Studies on the safety of intrasplenic hepatocyte transplantation: relevance to ex vivo gene therapy and liver repopulation in acute hepatic failure

Decellularized bovine placentome for portacavally-interposed heterotopic liver transplantation in rats

Scaffolds from healthy placentae offer advantages for tissue engineering with undamaged matrix, associated cytoprotective molecules, and embedded vessels for revascularization. As size disparities in human placenta and small recipients hamper preclinical studies, we studied alternative of bovine placentomes in smaller size ranges. Multiple cow placentomes were decellularized and anatomical integrity was analyzed. Tissue engineering used inbred donor rat livers. Placentomes were hepatized and immediately transplanted in rats with perfusion from portal vein and drainage into inferior vena cava. Cows yielded 99 ± 16 placentomes each. Of these, approximately 25% had 3 to 9 cm diameter and 7 to 63 ml volume, which was suitable for transplantation. After decellularization, angiography and casts documented 100% of vessels and vascular networks were well-perfused without disruptions or leaks. The residual matrix also remained intact for transplantation of placentomes. Perfusion in transplanted placentomes was maintained over up to 30 days. Liver tissue reassembled with restoration of hepatic acinar and sinusoidal structure. Transplanted tissue was intact without apoptosis, or necrosis. Hepatic functions were maintained. Preservation of hepatic homeostasis was verified by cytofluorimetric analysis of hepatocyte ploidy. The prevalence in healthy and transplanted liver of diploid, tetraploid and higher ploidy classes was similar with 57%, 41% and 2% versus 51%, 46.5% and 2.6%, respectively, p = 0.77, ANOVA. CONCLUSIONS: Cow placentomes will allow therapeutic development with disease models in small animals. This will also advance drug or toxicology studies. Portasystemic interposition of engineered liver will be particularly suitable for treating hepatic insufficiencies (metabolic, secretory or detoxification needs), including for children or smaller adults.

Analysis of Hepatocyte Distribution and Survival in Vascular Beds with Cells Marked by 99mTC or Endogenous Dipeptidyl Peptidase IV Activity

Knowledge of the kinetics of cell distribution in vascular beds will help optimize engraftment of transplanted hepatocytes. To noninvasively localize transplanted cells in vivo, we developed conditions for labeling rat hepatocytes with 99mTc–pertechnetate. The incorporated 99mTc was bound to intracellular proteins and did not impair cell viability. When 99mTc hepatocytes were intrasplenically injected into normal rats, cells entered liver sinusoids with time–activity curves demonstrating instantaneous cell translocations. 99mTc activity in removed organs was in liver or spleen, and lungs showed little activity. However, when cells were intrasplenically transplanted into rats with portasystemic collaterals, 99mTc appeared in both liver sinusoids and pulmonary alveolar capillaries. To further localize cells, we transplanted DPPIV+ F344 rat hepatocytes into syngeneic DPPIV – recipients. Histochemical staining for DPPIV activity demonstrated engraftment of intrasplenically transplanted cells in liver parenchyma. In contrast, when 99mTc hepatocytes were injected into a peripheral vein, cells were entrapped in pulmonary capillaries but were subsequently broken down with redistribution of 99mTc activity elsewhere. Intact DPPIV+ hepatocytes were identified in lungs, whereas only cell fragments were present in liver, spleen, or kidneys. These findings indicate that although the pulmonary vascular bed offers advantages of easy accessibility and a relatively large capacity, significant early cell destruction is an important limitation.

Human SeruM Albumin Microspheres Approximate Initial Organ-Specific Biodistributions of Transplanted Hepatocytes and Are Effective Cell Surrogates for Safety Studies

Liver repopulation with transplanted hepatocytes will generate novel cell-based therapies, although translocation of transplanted cells into lungs through portasystemic shunts has the potential for embolic complications. To facilitate safety analysis of hepatocyte transplantation, we wished to obtain effective cell surrogates and analyzed biodistributions of similarly sized 99mTc-labeled human serum albumin microspheres and rat hepatocytes. Image analysis with dual 99mTc and 111In labels indicated that cells and microspheres were similarly distributed in the liver when injected into normal rats via the spleen. Also, their distributions were similar when injected via a femoral vein or the superior mesenteric vein with cells and microspheres localizing in lungs or liver, respectively. Upon intraportal injection in rats with portal hypertension, microspheres localized in both liver and lungs, consistent with portasystemic shunting. These data demonstrate that human serum albumin microspheres are effective cell surrogates for approximating the safety of hepatocyte transplantation and should be clinically useful.

Long-Term Amerlioration of Bilirubin Glucuronidation Defect in Gunn Rats by Transplanting Genetically Modified Immortalized Autologous Hepatocytes

Ex vivo gene therapy, in which hepatocytes are harvested from mutants, retrovirally transduced with a normal gene and transplanted back into the donor, has been used for correction of inherited metabolic defects of liver. Major drawbacks of this method include limited availability of autologous hepatocytes, inefficient retroviral transduction of primary hepatocytes, and the limited number of hepatocytes that can be transplanted safely. To obviate these problems, we transduced primary hepatocytes derived from inbred bilirubin–UDP–glucuronosyl–transferase (BUGT)-deficient Gunn rats by infection with a recombinant retrovirus expressing temperature-sensitive mutant SV40 large T antigen (tsT). The immortalized cells were then transduced with a second recombinant retrovirus expressing human B-UGT, and a clone expressing high levels of the enzyme was expanded by culturing at permissive temperature (33°C). At 37°C, tsT antigen was degraded and the cells expressed UGT activity toward bilirubin at a level approximately twice that present in normal rat liver homogenates. For seeding the cells into the liver bed, 1 × 107 cells were injected into the spleens of syngeneic Gunn rats five times at 10-day intervals. Excretion of bilirubin glucuronides in bile was demonstrated by HPLC analysis and serum bilirubin levels were reduced by 27 to 52% in 40 days after the first transplantation and remained so throughout the duration of the study (120 days). None of the transplanted Gunn rats or SCID mice transplanted with the immortalized cells developed tumors. © 1998 Elsevier Science Inc.

Significant Improvement of Survival by Intrasplenic Hepatocyte Transplantation in Totally Hepatectomized Rats

The effect of intrasplenic hepatocyte transplantation (HTX) was studied in an experimental model of acute liver failure in rats with chronic liver atrophy. Rats underwent a portacaval shunt operation on Day -14 to induce liver atrophy, and underwent total hepatectomy on Day 0 as a start of acute liver failure. Intrasplenic hepatocyte or sham transplantation was performed on Day -7, -3, or -1 (n = 4 to 6 per group). During the period following hepatectomy, mean arterial blood pressure was maintained above 80 mm Hg and hypoglycaemia was prevented. Severity of hepatic encephalopathy was assessed by clinical grading and EEG spectral analysis, together with determination of blood ammonia and plasma amino acid concentrations, and “survival” time. Histological examination of the spleen and lungs was performed after sacrifice. Intrasplenic hepatocyte transplantation resulted in a significant improvement in clinical grading in all transplanted groups (p < 0.05), whereas a significant improvement in EEG left index was seen only in the group with transplantation on Day -1 (p < 0.05). In contrast to hepatocyte transplantation 1 day before total hepatectomy, rats with hepatocyte transplantation 3 and 7 days before total hepatectomy showed a significant 3- and 2-fold increase in “survival” time compared to sham transplanted controls: HTX at Day -1: 7.5 ± 0.3 h vs. 5.9 ± 0.6 h (p > 0.05), HTX at Day -3:19.7 ± 3.7 h vs. 6.5 ± 0.3 h (p < 0.05), and HTX at Day -7: 13.8 ± 3.2 h vs. 6.3 ± 0.3 h (p < 0.05). Furthermore, rats with hepatocyte transplantation on Day -3 and -7 showed significantly lower blood ammonia concentrations after total hepatectomy (p < 0.0001). Histological examination of the spleens after sacrifice showed clusters of hepatocytes in the red pulp. Hepatocytes present in the spleen for 3 and 7 days showed bile accumulation and spots of beginning necrosis. The present data show that in a hard model of complete liver failure in portacaval shunted rats, intrasplenic hepatocyte transplantation is able to prolong “survival” time significantly 2- to 3-fold. The relevance of this observation for human application is discussed.

Translation of amnion stem cells to the clinic

Cellular therapy for liver disease has been available in the clinic for more than 20 years, yet remarkably few patients receive this experimental therapy. Reasons for the small number of transplants performed are partially related to access to useful liver tissue and the difficulty with the isolation of viable cells. Stem cell sources of hepatocytes could theoretically relieve these obstacles to therapy if large numbers of functional hepatocytes could be generated and transplanted without risk of tumorigenicity. To date, there are no reports of stem cell sources with all of these characteristics, despite claims otherwise. Here we report the results of preclinical studies with appropriate animals models of metabolic liver disease and acute liver failure, and their correction by the transplantation of human amnion epithelial stem cells. The encouraging results of the preclinical studies have motivated the movement of isolation and banking of these cells to good manufacturing practice conditions so that the cells can be used in the clinic for transplantation of patients with liver disease.

Cell therapy to remove excess copper in Wilson's disease

To achieve permanent correction of Wilson's disease by a cell therapy approach, replacement of diseased hepatocytes with healthy hepatocytes is desirable. There is a physiological requirement for hepatic ATP7B-dependent copper (Cu) transport in bile, which is deficient in Wilson's disease, producing progressive Cu accumulation in the liver or brain with organ damage. The ability to repopulate the liver with healthy hepatocytes raises the possibility of cell therapy in Wilson's disease. Therapeutic principles included reconstitution of bile canalicular network as well as proliferation in transplanted hepatocytes, despite toxic amounts of Cu in the liver. Nonetheless, cell therapy studies in animal models elicited major differences in the mechanisms driving liver repopulation with transplanted hepatocytes in Wilson's disease versus nondiseased settings. Recently, noninvasive imaging was developed to demonstrate Cu removal from the liver, including after cell therapy in Wilson's disease. Such developments will help advance cell/gene therapy approaches, particularly by offering roadmaps for clinical trials in people with Wilson's disease.

Enhancement of P-glycoprotein expression by hepatocyte transplantation in carbon tetrachloride-induced rat liver

The multidrug resistance protein P-glycoprotein (P-gp) is physiologically expressed at the bile canalicular membrane of the liver, where it participates in the biliary excretion of various lipophilic drugs. Chronic exposure to carbon tetrachloride (CCI(4)) is known to induce hepatic fibrosis resulting in hepatotoxicity. This study focuses on the effects of CCI(4) and hepatic transplantation (HT) on the P-gp expressions in rat liver. Male SD rats were treated with CCI(4) to induce liver damage for 3, 7, 14, 21, and 28 days, respectively. Immunohistochemistry revealed that P-gp was widely distributed in the liver and was spread from the cytoplasm to cell membrane of the rat liver. Western blot showed remarkable increase of P-gp expression in 3 days CCI(4)-treated rats, whereas, a continuous decrease in the P-gp expression was seen in 7, 14, 21, and 28 days CCI(4)-treated rats. After HT with cells from the normal rat liver, the level of P-gp increased comparing with those from the sham operation. Blood biochemistry showed decreased levels of serum alanine transaminase, aspartate transaminase, and alkaline phosphatase and increased serum levels of triglyceride and total protein, which indicated the improved function of the liver damaged by CCI(4). These results illustrate the variation of the expression of P-gp in CCI(4)-induced hepatic damage and an increase of P-gp level after HT in the toxic liver induced by CCI(4). We hypothesized that P-gp may play a protective role in the process of liver injury. HT can be beneficial to ameliorate the rat liver functional damage induced by CCI(4).

Hepatic targeting and biodistribution of human fetal liver stem/progenitor cells and adult hepatocytes in mice

Tracking stem/progenitor cells through noninvasive imaging is a helpful means of assessing the targeting of transplanted cells to specific organs. We performed in vitro and in vivo studies wherein adult human hepatocytes and human fetal liver stem/progenitor cells were labeled with indium-111 ((111)In)-oxine and technetium-99m ((99m)Tc)-Ultratag or (99m)Tc-Ceretec. The labeling efficiency and viability of cells was analyzed in vitro, and organ biodistribution of cells was analyzed in vivo after transplantation in xenotolerant nonobese diabetic/severe combined immunodeficiency mice through intrasplenic or intraportal routes. We found that adult hepatocytes and fetal liver stem/progenitor cells incorporated (111)In but not (99m)Tc labels. After radiolabeling, cell viability was unchanged. Transplanted adult hepatocytes or fetal liver stem/progenitor cells were targeted to the liver more effectively by the intraportal rather than the intrasplenic route. Transplanted cells were retained in the liver after intraportal injection and in the liver and spleen after intrasplenic injection, without translocations into pulmonary or systemic circulations. Compared with fetal liver stem/progenitor cells, fewer adult hepatocytes were retained in the spleen after intrasplenic transplantation. The distribution of transplanted cells in organs was substantiated by genetic assays, including polymerase chain reaction amplification of DNA sequences from a primate-specific Charcot-Marie-Tooth element, and in situ hybridization for primate alphoid satellite sequences ubiquitous in all centromeres.

CONCLUSION

(111)In labeling of human fetal liver stem/progenitor cells and adult hepatocytes was effective for noninvasive localization of transplanted cells. This should facilitate continued development of cell therapies through further animal and clinical studies.

In vivo MR tracking of mesenchymal stem cells in rat liver after intrasplenic transplantation

PURPOSE

To prospectively track in vivo in rats intrasplenically transplanted stem cells labeled with superparamagnetic particles by using magnetic resonance (MR) imaging.

MATERIALS AND METHODS

The study was approved by the institutional Committee on Animal Research. Liver damage in 12 rats was induced with subcutaneous injection of carbon tetrachloride (CCl4). Intrasplenic transplantation of 6x10(6) rodent bone mesenchymal stem cells (BMSCs) with (n=6) and without (n=6) superparamagnetic particle Fe2O3-poly-L-lysine (PLL) labeling was performed via direct puncture. Cell labeling efficiency was assessed in vitro by using Prussian blue stain and an atomic absorption spectrometer. MR examinations were performed immediately before and 3 hours and 3, 7, and 14 days after transplantation. Liver-to-muscle contrast-to-noise ratios (CNRs) on T2*-weighted MR images obtained before and after injection were measured and correlated with histomorphologic studies. Statistical analyses were performed by using repeated-measures analysis of variance.

RESULTS

Rat BMSCs could be effectively labeled with approximately 100% efficiency. Migration of transplanted labeled cells to the liver was successfully documented with in vivo MR imaging. CNRs on T2*-weighted images decreased significantly in the liver 3 hours after injection of BMSCs (P<.05) and returned gradually to the level achieved without labeled cell injection in 14 days. Histologic analyses confirmed the presence of BMSCs in the liver. The labeled cells primarily localized in the sinusoids of periportal areas and the foci of CCl4-induced liver damage. Quantitative analysis of Prussian blue-stained cells indicated gradual decrease of dye pigments from 3 hours to 3, 7, and 14 days after injection. No free iron particles were found in the interstitium or within hepatic microvessels.

CONCLUSION

The rat BMSCs could be efficiently labeled with Fe2O3-PLL and the relocation of the labeled cells to rat livers after intrasplenic transplantation could be depicted at in vivo MR imaging.

Corneal epithelial stem cell delivery using cell sheet engineering: not lost in transplantation

Cell-based therapies have now generated significant interest as novel drug delivery systems, with various adult cell types used in treating a wide range of diseases. To overcome the limits that restrict treatments for corneal surface dysfunction, corneal epithelial stem cells expanded ex vivo have been applied as an alternative approach. While previous studies used various carrier substrates, we present a novel method using cell sheet engineering with temperature-responsive culture dishes to create carrier-free corneal epithelial stem cell sheets that can be transplanted without sutures. Results from clinical trials reveal successful transplantation with the recovery of lost visual acuity in all cases. Cell sheet engineering, therefore, presents a novel method for the delivery of corneal epithelial stem cells, and can also be applied for other approaches of cellular therapeutics.

Liver repopulation: a new concept of hepatocyte transplantation

Hepatocyte transplantation has been recognized as an alternative strategy for organ transplantation because the supply of donor livers is limited. However, in conventional hepatocyte transplantation, only 1%-10% of the liver replaced with transplanted hepatocytes. Recently a novel concept termed "liver repopulation" has been established, where the whole recipient liver can be replaced by a small number of donor hepatocytes. To induce liver repopulation, growth advantage of the donor hepatocytes against the host liver seems to be required according to the data of previous studies. Additionally, various cell sources, including bone marrow cells and other stem cells, could potentially be used as donor cells for liver repopulation. In this article, we discuss recent progress and future perspectives of this emerging technology.

HVEGF165 increases survival of transplanted hepatocytes within portal radicles: suggested mechanism for early cell engraftment

VEGF is a potent angiogenic factor that promotes hepatocyte growth, increases permeability of blood vessels, and induces vasodilatation, and may accelerate engraftment and function of transplanted hepatocytes. The aim was to study the effect of VEGF on early hepatocyte engraftment. Thirty-two Lewis syngeneic female rats underwent 70% partial hepatectomy. Eighteen received 240 ng VEGF165 and 14 received saline for control. Thereafter, intrasplenic transplantation of 10(7) male hepatocytes was done. Semiquantitative analysis of PCR product of the SRY region of the Y-chromosome was performed. Paraffin-embedded sections were stained for H&E and for PCNA immunostaining. By PCR, male hepatocytes were identified in 8 livers out of 14 VEGF-treated rats at 24-48 h, compared with only 1 liver out of 8 controls. Transplanted cells were seen within portal vessels radicles in 7 out of 14 VEGF-treated rats for as long as 48 h posttransplantation, compared with only one control liver at 24 h. There was no histological sign of cell injury to transplanted or adjacent cells. Two weeks after transplantation male transplanted cells were identified in two out of four rats treated with hVEGF165 and in one out of six rats treated with saline. No transplanted cells were detected within portal tracts 14 days after transplantation. hVEGF165 enhances the presence of transplanted hepatocytes within portal vessels after transplantation. We suggest an additional mechanism for cell engraftment, whereby transplanted hepatocytes first stick to each other in the portal radicles. Later they become included in the liver parenchyma as groups of organized cells in a process stimulated by VEGF.

Emerging insights into liver-directed cell therapy for genetic and acquired disorders

Treatment of acute or chronic liver diseases by cell transplantation is an attractive prospect because organ shortages greatly restrict liver transplantation. Moreover, a variety of genetic deficiency states affecting extrahepatic organs are amenable to liver-directed cell therapy. While the initial clinical experience with liver cell transplantation has been encouraging, further advances in several areas are necessary to improve these results. Insights into how engraftment and proliferation of transplanted cells may be modulated to obtain therapeutically effective masses of transplanted cells will be important in this pursuit. Studies of cell therapy in animal models of specific diseases have provided insights into the development of clinically relevant strategies for various disorders. Also, identification of suitable cell types, including stem/progenitor cells that could be expanded and manipulated in cell culture conditions, has begun to provide important new information for cell therapy. Similarly, advances in cryopreservation of cells and prevention of allograft rejection offer ways to accomplish cell therapy in an effective manner. Taken together, these advances indicate that liver-directed cell therapy will be well positioned in the near future to play significant roles in transplantation medicine.

Portal hemodynamic changes after hepatocyte transplantation in acute hepatic failure

Hepatocyte transplantation has been proposed as an alternative for rescuing patients with acute hepatic failure. However, portal hemodynamic changes and issues of safety after hepatocyte transplantation in acute hepatic failure have not been systemically evaluated because of the lack of a suitable experimentation system. In this study, we created a novel spring-guidewire introducer needle to simplify the technique for long-term portal cannulation in F-344 rats. The portal cannula was capable of being used for blood sampling, infusion of hepatocytes, and measurement of portal hemodynamic changes. One week after portal cannulation, rats were injected with D-galactosamine (1.35 g/kg, i.p.) to induce hepatic failure. Hepatocytes (2 x 10(7)) were infused intraportally 24-26 h after induction of liver injury. Portal pressures were recorded for up to 60 min after hepatocyte transplantation. Intraportal infusion of 2 x 10(7) hepatocytes caused an instantaneous onset of portal hypertension. The magnitude of the rise in portal pressure was similar in both normal rats and rats with acute hepatic failure (33.0 +/- 7.1 vs. 37.7 +/- 0.5 mm Hg; p = 0.23). However, the resolution rate of portal hypertension was remarkably delayed in rats with acute hepatic failure, and the portal pressure was significantly higher than that in normal rats 60 min after hepatocyte transplantation (25.0 +/- 2.8 vs. 14.5 +/- 2.4 mm Hg; p = 0.007). In conclusion, we have established a simple new technique for long-term portal cannulation of rats. Our studies provide critical insights into the delayed resolution of portal hemodynamics after hepatocyte transplantation in subjects with acute hepatic failure.

Intraportal infusion of 99mtechnetium-macro-aggregrated albumin particles and hepatocytes in rabbits: assessment of shunting and portal hemodynamic changes

BACKGROUND

Partial correction of metabolic liver disease by hepatocyte transplantation requires infusion of a large number of cells into the portal vein. Uncontrolled infusion of cells leads to extrahepatic shunting. Obstruction of the sinusoidal space may result in hemodynamic changes and impairment of liver function.

METHODS

Catheters connected to a port were placed into the caudal mesenteric vein of rabbits. After injection of 99mtechnetium-macroaggregated albumin (99mTc-MAA) surrogates or 99mTc-MAA/hepatocyte (Hc) mixtures (1:125), shunting into the lung was scintigraphically monitored. Volume flow (mL/min) and maximum velocity of the portal vein were recorded by color-coded Doppler ultrasound during intraportal application of 2.5 x 10(7) MAA particles, 2.5 x 10(7) isolated hepatocytes, and saline solution without particles or cells.

RESULTS

99mTc-MAA particles (2.5 x 10(7)) or equivalent MAA/Hc mixtures were completely retained in the liver. With additional application of 2.5 x 10(7) particles, shunting into the lung was observed in two animals of the MAA group. All animals in the hepatocyte group have received 5 x 10(7) MAA/Hc mixtures, and three of these received 10(8) mixtures without shunting. Maximum velocity and volume flow increased with saline infusion. Hepatocyte suspended in the same volume blunted the increase observed in the control group, but parameters remained normal. Liver enzymes increased after hepatocyte application but returned to normal values within 5 days.

CONCLUSIONS

Sinusoidal uptake capacity for hepatocyte or MAA particles varies at a wide range in normal rabbits. Scintigraphic monitoring of transplanted cells allows efficient monitoring of cell translocation into the lungs. No significant impairments of portal hemodynamics and liver function were detected.

Hepatocyte transplantation

Repopulation of the liver with transplanted cells holds significant promise for developing novel therapies. The liver is a most suitable target for treating a variety of genetic, metabolic and acquired diseases. Liver disease, such as chronic viral hepatitis, constitutes an enormous burden worldwide. Advancing liver cell therapy requires insights into mechanisms of cell engraftment and proliferation, as well as unique requirements of specific diseases for correction by cell transplantation. This review highlights recent developments in the area of hepatocyte transplantation. Aspects concerning modulation of cell engraftment, regulation of gene expression and proliferation of transplanted cells are discussed. Other issues concern the current status of clinical applications of hepatocyte transplantation, as well as novel sources of cells that could benefit cell therapy in the future. The general conclusion is that cell therapy has become more practical in recent years and insights into how the normal liver and the diseased liver can be repopulated will offer effective ways to treat many disorders in the near future.

Intrasplenic transplantation of syngenic hepatocytes modified by IFN-gamma gene ameliorates hepatic fibrosis in rats

Transplanted hepatocytes are ideal carriers for exogenous genes in liver gene therapy. The present study investigated the anti-fibrogenic effects of intrasplenically transplanted hepatocytes modified with interferon gamma (IFN-gamma) gene on cirrhotic rats. Hepatocytes isolated from normal Sprague-Dawley (SD) rats were transfected with an adenoviral vector encoding human IFN-gamma gene (AdCMVhIFN-gamma) and transplanted into the spleens of syngenic recipients with ongoing liver fibrosis induced by carbon tetrachloride (CCl(4)). Histology was assessed, and liver hydroxyproline was detected. Additionally, serum procollagen type III (PIIINP) levels and hepatic collagenase activity were measured to determine hepatic collagen synthesis and degradation. Transplantation with AdCMVhIFN-gamma transfected hepatocytes ameliorated the histological outcome of liver fibrosis by reducing liver collagen content and decreasing hepatic hydroxyproline. Additionally, IFN-gamma transfected hepatocytes reduced serum PIIINP levels and increased hepatic collagenase activity. Our data suggest that transplantation of IFN-gamma transfected hepatocytes may reduce the pace of liver fibrosis by inhibiting the synthesis and enhancing the degradation of hepatic collagen.

Kinetics of liver repopulation after bone marrow transplantation

Recent work has convincingly demonstrated that adult bone marrow contains cells capable of differentiating into liver epithelial cells in vivo. However, the frequency and time course with which fully functional hepatocytes emerge after bone marrow transplantation remained controversial. Here, we used the fumarylacetoacetate hydrolase knockout mouse to determine the kinetics of hepatocyte replacement after complete hematopoietic reconstitution. Single donor-derived hepatocytes were first detected 7 weeks after lethal irradiation and bone marrow transplantation. Liver disease was not required for this transdifferentiation. In the presence of selective pressure the single cells evolved into hepatocyte nodules by 11 weeks after transplantation and resulted in >30% overall liver repopulation by 22 weeks. The frequency with which hepatocytes were produced was between 10(-4) and 10(-6), resulting in only 50 to 500 repopulation events per liver. Hepatic engraftment was not observed without previous hematopoietic reconstitution even in the presence of liver injury. In addition, significant liver repopulation was completely dependent on hepatocyte growth selection. We conclude that hepatocyte replacement by bone marrow cells is a slow and rare event. Significant improvements in the efficiency of this process will be needed before clinical success can be expected.

IFN-gamma gene therapy by intrasplenic hepatocyte transplantation: a novel strategy for reversing hepatic fibrosis in Schistosoma japonicum-infected mice

Liver-targeted gene therapy using hepatocyte as recipient cells has recently been documented to be effective in treatment of numerous hepatic diseases, such as metabolic diseases and liver carcinoma. IFN-gamma elicits antipreliferative and antifibrogenic activity in a variety of mesenchymal cells, including hepatic satellite cells. To investigate the antifibrogenic response of liver gene therapy mediated by intrasplenic transplantation of gene-modified hepatocytes, normal mouse liver cell line BNL CL.2 cells were transfected with murine IFN-gamma gene (BNL.IFN-gamma) in vitro, and transplanted intrasplenically into Schistosoma japonicum-infected mice. The amounts and distribution of IFN-gamma (which inhibits collagen synthesis), TGF-beta (which stimulates collagen synthesis) and extracellular matrix, including type I and III collagen, were detected. In mice infected with S. japonicum and then treated with BNL.IFN-gamma, an increase of IFN-gamma and decrease of TGF-beta1 were detected at 20 weeks postinfection compared to untreated S. japonicum-infected mice. Immunohistochemical analysis showed that S. japonicum infection induced a marked increase of type I and III collagen synthesis. Whereas, 4 weeks after treatment with BNL.IFN-gamma, net synthesis rates of type I and III collagen were markedly decreased in the liver of infected mice. In addition, a decreased expression of TGF-beta1 and its receptor TGF-betaRII in the liver of BNL.IFN-gamma-treated mice was also observed. Moreover, the decrease in TGF-beta1 and TGF-betaRII protein approximately paralleled the decrease in their mRNA expression, which was detected by RNA dot blotting. The data indicate that intrasplenic transplantation of IFN-gamma gene-modified hepatocyte can be a candidate approach to treat hepatic fibrosis.

Hepatocyte transplantation. Advancing biology and treating children

Key advances over the past three decades have allowed the evolution of hepatocyte transplantation from its use as an experimental tool to study liver cell biology to the initial application as a potential treatment modality for patients with liver disease. Although little is known about the cellular and molecular mechanisms regulating the fate of transplanted cells, studies in animal models of liver disease clearly suggest that transplanted hepatocytes have the potential to repopulate diseased livers and correct metabolic defects. Based on these experiments, human hepatocytes have been used in the treatment of children and adults with metabolic disease and liver failure. In initial trials, the improved clinical course following hepatocyte transplantation points to a potential role of the technique as an adjunct to liver transplantation.

Use of indium-111-labeled hepatocytes to determine the biodistribution of transplanted hepatocytes through portal vein infusion

PURPOSE

Hepatocyte transplantation is useful for ex vivo gene therapy and liver repopulation. Methods for hepatic reconstitution were recently developed, but hepatocyte transplantation systems must be optimized. The authors report their experience with In-111 oxyquinolone labeling of a test dose of hepatocytes (108 cells) for noninvasive assessment of the biodistribution of transplanted hepatocytes in a 5-year-old child with omithine transcarbamoylase deficiency.

MATERIALS AND METHODS

Donor hepatocytes (approximately 108) were radiolabeled using a commercially available In-111 oxyquinolone solution (specific activity of 1 mCi/ml).

RESULTS

The overall labeling efficiency was 36.4%. A final dose of approximately 290 ,uCi of the In-111-labeled hepatocytes in 10 ml serum-free phosphate-buffered saline was infused percutaneously into the portal vein approximately 2.5 hours after their preparation. The study was performed 3 hours before cell transplantation (109 cells). Quantitative analysis of the biodistribution of In-111-labeled hepatocytes indicated that cells were predominantly localized in the liver immediately after portal vein-infused transplantation. The predominant hepatic distribution was persistent for as long as 7 days after the procedure, with an average liver-to-spleen ratio of 9.5 to 1. No significant pulmonary radiotracer uptake was present.

CONCLUSION

These results indicate that In-111 labeling of hepatocytes is useful for the short-term noninvasive analysis of the biodistribution of transplanted hepatocytes.

Transplanted hepatocytes engraft, survive, and proliferate in the liver of rats with carbon tetrachloride-induced cirrhosis

Repopulation of the cirrhotic liver with disease-resistant hepatocytes could offer novel therapies, as well as systems for biological studies. Establishing whether transplanted hepatocytes can engraft, survive, and proliferate in the cirrhotic liver is a critical demonstration. Dipeptidyl peptidase IV-deficient F344 rats were used to localize transplanted hepatocytes isolated from the liver of syngeneic normal F344 rats. Cirrhosis was induced by administration of carbon tetrachloride with phenobarbitone and these drugs were withdrawn prior to cell transplantation. Cirrhotic rats showed characteristic hepatic histology, as well as significant portosystemic shunting. When hepatocytes were transplanted via the spleen, cells were distributed immediately in periportal areas, fibrous septa, and regenerative nodules of the cirrhotic liver. Although some transplanted cells translocated into pulmonary capillaries, this was not deleterious. At 1 week, transplanted cells were fully integrated in the liver parenchyma, along with expression of glucose-6-phosphatase and glycogen as reporters of hepatic function. Transplanted cells proliferated in the liver of cirrhotic animals and survived indefinitely. At 1 year, transplanted hepatocytes formed large clusters containing several-fold more cells than normal control animals, which was in agreement with increased cell turnover in the cirrhotic rat liver. The findings indicate that the cirrhotic liver can be repopulated with functionally intact hepatocytes that are capable of proliferating. Liver repopulation using disease-resistant hepatocytes will be applicable in chronic conditions, such as viral hepatitis or Wilson's disease.

Multiple intrasplenic hepatocyte transplantations in the dalmatian dog

BACKGROUND

Hepatocyte transplantation is an attractive potential treatment for liver-based inborn errors of metabolism and for fulminant hepatic failure. Dalmatian dogs have a metabolic error that results in hyperuricosuria. This report focuses on the effect of multiple, sequential intrasplenic transplants of fresh and cryopreserved hepatocytes in dalmatians.

METHODS

Dalmatians underwent intrasplenic hepatocyte transplantation with hepatocytes taken from healthy mongrels. Dalmatian urinary uric acid excretion was measured preoperatively, and this served as the control value. Three hepatocyte transplantations were performed at 30-day intervals--the first with freshly isolated cells, and both the second and the third with cryopreserved hepatocytes from the same donor. Urinary uric acid excretion was measured postoperatively twice per week.

RESULTS

The urinary uric acid excretion decreased an average of 54% after the first hepatocyte transplantation. The effect was transient and lasted an average of 22 days (range, 19-50 days). Subsequent intrasplenic hepatocyte transplantation with cryopreserved hepatocytes resulted in similar decreases in urinary uric acid excretion. Each transplant resulted in a significant decrease in urinary uric acid excretion when compared with baseline values (P = < .001).

CONCLUSIONS

Sequential intrasplenic hepatocyte transplantation is feasible in this model. This method provided a significant, but transient, correction in urinary uric acid excretion that was similar with either fresh or cryopreserved hepatocytes. A substantial biologic effect provided by cryopreserved hepatocytes has important implications in clinical hepatocyte transplantation.

Liver repopulation with hepatocyte transplantation: new avenues for gene and cell therapy

Liver-directed gene therapy is appropriate for many conditions. Recent work established that liver repopulation with transplanted cells can be effective in treating genetic disorders. Although hepatocytes express therapeutic genes with considerable efficiency, correction of genetic disorders is constrained by limitations in permanent gene transfer into hepatocytes and repopulation of the liver with transplanted cells. Adenoviral vectors are highly efficient for hepatic gene transfer but the onset of deleterious host immune responses against adenoviral vectors, along with clearance of transduced hepatocytes have caused problems. Nonetheless, recent work concerning engraftment and proliferation of transplanted hepatocytes in the liver has provided significant new information, which should refocus interest in hepatocyte-based therapies. Moreover, hepatocyte transplantation systems offer creative tools for defining critical mechanisms in gene regulation and survival of transduced cells.

Xenogeneic transplantation of porcine hepatocytes into the CCl4 cirrhotic rat model

Liver support using extracorporeal devices and hepatocyte transplantation has received renewed interest for the management of acute and chronic liver failure. The aim of this study was to determine whether xenogeneic porcine hepatocytes could integrate into the liver parenchyma of cirrhotic Lewis rats when administered by an intrasplenic route. Cirrhosis was induced by carbon tetrachloride (CCl4) inhalation and confirmed histologically. Freshly isolated porcine hepatocytes were infused directly into the splenic pulp at laparotomy over a 5-15-min interval. Using (111)In-labeled hepatocytes, the degree of localization of porcine hepatocytes to the spleen and liver was found to be greater than 60% in both control and cirrhotic rats. Integration of porcine hepatocytes into the rat liver parenchyma was determined by immunohistochemical staining for porcine albumin in rat liver sections. Further confirmation was provided by in situ hybridization using a porcine-specific probe that binds to a distinct repetitive element (PRE) in porcine DNA. Evidence of integrated porcine hepatocytes was seen for over 50 days in animals under cyclosporine immunosuppression. These data demonstrate the integration of xenogeneic porcine hepatocytes into the liver of the cirrhotic rat and their ability to produce porcine albumin for up to 50 days.

Extracorporeal support and hepatocyte transplantation in acute liver failure and cirrhosis

The relative shortage of donor organs and lack of immediate availability mean that many patients with acute liver failure die before orthotopic liver transplantation can be performed. An effective temporary liver support system could improve the chance of survival with or without a transplant being ultimately carried out. Recent technological advances resulting in improved maintenance of hepatocyte viability and function in culture and bioreactor designs which facilitate adequate perfusion of the cellular component and removal of products of cellular metabolism have led to the development of a number of bioartificial devices for liver support. Three such devices have undergone preliminary clinical evaluation in the setting of acute liver failure, with a statistically significant reduction in raised intracerebral pressure along with improvements in consciousness level and some biochemical parameters associated with treatment with one of these. Several other devices with different characteristics have shown promise in vitro and/or in animal models but await clinical evaluation. Several new totally artificial systems have also been described, along with the emergence of isolated hepatocyte transplantation, with reports of successful 'bridging' to liver transplantation. Controlled trials on a multicentre basis in well-defined patient groups and with standardized outcome measures will be required to properly evaluate the clinical value of each of these approaches to providing liver support in acute liver failure and cirrhosis. A better understanding of mechanisms underlying multiorgan failure and of factors inhibiting liver regeneration, thereby allowing a more targeted approach, will be essential to the further development of effective liver support strategies in these settings.

Entry and integration of transplanted hepatocytes in rat liver plates occur by disruption of hepatic sinusoidal endothelium

To establish the process by which transplanted cells integrate into the liver parenchyma, we used dipeptidyl peptidase IV-deficient F344 rats as hosts. On intrasplenic injection, transplanted hepatocytes immediately entered liver sinusoids, along with attenuation of portal vein radicles on angiography. However, a large fraction of transplanted cells (>70%) was rapidly cleared from portal spaces by phagocyte/macrophage responses. On the other hand, transplanted hepatocytes entering the hepatic sinusoids showed superior survival. These cells translocated from sinusoids into liver plates between 16 and 20 hours after transplantation, during which electron microscopy showed disruption of the sinusoidal endothelium. Interestingly, production of vascular endothelial growth factor was observed in hepatocytes before endothelial disruptions. Portal hypertension and angiographic changes resulting from cell transplantation resolved promptly. Integration of transplanted hepatocytes in the liver parenchyma required cell membrane regenesis, with hybrid gap junctions and bile canaliculi forming over 3 to 7 days after cell transplantation. We propose that strategies to deposit cells into distal hepatic sinusoids, to disrupt sinusoidal endothelium for facilitating cell entry into liver plates, and to accelerate cell integrations into liver parenchyma will advance applications of hepatocyte transplantation.

Rapid clearance of transplanted hepatocytes from pulmonary capillaries in rats indicates a wide safety margin of liver repopulation and the potential of using surrogate albumin particles for safety analysis

BACKGROUND/AIMS

Applications of liver repopulation by hepatocyte transplantation require analysis of cell biodistributions, particularly when portasystemic shunting coexists. The aims of this study were to determine the fate of hepatocytes transplanted into the pulmonary vascular bed and to examine whether cell biodistributions could be approximated by convenient surrogates.

METHODS

Rat hepatocytes and macroaggregated serum albumin particles of similar sizes were injected into the portal and pulmonary vascular beds of rats, followed by biodistribution, survival and function analyses.

RESULTS

Although functionally intact, virtually all hepatocytes were cleared from the pulmonary capillaries within 24 h. Serum albumin levels increased minimally in Nagase analbuminemic rats with or without portacaval shunting to enhance delivery of portal factors to transplanted cells in lungs. Despite intravenous injection of hepatocytes approaching >1x10(9) cells in humans, the hemodynamic changes were limited to transient increases in right atrial pressures. The hepatocyte distributions in specific vascular beds were largely reproduced by macroaggregated human serum albumin particles.

CONCLUSIONS

Incidental intrapulmonary cell translocations during liver repopulation will have a wide safety margin. Use of macroaggregated serum albumin particles as surrogates for initial short-term biodistribution and safety analysis will advance hepatocyte transplantation, as the cost of GLP-certified laboratories and consumption of scarce donor livers will be avoided.

Allogeneic hepatocyte transplantation: Contribution of Fas-Fas ligand interaction to allogeneic hepatocyte rejection

Hepatocyte transplantation is a potential therapeutic modality for overcoming the shortage of liver donors, and the clinical application of allogeneic hepatocyte transplantation has been considered. However, there are two major problems with allogeneic hepatocyte transplantation: protection of transplanted hepatocytes from rejection and stimulation of the rapid proliferation of surviving cells. Without immunosuppression, allogeneic hepatocytes are rapidly rejected within a few days after transplantation, even though it is relatively easy to induce immunotolerance after allogeneic whole liver transplantation. Accordingly, different rejection mechanisms seem to operate after allogeneic hepatocyte transplantation and whole liver transplantation. To overcome the rejection of transplanted hepatocytes, induction of donor-specific unresponsiveness to graft without compromising the host immune system would be ideal. We previously reported that the Fas-Fas ligand system plays a critical role in the CD28-independent pathway of hepatocyte rejection. Therefore, blockade of rejection using CTLA4 immunoglobulin (CTLA4Ig) or anti-CD80/86 monoclonal antibodies and anti-FasL monoclonal antibody may prolong the survival of transplanted allogeneic hepatocytes. Furthermore, administration of hepatocyte growth factor (HGF) can promote the proliferation of allogeneic hepatocytes and this may lead to the development of a functioning liver substitute.

Liver repopulation with xenogenic hepatocytes in B and T cell-deficient mice leads to chronic hepadnavirus infection and clonal growth of hepatocellular carcinoma

To investigate host and viral mechanisms determining hepadnaviral persistence and hepatocarcinogenesis, we developed a mouse model by transplanting woodchuck hepatocytes into the liver of mice that contain the urokinase-type plasminogen activator transgene (uPA) and lack mature B and T lymphocytes due to a recombination activation gene 2 (RAG-2) gene knockout. The woodchuck hepatocytes were transplanted via intrasplenic injection and were found to integrate into the recipient mouse liver cord structure. Normal adult woodchuck hepatocytes proliferated and reconstituted up to 90% of the uPA/RAG-2 mouse liver. uPA/RAG-2 mice containing woodchuck hepatocytes were infectable with woodchuck hepatitis virus (WHV) and showed WHV replication for at least 10 months with titers up to 1 x 10(11) virions per ml in the peripheral blood. WHV-infected hepatocytes from chronic carrier woodchucks also established a persistent infection in uPA/RAG-2 mice after an 8- to 12-week lag period of viremia. Although WHV envelope, core, and X proteins were produced in the uPA/RAG-2 mice, no inflammatory host immune response was observed in the liver of WHV-replicating mice. A first antiviral test demonstrated a greater than four orders of magnitude drop in WHV titer in response to interferon alpha treatment. WHV replication was up-regulated by dexamethasone treatment. Comparison of precancerous lesions in donor woodchucks versus recipient uPA/RAG-2 mice revealed an enrichment of dysplastic precancerous hepatocytes in transplanted mice. Clonal amplification of hepatocytes from a woodchuck with hepatocellular carcinomas was demonstrated by the detection of unique WHV DNA integration patterns in hepatocellular carcinomas that arose in uPA/RAG-2 mice. In the absence of B or T cell-mediated immune responses, WHV establishes a persistent noncytotoxic infection of woodchuck hepatocytes in uPA/RAG-2 chimeric mouse livers. Further studies of the kinetics of hepadnavirus infection and replication in quiescent and proliferating hepatocytes should increase our understanding of hepadnavirus spread and aid in the design of therapies to block or cure persistent infection.

Expansion of transplanted hepatocytes during liver regeneration

BACKGROUND

Successful clinical application of hepatocyte transplantation has been limited by poor engraftment of the recipient liver by transplanted hepatocytes.

METHODS

To address the hypothesis that liver regeneration induced by an acute hepatotoxic injury promotes expansion of transplanted hepatocytes, we injected beta-galactosidase-labeled hepatocytes intrasplenically into mice 24 hr after treatment with carbon tetrachloride (CCl4) and into untreated controls.

RESULTS

Macroscopic examination of whole liver segments identified clusters of transplanted hepatocytes uniformly spread on the capsular surface of the recipient liver and in the liver core following the distribution pattern of portal vein branches. Frozen sections showed that although the degree of initial engraftment of transplanted hepatocytes was similar in CCl4-treated and control livers, there was a fourfold increase of engrafted hepatocytes in CCl4-treated livers 10 days after transplantation which persisted to 28 days.

CONCLUSIONS

We conclude that the number of transplanted hepatocytes increases in response to regeneration signal triggered by an acute hepatocyte-specific liver injury.

Enhancement of proliferation of intrasplenically transplanted hepatocytes in cirrhotic rats by hepatic stimulatory substance

This study aimed at investigating the efficacy of hepatic stimulatory substance (HSS) on the proliferation of transplanted hepatocytes in the spleen of rats with carbon tetrachloride (CCl4)-induced liver cirrhosis. After hepatocyte transplantation (HTx; 1x10(7) cells/rat), the recipients received intravenous administration of HSS (3ml) of 2, 4, or 7 times/week to investigate the effect of the frequency of HSS treatment on the proliferation of intrasplenically transplanted hepatocytes. Next, to investigate the effect of the severity of liver cirrhosis on HSS-stimulated proliferation of transplanted hepatocytes, different doses (0.00, 0.08, 0.12, and 0.16 ml/week) of CCl4 were given to rats after HTx. The recipients were killed and the spleens were removed at 2 and 4 weeks after HTx and stained with bromodeoxyuridine (BrdU) and hematoxylin and eosin for determining the BrdU labeling index (L.I.) and the hepatocyte-occupied area ratio in the longitudinal cut surface of the spleen (H:S ratio), respectively. The H:S ratio was measured in the hematoxylin and eosin-stained splenic sections under a light microscope connected to an image processor. HSS-treated rats showed significantly higher BrdU L.I. and H:S ratios than the untreated control rats at 2 and 4 weeks after HTx. However, the difference in the BrdU L.I. and H:S ratio was not statistically significant among the HSS-treated rats. Without HSS treatment, the severity of liver cirrhosis did not affect the proliferation of intrasplenically transplanted hepatocytes. On the other hand, HSS-induced proliferation of transplanted hepatocytes was further enhanced in proportion to the severity of liver cirrhosis. The H:S ratio of the rats treated with 0.04, 0.08, and 0.16 ml/week of CCl4 after HTx was 1.27+/-0.5%, 4.32+/-0.65%, and 6.25+/-0.70%, respectively, at week 4. During the long-term observation of up to 12 weeks, a marked decrease in the H:S ratio was observed in HSS-untreated control rats at weeks 4-12 compared with week 2. While HSS-treated rats revealed gradual proliferation of intrasplenically transplanted hepatocytes, the difference in the H:S ratio between HSS-treated and -untreated rats became larger. These results indicate that HSS treatment of recipient rats stimulated the proliferation of intrasplenically transplanted hepatocytes in cirrhotic rats and that the severity of liver cirrhosis enhanced the stimulative effect of HSS on the proliferation of transplanted hepatocytes.

Human gene therapy in gastrointestinal diseases: in vivo and in vitro approaches

The first clinical trial in human gene therapy began in 1989 with the successful introduction of marker genes into peripheral blood cells as tumor-infiltrating lymphocytes (TIL) in order to investigate the biological behavior of manipulated cells in humans. In further studies, it was possible to ameliorate clinical genetic diseases based on only one single genetic defect such as adenosine deaminase deficiency (ADA) by repeated infusion of manipulated peripheral blood cells. Meanwhile, a multitude of clinical gene transfer studies were initiated. Three main strategies have thus far been applied in human cancer gene therapy: (1) Reinforcement of the body's immune response by gene transfer into immunological cells; (2) reinforcement of the immune response by manipulating tumor cells; and (3) transfer of drug-sensitive genes into tumor cells with subsequent drug treatment. The first clinical trial in gene therapy for gastrointestinal diseases was performed in 1992 with the introduction of the low-density protein receptor gene (LDL) into liver tissue. Human cancer gene therapy of gastrointestinal diseases is still only in the initial phase of research.

Integration of transplanted hepatocytes into host liver plates demonstrated with dipeptidyl peptidase IV-deficient rats

To analyze mechanisms of liver repopulation, we transplanted normal hepatocytes into syngeneic rats deficient in dipeptidyl peptidase IV activity. When isolated hepatocytes were injected into splenic pulp, cells promptly migrated into hepatic sinusoids. To examine whether transplanted hepatocytes entered liver plates and integrated with host hepatocytes, we analyzed sharing of hepatocyte-specific gap junctions and bile canaliculi. Colocalization studies showed gap junctions uniting adjacent transplanted and host hepatocytes in liver plates. Visualization of bile canalicular domains in transplanted and host hepatocytes with dipeptidyl peptidase IV and ATPase activities, respectively, demonstrated hybrid bile canaliculi, which excreted a fluorescent conjugated bile acid analogue. These results indicate that transplanted hepatocytes swiftly overcome mechanical barriers in hepatic sinusoids to enter liver plates and join host cells. Integration into liver parenchyma should physiologically regulate the function or disposition of transplanted hepatocytes and benefit applications such as gene therapy.

Transcatheter hepatocyte transplantation: preclinical studies of anatomic consequences in the portal vascular bed

RATIONALE AND OBJECTIVES

Intrasplenic transplantation deposits hepatocytes in host hepatic sinusoids with amelioration of chronic liver failure and genetic deficiency states. Because portal resistance can be altered by intrasinusoidal transplanted cells, we examined whether hepatocyte recipients would develop deleterious portal hypertension or portosystemic collaterals.

METHODS

Syngeneic hepatocytes in suspension were transplanted into recipient rats by transcatheter injection into the splenic parenchyma. Subjects included recipients of 2 x 10(7) hepatocytes representing approximately 3% of the host hepatic mass, recipients of 7.5 x 10(7) hepatocytes representing approximately 12.5% of the host hepatic mass, normal control rats, and positive control rats with portal hypertension induced by partial portal vein constriction. Portal pressures were recorded with a sensitive transducer, portosystemic collaterals were demonstrated with direct splenoportography, and survival of transplanted cells was determined with an endogenous dipeptidyl peptidase IV reporter gene.

RESULTS

In normal rats, the portal pressure was 6.25 +/- 1.9 mm Hg with no portosystemic collaterals. By contrast, portal pressures were significantly increased in portal vein-constricted rats, 20.7 +/- 3.9 mm Hg (P < 0.001), with extensive portosystemic collaterals. In hepatocyte recipients, portal hypertension observed during transcatheter cell injection but proved transient. When animals were examined up to 16 weeks after hepatocyte transplantation, portal pressures were in the normal range (after 2 x 10(7) cells, 7.5 x 2.6 mm Hg; after 7.5 x 10(7) cells, 9.5 +/- 4.2 mm Hg, P = not significant). No portosystemic collaterals developed in hepatocyte recipients at various times up to 8 months after transplantation. Transplanted hepatocytes expressing the reporter gene were present in recipients with assimilation in host hepatic cords.

CONCLUSION

Despite injection of a massive number of cells, transcatheter hepatocyte transplantation was devoid of any significant portal vascular alterations or toxicity in recipients. These findings are consistent with assimilation of transplanted hepatocytes into host hepatic cords and will facilitate therapeutic applications in metabolic diseases or acute liver failure.

Hepatocytes exhibit superior transgene expression after transplantation into liver and spleen compared with peritoneal cavity or dorsal fat pad: implications for hepatic gene therapy

For hepatic gene therapy or applications of hepatocyte transplantation in liver failure, survival and function of transplanted cells is critical. Insights into site-specific gene regulation will significantly facilitate development of appropriate strategies for transplanting hepatocytes. To assess the function of transplanted cells, we used a transgenic hepatitis B virus (HBV) hepatocyte system, which allowed analysis of cellular gene expression with HBV surface antigen (HBsAg) mRNA expression, as well as secretion of HBsAg into peripheral circulation. When congeneic HBV hepatocytes were transplanted into the liver (via spleen), serum HBsAg promptly appeared in circulation and persisted for the entire duration of the studies. In contrast, transplantation of hepatocytes into the peritoneal cavity or dorsal fat pad resulted in serum HBsAg levels that were either significantly lower or gradually rose after a lag period. HBsAg mRNA expression was several-fold greater in transplanted hepatocytes in liver or spleen versus in peritoneal cavity or dorsal fat pad. Despite persistence of transplanted hepatocytes in peritoneal cavity or dorsal fat pad, serum HBsAg was cleared by antibody to HBsAg (anti-HBs) but this was not observed after hepatocyte transplantation into spleen. As the function of transplanted hepatocytes is optimally regulated in the liver, hepatic reconstitution with cell transplantation will be most appropriate for gene therapy.

111Indium labeling of hepatocytes for analysis of short-term biodistribution of transplanted cells

Hepatocyte transplantation is useful for ex vivo gene therapy and liver repopulation. Methods for hepatic reconstitution have recently been developed but optimization of hepatocyte transplantation systems is necessary. To develop systems for noninvasive assessment of the biodistribution of transplanted cells, we labeled hepatocytes with 111indium-oxine. Our initial studies showed that hepatocytes incorporated 111indium-oxine with an efficiency of approximately 20%. After labeling, cell viability was unchanged and 111indium was present in hepatocytes after overnight culture, as well as after intrasplenic transplantation. Transplanted cells were successfully localized by means of scintigraphic imaging. The scintigraphic patterns of cell distribution were different when hepatocytes were transplanted by means of either spleen or internal jugular vein, which deposit cells into separate vascular beds. Quantitative analysis of the biodistribution of 111indium-labeled hepatocytes indicated that within 2 hr of intrasplenic transplantation, cells were predominantly localized in liver and spleen, and occasionally in lungs. To determine whether the rate of intrasplenic cell injection influenced translocation of hepatocytes, we transplanted cells in normal rats. Despite intrasplenic cell injection at a variety of rates, organ-specific distribution of 111indium-labeled hepatocytes remained unchanged. Labeling with 111indium did not affect long-term survival of transplanted hepatocytes. These results indicate that 111indium-labeling of hepatocytes should greatly assist noninvasive analysis in the short-term of the biodistribution of transplanted hepatocytes.