Techniques for intrasplenic hepatocyte transplantation in the large animal model

BACKGROUND

The preferred therapy for acute and chronic liver insufficiency and severe heritable disorders of liver metabolism is whole-organ transplantation. However, due to the shortage of organ donors and high cost, alternative therapeutic approaches have been proposed, including transplantation of normal allogeneic hepatocytes. Recently, it has been reported that many hepatocytes transplanted into the spleen migrated to the liver. We therefore carried out a series of large-animal experiments to reexamine the intrasplenic route and to develop a method for large-scale hepatocellular transplantation in pigs.

METHODS

Allogeneic porcine hepatocytes were transplanted using the following routes: (1) retrograde injection of cells via the splenic vein, (2) intraarterial injection of cells, (3) direct intrasplenic injection of cells after laparotomy, (4) percutaneous intrasplenic injection of cells under laparoscopic control, (5) laparoscopic intrasplenic injection of cells. The number of cells injected varied from 2 x 10(9) to 10 x 10(9) cells.

RESULTS

Of all the methods tested, only direct intrasplenic injection of 2 bln of cells was found to be compatible with survival. However, even with this "small" number of cells (2% original liver mass), there was a significant risk of spleen infarction, perisplenic adhesion formation, and portal vein thrombosis. The laparoscopic approach was found to be reliable, simple, and safe.

CONCLUSION

Even though the spleen is considered by many authors the optimal site for hepatocellular transplantation, transplantation of cells in a number needed to support the failing liver may be associated with significant complications, morbidity, and mortality.

Clinical experience with a porcine hepatocyte-based liver support system

The only clinically proven effective treatment of fulminant hepatic failure (FHF) is orthotopic liver transplant (OLT). However, many patients die before an organ becomes available. Thus, there is a need for development of an extracorporeal liver support system to "bridge" these patients either to OLT or spontaneous recovery. We developed a bioartificial liver (BAL) based on plasma perfusion through a circuit of a hollow-fiber cartridge seeded with matrix-anchored porcine hepatocytes to treat patients with severe acute liver failure. Two groups of patients were studied. Group 1 (n = 12): patients with FHF. All patients were successfully "bridged" to OLT. "Bridge" time to OLT was 21-96 hr (mean: 39.3 hr). All patients were discharged neurologically intact. Reversal of decerebration was noted in all 11 deep stage 4 coma patients. There was reduction in intracranial pressure (ICP mmHg, 18.2 +/- 2.2 to 8.5 +/- 1.2; p < 0.004) and increase in cerebral perfusion pressure (CPP mmHg, 71.1 +/- 4.0 to 84.7 +/- 2.6; p < 0.006). Laboratory values pre- and post-BAL treatment: glucose (mg/dl) 122 +/- 11 to 183 +/- 21, p < 0.002; ammonia (mumol/l) 155.6 +/- 13.2 to 121.6 +/- 9.5, p < 0.02; total bilirubin (mg/dl) 21.6 +/- 2.8 to 18.2 +/- 2.2, p < 0.001; PT (sec) 23.2 +/- 1.7 to 21.9 +/- 1.0, p < 0.3. Group II (n = 8): patients with chronic liver failure experiencing acute exacerbation. Two patients survived and later underwent OLT. Six patients (not OLT candidates) died 1-14 days after last BAL treatment. Laboratory values pre- and post-treatment: ammonia (mumol/l) 201 +/- 47 to 143 +/- 25, p < 0.06; total bilirubin (mg/dl) 22.8 +/- 5.2 to 19.5 +/- 4.4, p < 0.01; PT (sec) 22.5 +/- 2.0 to 21.8 +/- 1.1, p < 0.6.

CONCLUSION

our clinical experience with the BAL suggests that it may serve as "bridge" to OLT in patients with FHF primarily by reversing intracranial hypertension, but it is not a substitute for OLT in patients with end-stage liver disease who are non-transplant candidates.

Treatment of hypercholesterolemia in the Watanabe rabbit using allogeneic hepatocellular transplantation under a regeneration stimulus

Numerous studies have reported successful allotransplantation of hepatocytes. However, none have shown long-term correction of a liver-related metabolic defect. In this study, we used a method of regional hepatocyte transplantation and subsequent induction of transplanted cell proliferation by regeneration response in the transplant-bearing liver lobes. New Zealand White rabbits were used as cell donors and Watanabe heritable hyperlipidemic (WHHL) rabbits were used as cell recipients (2 x 10(8) cells/rabbit). All recipient rabbits were maintained on daily cyclosporine. Two weeks after baseline serum cholesterol determination, group I WHHL rabbits (n = 7) received an infusion of cells into the right lateral liver lobe, and a loose ligature was placed around the portal venous branch supplying the anterior lobe. After 1 week, to allow engraftment, the portal venous branch was ligated, which resulted in the atrophy of the affected liver parenchyma and induction of hyperplasia in the transplant-bearing liver tissue. Group II rabbits (n = 6) were transplanted with New Zealand White hepatocytes without portal branch ligation (PBL) and group III rabbits (n = 4) were subjected to sham transplantation (saline) and PBL. The experimental period extended to 150 days after transplantation. All WHHL rabbits transplanted with normal hepatocytes showed reduction in serum cholesterol and low-density lipoprotein (LDL) levels. Group I (PBL-stimulated) recipients demonstrated a more pronounced and sustained effect than group II animals (P < 0.05). Group III controls showed only a slight, typical for aging decrease in serum cholesterol. Group I recipient livers perfused with LDL labeled with 1,1'-dioctadecyl-3,3,3',3'-tetramethyl indocarbocyanine perchlorate (DiI) showed much higher numbers of DiI-LDL-positive hepatocytes than those of group II recipients. In conclusion, a liver regeneration stimulus enhanced the population of transplanted hepatocytes and their functional effect in a large animal model of inborn error of liver metabolism.

Long-term correction of albumin levels in the Nagase analbuminemic rat: repopulation of the liver by transplanted normal hepatocytes under a regeneration response

Numerous studies have reported successful transplantation of hepatocytes with demonstration of function. However, none have shown long-term correction of a liver-related metabolic defect. Male Nagase analbuminemic rats, immunosuppressed with cyclosporin-A, were transplanted with normal hepatocytes (2 x 10(7) cells/rat) isolated from allogeneic male Sprague-Dawley rat donors. Hepatocytes were selectively transplanted via the portal vein tributary into the posterior liver lobes of Nagase analbuminemic rats. Following 2 wk, to allow engraftment, selected transplanted rats (Group I) were reoperated and the portal venous branch supplying the anterior liver lobes was permanently ligated, resulting in their atrophy and induction of regeneration in the residual transplant-bearing lobes. Control rats consisted of: Group II-transplanted with normal hepatocytes without portal branch ligation; Group III-transplanted with analbuminemic hepatocytes with portal branch ligation; and Group IV-nontransplanted analbuminemic rats with portal branch ligation. The experimental period extended to 3 mo posttransplantation. All rats transplanted with normal hepatocytes demonstrated a significant elevation in serum albumin levels (ELISA). Group I rats had dramatic elevations in serum albumin to near normal levels (1.78 +/- 0.20 g/dl), and maintained these levels until the end of the experiment. Albumin levels in Group II rats reached 0.26 +/- 0.07 g/dl (p < 0.001), whereas Group III and IV rats showed no changes in serum albumin levels throughout the experiment. Immunohistology of liver tissue obtained from Group I rats, demonstrated large numbers (22.6 +/- 7.5%) of albumin-positive hepatocytes populating the recipient liver. This is the first report of near-total and sustained correction of a genetic defect in liver function in an experimental animal model following allogeneic hepatocyte transplantation.

Matrix-induced liver cell aggregates (MILCA) for bioartificial liver use

Ex vivo reproduction of liver microstructure using isolated hepatocytes is critical for bioartificial liver use. We have developed a method of producing matrix-induced liver cell aggregates (MILCA) using a small number of collagen-coated beads as a nidus for formation of hepatocyte aggregates. Porcine hepatocytes were obtained by EDTA/collagenase digestion. Cell viability was assessed by trypan blue exclusion and LDH release. Cytochrome P-450 activity was determined at 4 and 24 hours by measuring the formation of 7-hydroxycoumarine (7-HC) from 7-ethoxycoumarine (7-EC). At 4 hours, the viability of MILCA was 92 +/- 2%, LDH release was 100 +/- 22 U/L and 7-HC formation was 140 +/- 34 nM/g cells. At 24 hours, MILCA viability remained greater than 90%, but 7-HC formation was lower than that of parallel control monolayer hepatocyte cultures (194 +/- 43 vs 481 +/- 78 nM/g cells; p < 0.002). On transmission electron microscopy, MILCA ultrastructure resembled that of a normal liver (maintenance of cell polarity, gap junctions, bile canaliculi, intact organellae, glycogen granules). MILCA were subsequently inoculated into hollow-fiber bioreactors which were perfused for 6 hours with plasma recovered from patients with fulminant hepatic failure (n = 6; 5 x 10(9) cells/cartridge, recirculation of 350 ml of plasma at 400 ml/min). In these studies, lidocaine (20 micrograms/ml) was cleared in less than 3 hours and 7-HC production at 6 hours was 71 +/- 8 nM/g cells. Other MILCA effects noted in this system included lowering of plasma lactate, bilirubin and ammonia and increase in the level of several non-essential amino acids.

Artificial liver. Evolution and future perspectives

Whole organ transplantation is the only clinically effective method of treating fulminant hepatic failure and chronic liver failure due to specific genetic, hepatocellular, and anatomic defects of liver function. However, wider application of liver transplantation is limited by shortage of organ donors, high cost, a relatively high morbidity rate, and need for life long immunotherapy. As a result, investigators have attempted to develop alternative methods to treat liver insufficiency. These ranged from use of plasma exchange to use of detoxification columns and extracorporeal devices loaded with various liver tissue preparations. Several liver support systems were developed in the 1950s and 1960s, but it was not until recently that advances in hepatocyte isolation and culture, improved understanding of hepatocyte-matrix interactions, availability of new biomaterials, improved hollow fiber technology, and better understanding of flow and mass transport across semipermeable membranes resulted in the development of a new generation of liver assist devices. Some of these devices are being tested in the clinical setting. In this article, the authors review past experience with liver support systems, critically examine the current status of the field by drawing primarily on their own experience, and attempt to speculate on the future direction of liver assist system development.

Teleost fish islets: a potential source of endocrine tissue for the treatment of diabetes

Anatomical separation of pancreatic islets in some teleost fish makes them a useful source of pancreatic endocrine tissue. Islets were harvested from tropical Tilapia fish (Oreochromis nilotica) and cultured for 24 hr at 37 degrees C. Eight athymic nude mice were rendered diabetic by streptozotocin (STZ) and transplanted under the kidney capsule with fish islets. After transplantation (Tx), nonfasting blood glucose (n-FBG), which was in all recipients > 450 mg/dl, decreased to < 100 mg/dl. At 4 and 7 weeks post-Tx, the intraperitoneal (ip) glucose tolerance test was performed in the normoglycemic Tx mice and in six normal controls. In controls, K value (percentage of decline in blood glucose/min) was 1.076 +/- 0.383 and in Tx mice it was 0.956 +/- 0.336 and 0.869 +/- 0.483 at 4 and 7 weeks, respectively (P = n.s.). Nephrectomy raised the n-FBG to pre-Tx levels. On immunohistochemistry, recipient's pancreata showed atrophic islets with no beta-cell granules, while the islet-bearing kidneys had distinct beta-cells under their capsules. Alginate-embedded fish islets were encapsulated in permselective (25-kDa) cellulose membranes and implanted ip in six STZ-diabetic nude mice. On the following day, all recipients became normoglycemic and their n-FBG remained normal for 7 days. In one animal, the n-FBG was < 200 mg/dl for 14 days and subsequent removal of the capsule raised the n-FBG to the pre-Tx level. Finally, it was found that fish islets can be cultured at 37 degrees C for extended periods of time.(ABSTRACT TRUNCATED AT 250 WORDS)

Automated liver cell processing facilitates large scale isolation and purification of porcine hepatocytes

An automated method for large scale isolation and purification of porcine hepatocytes is described. Liver cells were harvested by a two-step portal vein perfusion with ethylenediaminetetraacetate and collagenase. Hepatocyte purification was carried out using either a standard manual processing method (Procedure A) or an automated processing method using a filtration chamber and a programmable cell washer (Procedure B). Both methods produced high cell yields (Procedure A: 1.30 +/- 0.55 x 10(10) viable hepatocytes/liver; Procedure B: 1.38 +/- 0.32 x 10(10) viable hepatocytes/liver) and viability (Procedure A: 89 +/- 6.5%; Procedure B: 92 +/- 3.9%). Hepatocyte purity was significantly greater after Procedure B than after Procedure A (93.1 +/- 3.1% versus 83.1 +/- 3%, p < 0.01). Isolated hepatocytes by either method were morphologically intact, as demonstrated by transmission electron microscopy showing integrity of plasma membranes and intracellular organelles. Cultured hepatocytes isolated by either method were functionally intact, although those isolated by Procedure A showed significantly lower activity of microsomal 7-ethoxycoumarin-O-deethylase activity (p < 0.05) and mitochondrial succinate dehydrogenase activity (p < 0.01). In conclusion, use of the automated hepatocyte processing method resulted in efficient large scale preparation of porcine hepatocytes, with higher purity and greater retention of differentiated liver metabolic functions, and was found to be less time consuming and less labor intensive.

Differential patterns of reaction of human natural antibodies to pig hepatocytes and vascular endothelium

We have recently conducted a series of experiments to characterize the pattern of reaction of human natural antibodies (NA) with individual pig liver cells. Pooled normal human serum (PHS) was incubated with cultured pig hepatocytes (HEP), aortic endothelial cells (AEC), and portal endothelial cells (PEC), and the reaction of NA to different cell types was measured by antibody-mediated cytotoxic (MTT assay), antibody binding (ELISA), and flow cytometric analysis. The human NA displayed a differential pattern of binding with hepatocytes exhibiting a more limited expression of xenoantigen expression than either aortic or portal endothelial cells. These differences in reaction patterns were also noted for Western blot analysis of individual cell membrane extracts. Preincubation of the pig cells with anti-pig MHC antibodies did not inhibit the binding of human IgM natural antibodies to the pig cells. Comparison of the pattern of NA absorption following the use of bioartificial liver support in patients with acute hepatic failure demonstrated limited ability of pig hepatocytes to absorb substantial amounts of NA. These studies indicate that pig hepatocytes are less vulnerable to NA cytotoxicity than pig vascular endothelial cells and that pig vascular endothelial cells express xenoantigens that are unique and not found on hepatocytes.

Repeated intraportal hepatocyte transplantation in analbuminemic rats

The optimal site for implantation of isolated hepatocytes has not been established. We have developed a novel technique which allows repeated infusion of hepatocytes into the portal system via an indwelling catheter. Seven Nagase Analbuminemic rats (NAR) underwent single intraportal infusion of 2 x 10(7) isolated normal albumin-producing rat hepatocytes. Another seven NAR rats underwent placement of indwelling catheters into the portal venous system via the gastroduodenal vein. Each of them received six batches of 5 x 10(6) normal albumin producing hepatocytes. Seven control NAR rats were infused repeatedly (intraportally) with saline only. Plasma albumin (ELISA) showed significant increase in experimental animals and was more pronounced (p < 0.05) in rats transplanted repeatedly than in those given a single dose of cells. Immunohistochemical staining of the liver sections confirmed the presence of transplanted albumin producing hepatocytes. Rats transplanted with a single large batch of isolated hepatocytes showed liver tissue damage, whereas those subjected to repeated cell infusions had normal liver histology. We have developed a novel intraportal transplantation method which allows successful engraftment of a large number of isolated hepatocytes.

Plasma separation for artificial liver support

A bioartificial liver (BAL) support system, using plasma separation, has been developed to support acute liver failure patients. This study examined 14 consecutive BAL treatments in nine patients with severe acute liver failure. We report methods to achieve and manage plasma separation for an extended period of time. The mean duration of a BAL treatment was 435 minutes, with 26-59 liters of blood processed. Ionized hypocalcemia resulting in muscle twitching was a side effect of the therapy. Ionized calcium levels decreased significantly (P < .02) after BAL treatment; however, total calcium levels increased (P < .05). No significant changes were noted in heart rate, electrocardiogram [Q-T (Q-Tc) interval], blood pressure, prothrombin time, partial thromboplastin time, hematocrit, platelet count and serum phosphorous, magnesium, glucose, and pH. Plasma fibrinogen levels decreased significantly (P < .002). Ionized hypocalcemia due to the chelating effect of sodium citrate was controlled by calcium chloride administration, adjustment of blood separation rates, and reduction of the blood-to-citrate ratio. This report demonstrates that intensive, large-volume plasma separation for long periods of time can be achieved safely in critically ill patients without serious adverse effects.

Artificial hepatic support systems

Severe acute liver failure is associated with high mortality. Improved respiratory and hemodynamic management together with intracranial pressure monitoring and aggressive treatment of cerebral edema have greatly improved patient care. However, many patients die despite optimal medical treatment, because of failure to arrest the progression of cerebral edema. This in turn result in brain stem herniation with rapid neurologic deterioration and death. Liver transplantation has emerged as the definitive treatment for patients with severe acute liver failure. Unfortunately approximately up to one half of the patients with this severe form of liver failure will die while awaiting liver transplantation. There is thus a clear need for a liver support system to provide a "bridge" to transplantation. Over the years, many "bridge" systems were introduced which promised effective support but had no wide clinical success. Because of our incomplete understanding of the pathophysiology of liver failure and development of cerebral edema, it was felt that use of isolated hepatocytes or ex vivo whole liver perfusion would provide both detoxifying and synthetic functions. Whole liver perfusion appears to be effective but cumbersome and costly because it would require each center, where patients are being treated, to maintain animal colonies for patient treatment. Therefore, cryopreserved isolated xenogeneic hepatocytes appear to be the best candidates for building a "bridge" system. In a preliminary clinical study, we have used a porcine hepatocyte-based liver support system (Bioartificial Liver: BAL) to treat patients with acute liver failure as well as patients with acute exacerbation of chronic liver disease. Patients in the first group, who were candidates for transplantation, were successfully bridged to a transplant with excellent survival. No obvious benefit from BAL treatments was seen in the second group. In this group patients where cerebral edema is not a major component of the clinical presentation, it is possible that long-term support will be needed with repeated treatments over several weeks to provide adequate synthetic and detoxifying liver function until the patients' livers recover. For such liver recovery to take place, these chronic patients will need to be treated earlier in the course of their disease when they still have some residual liver mass as well as regenerative capacity. Prospective controlled trials will be initiated as soon as the current phase I study is concluded in order to determine the efficacy of this system in both patient populations.

Early clinical experience with a hybrid bioartificial liver

BACKGROUND

Severe liver failure is associated with high mortality. Orthotopic liver transplantation (OLT) is the only effective therapeutic modality; there is a need for a 'bridge' system to support patients until an organ becomes available.

METHODS

A bioartificial liver (BAL) was used to treat 10 patients with severe liver failure. A plasmapheresis system was used to pump patient plasma through a module with porcine hepatocytes. Each treatment lasted 6-7 h.

RESULTS

All patients tolerated the procedure(s) well. Eight patients underwent OLT following BAL treatment(s). There were two late deaths after recovery from liver failure. Five patients with increased intracranial pressure (ICP) and decerebration had ICP normalization, increased cerebral perfusion pressure and full neurologic recovery after OLT. There was improvement in the level of encephalopathy and a significant decrease in serum ammonia after BAL treatment(s).

CONCLUSIONS

BAL treatment is safe and beneficial and can be successfully used as a 'bridge' to transplantation.

Carboxyfluorescein (CFSE) labelling of hepatocytes for short-term localization following intraportal transplantation

Renewed interest in the transplantation of isolated hepatocytes into the liver as a potential therapy for liver disease has stimulated the development of methods for the identification of donor cells within the recipient organ. We describe a method for cellular tagging and in vivo identification of intraportally transplanted hepatocytes using an intracellular fluorescent dye, 5(6)-carboxyfluorescein diacetate, succinimidyl-ester (CFSE). Rat and porcine hepatocytes were isolated and labelled with CFSE. The optimal conditions for labelling consisted of a buffered saline suspension of hepatocytes (5 x 10(6) cells/mL) in 20.0 microM CFSE incubated for 15 min at 37 degrees C. In vitro, labelled hepatocytes were cultured either on fibronectin-coated chamber slides or in culture flasks. Cultures were evaluated in situ by fluorescence photomicrography or by fluorescence-activated cell sorting (FACS) after cell detachment. Cell viability was assessed serially and cultured, labelled hepatocytes retained the dye for up to 3 wk (last day of study). CFSE did not effect hepatocyte viability and there was no evidence of intercellular diffusion of the dye. In vivo, syngeneic Lewis rats underwent selective portal vein infusion of freshly isolated, labelled hepatocytes (2.0 x 10(7) cells/2.0 mL saline/animal) into the posterior liver lobes. All recipients were sacrificed 48 h and 96 h later and their livers examined. Transplanted hepatocytes were identified by fluorescence microscopy in tissue sections and by FACS following collagenase digestion of the liver tissue. CFSE persisted in a population of viable, engrafted hepatocytes. FACS analysis demonstrated that 9 +/- 3% of the hepatocytes in the posterior liver lobes were labelled 48 and 96 h after transplantation. At 96 h following transplantation, multiple engrafted hepatocytes could be observed by fluorescence microscopy around the central veins. CFSE labelling allows for both in vitro identification and in vivo localization of donor hepatocytes. Furthermore, it appears to be more stable and specific for labelling hepatocytes than other tested dyes (especially DiI).

Hepatic regeneration: current concepts and clinical implications

Liver regeneration occurs as a result of hepatic tissue loss or injury. The process of liver regeneration is carefully regulated in a controlled biologic scheme with closely interactive relationships between hormones, free neurotransmitters, and nutrients; protooncogenes; and polypeptide and glycolipid growth factors. These relationships are now being studied at the molecular and cellular levels and attempts are being made to reconstruct the complete intricate process. Although significant breakthroughs have occurred in understanding the effects and regulation of several subsystems (such as insulin and its receptors; TGF-alpha and TGF-beta; HGF and its receptors), the integral process remains a mystery. Improved comprehension of the regeneration process will lead to rational treatment algorithms for now dreaded hepatic diseases.

Control of cerebral oedema by total hepatectomy and extracorporeal liver support in fulminant hepatic failure

Keeping a patient with fulminant hepatic failure (FHF) alive until a donor liver is available for transplantation can be a problem. We describe an 18-year-old woman with paracetamol-induced FHF, who was treated by total hepatectomy, hypothermia, plasma exchange, and extracorporeal liver support. The patient was anhepatic for 14 h. The liver-support system consisted of plasma separation and perfusion through a charcoal filter and a hollow-fibre module seeded with matrix-attached porcine hepatocytes. With artificial liver treatment there was reversal of severe neurological dysfunction, normalisation of intracranial pressure, and decreased serum ammonia. The patient underwent emergency transplantation with an ABO-incompatible liver, followed by transplantation with a compatible organ eight days later. The patient has fully recovered and is neurologically intact.

Development and testing of a bioartificial liver

Management of patients with acute severe liver failure is a major clinical challenge. We need to understand better normal and abnormal liver physiology, develop methods of assessing the degree of liver dysfunction, standardize methods of intervention and develop rational procedures to support the acutely failing liver until it either recovers or is replaced. Investigators have attempted to support animals and patients with liver insufficiency, utilizing various extracorporeal support systems including cross-circulation, whole liver blood perfusion, hemadsorption, hemodialysis, plasma exchange, total body wash-out, use of microsomal enzymes bound to artificial carriers and other. None of these therapeutic modalities succeeded in gaining wide clinical acceptance. Charcoal hemoperfusion has been used to treat severe acute liver failure with mixed results. Although there is clear experimental evidence that the technique has some beneficial effects, a controlled prospective clinical study failed to demonstrate significant clinical advantages. Other methods which relied primarily upon blood detoxification, showed limited success as well. Thus it appears that, at least for now, whole organ transplantation remains the only method with clinically-proven efficacy for treating severe acute liver failure. In attempting to develop systems for temporarily supporting patients until an organ becomes available for transplantation and because of the complexity and vast number of metabolic and other physiologic functions provided by the liver, it was felt that to provide effective ex vivo liver support, either utilization of whole organ perfusion or construction of a liver support system utilizing intact, viable, functioning isolated liver cells will be needed.

Mass transfer in a hollow fiber device used as a bioartificial liver

The transport of albumin, glucose and fluid in a hollow fiber bioartificial liver (BAL) was predicted by theory and measured experimentally. Results from the experiment were used in a three compartment transport model to estimate the transfiber fluid flux. Fluid convection driven by the transfiber pressure gradient transported solutes across the semi-permeable fibers of the BAL. Diffusion contributed significantly to the transfiber transport of both glucose and albumin. Modification of the BAL system hydraulic geometry significantly increased transfiber pressure gradient with corresponding increase in transfiber fluid flux. Transfiber solute transport was increased by osmotically driven transport which resulted from the revised flow geometry. Substantial delivery of hepatocyte synthesis products is possible with careful control of the physical parameters and operating conditions of the BAL.