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State of the antioxidant protection system of rat liver in ischemia and reperfusion
- Authors: Popov K.A.1, Bykov I.M.1, Tsymbalyuk I.Y.1, Denisova Y.E.1, Stolyarova A.N.1, Azimov E.A.1, Shurygina L.A.1
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Affiliations:
- Kuban state medical university
- Issue: Vol 24, No 1 (2020)
- Pages: 93-104
- Section: PHYSIOLOGY. EXPERIMENTAL PHYSIOLOGY
- URL: https://journals.rudn.ru/medicine/article/view/23399
- DOI: https://doi.org/10.22363/2313-0245-2020-24-1-93-104
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Abstract
Purpose: determination of the state of the antioxidant protection system of the cytosolic fraction and suspension of rat liver mitochondria after experimental ischemia and reperfusion. Materials and methods: the study was conducted using white mature rats, divided into 3 groups: the control group (n = 15); The 2nd group of animals (n = 15), from which the liver was taken after 15 minutes of liver ischemia; the 3rd group of rats (n = 15), from which the liver was taken after a 15-minute reperfusion period, followed by a 15-minute ischemic period. Mitochondrial suspension and cytosolic fraction were isolated from liver tissue. Results: the obtained research results showed the presence of certain pathobiochemical changes in the suspension of mitochondria and the cytosolic fraction after ischemia or reperfusion. In the mitochondrial suspension during the reperfusion period it was found an adaptive increase in the activity of glutathione peroxidase by 39% and glutathione reductase by 61%. In the cytosolic fraction, it was the most remarkable increase of the total antioxidant capacity by 38% already during ischemia and a progressive decrease in the level of reduced glutathione form by 26% in ischemic and 55% in reperfusion period. The change in the state of the antioxidant system occurred against the background of an increase in the number of products of oxidative modifications of biomolecules by 40% during ischemia and 2.2 times after reperfusion. Conclusion: The results indicate the need to develop not only a mitochondria-oriented correction of oxidative disorders, but also active support for the components of the cytosol, which provide the main accumulation of free radical damage products and their subsequent removal from the cell, which is essential for survival.
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About the authors
Konstantin Andreevich Popov
Kuban state medical university
Author for correspondence.
Email: naftalin444@mail.ru
Krasnodar, Russian Federation
Ilia Mikhaylovich Bykov
Kuban state medical university
Email: naftalin444@mail.ru
Krasnodar, Russian Federation
Igor Yuryevich Tsymbalyuk
Kuban state medical university
Email: naftalin444@mail.ru
Krasnodar, Russian Federation
Yana Evgenievna Denisova
Kuban state medical university
Email: naftalin444@mail.ru
Krasnodar, Russian Federation
Anzhela Nikolaevna Stolyarova
Kuban state medical university
Email: naftalin444@mail.ru
Krasnodar, Russian Federation
Erustam Adamovich Azimov
Kuban state medical university
Email: naftalin444@mail.ru
Krasnodar, Russian Federation
Larisa Alekseevna Shurygina
Kuban state medical university
Email: naftalin444@mail.ru
Krasnodar, Russian Federation
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