requirement for PI 3-kinase, American Journal of Physiology-Lung Cellular and Molecular Physiology, 282(5), L1135-L1142.
  • [34] Barak, A.J., Beckenhauer, H.C., Mailliard, M.E., Kharbanda, K.K. and Tuma, D.J., (2003), Betaine lowers elevated S-adenosylhomocysteine levels in hepatocytes from ethanol-fed rats, The Journal of nutrition, 133(9), 2845-2848.
  • [35] Zhao, G., He, F., Wu, C., Li, P., Li, N., Deng, J., Zhu, G., Ren, W. and Peng, Y., (2018), Betaine in Inflammation: Mechanistic Aspects and Applications, Front Immunol, 9, 1070.
  • [36] Olli, K., Lahtinen, S., Rautonen, N. and Tiihonen, K., (2013), Betaine reduces the expression of inflammatory adipokines caused by hypoxia in human adipocytes, British journal of nutrition, 109(1), 43-49.
  • [37] Yang, Z., Yang, J.J., Zhu, P.J., Han, H.M., Wan, X.L., Yang, H.M. and Wang, Z.Y., (2022), Effects of betaine on growth performance, intestinal health, and immune response of goslings challenged with lipopolysaccharide, Poultry Science, 101(11), 102153.
  • [38] Shi, Q.Z., Wang, L.W., Zhang, W. and Gong, Z.J., (2010), Betaine inhibits toll-like receptor 4 expression in rats with ethanol-induced liver injury, World Journal of Gastroenterology: WJG, 16(7), 897-903.

BETAINE SUPPLEMENTATION PROTECTS RATS AGAINST ALCOHOL-INDUCED HEPATIC AND DUODENAL INJURY: AN HISTOPATHOLOGICAL STUDY

Year 2023, , 220 - 233, 29.03.2023
https://doi.org/10.59313/jsr-a.1232251

Abstract

Betaine is a natural compound synthesized endogenously in animals, plants, and microorganisms and can be intaken by diet. There is a growing body of evidence that suggests betaine has properties that can protect against damage caused by oxidation, inflammation, and cell death in various human diseases. Additionally, recent studies suggest that betaine may help prevent and/or ameliorate tissue damage from alcohol consumption. In the present study, we evaluated histopathological changes in the liver and duodenum tissues stained with hematoxylin and eosin (H&E) in the four groups of twenty-eight Wistar albino rats: control group, betaine pre-treated group (250 mg/kg/bw, 21 days, i.g.), acute ethanol ingested group (75% ethanol, 4 ml/kg/bw, i.g.) and betaine+ethanol group (75% ethanol, 4 ml/kg/bw, following betaine 250 mg/kg/bw, i.g.). We found that betaine pre-treatment reduced significantly ethanol-induced hepatocyte degeneration, sinusoidal dilatation, hemorrhage, and inflammatory cell infiltration in the liver (p < 0.05). We also showed that betaine protects duodenal mucosa significantly against epithelial damage at the tips of villi and hemorrhage (p < 0.001). Collectively, this study indicated that betaine supplementation could protect against histopathological changes induced by ethanol in hepatic and duodenal tissues.

Thanks

Declared none.

References

  • [1] WHO, (2018), Global Status Report on Alcohol and Health; World Health Organization: Geneva, Switzerland.
  • [2] Yuan, R., Tao, X., Liang, S., Pan, Y., He, L., Sun, J., Wenbo, J., Li, X., Chen, J. and Wang, C., (2018), Protective effect of acidic polysaccharide from Schisandra chinensis on acute ethanol-induced liver injury through reducing CYP2E1-dependent oxidative stress, Biomed Pharmacother, 99, 537-542.
  • [3] Qiao, J.Y., Li, H.W., Liu, F.G., Li, Y.C., Tian, S., Cao, L.H., Hu, K., Wu, X.X. and Miao, M.S., (2019), Effects of Portulaca Oleracea Extract on Acute Alcoholic Liver Injury of Rats, Molecules, 24(16), 2887.
  • [4] Pronko, P., Bardina, L., Satanovskaya, V., Kuzmich, A. and Zimatkin, S., (2002), Effect of chronic alcohol consumption on the ethanol-and acetaldehyde-metabolizing systems in the rat gastrointestinal tract, Alcohol and Alcoholism, 37(3), 229-235.
  • [5] Bode, C. and Bode, J.C., (2003), Effect of alcohol consumption on the gut, Best practice & research Clinical gastroenterology, 17(4), 575-592.
  • [6] Day, C.R. and Kempson, S.A., (2016), Betaine chemistry, roles, and potential use in liver disease, Biochimica et Biophysica Acta (BBA)-General Subjects, 1860(6), 1098-1106.
  • [7] Rosas-Rodríguez, J.A. and Valenzuela-Soto, E.M., (2021), The glycine betaine role in neurodegenerative, cardiovascular, hepatic, and renal diseases: Insights into disease and dysfunction networks, Life Sciences, 285, 119943.
  • [8] Alirezaei, M., Jelodar, G., Niknam, P., Ghayemi, Z. and Nazifi, S., (2011), Betaine prevents ethanol-induced oxidative stress and reduces total homocysteine in the rat cerebellum, Journal of physiology and biochemistry, 67, 605-612.
  • [9] Alirezaei, M., Jelodar, G. and Ghayemi, Z., (2012), Antioxidant defense of betaine against oxidative stress induced by ethanol in the rat testes, International Journal of Peptide Research and Therapeutics, 18, 239-247.
  • [10] Rehman, A. and Mehta, K.J., (2022), Betaine in ameliorating alcohol-induced hepatic steatosis, European Journal of Nutrition, 61(3), 1167-1176.
  • [11] Arumugam, M.K., Chava, S., Perumal, S.K., Paal, M.C., Rasineni, K., Ganesan, M., Donohue, T.M., Jr., Osna, N.A. and Kharbanda, K.K., (2022), Acute ethanol-induced liver injury is prevented by betaine administration, Front Physiol, 13, 940148.
  • [12] Çakır Gündoğdu, A., Kar, F. and Özbayer, C., (2022), Investigation of the Gastroprotective Effect of Betaine-Homocysteine Homeostasis on Oxidative Stress, Inflammation and Apoptosis in Ethanol-Induced Ulcer Model, Journal of Investigative Surgery, 35(11-12), 1806-1817.
  • [13] Ozlu, H., Cakir Gundogdu, A., Elmazoglu, Z., Take Kaplanoglu, G., Oktar, L. and Karasu, C., (2021), Bacopa monnieri protects the directly affected organ as well as distant organs against I/R injury by modulating anti-inflammatory and anti-nitrosative pathways in a rat model for infra-renal aortic occlusion, Journal of Investigative Surgery, 34(9), 935-946.
  • [14] Akbulut, S., Elbe, H., Eris, C., Dogan, Z., Toprak, G., Otan, E., Erdemli, E. and Turkoz, Y., (2014), Cytoprotective effects of amifostine, ascorbic acid and N-acetylcysteine against methotrexate-induced hepatotoxicity in rats, World journal of gastroenterology: WJG, 20(29), 10158-10165.
  • [15] Ewer, A.K., Al-Salti, W., Coney, A.M., Marshall, J.M., Ramani, P. and Booth, I.W., (2004), The role of platelet activating factor in a neonatal piglet model of necrotising enterocolitis, Gut, 53(2), 207-213.
  • [16] Güney, T.G., Çalışkan, A., Kar, F., Çakır Gündoğdu, A. and Özbayer, C., (2022), Sıçan böbrek dokusunda etanolün akut toksisitesi ve borik asitin koruyucu rolü, Biyolojik Çeşitlilik ve Koruma, 15(1), 107-113.
  • [17] Fernández-Solà, J., (2020), The effects of ethanol on the heart: alcoholic cardiomyopathy, Nutrients, 12(2), 572.
  • [18] Ding, Y., Wu, Y., Chen, J., Zhou, Z., Zhao, B., Zhao, R., Cui, Y., Li, Q. and Cong, Y., (2022), Protective effect of Eucommia ulmoides Oliver male flowers on ethanol‐induced DNA damage in mouse cerebellum and cerebral cortex, Food Science & Nutrition, 10(8), 2794-2803.
  • [19] Stickel, F., Hoehn, B., Schuppan, D. and Seitz, H., (2003), Nutritional therapy in alcoholic liver disease, Alimentary pharmacology & therapeutics, 18(4), 357-373.
  • [20] Ozdil, S., Bolkent, S., Yanardag, R. and Arda-Pirincci, P., (2004), Protective effects of ascorbic acid, dl-alpha-tocopherol acetate, and sodium selenate on ethanol-induced liver damage of rats, Biol Trace Elem Res, 97(2), 149-162.
  • [21] Sathiavelu, J., Senapathy, G.J., Devaraj, R. and Namasivayam, N., (2009), Hepatoprotective effect of chrysin on prooxidant-antioxidant status during ethanol-induced toxicity in female albino rats, J Pharm Pharmacol, 61(6), 809-817.
  • [22] Xiao, Q., Chen, Y.H., Pratama, S.A., Chen, Y.L., Shirakawa, H., Peng, H.C. and Yang, S.C., (2021), The Prophylactic Effects of Glutamine on Muscle Protein Synthesis and Degradation in Rats with Ethanol-Induced Liver Damage, Nutrients, 13(8), 2788.
  • [23] Zhong, W., Zhao, Y., Sun, X., Song, Z., McClain, C.J. and Zhou, Z., (2013), Dietary zinc deficiency exaggerates ethanol-induced liver injury in mice: involvement of intrahepatic and extrahepatic factors, PLoS One, 8(10), e76522.
  • [24] Bode, C. and Bode, J.C., (1997), Alcohol’s role in gastrointestinal tract disorders, Alcohol health and research world, 21(1), 76-83.
  • [25] Person, J., (1991), Alcohol and the small intestine, Scandinavian journal of gastroenterology, 26(1), 3-15.
  • [26] Persson, J., Berg, N., Sjolund, K., Stenling, R. and Magnusson, P., (1990), Morphologic changes in the small intestine after chronic alcohol consumption, Scandinavian journal of gastroenterology, 25(2), 173-184.
  • [27] Kar, F., Hacioglu, C., Kacar, S., Sahinturk, V. and Kanbak, G., (2019), Betaine suppresses cell proliferation by increasing oxidative stress–mediated apoptosis and inflammation in DU-145 human prostate cancer cell line, Cell Stress and Chaperones, 24(5), 871-881.
  • [28] Hagar, H. and Al Malki, W., (2014), Betaine supplementation protects against renal injury induced by cadmium intoxication in rats: role of oxidative stress and caspase-3, Environ Toxicol Pharmacol, 37(2), 803-811.
  • [29] Zhang, M., Zhang, H., Li, H., Lai, F., Li, X., Tang, Y., Min, T. and Wu, H., (2016), Antioxidant mechanism of betaine without free radical scavenging ability, Journal of agricultural and food chemistry, 64(42), 7921-7930.
  • [30] Ahn, M., Park, J.S., Chae, S., Kim, S., Moon, C., Hyun, J.W. and Shin, T., (2014), Hepatoprotective effects of Lycium chinense Miller fruit and its constituent betaine in CCl4-induced hepatic damage in rats, Acta histochemica, 116(6), 1104-1112.
  • [31] Kharbanda, K.K., Rogers II, D.D., Mailliard, M.E., Siford, G.L., Barak, A.J., Beckenhauer, H.C., Sorrell, M.F. and Tuma, D.J., (2005), Role of elevated S-adenosylhomocysteine in rat hepatocyte apoptosis: protection by betaine, Biochemical pharmacology, 70(12), 1883-1890.
  • [32] Ratter, F., Germer, M., Fischbach, T., Schulze-Osthoff, K., Peter, M.E., Dröge, W., Krammer, P.H. and Lehmann, V., (1996), S-adenosylhomocysteine as a physiological modulator of Apo-1-mediated apoptosis, International immunology, 8(7), 1139-1147.
  • [33] Bellas, R.E., Harrington, E.O., Sheahan, K.L., Newton, J., Marcus, C. and Rounds, S., (2002), FAK blunts adenosine-homocysteine-induced endothelial cell apoptosis: requirement for PI 3-kinase, American Journal of Physiology-Lung Cellular and Molecular Physiology, 282(5), L1135-L1142.
  • [34] Barak, A.J., Beckenhauer, H.C., Mailliard, M.E., Kharbanda, K.K. and Tuma, D.J., (2003), Betaine lowers elevated S-adenosylhomocysteine levels in hepatocytes from ethanol-fed rats, The Journal of nutrition, 133(9), 2845-2848.
  • [35] Zhao, G., He, F., Wu, C., Li, P., Li, N., Deng, J., Zhu, G., Ren, W. and Peng, Y., (2018), Betaine in Inflammation: Mechanistic Aspects and Applications, Front Immunol, 9, 1070.
  • [36] Olli, K., Lahtinen, S., Rautonen, N. and Tiihonen, K., (2013), Betaine reduces the expression of inflammatory adipokines caused by hypoxia in human adipocytes, British journal of nutrition, 109(1), 43-49.
  • [37] Yang, Z., Yang, J.J., Zhu, P.J., Han, H.M., Wan, X.L., Yang, H.M. and Wang, Z.Y., (2022), Effects of betaine on growth performance, intestinal health, and immune response of goslings challenged with lipopolysaccharide, Poultry Science, 101(11), 102153.
  • [38] Shi, Q.Z., Wang, L.W., Zhang, W. and Gong, Z.J., (2010), Betaine inhibits toll-like receptor 4 expression in rats with ethanol-induced liver injury, World Journal of Gastroenterology: WJG, 16(7), 897-903.
There are 38 citations in total.

Details

Primary Language English
Journal Section Research Articles
Authors

Ayşe Çakır Gündoğdu 0000-0002-2466-9417

Fatih Kar 0000-0001-8356-9806

Cansu Özbayer 0000-0002-1120-1874

Publication Date March 29, 2023
Submission Date January 10, 2023
Published in Issue Year 2023

Cite

IEEE A. Çakır Gündoğdu, F. Kar, and C. Özbayer, “BETAINE SUPPLEMENTATION PROTECTS RATS AGAINST ALCOHOL-INDUCED HEPATIC AND DUODENAL INJURY: AN HISTOPATHOLOGICAL STUDY”, JSR-A, no. 052, pp. 220–233, March 2023, doi: 10.59313/jsr-a.1232251.