Intrasplenic Hepatocyte Transplantation Prolonged the Survival in Nagase Analbuminemic Rats with Liver Failure Induced by Common Bile Duct Ligation

Current and Emerging Approaches for Hepatic Fibrosis Treatment

Liver fibrosis resulting from chronic liver injury is a key factor to develop liver cirrhosis and risk of hepatocellular carcinoma (HCC) which are major health burden worldwide. Therefore, it is necessary for antifibrotic therapies to prevent chronic liver disease progression and HCC development. There has been tremendous progress in understanding the mechanisms of liver fibrosis in the last decade, which has created new opportunities for the treatment of this condition. In this review, we aim to make an overview on information of different potential therapies (drug treatment, cell therapy, and liver transplantation) for the liver fibrosis and hope to provide the therapeutic options available for the treatment of liver fibrosis and discuss novel approaches.

Mechanisms Underlying Cell Therapy in Liver Fibrosis: An Overview

Fibrosis is a common feature in most pathogenetic processes in the liver, and usually results from a chronic insult that depletes the regenerative capacity of hepatocytes and activates multiple inflammatory pathways, recruiting resident and circulating immune cells, endothelial cells, non-parenchymal hepatic stellate cells, and fibroblasts, which become activated and lead to excessive extracellular matrix accumulation. The ongoing development of liver fibrosis results in a clinically silent and progressive loss of hepatocyte function, demanding the constant need for liver transplantation in clinical practice, and motivating the search for other treatments as the chances of obtaining compatible viable livers become scarcer. Although initially cell therapy has emerged as a plausible alternative to organ transplantation, many factors still challenge the establishment of this technique as a main or even additional therapeutic tool. Herein, the authors discuss the most recent advances and point out the corners and some controversies over several protocols and models that have shown promising results as potential candidates for cell therapy for liver fibrosis, presenting the respective mechanisms proposed for liver regeneration in each case.

Impaired hepatocyte regeneration in acute severe hepatic injury enhances effective repopulation by transplanted hepatocytes

Efficient repopulation by transplanted hepatocytes in the severely injured liver is essential for their clinical application in the treatment of acute hepatic failure. We studied here whether and how the transplanted hepatocytes are able to efficiently repopulate the toxin-induced acute injured liver. Male dipeptidyl peptidase IV-deficient F344 rats were randomized to receive retrorsine plus D-galactosamine (R+D-gal) treatment or D-galactosamine-alone (D-gal) to induce acute hepatic injury, and retrorsine-alone. In these models, retrorsine was used to inhibit the proliferation of endogenous hepatocytes while D-galactosamine induced acute hepatocyte damage. Wild-type hepatocytes (1 x 10(7)/ml) were transplanted intraportally 24 h after D-galactosamine or saline injection. The kinetics of proliferation and repopulation of transplanted cells and the kinetics of cytokine response, hepatic stellate cell (HSC) activation, and matrix metalloproteinase (MMP2) expression were analyzed. We observed that early entry of transplanted hepatocytes into the hepatic plates and massive repopulation of the liver by transplanted hepatocytes occurred in acute hepatic injury induced by R+D-gal treatment but not by D-gal-alone or retrorsine-alone. The expressions of transforming growth factor-alpha and hepatocyte growth factor genes in the R+D-gal injured liver were significantly upregulated and prolonged up to 4 weeks after hepatocyte transplantation. The expression kinetics were parallel with the efficient proliferation and repopulation of transplanted hepatocytes. HSC was activated rapidly, markedly, and prolongedly up to 4 weeks after hepatocyte transplantation, when the expression of HGF gene and repopulation of transplanted hepatocytes were reduced afterward. Furthermore, the expression kinetics of MMP2 and its specific distribution in the host areas surrounding the expanding clusters of transplanted hepatocytes are consistent with those of activated HSC. Impaired hepatocyte regeneration after acute severe hepatic injury may initiate serial compensatory repair mechanisms that facilitate the extensive repopulation by transplanted hepatocytes that enter early the hepatic plates.

Review of hepatocyte transplantation

BACKGROUND

Hepatocyte transplantation is a promising treatment for several liver diseases and can also be used as a "bridge" to liver transplantation in cases of liver failure. Although the first animal experiments with this technique began in 1967, it was first applied in humans only in 1992. Unfortunately, unequivocal evidence of transplanted human hepatocyte function has been obtained in only one patient with Crigler-Najjar syndrome type I and, even then, the amount of bilirubin-UDP-glucuronosyltransferase enzyme activity derived from the transplanted cells was not sufficient to eliminate the patient's eventual need for organ transplantation.

METHODS

A literature review was carried out using MEDLINE and library searches.

RESULTS

This review considers the following: (1) alternatives or bridges to orthotopic liver transplantation (OLT); (2) solutions to the shortage of organs-the shortage of organ donors has impeded the development of human hepatocyte transplantation, and immortalized hepatocytes in particular could provide an unlimited supply of transplantable cells in a nearly future; (3) future directions. We review these efforts along with hepatocyte transplantation over the last 13 years.

Immortalized hepatocytes using human artificial chromosome

The shortage of organ donors has impeded the development of human hepatocyte transplantation. Immortalized hepatocytes could provide an unlimited supply of transplantable cells. To determine whether immortalized hepatocytes could provide global metabolic support in end-stage liver disease, rat hepatocyte clones were developed by transduction with the gene encoding the Simian virus 40 T antigen (SVT) using the human artificial minichromosome (HAC). The SVLT sequence was excised by FRT recombination. Following HAC infusion, the transduced hepatocytes express SVT, blasticidine resistance (BS), and the PGK promoter TK gene. Forty-six cell clones were obtained and at least partially characterized, as previously described, for albumin, alpha-1-antitrypsin, glucose-6-phosphatase (G6Pase), dipeptidylpeptidase 4 (Dpp4), gamma-glutamyltransferase 1 (Ggt), SVT, and beta-actin expression using RT-PCR. Clones were also assessed for albumin secretion into the culture medium using ELISA. All of the cell line secreted approximately 10 mg/dl of albumin, which is equivalent to the amount secreted by primary hepatocytes. In further experiments, this cell line will be used for transplantable cells or artificial organ using HAC. These results represent an important step toward the development of immortalized hepatocytes.

Laparoscopy-assisted creation of a liver failure model in pigs

We created a hepatic failure pig model that was suitable for the assessment of cell therapies, such as hepatocyte transplantation and bioartificial livers, using a laparoscopic surgical technique. In our model, all of three hepatic arteries were resected, 5, 7.5, or 10 ml of carbon tetrachloride (CCL4) was injected into the liver through the portal vein, and subsequently the portal vein was mechanically occluded for 30 min. After the portal occlusion was released, a liver biopsy was performed, and then the surgery was completed. Blood samples were regularly taken during the surgery in order to perform biochemical examinations. All of five pigs in which 5 ml of CCL4 was infused recovered spontaneously and survived; in contrast, all of five pigs that received 10 ml CCL4 died within 1.5 h after surgery. The pigs in which 7.5 ml CCL4 was administered developed liver failure and survived for 6.4 h on average (+/-1.4 SD). Induction of liver failure with the use of 7.5 ml CCL4 and 30-min hepatic ischemia fulfilled five of the six criteria that were proposed by Terblanche and Hickman: reversibility, reproducibility, death from liver failure, a therapeutic window, and a large-animal model. We believe that our model is the first report on creation of a reliable model for liver failure in pigs to assess the efficacy of liver-targeted cell therapies.