Computational problems associated with fitting the Michaelis-Menten models

Akhter, K. P.

January 1988

No description available.

615.1

Drug disposition modelling

Billiary excretion in uraemia and the effect of albumin concentration on drug binding

Clegg, L. S.

January 1983

No description available.

615.1

Disease on drug disposition

Non-Alcoholic Fatty Liver Disease Alters the Three Stages of Hepatic Drug Management

Fisher, Craig

January 2008

In pharmacotherapeutics, the term "correct dosing" is based on the concept that too high a systemic concentration will lead to drug toxicity, while drug levels that are too low may not produce the intended therapeutic effect. Often, the factors determining the ability of a patient to manage a given dose rely on their capacity to efficiently metabolize and eliminate drugs from the body. The liver plays a crucial role in the processing of many clinically relevant drugs via three stages of hepatic drug management. Drugs must first be taken into hepatocytes by uptake transporters. Drugs are then metabolized by phase I and phase II enzymes to make them more manageable. Finally, metabolites are removed from the hepatocyte by efflux transporters either into the bile for elimination or reintroduction to systemic blood. Alterations in one or more of the hepatic drug management stages increase the potential for adverse drug reactions (ADRs).In the United States, ADRs account for between 3%-12% of admissions to hospitals, and approximately 5% of deaths each year. While less than 20% of these cases are due to genetic polymorphisms, the vast majority of ADRs are due to environmental factors including disease. Non-alcoholic fatty liver disease (NAFLD) comprises a spectrum of conditions progressing from steatosis to non-alcoholic steatohepatitis (NASH) and often leading to cirrhosis. Presently, NASH patients represent the greatest population of candidates for liver transplant, illustrating the severity as well as the incidence of this disease. Patients with NAFLD are typically treated for co-existing conditions of the metabolic syndrome (i.e. hyperlipidemina or type II diabetes) and therefore represent a distinct population at risk for adverse drug reactions.The following studies show that experimental NAFLD affects both the signal transduction pathways regulating hepatic drug management genes as well as the hepatic uptake transporter function. Additionally, patient livers diagnosed with progressive stages of NAFLD, display altered CYP activity and efflux transporter expression similar to those previously reported in experimental NAFLD. Given that changes observed in experimental NAFLD result in functional changes in hepatic drug management, similar changes observed in patients with this disease suggest an increased risk for ADRs.

Cytochrome P450 enzymes

Drug Disposition

Hepatic transporters

Non-alcoholic fatty liver disease

Nash Alters Drug Metabolizing Enzyme and Transporter Expression Resulting in Significant Consequences for Pharmaceutical Disposition and Toxicity

Hardwick, Rhiannon Nicole

January 2012

The body encounters an innumerable amount of foreign substances, termed xenobiotics, which it must remove in order to prevent damage to cells and organs. This system of removal is a collection of processes known as ADME (absorption, distribution, metabolism, and excretion). The dynamics of ADME ultimately determine the fate, or pharmacokinetics, of a xenobiotic in the body whether it be an administered pharmaceutical or a potentially harmful toxicant. The major cellular effectors of ADME are the drug metabolizing enzymes (DMEs) and transporters. DMEs function to transform xenobiotics into a metabolite that is more suitable for excretion, whereas drug transporters serve a two-fold function. They may facilitate the uptake of the xenobiotic into the cell so that it can be acted upon by DMEs, or they may function to actively secrete xenobiotics and metabolites from the cell, encouraging their removal from the body. Any perturbations in the expression or function of these critical cellular effectors can result in the diminished therapeutic effect of a pharmaceutical via accelerated removal from the body, or increased toxicity of a pharmaceutical or toxicant due to retention in the body and increased exposure.Perturbations in the ADME processes may result in adverse drug reactions (ADRs) which are an unintended response to a pharmaceutical when administered at the recommended dose. In the last reporting year, the USFDA documented 471,291 serious ADRs causing hospitalization or permanent disabilities, of which 82,724 resulted in death. ADRs can be categorized as two types: dose-related ADRs, and those that are generally unpredictable and mostly occur in susceptible individuals. The major factors that make a person susceptible to ADRs are genetics and disease; however, genetics account for only a small proportion. This dissertation is focused on the contribution of an environmentally-derived component, particularly liver disease, to the occurrence of ADRs. Nonalcoholic fatty liver disease (NAFLD) is the most common liver disease of industrialized nations. It represents a spectrum of damage progressing to the severe stage of nonalcoholic steatohepatitis (NASH), and is closely related to obesity and type 2 diabetes. The following studies have determined the effect of NAFLD and NASH on DMEs and transporters, and demonstrated the propensity for NASH to result in serious ADRs.

drug transporters

nonalcoholic fatty liver disease

nonalcoholic steatohepatitis

Pharmacology & Toxicology

drug disposition

drug metabolizing enzymes

Application of Pharmacokinetic Theory to Examine Roles of Transporters and Enzymes in Intestinal and Hepatic Drug Disposition

Sun, Huadong

26 February 2009

The interplay of transporters and enzymes and their transporter-enzyme was examined in Caco-2 cell monolayer and recirculating perfused rat liver preprations via both theoretical and experimental approaches. First, a Caco-2 catenary model that consisted of the apical, cellular, basolateral compartments and encompasses influx, efflux transporters and enzymes was shown to be superior to the single barrier approach for data interpretation on transporter- and enzyme- mediated processes. The kinetics of baicalein, a flavonoid that undergoes glucuronidation and sulfation, were found to be described better by the catenary model for the complex kinetics of substrate inhibition in metabolism. Second, estradiol-17beta-D-glucuronide (E217G), a protypic substrate of Oatp1a1, 1a4, and 1b2 and Mrp2 that underwent futile cycling with its 3-sulfate metabolite (E23S17G) via estrogen sulfotransferase (Sult1e1) and arylsulfatase C, was examined in the perfused rat liver preparation. Solutions of the AUC and clearances were solved to relate the intrinsic clearances of transporters and enzymes to understand how these affected the apparent clearances in the presence of futile cycling. Transporters and enzymes were perturbed experimentally by the intraportal injection of CC531 colon carcinoma cells for tumor induction in Wag/Rij rat livers. The protein expression of Oatp1a1 and Oatp1b2 were reduced to half whereas Sult1e1 was increased by 40% with tumor development versus the sham-operated control. These data were well predicted by the physiologically-based liver model, showing the impact of increased sulfation intrinsic clearance but not the decreased influx clearance. The TR- (Mrp2 mutant) rat model was used to examine how the absence of Mrp2 for biliary secretion of both E217G and E23S17G affected futile cycling. Absence of Mrp2 was found to result in a pseudo steady-state and reduction of the total, excretion, and metabolic clearances in the liver. The work shed new insight on the interplay between enzymes and transporters and how kinetic processes mediated by enzymes or efflux transporters affected futile cycling.

pharmacokinetics

transporter

enzyme

drug disposition

PBPK modeling

drug first-pass removal

Caco-2

liver perfusion

0572

Application of Pharmacokinetic Theory to Examine Roles of Transporters and Enzymes in Intestinal and Hepatic Drug Disposition

Sun, Huadong

26 February 2009

The interplay of transporters and enzymes and their transporter-enzyme was examined in Caco-2 cell monolayer and recirculating perfused rat liver preprations via both theoretical and experimental approaches. First, a Caco-2 catenary model that consisted of the apical, cellular, basolateral compartments and encompasses influx, efflux transporters and enzymes was shown to be superior to the single barrier approach for data interpretation on transporter- and enzyme- mediated processes. The kinetics of baicalein, a flavonoid that undergoes glucuronidation and sulfation, were found to be described better by the catenary model for the complex kinetics of substrate inhibition in metabolism. Second, estradiol-17beta-D-glucuronide (E217G), a protypic substrate of Oatp1a1, 1a4, and 1b2 and Mrp2 that underwent futile cycling with its 3-sulfate metabolite (E23S17G) via estrogen sulfotransferase (Sult1e1) and arylsulfatase C, was examined in the perfused rat liver preparation. Solutions of the AUC and clearances were solved to relate the intrinsic clearances of transporters and enzymes to understand how these affected the apparent clearances in the presence of futile cycling. Transporters and enzymes were perturbed experimentally by the intraportal injection of CC531 colon carcinoma cells for tumor induction in Wag/Rij rat livers. The protein expression of Oatp1a1 and Oatp1b2 were reduced to half whereas Sult1e1 was increased by 40% with tumor development versus the sham-operated control. These data were well predicted by the physiologically-based liver model, showing the impact of increased sulfation intrinsic clearance but not the decreased influx clearance. The TR- (Mrp2 mutant) rat model was used to examine how the absence of Mrp2 for biliary secretion of both E217G and E23S17G affected futile cycling. Absence of Mrp2 was found to result in a pseudo steady-state and reduction of the total, excretion, and metabolic clearances in the liver. The work shed new insight on the interplay between enzymes and transporters and how kinetic processes mediated by enzymes or efflux transporters affected futile cycling.

pharmacokinetics

transporter

enzyme

drug disposition

PBPK modeling

drug first-pass removal

Caco-2

liver perfusion

0572

Biopharmaceutical Evaluation of Intra-arterial Drug-Delivery Systems for Liver Cancer : Investigations in healthy pigs and liver cancer patients

Lilienberg, Elsa

January 2015

There are currently two types of intra-arterial drug-delivery system (DDS) in clinical use in the palliative treatment of primary liver cancer. The chemotherapeutic drug doxorubicin (DOX) can be formulated into a drug-in-lipiodol emulsion (LIPDOX) or a microparticulate drug-eluting bead system (DEBDOX). To facilitate development of future DDSs, we need to understand the release and local distribution of drug from these DDSs into the complex, in vivo, pathological environment. The overall aim of this project was to assess and improve understanding of the in vivo release of DOX from LIPDOX and DEBDOX and its local disposition in the liver. These processes were investigated in detail in a multisampling-site, healthy pig model and in human patients with liver cancer. The mechanisms involved in DOX disposition were studied by examining potential interactions between DOX and lipiodol and/or cyclosporine A (CsA) in pigs.   In this project, the main elimination pathway for DOX and its primary metabolite doxorubicinol (DOXol) was via bile; their extensive canalicular carrier-mediated transport (e.g. ATP-binding cassette transporters ABCB1, ABCC1, ABCC2 and ABCG2) was inhibited by CsA. CsA had no effect on the carbonyl and aldo-keto reductases responsible for the metabolism of DOX into DOXol. LIPDOX released DOX more rapidly and to a greater extent into the circulation than DEBDOX, which had only released 15% of the dose in patients after 24 hrs. The systemic exposure to DOX was lower for DEBDOX than for LIPDOX. Greater fractions of DOXol were formed in blood and bile with LIPDOX than with DEBDOX. This may have been because DOX was more widely distributed into regions with increased metabolic capacity or because of increased intracellular uptake when DOX was delivered in LIPDOX. The excipient lipiodol in the LIPDOX formulation did not interact with transporters, enzymes or membranes that would explain the increased cellular uptake of DOX. In conclusion, the release of DOX from DEBDOX is more controlled in vivo than that from LIPDOX, indicating that DEBDOX is a more robust pharmaceutical product. The formulations for future optimized DDSs should therefore be more similar to DEBDOX than to LIPDOX.

in vivo release

drug delivery systems

local delivery

drug disposition

doxorubicin

hepatocellular carcinoma

transarterial chemoembolization

transarterial chemotherapy infusion

Biopharmaceutical investigations of doxorubicin formulations used in liver cancer treatment : Studies in healthy pigs and liver cancer patients, combined with pharmacokinetic and biopharmaceutical modelling

Dubbelboer, Ilse R

January 2017

There are currently two types of drug formulation in clinical use in the locoregional treatment of intermediate hepatocellular carcinoma (HCC). In the emulsion LIPDOX, the cytostatic agent doxorubicin (DOX) is dissolved in the aqueous phase, which is emulsified with the oily contrast agent Lipiodol® (LIP). In the microparticular system DEBDOX, DOX is loaded into the drug-eluting entity DC Bead™. The overall aim of the thesis was to improve pharmaceutical understanding of the LIPDOX and DEBDOX formulations, in order to facilitate the future development of novel drug delivery systems. In vivo release of DOX from the formulations and the disposition of DOX and its active metabolite doxorubicinol (DOXol) were assessed in an advanced multisampling-site acute healthy pig model and in patients with HCC. The release of DOX and disposition of DOX and DOXol where further analysed using physiologically based pharmacokinetic (PBPK) and biopharmaceutical (PBBP) modelling. The combination of in vivo investigations and in silico modelling could provide unique insight into the mechanisms behind drug release and disposition. The in vivo release of DOX from LIPDOX is not extended and controlled, as it is from DEBDOX. With both formulations, DOX is released as a burst during the early phase of administration. The in vivo release of DOX from LIPDOX was faster than from DEBDOX in both pigs and patients. The release from DEBDOX was slow and possibly incomplete. The in vivo release of DOX from LIPDOX and DEBDOX could be described by using the PBBP model in combination with in vitro release profiles. The disposition of DOX and DOXol was modelled using a semi-PBPK model containing intracellular binding sites. The contrast agent Lipiodol® did not affect the hepatobiliary disposition of DOX in the pig model. The control substance used in this study, cyclosporine A, inhibited the biliary excretion of DOX and DOXol but did not alter metabolism in healthy pigs. The disposition of DOX is similar in healthy pigs and humans, which was shown by the ease of translation of the semi-PBPK pig model to the human PBBP model.

drug delivery system

in vivo release

PBPK modelling

hepatocellular carcinoma

doxorubicin

transarterial chemoembolization

drug disposition

Pharmaceutical Sciences

Farmaceutisk vetenskap

Characterizing Intentional and Unintentional Drug-Drug Interactions to Improve the Pharmacokinetics of Ibrutinib and Venetoclax

Eisenmann, Eric Daniel

January 2021

No description available.

Pharmaceuticals

Pharmacy Sciences

Pharmacology

Biomedical Research

Medicine

Targeted chemotherapeutics

drug disposition

ibrutinib

venetoclax

drug metabolizing enzymes

drug transporters

boosting