D Galavotti scite author profile

The variety of methods for measuring bioactive mass and functionality of bioartificial livers (BAL) is confusing and prevents accurate comparison of reported data. Here we present a comparison of different hepatocyte quantification methods and propose that estimation of cell pellet volume after centrifugation generates a reliable, useful and fast method. In addition a correlation is made between several function tests performed in 26 bioreactors to assess their predictive value. The ammonia eliminating capacity was found to be most predictive for other liver functions, except for lidocaine elimination as a measure of mixed function oxidase activity, which should therefore be determined separately. The oxygen consumption test proved to be an easy and predictive parameter as well. The first generation of our BAL system needed further development to assure optimal treatment of acute liver failure (ALF) patients. Changes in the porcine hepatocyte isolation method and bioreactor loading as well as changes in bioreactor configuration, including use of different materials, resulted in a significantly improved level and maintenance of in vitro BAL function. A fourfold increase in ammonia eliminating capacity, which is only reduced to 75% after seven days of culturing, offers promising prospects for further clinical application. Conclusion The current second generation of our BAL and improvement of hepatocyte isolation and testing protocols have led to a significant increase in the level as well as the maintenance of hepatocyte specific function in our BAL. Finally, consensus on definition of the bioactive mass to be loaded in the bioreactor and insight in the variation and reliability of the functional and metabolic parameters enhances comparison of the different types of bioartificial livers presented in literature.

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Long‐Term Expression of Highly Differentiated Functions by Isolated Porcine Hepatocytes Perfused in a Radial‐Flow Bioreactor

Morsiani¹,

Brogli²,

Galavotti³

et al. 2001

Artificial Organs

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To overcome the limitations of standard hollow-fiber module in ensuring efficient cell perfusion and long-term expression of highly differentiated hepatocyte functions, we developed a novel bioreactor in which a three-dimensional hepatocyte culture system was perfused in radial-flow geometry. Isolated porcine hepatocytes were cultured for 2 weeks in recirculating serum-free tissue culture medium, in which NH4Cl and lidocaine were repeatedly added, and ammonia removal, urea synthesis, monoethylglycinexylide (MEGX) production, albumin secretion, Po2, Pco2, O2 consumption, and pH were measured thereafter. During the whole duration of the study, ammonia removal was paralleled by urea production, while MEGX concentration was constantly increased. Our results indicated that hepatocytes remained differentiated and metabolically active throughout the duration of the study. The radial-flow bioreactor allowed physiological contact between recirculating fluid and cells by equalizing the concentration of the perfusing components, including O2, throughout the module, suggesting a potential use of this configuration for extracorporeal liver support.

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Biologic Liver Support: Optimal Cell Source and Mass

Morsiani¹,

Brogli²,

Galavotti³

et al. 2002

Int J Artif Organs

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Hepatic support is indicated in acute liver failure (ALF) patients to foster liver regeneration, or until a liver becomes available for orthotopic liver transplantation (OLT), in primary non function of the transplanted liver, and hopefully in chronic liver disease patients affected by ALF episodes, in whom OLT is not a therapeutic option. The concept of bioartificial liver (BAL) is based on the assumption that only the hepatocytes can perform the whole spectrum of biotransformation functions, which are needed to prevent hepatic encephalopathy, coma and cerebral edema. Among others, two important issues are related to BAL development: 1) the choice of the cellular component; 2) the cell mass needed to perform an adequate BAL treatment. Primary hepatocytes, of human or animal origin, should be considered the first choice because they express highly differentiated functions. Accordingly, a minimal cell mass corresponding to 10% of a human adult liver, i.e. 150 grams of freshly isolated, ≥90% viable hepatocytes should be used. When 4 °C cold-stored or cryopreserved hepatocytes are used, the cellular mass should be increased because of a drop in cell viability and function. In case of hepatoma-derived cells, cultured cell lines or engineered cells, an adequate functional cell mass should be used, expressing metabolic and biotransformation activities comparable to those of primary hepatocytes. Finally, the use of porcine hepatocytes or other animal cells in BAL devices should be presently directed only to ALF patients as a bridge treatment to OLT, because of potential transmission of animal retrovirus and prions which may potentially cause major pandemics..

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Time-Related Analysis of Metabolic Liver Functions, Cellular Morphology, and Gene Expression of Hepatocytes Cultured in the Bioartificial Liver of the Academic Medical Center in Amsterdam (AMC-BAL)

et al. 2007

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A comprehensive understanding of the mechanisms that underlie hepatic differentiation inside a bioartificial liver (BAL) device is obtained when functional, histological, and gene expression analyses can be combined. We therefore developed a novel cell-sampling technique that enabled us to analyze adherent hepatocytes inside a BAL device during a 5-day culture period, without the necessity of terminating the culture. Biochemical data showed that hepatocyte-specific functions were relatively stable, despite an increase in glycolytic activity. Quantitative reverse transcriptase polymerase chain reaction analysis of hepatic genes cytochrome p450 3A29, albumin, glutamine synthetase, alpha-1 antitrypsin, and carbamoyl-phosphate synthetase, but also de-differentiation marker pi-class glutathione S transferase showed stable messenger ribonucleic acid (mRNA) levels from day 1 to 5. In contrast, mRNA levels of alpha-fetoprotein, pro- and anti-apoptotic genes Bax-alpha and Bcl-X(L), metabolic genes lactate dehydrogenase and uncoupling protein 2, and cytoskeleton genes alpha- and beta-tubulin and beta-actin increased in 5 days. Histological analysis revealed viable tissue-like structures with adaptation to the in vitro environment. We conclude that hepatocytes show a tendency for de-differentiation shortly after seeding but thereafter remain acceptably differentiated during 5 days of culture. Furthermore, partly impaired mitochondrial function is suggestive for local hypoxic regions and may trigger the observed metabolic changes. Anti-apoptotic activity seems to balance pro-apoptotic activity. This new cell-sampling technique facilitates the analysis of dynamic processes of hepatocyte culture inside a BAL.

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Advanced Technology for Extracorporeal Liver Support System Devices

Borra¹,

Galavotti²,

Bellini³

et al. 2002

Int J Artif Organs

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Acute Liver Failure (ALF) still presents high mortality rates, and liver transplant is the only treatment with proven efficacy. However transplant is not always possible and systems for Extracorporeal Liver Support (ELS) are being developed which can treat patients with ALF, for whom a transplant is not available, or is delayed. They can also treat patients with chronic liver disease who develop ALF. There are two types of ELS: artificial systems (hemoperfusion, plasmaperfusion, therapeutic plasma exchange, continuous hemodialysis and high volume continuous hemofiltration) and bioartificial systems. These are based on a biological component (animal or human hepatocytes) inserted into a bioreactor, whose main function is to perform the metabolic activity and synthesis that the liver can no longer perform. The results obtained in clinical trials have so far shown that the best results in terms of compensating for lost metabolic function and detoxification are obtained inserting artificial components in the bioartificial circuit.

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D Galavotti

Assessment and Improvement of Liver Specific Function of the AMC-Bioartificial Liver

Long‐Term Expression of Highly Differentiated Functions by Isolated Porcine Hepatocytes Perfused in a Radial‐Flow Bioreactor

Biologic Liver Support: Optimal Cell Source and Mass

Time-Related Analysis of Metabolic Liver Functions, Cellular Morphology, and Gene Expression of Hepatocytes Cultured in the Bioartificial Liver of the Academic Medical Center in Amsterdam (AMC-BAL)

Advanced Technology for Extracorporeal Liver Support System Devices

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