Hesperidin Reduces Hepatic Injury Induced by Doxorubicin in Rat Model Through Its Antioxidative and Anti‐Inflammatory Effects, Focusing on SIRT‐1/NRF‐2 Pathways
Alzahraa A. Elhemiely, Shaimaa H. El‐Fayoumi, Mohamed H. A. Gadelmawla, Nievin Ahmed Mahran, Amany M. Gad
Abstract
Doxorubicin (DOX) is a member of the anthracycline class that acts as a chemotherapeutic drug. It causes toxicity by killing both noncancerous cells and cancer cells, even in organs that are not its intended target. Hepatotoxicity from DOX injection is mainly induced by the liver's involvement in the detoxifying process. Exposure to DOX mainly causes inflammatory insult, oxidative stress (OS), and apoptotic cell death, which cause hepatic damage. To lessen the hepatotoxicity caused by DOX, it is essential to comprehend these processes and investigate protective medications. Thus, our goal was to investigate the molecular pathways responsible for DOX-induced hepatotoxicity, focusing on Sirt-1/Nrf2, NFκ-B, and P53. Additionally, our work is designed to assess the potential of Hesperidin to confer protection against liver injury, which is administered orally in two different doses, to estimate the most efficient dose. In vivo investigations were performed on adult male rats arbitrarily allocated to five groups, including a normal control group, Hesperidin 100 mg/kg treated group, DOX exposure, and DOX exposure treated with Hesperidin (50, 100 mg/kg), respectively. Increased MDA and MPO levels and SIRT-1 suppression were indicators of hepatic OS brought on by DOX exposure, which also disrupted antioxidant pathways and triggered inflammatory and apoptotic pathways. Additionally, the elevated liver function biomarkers and observed histological alterations confirmed these results. Both doses effectively modified these effects, with the high dose, 100 mg/kg, revealing superior effectiveness in alleviating Dox-induced biochemical and histological changes. The present research sheds information on the molecular processes that accompany liver damage caused by DOX while also highlighting Hesperidin's hepatoprotective capabilities. These data imply that Hesperidin, especially when administered at 100 mg/kg, has a powerful effect as a therapeutic compound for combating DOX-induced hepatotoxicity.