Abstract
Background: The relationship between liver disease and neuropathology in hepatic encephalopathy is well known, but the genesis of encephalopathy in liver failure is yet to be elucidated. Conceptually, the main cause of hepatic encephalopathy is the accumulation of brain ammonia due to impaired liver detoxification function or occurrence of portosystemic shunt. Yet, as well as taking up toxic ammonia, the liver also produces vital metabolites that ensure normal cerebral function. Given this, for insight into how perturbations in the metabolic capacity of the liver may be related to brain pathology, it is crucial to understand the extent of ammonia-related changes in the hepatic metabolism that provides respiratory fuel for the brain, a deficiency of which can give rise to encephalopathy. Methods: Hepatic encephalopathy was induced in starved rats by injection of ammonium acetate. Ammonia-induced toxicity was evaluated by plasma and freeze-clamped liver and brain energy metabolites, and mitochondrial, cytoplasmic, and microsomal gluconeogenic enzymes, including mitochondrial ketogenic enzymes. Parameters of oxidative phosphorylation were recorded polarographically with a Clark-type electrode, while other measures were determined with standard fluorometric enzymatic methods. Results: Progressive impairment of liver mitochondrial respiration in the initial stage of ammonia-induced hepatotoxicity and the subsequent energy crisis due to decreased ATP synthesis lead to cessation of gluconeogenesis and ketogenesis. Reduction in glucose and ketone body supply to the brain is a terminal event in liver toxicity, preceding the development of coma. Conclusions: Our study provides a framework to further explore the relationship between hepatic dysfunction and progression of brain energy crisis in hepatic encephalopathy.
Highlights
Hepatic encephalopathy (HE) is a neuropsychiatric disorder developing in patients with severe liver disease
The results show that 10 min after injection of ammonia into the starved animals, the ATP content in mitochondria fell by 54% compared to control, while inversely, ADP increased by 38%, and AMP by 49% (Figure 3)
The liver performs a myriad of functions, and in addition to filtering toxins, plays a unique role in the regulation of blood glucose homeostasis, crucial for normal cerebral function, since the brain neither synthesizes nor stores the required amount of glucose [59]
Summary
Hepatic encephalopathy (HE) is a neuropsychiatric disorder developing in patients with severe liver disease. Med. 2020, 9, 2259 investigating acute ammonia intoxication in which the concentration of ammonia in the blood quickly increases to the level found in idiopathic hyperammonemia following lung transplantation [29] and many other human pathologies [30] Since these metabolic processes are energy-dependent and closely related to mitochondrial function and fatty acid oxidation [31], we sought to study the effect of acute hyperammonemia on the hepatic mitochondrial function, including oxidative phosphorylation, fatty acid oxidative capacity, and how fluctuation of glucose and ketone body levels in the blood can affect brain bioenergetics and coma development. This research will advance understanding of the role of liver mitochondria in brain energy metabolism
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