Mechanisms involved in the valproic acid-induced hepatotoxicity: a comprehensive review.

Adverse drug reactions (ADR) remain a challenge in modern healthcare, particularly given the increasing complexity of therapeutics. An anticonvulsant medicine which is frequently used in treatment of epilepsy and other neurological conditions is valproic acid (VPA), is frequently associated with hepatotoxicity, a severe ADR that complicates its clinical use, which can take two different forms: Type I, which is defined by dose-dependent and reversible liver damage, and Type II, an idiosyncratic reaction that can result in severe liver failure, frequently complicates its clinical application. Oxidative stress, the creation of reactive metabolites, mitochondrial dysfunction, carnitine shortage, immune-mediated reactions, glutathione depletion, and blockage of the bile salt export pump (BSEP) are some of the numerous underlying mechanisms of VA-induced hepatic damage. The production of reactive oxygen species and the liver's antioxidant protection are out of balance as a cause of oxidative stress, which is a significant factor in VPA intoxication. VPA can also accelerate the build-up of fatty acids, which increases the risk of steatosis, due to its interaction with the metabolism of carnitine. Immune-mediated processes have been shown to increase liver injury, implying that the immunity system may possibly be involved in VPA hepatotoxicity. Hepatocyte injury and cholestasis are caused by BSEP inhibition, which impairs bile flow. The complex interaction between biochemical and cellular mechanisms that underlie valproic acid's hepatotoxic potential calls for additional research to clarify the precise pathways implicated and create mitigation techniques for this ADR.