Influence of inflammation on voriconazole metabolism.

Voriconazole pharmacokinetics shows a large inter- and intrapatient variability. Inflammation is associated with changes in the expression of CYP isoenzymes. Here, we evaluated the influence of inflammation, marked by C-reactive protein (CRP) levels in blood, on the metabolism of voriconazole. Observational data showed an association between CRP level and the ratio of voriconazole N-oxide to voriconazole.

Nutlin-3 preferentially sensitises wild-type p53-expressing cancer cells to DR5-selective TRAIL over rhTRAIL.

BACKGROUND: Tumour cell-selective activation of apoptosis by recombinant human TNF-related apoptosis-inducing ligand (rhTRAIL) is enhanced through co-activation of p53 by chemotherapeutic drugs. The novel anticancer agent nutlin-3 provides a promising alternative for p53 activation by disrupting the interaction between p53 and its negative feedback regulator MDM2. METHODS: We examined whether nutlin-3 enhances apoptosis induction by rhTRAIL and the DR5-selective TRAIL variant D269H/E195R in wild-type p53-expressing ovarian, colon and lung cancer cell lines and in an ex vivo model of human ovarian cancer. RESULTS: Nutlin-3 enhanced p53, p21, MDM2 and DR5 surface expression. Although nutlin-3 did not induce apoptosis, it preferentially enhanced D269H/E195R-induced apoptosis over rhTRAIL. Combination treatment potentiated the cleavage of caspases 8, 9, 3 and PARP. P53 and MDM2 siRNA experiments showed that this enhanced apoptotic effect was mediated by wild-type p53. Indeed, nutlin-3 did not enhance rhTRAIL-induced apoptosis in OVCAR-3 cells harbouring mutant p53. Addition of the chemotherapeutic drug cisplatin to the combination further increased p53 and DR5 levels and rhTRAIL- and D269H/E195R-induced apoptosis. As a proof of concept, we show that the combination of D269H/E195R, nutlin-3 and cisplatin induced massive apoptosis in ex vivo tissue slices of primary human ovarian cancers. CONCLUSION: Nutlin-3 is a potent enhancer of D269H/E195R-induced apoptosis in wild-type p53-expressing cancer cells. Addition of DNA-damaging agents such as cisplatin further enhances DR5-mediated apoptosis.

Evaluation of fibrosis in precision-cut tissue slices.

1.In this review, the use of precision-cut tissue slices (PCTS) of the liver, kidney, lung and intestine in fibrosis research are evaluated and future possibilities are discussed. 2.In vivo models or techniques that are applicabless to be investigated in PCTS are discussed. 3.It is concluded that the early onset of fibrosis can be induced successfully in PCTS prepared from human and experimental animals. 4.Moreover, precision-cut slices of fibrotic tissue are effective in gaining new knowledge of the mechanisms of fibrosis and of the mode of action of potential antifibrotic drugs. 5.Both healthy and fibrotic human tissue slices will pave the way for the testing of novel therapeutic drugs to treat patients with fibrosis avoiding interspecies extrapolation.

Gene expression analysis of precision-cut human liver slices indicates stable expression of ADME-Tox related genes.

In the process of drug development it is of high importance to test the safety of new drugs with predictive value for human toxicity. A promising approach of toxicity testing is based on shifts in gene expression profiling of the liver. Toxicity screening based on animal liver cells cannot be directly extrapolated to humans due to species differences. The aim of this study was to evaluate precision-cut human liver slices as in vitro method for the prediction of human specific toxicity by toxicogenomics. The liver slices contain all cell types of the liver in their natural architecture. This is important since drug-induced toxicity often is a multi-cellular process. Previously we showed that toxicogenomic analysis of rat liver slices is highly predictive for rat in vivo toxicity. In this study we investigated the levels of gene expression during incubation up to 24 h with Affymetrix microarray technology. The analysis was focused on a broad spectrum of genes related to stress and toxicity, and on genes encoding for phase-I, -II and -III metabolizing enzymes and transporters. Observed changes in gene expression were associated with cytoskeleton remodeling, extracellular matrix and cell adhesion, but for the ADME-Tox related genes only minor changes were observed. PCA analysis showed that changes in gene expression were not associated with age, sex or source of the human livers. Slices treated with acetaminophen showed patterns of gene expression related to its toxicity. These results indicate that precision-cut human liver slices are relatively stable during 24h of incubation and represent a valuable model for human in vitro hepatotoxicity testing despite the human inter-individual variability.

Development of a Novel Ex-vivo 3D Model to Screen Amoebicidal Activity on Infected Tissue.

Amoebiasis is a parasitic disease that causes thousands of deaths every year, its adverse effects and resistance to conventional treatments have led to the search of new treatment options, as well as the development of novel screening methods. In this work, we implemented a 3D model of intestine and liver slices from hamsters that were infected ex vivo with virulent E. histolytica trophozoites. Results show preserved histology in both uninfected tissues as well as ulcerations, destruction of the epithelial cells, and inflammatory reaction in intestine slices and formation of micro abscesses, and the presence of amoebae in the sinusoidal spaces and in the interior of central veins in liver slices. The three chemically synthetized compounds T-001, T-011, and T-016, which act as amoebicides in vitro, were active in both infected tissues, as they decreased the number of trophozoites, and provoked death by disintegration of the amoeba, similar to metronidazole. However, compound T-011 induced signs of cytotoxicity to liver slices. Our results suggest that ex vivo cultures of precision-cut intestinal and liver slices represent a reliable 3D approach to evaluate novel amoebicidal compounds, and to simultaneously detect their toxicity, while reducing the number of experimental animals commonly required by other model systems.

Liver slices as a model to study fibrogenesis and test the effects of anti-fibrotic drugs on fibrogenic cells in human liver.

Cell culture models have contributed significantly to the study of liver fibrosis, but cannot accurately incorporate in vivo cell-cell and cell-extracellular matrix interactions or account for the heterogeneity of the fibrogenic cell population involved in fibrosis development. Thus, there persists a need for an in vitro model that mimics the in vivo situation more closely, which may be provided by using precision-cut liver slices. In the present study we evaluated human liver slices as a tool to study fibrogenesis and test anti-fibrotic drugs. In this study we examined the responses of fibrogenic cells in human liver slices during control incubation and studied the effect of the anti-fibrotic compound pentoxifylline both during control incubation and after induction of early hepatic stellate cell (HSC) activation by carbon tetrachloride. After prolonged (>24 h) incubation, alphaSMA and pro-collagen 1a1 mRNA expression in human liver slices started to increase. Analysis of synaptophysin and fibulin-2 mRNA expression indicated that both activated HSC and other (myo)fibroblasts may be involved in this process. This response of fibrogenic cells to prolonged incubation of the liver slices was accompanied by an increased collagen protein content and could be inhibited by pentoxifylline. Early HSC activation, which was reflected by increased HSP47 and alphaB-crystallin mRNA expression, was not inhibited by pentoxifylline. Preparation and/or culturing of human liver slices induces fibrogenesis, which may be mediated by both activated HSC and resident liver (myo)fibroblasts and may represent a simple and rapid method to test the effects of potential anti-fibrotic drugs on fibrogenic cells in human liver.

Coordinated induction of drug transporters and phase I and II metabolism in human liver slices.

Although regulation of phase I drug metabolism in human liver is relatively well studied, the regulation of phase II enzymes and of drug transporters is incompletely characterized. Therefore, we used human liver slices to investigate the PXR, CAR and AhR-mediated induction of drug transporters and phase I and II metabolic enzymes. Precision-cut human liver slices were incubated for 5 or 24h with prototypical inducers: phenobarbital (PB) (50 microM) for CAR, beta-naphthoflavone (BNF) (25 microM) for AhR, and rifampicin (RIF) (10 microM) for PXR, and gene expression of the phase I enzymes CYP1A1, 1A2, 3A4, 3A5, 2B6, 2A6, the phase II enzymes UGT1A1 and 1A6, and the transporters MRP2, MDR1, BSEP, NTCP and OATP8 was measured. BNF induced CYP1A1, UGT1A1 and UGT1A6 and MRP2, NTCP and MDR1. RIF induced CYP3A4, 3A5, 2B6, 2A6, UGT1A1, UGT1A6 and BSEP, MRP2 and MDR1 and slightly downregulated OATP8. PB induced CYP3A4, 3A5, 2B6 and 2A6, UGT1A1 and all transporters. Large interindividual differences were found with respect to the level of induction. Enzyme activity of CYP3A4, measured by testosterone metabolism, was increased after 24h by RIF. 7-Ethoxycoumarin O-deethylation activity, mediated predominantly by CYP 1A1/1A2 but also by other CYPs, was increased after 24h with PB. We have shown that regulation of all phases of the (in)activation of a drug via the CAR, AhR and the PXR pathways can be studied in human liver slices. The concomitant induction of metabolic enzymes and transporters shows that also in the human liver transporters and metabolic enzymes are regulated coordinately.

Highly efficient and carcinoma-specific adenoviral replication restricted by the EGP-2 promoter.

Although some successes have been reported using adenoviral vectors for the treatment of cancer, adenoviral cancer gene therapy is still hampered by the lack of sufficient tumor cell killing. To increase the efficiency, adenoviruses have been modified to replicate specifically in tumor tissues by using tumor specific promoters controlling genes essential for adenoviral replication. However, many conditionally replicating adenoviral vectors replicate in one tumor type only, which limits their application. The epithelial glycoprotein-2 (EGP-2) promoter is active in a broad variety of carcinomas, the most common type of cancer. We utilized this promoter to restrict adenoviral replication. In this report we demonstrate that the potency of the replication-competent adenovirus AdEGP-2-E1 to specifically lyse EGP-2 positive cells is comparable to wild-type adenovirus (AdWT). In addition, we show that in vivo AdEGP-2-E1 replicates as efficient as AdWT in EGP-2 positive tumor cells. On the contrary, in EGP-2 negative cell lines as well as in primary human liver samples, the replication was attenuated up to 4-log in comparison to wild-type virus. This report clearly shows the potency of the EGP-2 promoter to mediate highly efficient and specific adenoviral replication for carcinoma gene therapy.

Liver fibrosis in vitro: cell culture models and precision-cut liver slices.

Chronic liver injury of various etiologies can cause liver fibrosis, which is characterized by the progressive accumulation of connective tissue in the liver. As no effective treatment for liver fibrosis is available yet, extensive research is ongoing to further study the mechanisms underlying the development of disease- or toxicity-induced liver fibrosis and to identify potential pro- or anti-fibrotic properties of compounds. This review gives an overview of the in vitro methods that are currently available for this purpose. The first focus is on cell culture models, since the majority of in vitro research uses these systems. Both primary cells and cell lines as well as the use of different culture matrices and co-culture models are discussed. Second, the use of precision-cut liver slices, which recently came into attention as in vitro model for the study of fibrosis, is discussed. The overview clearly shows that continuous optimization and adaptation have extended the potential of in vitro models for liver fibrosis during the past years. By combining the use of the different cell and tissue culture models, the mechanisms underlying multicellular fibrosis development can be studied in vitro and potential pro- or anti-fibrotic properties of compounds can be identified both on single liver cell types and in human liver tissue.

Bioconjugation strategies to couple supramolecular exo-functionalized palladium cages to peptides for biomedical applications.

Supramolecular Pd2L4 cages (L = ligand) hold promise as drug delivery systems. With the idea of achieving targeted delivery of the metallacages to tumor cells, the bioconjugation of exo-functionalized self-assembled Pd2L4 cages to peptides following two different approaches is reported for the first time. The obtained bioconjugates were analyzed and identified by high-resolution mass spectrometry.

Human liver slices as an in vitro model to study toxicity-induced hepatic stellate cell activation in a multicellular milieu.

INTRODUCTION: Hepatic stellate cell (HSC) activation is a key event in wound healing as well as in fibrosis development in the liver. Previously we developed a technique to induce HSC activation in slices from rat liver. Although this model provides a physiologic, multicellular milieu that is not present in current in vitro models it might still be of limited predictive value for the human situation due to species-differences. Therefore, we now aimed to evaluate the applicability of human liver slices for the study of HSC activation. METHOD: Liver slices (8 mm diameter, 250 microm thickness) were generated from human liver tissue and incubated for 3 or 16 h with 0-15 microl of carbon tetrachloride (CCl4) after which ATP-content and expression levels of HSC (activation) markers was determined. RESULTS: Human liver slices remained viable during incubation as shown by constant ATP levels. Incubation with CCl(4) caused a dose-dependent decrease in viability and an increase in mRNA expression of the early HSC activation markers HSP47 and alphaB-crystallin, but not the late markers for HSC activation, alphaSMA and pro-collagen 1a1. Synaptophysin mRNA expression remained constant during incubation with or without CCl4, indicating a constant number of HSC in the liver slices. CONCLUSION: We developed a technique to induce early toxicity-induced HSC activation in human liver slices. This in vitro model provides a multicellular, physiologic milieu to study mechanisms underlying toxicity-induced HSC activation in human liver tissue.

Plasma membrane specialization and intracellular polarity of freshly isolated rat hepatocytes.

It was investigated whether rat hepatocytes maintain their plasma membrane specialization (sinusoidal, lateral and bile canalicular sites) and their intracellular polarity (peribiliary region, rich in lysosomes and poor in mitochondria) after isolation. The morphology of the hepatocytes and the cytochemical localization of marker enzymes for the bile canalicular membrane (alkaline phosphatase, adenosine triphosphatase and 5' nucleotidase), for the lysosomes (acid phosphatase) and for the mitochondria (beta-hydroxybutyrate dehydrogenase and succinate dehydrogenase) were studied in situ and directly after isolation using both light and electron microscopy. The morphology of the cells and the cytochemical activity of acid phosphatase, succinate dehydrogenase and beta-hydroxybutyrate dehydrogenase showed that in isolated cells, as in situ, the lysosomes were concentrated in bands, devoid of mitochondria. Unlike in situ the reaction product of alkaline phosphatase, adenosine triphosphatase and 5'nucleotidase was evenly distributed along the entire plasma membrane of the isolated cells. Morphologically, no tight or gap junctions or desmosomes could be detected in the isolated cells, while the plasma membrane appeared to be homogeneously covered with uniform microvilli. In conclusion it can be stated that during isolation the hepatocytes loose their distinct plasma membrane specialization, but maintain their peribiliary region rich in lysosomes and poor in mitochondria.

Precision-cut organ slices as a tool to study toxicity and metabolism of xenobiotics with special reference to non-hepatic tissues.

Metabolism of xenobiotics is often seen as an exclusive function of the liver, but some current findings support the notion that the lungs, kidneys and intestine may contribute considerably. After the establishment of the use of liver slices as a useful in vitro model to study metabolism and toxicity of xenobiotics, the same concept is currently being used for slices from lung, kidney and intestine. It is the aim of this review to discuss the use of organ slices in biotransformation research. The basic idea behind the use of tissue slices in biomedical research is the assumption that the cells under study will function optimally in vitro if they are cultivated in an environment that is most alike to their natural in vivo embedding, which is the case in tissue slices. Advantages in the use of organ slices are the relatively easy preparation as well as the potential standardization of both the preparation and use. Moreover, a direct interspecies comparison can be made between liver, lungs, kidneys and intestines, for example with respect to their metabolic capacity and their sensitivity for toxicants. Of major importance is that organ slices can be made with a similar procedure from organs/tissues originating from different species, including man. This latter aspect is useful in drug development in general but also for a better insight in the metabolic fate of compounds in man. Importantly the use of slices may largely contribute to a reduction in the use of experimental animals.

Drug uptake systems in liver and kidney.

The hepatobiliary system and the kidneys are the main routes by which drugs and their metabolites leave the body. Compounds that are mainly excreted into bile in general have relatively high molecular weights, are amphipathic and highly bound to plasma proteins. In contrast, compounds that are predominantly excreted into urine have relatively low molecular weights, are more hydrophilic and generally less protein bound. The first step in drug elimination in liver and kidney is uptake into hepatocytes or into proximal tubular cells. The substrate specificity and affinity of the uptake carriers expressed at the basolateral membranes of hepatocytes and proximal tubular cells could therefore play an important role for the determination of the main elimination route of a compound. This review discusses the tissue distribution, substrate specificity, transport mechanism, and regulation of the members of the organic anion transporting polypeptide (Oatp/OATP) superfamily (solute carrier family SLC21A) and the SLC22A family containing transporters for organic cations (OCTs) and organic anions (OATs). The Oatps/OATPs are mainly important for the hepatic uptake of large amphipathic organic anions, organic cations and uncharged substrates, whereas OCTs and OATs mediate uptake of predominantly small organic cations and anions in liver and kidney.

Value of the in vitro or in vivo monoethylglycinexylidide test for predicting liver graft function.

BACKGROUND: An adequate function test for donor livers is still lacking. The monoethylglycinexylidide (MEGX) test, performed in vivo in the donor to measure the metabolic rate of lidocaine conversion to MEGX, has been proposed as a function test for donor livers to predict postoperative organ function. METHODS: In the present study, we investigated whether the MEGX formation rate measured in needle biopsy specimens in vitro correlates with the rate of MEGX formation in vivo. The in vivo MEGX test was performed in the donors and in the recipients on days 1 and 2. The in vivo and in vitro MEGX tests were compared with posttransplant liver function in the recipients in order to investigate their possible relevance as predictors of graft function. RESULTS: The MEGX formation rate in needle biopsy specimens in vitro showed a significant correlation with the MEGX serum concentration found in the donor. A low rate of MEGX formation in the biopsy specimens tended to predict initial poor function of the grafts. In the donor, the MEGX test did not correlate with general liver function after transplantation. Only the MEGX serum concentration in the recipients on day 2 gave an indication of graft function. CONCLUSIONS: MEGX formation in liver biopsy specimens in vitro properly reflects metabolic function of the particular liver. Therefore, liver biopsies may be a valuable tool to help predict liver function in vivo. However, the MEGX test alone is not sufficient to provide the gold standard to determine liver function in donor and transplantation livers.

Angiotensin-converting enzyme inhibition-induced changes in hippurate renography and renal function in renovascular hypertension.

UNLABELLED: We studied the mechanism of angiotensin-converting enzyme (ACE) inhibition-induced changes in hippurate renography of the poststenotic kidney. METHODS: Ten male mongrel dogs, six with unilateral and four with bilateral renal artery stenosis, were equipped with renal artery blood flow probes and catheters in the aorta, atrium and both renal veins. RESULTS: Enalaprilat (10 mg intravenously) in conscious dogs with renal artery stenoses produced changes in all stenotic (n = 11) but not in nonstenotic kidney 123I-hippurate renograms (n = 6). Renographic changes correlated significantly with initiation of intrarenal 131I-hippurate retention, a decrease in mean arterial pressure (MAP), renal extraction of 131I-hippurate and 125I-iothalamate (r = 0.68, r = 0.62, r = 0.84, r = 0.83, respectively) but not with renal blood flow changes (r = 0.34). Furthermore, renal uptake of 131I-hippurate and 125I-iothalamate decreased in stenotic kidneys with a grade II renogram (-52 +/- 11% and -79 +/- 6%, respectively). Iodine-125-hippurate autoradiograms of stenotic kidneys during ACE inhibition showed tracer retention mainly in the proximal tubular cells. Results during osmotic diuresis supported our findings. CONCLUSION: Angiotensin-converting enzyme inhibition-induced hippurate retention curves of poststenotic kidneys appear to result from a sequence of events. A decrease in MAP combined with efferent vasodilation leads to a decrease in intraglomerular capillary pressure. This decrease in pressure causes a decrease in glomerular filtration rate and proximal tubular urine flow. This decrease in turn hampers tubular hippurate transit and transport across the luminal membrane, leading to intrarenal hippurate retention and, in more severe cases, decreased renal hippurate uptake.

Mechanistic aspects of uptake and sinusoidal efflux of dibromosulfophthalein in the isolated perfused rat liver.

Using the isolated perfused rat liver technique we examined whether the accumulation and sinusoidal efflux processes of the organic anion dibromosulfophthalein (DBSP) are dependent on the intracellular ATP content, chloride concentration in the perfusion medium as well as temperature of the medium and whether they are mediated by the same or by separate carrier mechanisms. The net sinusoidal efflux rate, being the resultant of sinusoidal efflux and re-uptake, was decreased more than 50% after lowering the medium temperature from 37 to 26 degrees indicating that the efflux process is carrier-mediated. The uptake rate was decreased only 18% after lowering the medium temperature to 26 degrees. Lowering of the hepatic ATP content for more than 80% clearly decreased the DBSP uptake rate but not the sinusoidal efflux rate. These observations indicate that these opposing transport steps probably are mediated by two separate carriers. Additional evidence for this hypothesis originated from the observation that sinusoidal efflux of DBSP was decreased about 30% whereas hepatic uptake of the substrate remained unaltered after replacing chloride in the perfusion medium with gluconate. In summary, we conclude that uptake and sinusoidal efflux of DBSP are mediated by two separate carrier systems that are influenced differently by ATP depletion, temperature lowering and presence of Cl-gradients.

Drug transport, viability and morphology of isolated rat hepatocytes preserved for 24 hours in University of Wisconsin solution.

Isolated hepatocytes are a valuable tool to study liver functions. Suitable methods to preserve the isolated cells with good maintenance of viability and functions are crucial to extend experiments with hepatocytes from a single isolation over 2 or more consecutive days. We investigated whether University of Wisconsin (UW) solution, which was designed to preserve organs for transplantation, is also suitable for preservation of isolated rat hepatocytes. Viability, as determined by Trypan blue exclusion and reduction of the tetrazolium 3(4,5-dimethyl-thiazoyl-2-yl)2,5 diphenyltetrazolium bromide to a purple formazan, morphological appearance using electron microscopy, ATP levels and uptake and storage of three model drugs ([3H]vecuronium, [3H]taurocholic acid and [3H]ouabain) were determined directly after isolation and after 22 hr of storage in UW solution at 0-4 degrees. The present study shows that cold storage of rat hepatocytes for 22 hr in UW can be performed without significant loss of viability and with maintenance of proper morphology, cellular ATP and transport functions. In contrast, after storage in Krebs-Henseleit buffer the normal morphology, ATP content and transport functions were strongly affected. These results imply that hepatocytes from a single isolation and stored in UW solution can be used for experiments on 2 consecutive days.

Secretion of the organic anion harmol sulfate from liver into blood. Evidence for a carrier-mediated mechanism.

In the liver, drugs with phenolic groups can be converted to sulfate or glucuronide conjugates and are then transported into bile or back into the bloodstream. The mechanism for transport of drugs and drug conjugates from the hepatocytes into the blood at the sinusoidal side of the cell are not well defined. In the case of carrier-mediated transport of these strongly polar conjugates, saturability of transport and mutual competition between structurally related compounds would be anticipated. This competitive aspect was investigated by using two organic anions, dibromosulfophthalein (DBSP) and harmol sulfate. The latter compound was generated by the hepatocytes from harmol, which was continuously infused into the rat in vivo and in isolated perfused rat livers. In addition we loaded the perfused rat livers with preformed harmol sulfate and studied its efflux rate to the perfusate as influenced by DBSP. In steady state, about 80% of harmol was sulfated and 20% was glucuronidated. Harmol sulfate was mainly excreted in the urine, the glucuronide was equally excreted in urine and bile. DBSP lowered the urinary excretion of harmol sulfate by about 30% which was due to a decrease in plasma concentration. However, renal clearance of harmol sulfate (3.2 +/- 0.2 ml/min) was unchanged. At the same time DBSP doubled the biliary clearance of harmol sulfate (1.0 +/- 0.1 and 2.2 +/- 0.2 ml/min in controls and DBSP studies respectively). DBSP decreased glucuronide excretion both in urine and bile. The increase in biliary output and decrease in urinary excretion of harmol sulfate is explained by competitive interaction between the organic anion DBSP and harmol sulfate at the sinusoidal level. Efflux experiments in single pass perfused isolated livers showed a clear decrease of harmol sulfate transport from liver into plasma by DBSP and provided evidence for such an inhibitory phenomenon (t 1/2 of efflux was 3.58 +/- 0.21 compared with 2.46 +/- 0.07 min for controls). These results indicate that organic anion transport from the hepatocyte into the blood stream is very likely carrier-mediated. A decrease in renal output of drug conjugates therefore may not only be due to a decrease in the conjugation process but also to a lower liver to blood transport rate which at the same time may produce a higher biliary output.

Acinar heterogeneity in hepatic transport of dibromosulfophthalein and ouabain studied by autoradiography, normal and retrograde perfusions and computer simulation.

This study is aimed to investigate the relative involvement of periportal (zone 1) and perivenous (zone 3) hepatocytes in the uptake and biliary excretion of the organic anion dibromosulfophthalein (DBSP) and the uncharged cardiac-glycoside ouabain. The localization in the acinus of [35S]BSP (sulfobromophthalein, the tetra-bromo-analogue of DBSP) and [3H]ouabain administered to livers perfused with normal and retrograde flow, was detected by autoradiography. The plasma disappearance and biliary excretion rates of DBSP and [3H]ouabain were determined in normal and retrograde perfusions. In addition, computer simulations were performed to predict the effect of reversal of the perfusate flow on the plasma disappearance and biliary excretion rate curves and on the concentration of label in zones 1 and 3. Autoradiography showed that 2 and 10 min after injection of [35S]BSP to normally and retrogradely perfused livers, the label was uniformly distributed in the liver acinus. The same results were found 30 sec and 10 min after injection of [3H]ouabain to normally and retrogradely perfused livers. The plasma disappearance and biliary excretion rate of DBSP were slightly faster in retrograde perfusions compared to normal perfusions both with and without a basal bile salt infusion of 15 mumole/hr. This could not be explained by an acinar heterogeneity with respect to any of the DBSP transport steps (plasma to liver, liver to plasma, liver to bile) as was shown by computer simulations. The plasma disappearance and biliary excretion rate of ouabain were similar in normal and retrograde perfusions. It is concluded that periportal and perivenous hepatocytes are equally involved in the uptake of (D)BSP and ouabain from the medium. However, due to the particular distribution patterns no conclusions can be drawn from normal and retrograde perfusions about the relative involvement of these cells in biliary excretion, as was shown by computer simulation. The unaffected kinetic behaviour of the retrogradely perfused livers indicated that no liver damage occurs during retrograde perfusion with respect to transport function.