Intraportal hepatocyte transplantation in the pig: hemodynamic and histopathological study

BACKGROUND: Hepatocyte transplantation is an attractive treatment for various liver diseases. The intraportal route of transplantation is favored, but little information is available on the possible adverse effects in this technique. We investigated the influence of intraportal loads of hepatocytes on portal, pulmonary, and systemic hemodynamics in 13 pigs. METHODS: Under general anesthesia, pigs were provided with an arterial line, a Swan-Ganz catheter, and two intraportal catheters, one for cell infusion and one for heparin infusion and portal pressure measurement. Pig hepatocytes were infused at a rate of 25 million cells/min. RESULTS: The first six animals were used to develop the infusion technique. In the last seven animals, portal pressure increased linearly with cell load upon infusion of 400-2400 x 10(6) hepatocytes (r(2)=0.704;P<0.05). Portal flow measured by Doppler sonography decreased by 23-66% below basal values. An inverse linear relationship was found between portal pressure and portal flow (r(2)=0.679; P<0.05), portal flow approaching zero for portal pressure >40 mmHg. Pulmonary arterial pressure increased by 11-62%. AST increased up to 10-fold, and platelets decreased by 22-58%. Hepatocytes-containing thrombi were present in segmental and in smaller portal branches. Hepatocytes were always identified in lung sinusoids 48 hr after infusion, and a small basal pulmonary infarction was found in one animal. CONCLUSION:. These data suggest that up to 2.4% of total hepatocyte mass can be infused in this large animal model. However, the risk of significant thrombotic complications should be considered for clinical applications.     

State of hepatocyte transplantation: a risk or a chance?

Over the past few years, hepatocyte transplantation has been considered as an alternative method for orthotopic liver transplantation for the treatment of various liver diseases. Beside curative approach for genetic metabolic deficiencies (familial hypercholesterolemia, hemophilia, etc.), it could be a useful tool for bridging the waiting period until an appropriate donor organ is obtained. In preclinical animal studies, hepatocytes injected intraperitoneally, intraportally or into the spleen settle down in the diseased liver. This enables genetic modification to correct inborn metabolic deficiencies and improves survival in acute liver failure. In 1992, the first clinical transplantation of isolated hepatocytes in 10 patients was performed. In 1998, Fox and coworkers described the successful transplantation of allogeneic liver cells in a child with Crigler-Najjar syndrome. Accomplished studies of Strom et al. resp. Bilir et al. of the same year proved the effectiveness of liver cell transplantation for transient treatment of acute liver failure. Prerequisite of this cell-based therapeutic strategy is a sufficient amount of highly differentiated hepatocytes, hence, a well established in-vitro cell-culture technique is necessary to yield a reproducible number of proliferating hepatocytes and to preserve the physiological cell function. This review discusses the different experimental approaches regarding the cultivation of human hepatocytes and also the use of alternative cell sources (like animal hepatocytes, immortalized cells of human origin, progenitor cells from fetal human liver/liver stem cells) for hepatocyte transplantation.     

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.     

Evidence that temporary complete occlusion of splenic vessels prevents massive embolization and sudden death associated with intrasplenic hepatocellular transplantation

It has been reported elsewhere that liver cell suspensions injected at several locations retain some proper hepatic functions, significantly improve the survival rate of rats with different models of acute fulminant hepatic injury, correct some congenital enzyme deficiency diseases, and improve liver function in cirrhotic animals. Among several locations, the splenic parenchyma has been shown to be the most suitable place for hepatocellular transplantation. Unfortunately, infusion of cells into the splenic pulp is not without risk. In fact, portal hypertension and hepatic embolizations have been described after intrasplenic transplantation of hepatocytes or pancreatic islets or fragments. In addition, pulmonary hepatocyte embolizations have been observed in rats with spontaneous (unpublished observations) or surgically induced portosystemic shunts. In this work, we evaluate the efficacy of temporary occlusion of splenic vessels to prevent hepatic and pulmonary embolizations after liver cell transplantation into the spleen in portal hypertension cirrhotic rats with portosystemic shunts.     

Transplantation of hepatocytes: elimination of recipient natural killer cells with irradiation and bone marrow reconstitution prevent early graft dysfunction

Transplanted isolated syngeneic and allogeneic hepatocytes rapidly disintegrate, irrespective of the origin or the site of engraftment namely spleen, liver, portal vein, peritoneum, or subcutaneous tissues. Although various methods have been applied to attenuate this reaction, none have been found effective. We applied a combined protocol consisting of administration of anti-asialoGM1 antiserum (eliminating NK cells), sublethal whole-body irradiation, and reconstitution with syngeneic bone marrow cells to intrasplenic hepatocyte transplantation and 3 consecutive partial hepatectomies. This method overcame the early disintegration of grafted hepatocytes. Ninety days after transplantation numerous hepatocyte clusters and dilated bile canaliculae, occupying two thirds of the spleen, were observed, with some hepatocytes adhering to the bile ducts forming Hering's canals. Mitotic figures were noticed. There were no recipient mononuclear infiltrates around the hepatocyte clusters.     

Hepatic arterial buffer response after pediatric living donor liver transplantation: report of a case

Background

Excessive portal pressure at an early stage after living-donor liver transplantation (LDLT) can damage sinusoidal endothelial cells and hepatocytes through shear stress leading to graft failure, or hepatic arterial complications due to low hepatic artery flow from a hepatic arterial buffer response. We encountered a case in which excessive portal vein flow was observed from an early stage after pediatric LDLT. The hepatic artery flow decreased due to a hepatic arterial buffer response.

Case report

A 6-month-old boy with biliary atresia showed excessive portal vein flow early after LDLT with a decreasing hepatic artery flow without anastomotic stenosis from postoperative day 3. The PV flow gradually exhibited a decrease at approximately postoperative day 8 and, similtaneously, hepatic artery flow exhibited improvement.

Conclusion

Because excessive portal pressure after LDLT is reversible, it has been suggested that it may be possible to prevent the progress of hepatic arterial complications if temporary portal pressure modulation can be performed for cases among the high-risk group for hepatic arterial complications.     

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.     

Efficient hepatocyte engraftment in a nonhuman primate model after partial portal vein embolization

BACKGROUND: Hepatocyte transplantation could be an alternative to whole liver transplantation for the treatment of metabolic liver diseases. However, the results of clinical investigations suggest that the number of engrafted hepatocytes was insufficient to correct metabolic disorders. This may partly result from a lack of proliferation of transplanted hepatocytes. In rodents, portal ligation enhances hepatocyte engraftment after transplantation. We investigated the effects of partial portal ligation and embolization on engraftment and proliferation of transplanted hepatocytes in primates. METHODS: Hepatocyte autotransplantation was performed in Macaca monkeys. The left lateral lobe was resected for hepatocyte isolation. The first group of monkeys underwent surgical ligation of the left and right anterior portal branches; in the second group, the same portal territories were obstructed by embolization with biological glue. To evaluate the proportion of cell engraftment hepatocytes were Hoechst-labeled and transplanted via the portal vein. Cell proliferation was measured by BrdU incorporation. RESULTS: Hepatocyte proliferation was induced by both procedures but it was significantly higher after partial portal embolization (23.5% and 11.2% of dividing hepatocytes on days 3 and 7) than after ligation (3% and 0.8%). Hepatocytes engrafted more efficiently after embolization than after ligation. They proliferated and participated to liver regeneration representing 10% of the liver mass on day seven and their number remained constant on day 15. CONCLUSIONS: These data suggest that partial portal embolization of the recipient liver improves engraftment of transplanted hepatocytes in a primate preclinical model providing a new strategy for hepatocyte transplantation.     

The origin of biliary ductular cells that appear in the spleen after transplantation of hepatocytes

Transplantation of rat hepatocytes into the syngeneic rat spleen results in the appearance of cytokeration (CK)-19-positive biliary cells that form ductules. The exact origin of CK-19-positive cells is not known and the possibility that they are derived from biliary cells or precursors of oval cells in transplanted hepatocyte preparations has been raised. In the present study, we found that the number of CK-19-positive biliary cells increased rapidly after transplantation of hepatocytes, reached the maximum at 4 weeks, and then gradually decreased. However, a Ki-67 labeling index of CK-19-positive biliary cells was low and showed no significant changes throughout the experimental period. In addition, no or few CK-19-positive cells appeared in the spleen after transplantation of nonparenchymal liver cells enriched with biliary cells. These results showed that biliary cells were not the source of CK-19-positive cells in the spleen. Impairment of precursors of oval cells in the liver by administration of 4,4'-diaminodiphenylmethane 24 h before transplantation of hepatocytes did not prevent the appearance of CK-19-positive biliary cells in the spleen. Moreover, transplantation of nonparenchymal cells carrying an increased number of oval cells by means of treatment with 2-acetylaminofluorene and partial hepatectomy resulted in no appearance of CK-19-positive biliary cells in the spleen. These results ruled out oval cells as the origin of CK-19-positive biliary cells in the spleen. Because CK-19-positive biliary cells appeared in the spleen only when hepatocyte fractions were transplanted, we suggest transdifferentiation of heptocytes may be the mechanism by which CK-19-positive biliary cells are generated.     

Three different hepatocyte transplantation techniques for enzyme deficiency disease and acute hepatic failure

The effects of three different techniques of hepatocyte transplantation were investigated: transplantation of free hepatocytes into the spleen and intraperitoneal transplantation of microcarrier-attached hepatocytes or of microencapsulated hepatocytes. The liver-supportive functions of these transplanted hepatocytes were analyzed using either the Gunn rat (hyperbilirubinemia) or rats with acute liver failure. In the Gunn rat intraperitoneal transplantation of microcarrier-attached hepatocytes resulted in a significant reduction of plasma bilirubin for 28 days whereas intraperitoneal transplantation of microencapsulated hepatocytes was ineffective notwithstanding immunosuppression by cyclosporin A. Intrasplenic hepatocyte transplantation was only effective in reducing plasma bilirubin for 14 days. During acute liver failure, liver support was achieved temporarily by hepatocyte transplantation in the spleen, by intraperitoneally transplanted microcarrier-attached hepatocytes, and by microencapsulated hepatocytes to equal extents, the microencapsulated hepatocytes being the least effective after 8 h of liver ischemia.     

Transplantation of hepatocytes: temporary elimination of scavenger cells prevents early loss of grafted cells

Transplants of isolated syngeneic and allogeneic hepatocytes are rapidly disintegrated, irrespective of the site of engraftment; be it spleen, liver, portal vein, peritoneum, or subcutaneous tissue. Host scavenger cells are responsible for this reaction. We designed a method overcoming early disintegration of the grafted hepatocytes. It consisted of administration of anti-asialoGM1 antiserum eliminating natural killer cells; sublethal whole body irradiation; and reconstitution with syngeneic bone marrow cells, ligation of host bile duct, intrasplenic hepatocyte transplantation, and three consecutive partial hepatectomies. Six months after transplantation a glycogen-rich, trabeculae-forming, dividing hepatocytes, situated along strands of newly-formed fibrous tissue and numerous dilated blind bile cannaliculae were observed. There was evidently more bile canaliculae in hosts with ligated bile duct than nonligated controls. This is the first study showing fibrous tissue formed at the site of hepatocyte implantation, and stellate cells are presumably involved in this process.     

Teratoma formation and hepatocyte differentiation in mouse liver transplanted with mouse embryonic stem cell-derived embryoid bodies

We previously reported that mouse embryonic stem (ES) cells are capable of differentiating into hepatocytes in cultured embryoid bodies (EBs) and that hepatocytes generate in the recipient liver injected with cultured day-9 EB cells via spleen without the formation of a teratoma. Because ES cells frequently form teratomas in recipient mice, we investigated incidence of teratoma formation when day-9 EBs derived from ES cells were transplanted directly into the subcapsule of mouse liver. In contrast to injection of day-9 EB cells through the portal vein via the spleen, direct subcapsular injection of cultured day-9 EB cells into liver, and even of cultured day-15 EBs, resulted in an high incidence of teratoma in the liver. In teratomas of livers injected directly with day-15 EBs, hepatocytes were detected singly and in clusters. These results imply that undifferentiated cells capable of developing into teratomas exist in cultured EBs, and even in cultured day-15 EBs containing differentiated hepatocytes.     

Liver repopulation after hepatocellular transplantation: integration and interaction of transplanted hepatocytes in the host

The mechanisms of donor hepatocyte integration into recipient liver are not fully understood. We investigated mechanisms of both the integration and interaction of transplanted hepatocytes with host liver cells as well as the repopulation of the host organ following intraportal transplantation. Mature hepatocytes were injected into the portal vein of dipeptidylpeptidase IV (DPPIV)-deficient rats pretreated with retrorsine and subjected to 30% partial hepatectomy to ensure selective donor growth. The degree of integration and proliferation was studied by colocalizing transplanted cells (DPPIV positive) with connexin 32, MMP-2, and OX-43 (multilayer immunofluorescence imaging). FACS analysis was established to assess the extent of repopulation quantitatively. Transplanted hepatocytes reached the distal portal spaces and sinusoids within 1 h after injection. A small proportion of cells succeeded in traversing the endothelial barrier through mechanical disruption in both locations. Transplanted hepatocytes lost their membrane-bound gap junctions (connexin 32) during this process. Successful integration of the donor cells required up to 5 days, heralded by gap junction reconstitution and the specific basolateral membrane expression of DPPIV. MMP-2 degraded the extracellular matrix in close proximity to donor cells, providing space for cell division. FACS analysis revealed that more than 37% of the liver was repopulated by cells derived from donors at 2 months after transplantation. Our data demonstrate a high degree of donor cell repopulation of the host organ and provide valuable insight into the specific mechanisms of donor cell integration. Connexin 32 expression in transplanted hepatocytes may serve as an indicator of their effective incorporation and communication within the recipient liver. FACS analysis reveals an accurate method to determine quantitatively the extent of liver repopulation.     

A novel system for transplantation of isolated hepatocytes utilizing HBsAg-producing transgenic donor cells

Hepatocytes from donor transgenic mice that produce an easily assayable circulating marker have been used to develop a novel hepatocyte transplantation system. Isolated G7 HBV transgenic donor hepatocytes secreting HBsAg were transplanted into congeneic or allogeneic mouse recipients. Serum HBsAg was present three days after hepatocyte transplantation in congeneic animals and persisted indefinitely when hepatocytes were transplanted into the spleen. Transplanted hepatocytes within the splenic pulp were identified by morphologic and histochemical analysis. Migration of hepatocytes injected into the spleen to the liver was demonstrated by in situ hybridization using an RNA probe for HBsAg. Transplantation into nonimmunosuppressed allogeneic recipients resulted in disappearance of detectable hepatocytes in the spleen within two weeks. This novel transplantation system should facilitate studies of hepatocyte engraftment and survival, modulation of allograft rejection, and development of hepatocyte-directed gene therapy.     

Monitoring of Intrasplenic Hepatocyte Transplantation for Acute-on-Chronic Liver Failure: A Prospective Five-Year Follow-Up Study

Background

Acute-on-chronic liver failure (ACLF) is defined as an acute deterioration of chronic liver disease. Intrasplenic hepatocyte transplantation is increasingly recognized as a treatment for liver failure and genetic metabolic liver diseases. We describe our experience of intrasplenic hepatocyte transplantation in a small cohort of patients as bridge therapy or as an alternative to orthotopic liver transplantation (OLT).

Methods

Seven patients with ACLF with an expected survival of less than 8 weeks were enrolled into the study. The donor hepatocytes were collected from 2 healthy males and cryopreserved. Donor hepatocytes were transplanted into the spleen of recipients via catheterization of the femoral artery. All patients were followed up for 5 years or to death.

Results

A total of (4.2–6.0) × 10¹⁰ hepatocytes were harvested from the 2 donors' livers and their survival after recovery from the frozen stock was 63% ± 2.8% and 73.5% ± 3.2%, respectively. Following intrasplenic hepatocyte transplantation, 3 patients fully recovered from liver failure, 1 survived and subsequently underwent OLT, and the remaining 3 patients died between 2.5 and 12 months after intrasplenic hepatocyte transplantation. At month 48 post–intrasplenic hepatocyte transplantation, living hepatocyte signals were observed in the spleen using magnetic resonance imaging (MRI) with gadobenate dimeglumine (Gd-BOPTA).

Conclusions

Intrasplenic hepatocyte transplantation is a promising therapy for liver failure that may reduce mortality rates among patients with end-stage liver disease awaiting OLT. Conceivably, intrasplenic hepatocyte transplantation may be considered an alternative to OLT for patients with acute liver failure. MRI (Gd-BOPTA) is a useful tool for detecting living hepatocytes in the spleen after intrasplenic hepatocyte transplantation.     

Evidence of metabolic activity of adult and fetal rat hepatocytes transplanted into solid supports.

This study was undertaken to assess the metabolic effect of fetal and adult hepatocyte transplantation in the Gunn rat, genetically incapable of bilirubin conjugation. A comparison was made between fetal and adult hepatocytes transplanted into the spleen, and those injected into polytetrafluoroethylene (PTFE) solid supports that had previously been implanted intraperitoneally. Between 4 and 12 weeks after intrasplenic transplantation of adult liver cells, serum bilirubin was significantly decreased when compared with control animals (39.6 +/- 5.6%; P less than 0.01 vs. controls). Intrasplenic transplantation of fetal hepatocytes resulted in a maximal decrease of 33.2 +/- 9.1% at 8 weeks postoperatively (P less than 0.02 vs. controls). Similar declines of serum bilirubin levels were found after transplantation of adult or fetal liver cells into the solid supports. At 12 weeks after transplantation, bilirubin conjugates were detectable in the bile of all animals that underwent intrasplenic hepatocyte transplantation and in 60% of those that underwent the solid support procedure, whereas none could be detected in control animals. Histological evidence of surviving cells was obtained in all but one animal at 12 weeks, and confirmed at 12 months postoperatively. It is concluded that the PTFE solid support technique offers an attractive alternative to the intrasplenic route, and that both fetal and adult hepatocytes, transplanted in either way still exert their conjugating activity after 12 weeks.     

Comparison of clevidipine with sodium nitroprusside in the control of blood pressure after coronary artery surgery

BACKGROUND AND OBJECTIVE: We set out to compare the efficacy of clevidipine and sodium nitroprusside infusions in the control of blood pressure and the haemodynamic changes they produce in hypertensive patients after operation for elective coronary bypass grafting. METHODS: Thirty patients were randomly allocated to receive either clevidipine or sodium nitroprusside after their mean arterial pressure (MAP) had reached > 90 mmHg for at least 10 min in the postoperative period. The MAP was continuously measured and related to time. Thus, the efficacy of the drugs in controlling arterial pressure could be inversely related to the total area under the MAP-time curve outside a target MAP range of 70-80 mmHg normalized per hour (AUC(MAP) mmHg min h(-1)). Haemodynamic variables and the number of dose-rate adjustments required to maintain MAP were also studied. RESULTS: There was no statistically significant difference in the efficacy (AUC(MAP) mmHg min h(-1)) of clevidipine (106 +/- 25 mmHg min h(-1)) compared with sodium nitroprusside (101 +/- 28 mmHg min h(-1)). Nor was any significant difference found in the total number of dose adjustments required to control MAP within the target range. The heart rate in patients receiving clevidipine increased less than in those given sodium nitroprusside. Stroke volume, central venous pressure and pulmonary artery pressure were significantly reduced upon administration of sodium nitroprusside but not of clevidipine. CONCLUSIONS: There was no significant difference between clevidipine and sodium nitroprusside in their efficacy in controlling MAP. The haemodynamic changes, including tachycardia, were less pronounced with clevidipine than with sodium nitroprusside.     

Establishment of practical recellularized liver graft for blood perfusion using primary rat hepatocytes and liver sinusoidal endothelial cells

Tissue decellularization produces a three‐dimensional scaffold that can be used to fabricate functional liver grafts following recellularization. Inappropriate cell distribution and clotting during blood perfusion hinder the practical use of recellularized livers. Here we aimed to establish a seeding method for the optimal distribution of parenchymal and endothelial cells, and to evaluate the effect of liver sinusoidal endothelial cells (LSECs) in the decellularized liver. Primary rat hepatocytes and LSECs were seeded into decellularized whole‐liver scaffolds via the biliary duct and portal vein, respectively. Biliary duct seeding provided appropriate hepatocyte distribution into the parenchymal space, and portal vein–seeded LSECs simultaneously lined the portal lumen, thereby maintaining function and morphology. Hepatocytes co‐seeded with LSECs retained their function compared with those seeded alone. Platelet deposition was significantly decreased and hepatocyte viability was maintained in the co‐seeded group after extracorporeal blood perfusion. In conclusion, our seeding method provided optimal cell distribution into the parenchyma and vasculature according to the three‐dimensional structure of the decellularized liver. LSECs maintained hepatic function, and supported hepatocyte viability under blood perfusion in the engineered liver graft owing to their antithrombogenicity. This recellularization procedure could help produce practical liver grafts with blood perfusion.     

肝细胞体内移植治疗重型肝炎临床研究

目的探讨肝细胞体内移植治疗重型肝炎临床应用的安全性、疗效及免疫抑制剂方案的可行性。方法采用肝细胞分离纯化、体外培养、冷冻及复苏方法，经股动脉插管原位肝细胞体内移植。结果7例重型肝炎病人中，2例临床治愈；2例好转出院；1例肝细胞移植后第8天等到供体肝脏行原位肝移植；2例死亡。结论肝细胞体内移植是一项安全，近期疗效确定的治疗方法，免疫抑制剂方案有可行性，移植后的肝细胞能够在脾脏内增殖、分化，替代或部分恢复肝脏合成、解毒和代谢功能。     

Construction of liver tissue in vivo with preparative partial hepatic irradiation and growth stimulus: investigations of less invasive techniques and progenitor cells

Background

The selective proliferation of transplanted hepatocytes with a growth stimulus, such as partial hepatectomy or hepatocyte growth factor, concomitant with hepatic irradiation (HIR), which can suppress proliferation of host hepatocytes, has been reported. We have conducted experiments that focused on less invasive and clinically applicable techniques and progenitor cells.

Materials and methods

First, dipeptidyl-peptidase IV-F344 or jaundiced Gunn rats underwent partial HIR (only 30% of whole liver) and portal vein branch ligation (PVBL) of one lobe, followed by intrasplenic hepatocyte transplantation at 1 × 10⁷. Second, after partial HIR and PVBL, two types of progenitor cells were transplanted (i.e., small hepatocytes (SHs) or adipose-derived mesenchymal stem cells.

Results

Sixteen weeks after transplantation, the donor cells constituted > 70% of the hepatocytes of the irradiated lobe, showing connexin 32, phosphoenolpyruvate carboxykinase-1, and glycogen storage. Moreover, the serum bilirubin level had decreased significantly in the jaundiced Gunn rats and remained at this level throughout the 24 wk experimental period. The SHs grew more quickly than the hepatocytes. After 8 wk, around 40% of the host hepatocytes had been replaced by transplanted SHs. Although the donor adipose-derived mesenchymal cells were engrafted after 8 wk, their proliferation was not observed.

Conclusions

HIR, combined with PVBL, can be given to a selective liver lobe and is a less-invasive but effective method for proliferation of transplanted hepatocytes. Even a smaller number of SHs can construct liver tissue with their prevailing proliferative ability.