@phdthesis{Bellwon2015,
  author    = {Bellwon, Patricia},
  title     = {Kinetic assessment by in vitro approaches - A contribution to reduce animals in toxicity testing},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-122693},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2015},
  abstract  = {The adoption of directives and regulations by the EU requires the development of alternative testing strategies as opposed to animal testing for risk assessment of xenobiotics. Additionally, high attrition rates of drugs late in the discovery phase demand improvement of current test batteries applied in the preclinical phase within the pharmaceutical area. These issues were taken up by the EU founded 7th Framework Program "Predict-IV"; with the overall goal to improve the predictability of safety of an investigational product, after repeated exposure, by integration of "omics" technologies applied on well established in vitro approaches. Three major target organs for drug-induced toxicity were in focus: liver, kidney and central nervous system. To relate obtained dynamic data with the in vivo situation, kinetics of the test compounds have to be evaluated and extrapolated by physiologically based pharmacokinetic modeling. This thesis assessed in vitro kinetics of the selected test compounds (cyclosporine A, adefovir dipivoxil and cisplatinum) regarding their reliability and relevance to respective in vivo pharmacokinetics. Cells were exposed daily or every other day to the test compounds at two concentration levels (toxic and non-toxic) for up to 14 days. Concentrations of the test compounds or their major biotransformation products were determined by LC-MS/MS or ICP-MS in vehicle, media, cells and plastic adsorption samples generated at five different time-points on the first and the last treatment day. Cyclosporine A bioaccumulation was evident in primary rat hepatocytes (PRH) at the high concentration, while efficient biotransformation mediated by CYP3A4 and CYP3A5 was determined in primary human hepatocytes (PHH) and HepaRG cells. The lower biotransformation in PRH is in accordance with observation made in vivo with the rat being a poor model for CYP3A biotransformation. Further, inter-assay variability was noticed in PHH caused by biological variability in CYP3A4 and CYP3A5 activity in human donors. The inter-assay variability observed for PRH and HepaRG cells was a result of differences between vehicles regarding their cyclosporine A content. Cyclosporine A biotransformation was more prominent in HepaRG cells due to stable and high CYP3A4 and CYP3A5 activity. In addition, in vitro clearances were calculated and scaled to in vivo. All scaled in vitro clearances were overestimated (PRH: 10-fold, PHH: 2-fold, HepaRG cells: 2-fold). These results should be proven by physiologically-based pharmacokinetic modeling and additional experiments, in order to verify that these overestimations are constant for each system and subsequently can be diminished by implementation of further scaling factors. Brain cell cultures, primary neuronal culture of mouse cortex cells and primary aggregating rat brain cells, revealed fast achieved steady state levels of cyclosporine A. This indicates a chemical distribution of cyclosporine A between the aqueous and organic phases and only minor involvement of biological processes such as active transport and biotransformation. Hence, cyclosporine A uptake into cells is presumably transport mediated, supported by findings of transporter experiments performed on a parallel artificial membrane and Caco-2 cells. Plastic adsorption of cyclosporine A was significant, but different for each model, and should be considered by physiologically based pharmacokinetic modeling. Kinetics of adefovir dipivoxil highlights the limits of in vitro approaches. Active transporters are required for adefovir uptake, but were not functional in RPTECT/TERT1. Therefore, adefovir uptake was limited to passive diffusion of adefovir dipivoxil, which itself degrades time-dependently under culture conditions. Cisplatinum kinetics, studied in RPTEC/TERT1 cells, indicated intracellular enrichment of platinum, while significant bioaccumulation was not noted. This could be due to cisplatinum not reaching steady state levels within 14 days repeated exposure. As shown in vivo, active transport occurred from the basolateral to apical side, but with lower velocity. Hence, obtained data need to be modeled to estimate cellular processes, which can be scaled and compared to in vivo. Repeated daily exposure to two different drug concentrations makes it possible to account for bioaccumulation at toxic concentrations or biotransformation/extrusion at non-toxic concentrations. Potential errors leading to misinterpretation of data were reduced by analyses of the vehicles as the applied drug concentrations do not necessarily correspond to the nominal concentrations. Finally, analyses of separate compartments (medium, cells, plastic) give insights into a compound's distribution, reduce misprediction of cellular processes, e.g. biotransformation, and help to interpret kinetic data. On the other hand, the limits of in vitro approaches have also been pointed out. For correct extrapolation to in vivo, it is essential that the studied in vitro system exhibits the functionality of proteins, which play a key role in the specific drug induced toxicity. Considering the benefits and limitations, it is worth to validate this long-term treatment experimental set-up and expand it on co-culture systems and on organs-on-chips with regard to alternative toxicity testing strategies for repeated dose toxicity studies.},
  subject      = {Zellkultur},
  language  = {en}
}
@phdthesis{Vogl2011,
  author    = {Vogl, Silvia},
  title     = {Investigation of individual differences in the metabolic elimination of drugs by the polymorphic enzymes CYP2C9, 2C19 and 2D6 based on metabolite profiling by LC-MS/MS},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-67216},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2011},
  abstract  = {Mit der vorliegenden Studie sollte zu dem wichtigen Forschungsfeld der Pharmakogenetik beigetragen werden, indem zum einen eine einfache und sichere kombinierte Ph{\"a}notypisierung der drei zuvor erw{\"a}hnten CYPs (CYP2D6, CYP2C9 und CYP2C19) entwickelt, und zum anderen die Vorhersagekraft des Genotyps f{\"u}r den gemessenen Ph{\"a}notyp n{\"a}her untersucht werden sollte. Es ist uns gelungen eine sichere, einfache, schnelle und kombinierte Ph{\"a}notypisierung der beiden wichtigen Monooxygenasen CYP2D6 und CYP2C9 zu etablieren. Zun{\"a}chst wurden dazu Wechselwirkungsstudien mit den ausgew{\"a}hlten Testsubstanzen Dextromethorphan (DEX, CYP2D6), Flurbiprofen (FLB, CYP2C9) und Omeprazole (OME, CYP2C19) durchgef{\"u}hrt. Es konnte gezeigt werden, dass DEX und FLB als Kombination verabreicht werden k{\"o}nnen. Die Gabe von OME gemeinsam mit FLB ver{\"a}ndert jedoch das Ergebnis der CYP2C9 Ph{\"a}notypisierung. Dies ist eine neue Erkenntnis, denn noch 2004 wurde ein Ph{\"a}notypisierungscocktail ver{\"o}ffentlicht, der die Kombination von FLB und OME enthielt. Bei der genannten Studie wurden jedoch, unseres Wissens nach, keine Wechselwirkungsstudien zu den einzelnen Testsubstanz-Kombinationen durchgef{\"u}hrt. Die von uns entwickelte Ph{\"a}notypisierungsmethode wurde durch Wechselwirkungsstudien verifiziert. Sie ist jedoch auch in anderen Bereichen den bisher ver{\"o}ffentlichten ph{\"a}notypisierungscocktails {\"u}berlegen. Zum einen wurden nur sehr kleine Dosen sicherer Testsubstanzen verwendet. Dies wurde durch Entwicklung neuer, sensitiver LC-MS/MS Methoden erm{\"o}glicht. Zum anderen ist diese neue Prozedur schnell und nicht-invasiv durchf{\"u}hrbar. Nach Verabreichung der Testsubstanz muss der Urin nur f{\"u}r zwei Stunden gesammelt werden. Zudem weisen unsere Ergebnisse darauf hin, dass die normalerweise durchgef{\"u}hrte, aufwendige Glucuronidspaltung des CYP2D6 abh{\"a}ngigen DEX-Metaboliten, Dextrorphan, vermutlich vernachl{\"a}ssigt werden kann. Die wichtigsten Ergebnisse dieser Studie sind jedoch die Einblicke, die in die Vorhersagekraft der CYP2D6 und CYP2C9 Genotypen f{\"u}r die entsprechenden Ph{\"a}notypen gewonnen werden konnten. Fast 300 ph{\"a}notypisierte Kaukasier wurden auch in Hinsicht auf die wichtigsten varianten Allele von CYP2D6, CYP2C9 und CYP2C19 mithilfe bekannter und neu etablierter Methoden genotypisiert. Aufgrund der parallelen Ph{\"a}no- und Genotypisierung konnten Geno- und Ph{\"a}notyp direkt korreliert werden. Mit linearen Modellen war es m{\"o}glich, allen detektierten varianten CYP2D6- und CYP2C9-Allelen Aktivit{\"a}tskoeffizienten zuzuweisen. Diese k{\"o}nnen nun verwendet werden, um den Beitrag der einzelnen Allele zur resultierenden Enzymaktivit{\"a}t zu bestimmen, wodurch sich die Vorhersage dieser Aktivit{\"a}t ausgehend vom Genotyp verbessern lassen sollte. Besonders f{\"u}r CYP2D6 erm{\"o}glicht das neue Korrelationsmodel pr{\"a}zisere Vorhersagen des Ph{\"a}notyps als bisher ver{\"o}ffentlichte Modelle. Zusammengefasst leistet diese Studie durch die Entwicklung eines sicheren und einfachen Ph{\"a}notypisierungsprozesses f{\"u}r CYP2D6 und CYP2C9 und durch die Bestimmung von Aktivit{\"a}tskoeffizienten f{\"u}r alle einbezogenen CYP2D6 und CYP2C9 Allele und der damit verbundenen pr{\"a}ziseren Vorhersage des Ph{\"a}notyps ausgehend vom Genotyp einen wesentlichen Beitrag zum Forschungsfeld der Pharmakogenetik.},
  subject      = {Pharmakogenetik},
  language  = {en}
}