Cel To obtain primary porcine hepatocyte cultures and determine rate equations for oxygen consumption and other metabolic reactions in various culture media and in liver failure serum.To perform hydrodynamic optimisation and obtain macroscopic transfer models of specific bioreactors containing immobilised primary porcine hepatocytes. To evaluate bioreactor function in vivo model of liver failure.Engineering design techniques and mathematical analysis in conjunction with relevant cell biology and clinical experience will be employed to develop optimised hepatocyte bioreactors for treatment of fulminant hepatic failure (FHF). Primary porcine hepatocytes will be obtained and evaluated in static cultures using different culture media, normal blood plasma and FHF plasma. Cell viability will be assessed by lactate dehydrogenase release and function by cytochrome P450 content, activities of P450 isoenzymes, urea synthesis and changes in reduced glutathione content. Rate equations for several liver dependent metabolic functions will be obtained in a smallscale flow reactor seeded with porcine hepatocytes. The influence of metabolite concentrations and physical operatic;, parameters ( e.g. shear rate. cell density. pH) will be studied. A novel oxystat apparatus will be used to determine cellular oxygen consumption during the critical phase of cell attachment to selected substrata as well as in the post-attachment phase of operation. These fundamental properties will enable the development of macroscopic mass transfer models of two existing bioreactor designs. Both designs utilise fibre technology to provide integral oxygenation. Fluid dynamic optimisation of these devices will he carried out and scaling rules established for bioreactor scale-up. Long term in bitro testing of the bioreactors will be performed with different culture media, normal plasma and FHF plasma. Finally, a scaled-up design will be evaluated in an animal model of FHR. Important aspects of this latter task are the establishment of a stable model of FHF and successful integration of the bioreactor and associated plasmapheresis system in the extra-corporal circuit. Dziedzina nauki engineering and technologyenvironmental biotechnologybioremediationbioreactorsnatural sciencesmathematicspure mathematicsmathematical analysisnatural sciencesbiological sciencescell biologynatural sciencesphysical sciencesclassical mechanicsfluid mechanicsfluid dynamicsmedical and health sciencesmedical biotechnologytissue engineeringbioartificial liver Program(-y) FP4-BIOMED 2 - Specific research, technological development and demonstration programme in the field of biomedicine and health, 1994-1998 Temat(-y) 2.5 - Cellular engineering Zaproszenie do składania wniosków Data not available System finansowania CSC - Cost-sharing contracts Koordynator University of Strathclyde Wkład UE Brak danych Adres 106 Rottenrow G4 0NW Glasgow Zjednoczone Królestwo Zobacz na mapie Koszt całkowity Brak danych Uczestnicy (4) Sortuj alfabetycznie Sortuj według wkładu UE Rozwiń wszystko Zwiń wszystko Humboldt-Universität zu Berlin Niemcy Wkład UE Brak danych Adres 1,AUGUSTENBURGER PLATZ 13353 BERLIN Zobacz na mapie Koszt całkowity Brak danych National and Kapodistrian University of Athens Grecja Wkład UE Brak danych Adres 17,AG THOMA STREET 115 27 ATHENS Zobacz na mapie Koszt całkowity Brak danych University of Edinburgh Zjednoczone Królestwo Wkład UE Brak danych Adres LAURISTON PLACE EH3 9YW EDINBURGH Zobacz na mapie Koszt całkowity Brak danych Università degli Studi della Calabria Włochy Wkład UE Brak danych Adres Via Pietro Bucci 87030 Arcavacata di Rende Zobacz na mapie Koszt całkowity Brak danych