Abstract
Diseases and toxins may lead to death of active liver tissue, resulting in a loss of total clearance capacity at the whole-body level. However, it remains difficult to study, whether the loss of metabolizing tissue is sufficient to explain loss of metabolic capacity of the liver or whether the surviving tissue undergoes an adaptive response to compensate the loss. To understand the cellular impact of toxic liver damage in an in vivo situation, we here used physiologically-based pharmacokinetic modelling to investigate pharmacokinetics of a specifically designed drug cocktail at three different sampling sites of the body in healthy mice and mice treated with carbon tetrachloride (CCl4). Liver zonation was explicitly quantified in the models through immunostaining of cytochrome P450s enzymes. Comparative analyses between the simulated decrease in clearance capacity and the experimentally measured loss in tissue volume indicated that CCl4-induced impairment of metabolic functions goes beyond the mere loss of metabolically active tissue. The here established integrative modelling strategy hence provides mechanistic insights into functional consequences of toxic liver damage in an in vivo situation, which would not have been accessible by conventional methods.
Highlights
The liver is the organ with the highest detoxification capacity in mammals
To account for liver zonation, we quantified the area of expression of four cytochrome P450 enzymes involved in the metabolism of the drug cocktail in mice, namely CYP1A, CYP2C, CYP3A and CYP2D
We here analyzed the impact of CCl4-induced damage on hepatic clearance capacity by using an integrative approach of Physiologically-based pharmacokinetic (PBPK) models and targeted experimental data
Summary
The liver is the organ with the highest detoxification capacity in mammals. Hepatocytes, the parenchymal cells of the liver, modify the structure of xenobiotics to improve excretion through urine or feces. Hepatocytes in the periportal zone (upstream, at the side of the portal vein and the hepatic artery) have a different enzymatic setup than hepatocytes in the pericentral zone (downstream, at the side of the central vein)[1] This compartmentalization of parenchymal cells along the sinusoid, usually referred to as zonation, has a significant functional impact on hepatic metabolic capacity, including drug activation and detoxification. CCl4 intoxication was used as a model to investigate how toxin-induced liver damage of the pericentral zone affects drug PK in mice and in particular hepatic clearance capacity. A comparison between the functional damage and the tissue damage allowed us to draw further conclusions about the extent of CCl4-induced intoxication within the surviving liver tissue
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