Abstract
Ethanol is one of the most widely used recreational substances in the world and due to its ubiquitous use, ethanol abuse has been the cause of over 3.3 million deaths each year. In addition to its effects, ethanol's primary metabolite, acetaldehyde, is a carcinogen that can cause symptoms of facial flushing, headaches, and nausea. How strongly ethanol or acetaldehyde affects an individual depends highly on the genetic polymorphisms of certain genes. In particular, the genetic polymorphisms of mitochondrial aldehyde dehydrogenase, ALDH2, play a large role in the metabolism of acetaldehyde. Thus, it is important to characterize how genetic variations can lead to different exposures and responses to ethanol and acetaldehyde. While the pharmacokinetics of ethanol metabolism through alcohol dehydrogenase have been thoroughly explored in previous studies, in this paper, we combined a base physiologically-based pharmacokinetic (PBPK) model with a whole-body genome-scale model (WBM) to gain further insight into the effect of other less explored processes and genetic variations on ethanol metabolism. This combined model was fit to clinical data and used to show the effect of alcohol concentrations, organ damage, ALDH2 enzyme polymorphisms, and ALDH2-inhibiting drug disulfiram on ethanol and acetaldehyde exposure. Through estimating the reaction rates of auxiliary processes with dynamic Flux Balance Analysis, The PBPK-WBM was able to navigate around a lack of kinetic constants traditionally associated with PK modelling and demonstrate the compensatory effects of the body in response to decreased liver enzyme expression. Additionally, the model demonstrated that acetaldehyde exposure increased with higher dosages of disulfiram and decreased ALDH2 efficiency, and that moderate consumption rates of ethanol could lead to unexpected accumulations in acetaldehyde. This modelling framework combines the comprehensive steady-state analyses from genome-scale models with the dynamics of traditional PK models to create a highly personalized form of PBPK modelling that can push the boundaries of precision medicine.
Highlights
Ethanol is a drug that has been extensively studied and is widely used in the world today
We show that the whole-body genome-scale model demonstrates flexibility and robustness that has not been seen before in pharmacokinetic models
It is understood that ethanol is primarily metabolized by liver alcohol dehydrogenase (ADH) into acetaldehyde, which is in turn eliminated by mitochondrial aldehyde dehydrogenase (ALDH2) into acetate [3,4]
Summary
Ethanol is a drug that has been extensively studied and is widely used in the world today. Ethanol abuse can lead to dependence, liver cirrhosis, social withdrawal, and serious implications when driving under the influence, leading to approximately 3.3 million deaths each year [1]. This alarming number has encouraged researchers to develop mathematical models to better understand ethanol metabolism [2]. It is understood that ethanol is primarily metabolized by liver alcohol dehydrogenase (ADH) into acetaldehyde, which is in turn eliminated by mitochondrial aldehyde dehydrogenase (ALDH2) into acetate [3,4]. It is important to characterize how different populations’ genetic variations and drinking habits can lead to various exposure and responses to ethanol and acetaldehyde
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