Intermittent high-flux albumin dialysis with continuous venovenous hemodialysis for acute-on-chronic liver failure and acute kidney injury.

Acute-on-chronic liver failure (ACLF) requiring intensive medical care and associated with acute kidney injury (AKI) has a mortality rate as high as 90% due to the lack of effective therapies. In this study, we assessed the effects of intermittent high-flux single-pass albumin dialysis (SPAD) coupled with continuous venovenous hemodialysis (CVVHD) on 28-day and 90-day survival and an array of clinical and laboratory parameters in patients with severe ACLF and renal insufficiency. Sixteen patients were studied. The diagnosis of ACLF and AKI was made in accordance with current EASL Clinical Practice Guidelines, including the recommendations of the International Club of Ascites. All patients received SPAD/CVVHD treatments as the blood purification therapy to support liver, kidneys, and other organs. Five patients were transplanted and 11 were not listed for transplantation because of active alcoholism. Data at the initiation of SPAD/CVVHD were compared with early morning data after the termination of the extracorporeal treatment phase. All patients had ACLF and renal insufficiency with 13/16 additionally fulfilling the AKI criteria. A total of 37 SPAD/CVVHD treatments were performed [2.3 ± 1.4]. The baseline MELD-Na score was 37.6 ± 6.6 and decreased to 33.4 ± 8.7 after SPAD/CVVHD (P < 0.001). In parallel, the CLIF-C ACLF grade and OF score, estimated at 28- and 90-day mortality, AKI stage, hepatic encephalopathy grade, and liver function tests were lowered (P = 0.001-0.032). The 28- and 90-day survivals were 56.2% overall and 53.8% in AKI. Survival in patients not transplanted (n = 11) was 45.4%. In patients with severe ACLF and AKI, the renal replacement therapy coupled with high-performance albumin dialysis improved estimated 28- and 90-day survival and several key clinical and laboratory parameters. It is postulated that these results may be further improved with earlier intervention and more SPAD treatments per patient. High-performance albumin dialysis improves survival and key clinical and laboratory parameters in severe ACLF and AKI.

Albumin Apheresis for Artificial Liver Support: In Vitro Testing of a Novel Filter.

Currently there is no direct therapy for liver failure. We have previously described selective plasma exchange therapy using a hemofilter permeable to substances that have a molecular mass of up to 100 kDa. The proof-of-concept studies and a Phase I study in patients with decompensated cirrhosis demonstrated that hemofiltration using an albumin-leaking membrane is safe and effective in removing target molecules, alleviating severe encephalopathy and improving blood chemistry. In this study a novel large-pore filter for similar clinical application is described. The performance of the filter was studied in vitro; it was found to effectively remove a wide spectrum of pathogenic factors implicated in the pathophysiology of hepatic failure, including protein bound toxins and defective forms of circulating albumin. Data on mass transport characteristics and functionality using various modes of filtration and dialysis provide rationale for clinical evaluation of the filter for artificial liver support using albumin apheresis.

Human albumin: old, new, and emerging applications.

Human serum albumin has been widely used in an array of clinical settings for nearly 7 decades. Although there is no evidence to support the use of albumin rather than crystalloid in acute volume resuscitation, many clinicians continue to use albumin because it has other important physiologic effects besides the oncotic function. In keeping with the improved understanding of albumin physiology and pathophysiology of many acute and chronic diseases, use of albumin for medical applications has increased in recent years. This, along with increased costs of manufacturing and lower production volume of medical-grade albumin, has lead to an ongoing shortage and rapid increase in albumin prices. This review is based on the analysis of major publications, related to albumin chemistry, physiology, and medical uses including guidelines developed by professional and governmental organizations. Results reflect current knowledge about the role of albumin in health and disease and relevance of albumin therapy in specific clinical settings. Albumin therapy is currently recommended in spontaneous bacterial peritonitis with ascites, refractory ascites not responsive to diuretics, large-volume paracentesis, post-paracentesis syndrome, and the treatment of hepatorenal syndrome as an adjunct to vasoconstrictors. New indications for albumin therapy are linked to the antioxidant activity of albumin and its effects on capillary integrity. In recent years, large-pore hemofiltration and albumin exchange have emerged as promising liver support therapies for liver failure and other toxic syndromes. They are designed to remove a broad range of blood-borne toxins and to restore normal functions of the circulating albumin by replacing defective forms of albumin and albumin molecules saturated with toxins with normal albumin. In view of the ongoing worldwide shortage and high cost of human albumin (native and recombinant), new usage criteria, protocols, and guidelines for appropriate utilization of albumin are needed.

Artificial liver support: quo vadis?

BACKGROUND: Approximately 2 million persons worldwide die each year from hepatic failure. Because of the scarcity of donor organs, artificial liver support systems are being developed with the aim of either supporting patients with borderline functional liver cell mass until an appropriate organ becomes available for transplantation or until their livers recover from injury. MATERIAL/METHODS: A literature review was performed using MEDLINE, PubMed, EMBASE, and library searches. Only major liver support techniques are included in this review. RESULTS: A number of extracorporeal liver assist systems are in various stages of clinical development. Published data indicate that patients with acute and acute-on-chronic liver failure may benefit from treatment with some of these therapeutic measures. Results from large prospective randomized trials have shown that treatment with MARS® and PROMETHEUS® may not confer a survival advantage, despite positive effects on blood toxemia and improvement in hepatic encephalopathy. Currently, hemofiltration using albumin-leaking membranes is being explored as a novel promising approach to blood purification in liver failure. CONCLUSIONS: Developing an effective liver assist technology has proven difficult, because of the complexity of liver functions that must be replaced, as well as heterogeneity of the patient population. Non-biological systems may have a role in the treatment of specific forms of liver failure where the primary goal is to provide blood detoxification/purification. Biological systems appear to hold promise for treating liver failure where the primary objective is to provide whole liver functions which are impaired or lost.

Liver support technology--an update.

BACKGROUND: Currently, there is no direct treatment for hepatic failure, and patients must receive a transplant or endure prolonged hospitalization, with significant morbidity and mortality. Because of the scarcity of donor organs, liver support strategies are being developed with the aim of either supporting patients with borderline functional liver cell mass until an appropriate organ becomes available for transplantation or until their livers recover from injury. METHODS: A literature review was performed using MEDLINE and library searches. Only major blood detoxification/purification devices and cell-based techniques are included in this review. RESULTS: Currently, a number of blood purification systems and devices utilizing viable liver cells are in various stages of clinical development. Non-biological systems include plasma exchange, albumin dialysis, hemo(dia)filtration, and sorbent-based devices (charcoal, resin). These systems are able to remove toxins of hepatic failure, and their utility is limited by their inability to provide missing liver-specific functions. In contrast, hepatocyte-based devices are able to provide whole liver functions, including detoxification, biosynthesis, and biotransformation. Molecular adsorbent recycling system (MARS) blood detoxification system has been tested in thousands of patients, but additional well-conducted controlled studies are warranted to better define the role of MARS in the treatment of patients with acute hepatic failure and acute exacerbation of chronic liver disease. HepatAssist was tested in a phase II/III controlled clinical trial that demonstrated safety and proof of concept for use of biological liver support systems to improve patient survival in acute hepatic failure. CONCLUSIONS: Developing an effective liver assist technology has proven difficult, because of the complexity of liver functions that must be replaced, as well as heterogeneity of the patient population. Non-biological systems may have a role in the treatment of specific forms of liver failure where the primary goal is to provide blood detoxification/purification. Biological systems appear to be useful in treating liver failure where the primary objective is to provide whole liver functions which are impaired or lost. It is suggested that there will be a role for hybrid liver support systems that offer liver cell therapy and various forms of blood purification (sorption, hemofiltration and diafiltration) to treat patients with specific forms of liver failure at various stages of their illness.

A novel plasma filtration therapy for hepatic failure: preclinical studies.

There is a need to develop artificial means of liver replacement and/or assistance with the aim of either supporting patients with borderline functional liver cell mass until their liver regenerates, or until a donor liver becomes available for transplantation. Selective plasma filtration is a novel approach to blood purification therapy designed to reduce the level of circulating toxins of hepatic and renal failure, mediators of inflammation and inhibitors of hepatic regeneration. The results of preclinical studies indicate that treatment of pigs with experimentally-induced fulminant hepatic failure is safe and effective in extending survival time and arresting brain swelling. In addition, the amount of ammonia, aromatic amino acids, IL6, TNFalpha and C3a removed during the 6-h treatment in the present study was higher by 34% to 175% than the total plasma content of those substances at the start of therapy.

Intrasplenic transplantation of encapsulated genetically engineered mouse insulinoma cells reverses streptozotocin-induced diabetes in rats.

Pancreatic islet transplantation is limited by shortage of donor organs. Although beta-cell lines could be used, their secretion of insulin is characteristically glucose independent and immunoisolation is required. Here we show that intrasplenic transplantation of encapsulated glucose-responsive mouse insulinoma cells reversed streptozotocin (STZ)-induced diabetes in rats. MIN-6 cells derived from a transgenic mouse expressing SV 40 large T antigen in pancreatic beta-cells were transfected with minigene encoding for human glucagon-like-peptide-1 under the control of rat insulin promoter. The cells were encapsulated in alginate/poly-L-lysine and used for cell transplantation in STZ-diabetic rats. Rats with nonfasting blood glucose (n-FBG) greater than 350 mg/dl were used. In group I rats (n=6) 20 million encapsulated cells were injected into the spleen. Group II rats (n=6) received empty capsules. n-FBG was measured biweekly. After 4 and 8 weeks, an intraperitoneal glucose tolerance test (IPGTT) was performed in group I; normal rats served as controls. Plasma insulin level was measured every other week (RIA). After 8 weeks, spleens were removed 1 day before sacrifice. In rats transplanted with cells the n-FBG was 100-150 mg/dl until the end of the study. After splenectomy, all cell recipients became diabetic (glucose 400 +/- 20 mg/dl). Transplanted rats showed increase in body weight and insulin production (3.3 +/- 1.0 ng/ml versus 0.92 +/- 0.3 ng/ml; p < 0.01) and had normal IPGTT. Spleens contained capsules with insulin-positive cells. Overall, data from this work indicate that intrasplenic transplantation of xenogeneic encapsulated insulin-producing cells without immunosuppression reversed diabetes in rats. Excellent survival and function of the transplanted cells was due to the fact that the cells were separated from the bloodstream by the immunoisolatory membrane only and insulin was delivered directly to the liver (i.e., in a physiological manner).

A novel molecular marker of pituitary tumor transforming gene involves in a rat liver regeneration.

BACKGROUND: Pituitary tumor transforming gene (PTTG), homologous to a mammalian securin, plays a pivotal role in cell transformation, however, its biological function(s) in normal tissues is not fully understood. Because the liver is a regenerative organ, the relevant biological function of PTTG in the liver would be more feasible to understand PTTG. Also, PTTG may be involved in the liver regeneration. MATERIALS AND METHODS: Expressions of rat hepatic PTTG messengerRNA (mRNA) and cellular immunoreactivities during the cell proliferative period of the liver regeneration both in vitro and in vivo were tested. RESULTS: PTTG expression of the rat primary hepatocyte was stimulated by HGF in a dose dependent manner, and was suppressed when hepatocyte proliferation was inhibited by transforming growth factor-beta1. A positive PTTG immunoreactive co-localizing with 5-bromo-2'-deoxyuridine (BrdU) in the hepatocyte nucleus was found and there was a concurrent sister chromatin itself by the immunofluorescent labeling of PTTG with cytokeratin 18 (CK18). DISCUSSION: Since the correlation of PTTG mRNA expression, cell proliferation and immunoreactivity were observed in primary rat cultured hepatocytes, PTTG may be a novel marker of cell proliferation both in vitro and in vivo liver regeneration.

Intrasplenic transplantation of encapsulated hepatocytes decreases mortality and improves liver functions in fulminant hepatic failure from 90% partial hepatectomy in rats.

BACKGROUND: Encapsulated cell therapy might be a promising approach to enable cell transplantation without immunosuppression. This study investigates the viability and hepatic function of hepatocytes encapsulated with alginate/poly-L-lysine in vitro and the effect of the intrasplenic transplantation of cultured encapsulated hepatocytes on survival in 90% hepatectomized rats as a preliminary step toward allogeneic hepatocyte transplantation without immunosuppression. MATERIALS AND METHODS: Rat hepatocytes were isolated and encapsulated using alginate/poly-L-lysine. Encapsulated hepatocytes were cultured for 28 days to measure cell viability, liver function, and morphology. Rats were treated with a 90% partial hepatectomy and then immediately underwent the intrasplenic transplantation of the cultured encapsulated hepatocytes, the capsule alone, or the allogeneic hepatocytes without the capsule. The survival rate, liver function, and cell morphology were assessed after transplantation. RESULTS: The cultured encapsulated hepatocytes maintained their viability and showed better metabolic activity than day 0 cultured encapsulated hepatocytes. The encapsulated cells strongly expressed albumin and were positive for periodic acid-Schiff staining. Electron microscopy demonstrated that the microencapsulated hepatocytes retained the structural elements of hepatic cytoplasm and nuclei. Intrasplenic transplantation of the encapsulated hepatocytes increased the survival rate and improved the hepatic function. Encapsulated hepatocytes transplanted into rat spleen survived well and retained their hepatic function. Moreover, dramatic liver regeneration was observed 48 hr after transplantation in the group that received intrasplenic transplantations of encapsulated hepatocytes. CONCLUSIONS: The intrasplenic transplantation of cultured encapsulated hepatocytes improved the survival rate of an acute liver failure rat model induced by a 90% partial hepatectomy.

Intrasplenic transplantation of encapsulated cells: a novel approach to cell therapy.

Cell therapy is likely to succeed clinically if cells survive at the transplantation site and are protected against immune rejection. We hypothesized that this could be achieved with intrasplenic transplantation of encapsulated cells because the cells would have instant access to oxygen and nutrients while being separated from the host immune system. In order to provide proof of the concept, primary rat hepatocytes and human hepatoblastoma-derived HepG2 cells were used as model cells. Rat hepatocytes were encapsulated in 100-kDa hollow fibers and cultured for up to 28 days. Rat spleens were implanted with hollow fibers that were either empty or contained I x 10(7) rat hepatocytes. Human HepG2 cells were encapsulated using alginate/ poly-L-lysine (ALP) and also transplanted into the spleen; control rats were transplanted with free HepG2 cells. Blood human albumin levels were measured using Western blotting and spleen sections were immunostained for albumin. Hepatocytes in monolayer cultures remained viable for only 6-10 days, whereas the cells cultured in hollow fibers remained viable and produced albumin throughout the study period. Allogeneic hepatocytes transplanted in hollow fibers remained viable for 4 weeks (end of study). Free HepG2 transplants lost viability and function after 7 days, whereas encapsulated HepG2 cells remained viable and secreted human albumin at all time points studied. ALP capsules, with or without xenogeneic HepG2 cells, produced no local fibrotic response. These data indicate that intrasplenic transplantation of encapsulated cells results in excellent survival and function of the transplanted cells and that the proposed technique has the potential to allow transplantation of allo- and xenogeneic cells (e.g., pancreatic islets) without immunosuppression.

Bone marrow-derived liver stem cell and mature hepatocyte engraftment in livers undergoing rejection.

BACKGROUND: The definitive therapy for end-stage liver disease is orthotopic liver transplantation (OLT). However, rejection is still a major cause of mortality and morbidity following OLT. Hepatocyte transplantation has been used experimentally to treat liver diseases. The aim of this study was to investigate whether bone marrow-derived liver stem cells (BDLSC) and mature hepatocytes could repopulate transplanted livers undergoing rejection. METHODS: OLT was carried out from D'Agouti (C3-positive female) into Lewis (C3-negative female) rats. BDLSC were transplanted from Lewis (male) into livers of D'Agouti (female) rats. Group A (n = 9) received intraportal normal saline. Groups B (n = 9) and C (n = 9) underwent intraportal transplantation of mature hepatocytes (Lewis female, 0.75 x 10(7)) and DBLSC (Lewis male, 5 x 10(4)) respectively. All groups received subtherapeutic immunosuppression (Cyclosporin 0.25 mg/kg/d) for 13 days. Liver repopulation was assessed using immunohistochemistry (C3 antigen-negative cells), in-situ hybridization, (Y-chromosome-positive BDLSC) and histologic assessment (hematoxylin and eosin) for rejection. RESULTS: BDLSC and mature hepatocytes repopulated 62 +/- 12.3% and 2.5 +/- 1.7% of rejecting livers, respectively. BDLSC demonstrated formation of hepatic lobules and portal triads with little evidence of rejection 36 days after discontinuation of immunosuppression. CONCLUSIONS: BDLSC can repopulate livers undergoing severe rejection. Moreover, BDLSC can differentiate into hepatocytes and cholangiocytes. This finding may have important clinical implications.

Long-term insulin independence following repeated islet transplantation in totally pancreatectomized diabetic pigs.

Clinical islet transplantation (Tx) in type I diabetic patients has been successful so far only in a minority of cases, probably because of multiple factors, partly immunologic and partly nonimmunologic in nature. Preclinical studies of islet Tx in large animals are still needed to clarify the reasons and find possible solutions. In this study, we tested the feasibility of noninvasive, repeated intrahepatic allo-Tx of porcine pancreatic islets obtained from multiple donors, in pigs rendered diabetic by total pancreatectomy (Pct). In group I Yucatan miniature swine (n = 6), after induction of diabetes by Pct, repeated islet allo-Tx of > or = 80% pure islets was performed. Islets obtained from two pigs of the Hanford breed were injected twice a week, half freshly isolated and half 48-h cultured, over a period of 11 days, for a total of 23,647 +/- 1617 islet equivalents (IE)/kg recipient body weight (BW). In group II Yucatan miniature swine (n = 3), after Pct, a single allo-Tx of > or = 80% pure islets, previously obtained from two donors of the Hanford breed, was performed, using a total of 22,416 +/- 1124 IE/kg BW. In group III Yucatan miniature swine (n = 3), auto-Tx of 60-75% pure islets, averaging 2980 +/- 424 IE/kg BW, was performed a few hours after Pct. Group IV Yucatan mini pigs (n = 3) underwent Pct and were used as diabetic controls. Group V animals (n = 3) were normal control Yucatan mini pigs. Porcine islets were isolated by a modification of the standard collagenase digestion and Ficoll gradient purification method. Donors and recipients were chosen on the basis of moderate to high mutual alloreactivity in mixed lymphocyte culture (MLC). In groups I and II, cyclosporine A (CsA) was started 4 days before allo-Tx, at the dose of 15 mg/kg IM, and then gradually reduced to 4 mg/kg IM. In all group I animals, normal fasting blood glucose (FBG) was restored within 2-3 weeks. Two normoglycemic pigs died of acute pneumonia at 33 and 112 days, respectively, and one animal became progressively hyperglycemic at 100 days. After 3 months, discontinuation of CsA treatment resulted in FBG increase in two group I animals. In one pig, CsA was stopped after 151 days, and normoglycemia persisted until euthanasia, after 8 months. In group II pigs, normoglycemia lasted 4-20 days, with a progressive increase of insulin requirement thereafter. In group III animals, after islet auto-Tx, normoglycemia lasted 7-10 days, while insulin daily requirement progressively increased thereafter, stabilizing at 0.4 IU/kg/day, corresponding to about one third of the amount required in diabetic controls. The single most important result in this series of experiments is that intraportal allo-Tx of a sufficient islet mass, divided in multiple subtherapeutic doses, produced a better metabolic long-term control in comparison to a single injection of the same amount of islets. The technique of multiple-donor repeated islet Tx may prove useful to overcome the problem of primary nonfunction or early graft failure, currently limiting the success of clinical islet Tx in most cases.

Immediate early genes and p21 regulation in liver of rats with acute hepatic failure.

It has been observed that liver regeneration in acute hepatic failure (AHF) is suppressed [Eguchi et al. Hepatology 1996;24(6):1452-9]. The molecular mechanism regulating this inhibition is not known. We previously reported that in AHF rats, hepatocyte proliferation was significantly impaired with elevation in serum IL-6, TGF-beta1, and HGF [Kamohara et al. Biochem Biophys Res Commun 2000;273(1):129-35]. Following either 70% partial hepatectomy (PH) or liver injury, quiescent mature hepatocytes are "primed" to re-enter the cell cycle. The process of "priming" appears to be triggered by extracellular cytokines (IL-6 and TNF-alpha) and is characterized by expression of immediate early genes. Under the stimulation of growth factors such as HGF, "primed" hepatocytes exit the G1 phase of the cell cycle. G1-associated cyclins and their inhibitors play a pivotal role in G1/S cell cycle transition. Here, we demonstrate that immediate early gene (i.e. c-myc, c-fos) expression and AP-1 activity are preserved in AHF rat livers despite absence of hepatocyte proliferation. In contrast, p21 mRNA and protein are both over-expressed in AHF livers compared to livers from rats undergoing PH; this elevation leads to inhibition in Cdk2 activity, resulting in G1 cell cycle arrest and inhibition of regeneration.

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.

Glycerol suppresses proliferation of rat hepatocytes and human HepG2 cells.

BACKGROUND: In fulminant hepatic failure (FHF), the ability of surviving hepatocytes to proliferate is diminished. Therefore, it is important that medical therapy cause no further impairment of liver regeneration. In FHF, intracranial hypertension secondary to brain edema is the most common cause of brain injury and death and glycerol is used in some countries to treat this complication. Glycerol has been long known to suppress the growth of various cell types. We therefore decided to examine the effect of glycerol on hepatocyte proliferation in vitro and in vivo in rats subjected to partial (2/3) hepatectomy. Additionally, we investigated the effect of glycerol on the proliferation of HepG2 cells. MATERIALS AND METHODS: Mitogen-induced primary rat hepatocytes were cultured in a hormonally defined Dulbecco's modified Eagle's medium containing increasing amounts of glycerol (0.5, 1.0, 2.0, 4.0%). HepG2 cells were cultured in minimal essential medium/10% FBS. After 2 days, HepG2 cells were exposed to glycerol (1.0-2.0-4.0%) and harvested after 48 h. Control dishes contained no glycerol. Cell proliferation was measured by the incorporation of [(3)H]thymidine and/or bromodeoxyuridine (BrdU). In vivo, Sprague-Dawley rats were subjected to standard partial 2/3 hepatectomy and assigned to intraportal administration of either 400 microl of glycerol or saline. Rats were killed after 1, 2, 3, 5, and 7 days. Liver weight/body weight ratio and BrdU uptake were measured. RESULTS: In all cultures tested, glycerol suppressed the growth of cells in a dose-dependent manner. In vivo, a single intraportal dose of glycerol slowed the liver regenerative response. CONCLUSIONS: This study demonstrated that glycerol has a potent growth-inhibitory effect on hepatocyte proliferation in vivo and in vitro. Remarkably, glycerol inhibited the proliferation of liver cancer cells as well. The results of this study have important clinical implications.

Hepatocyte proliferation in health and in liver failure.

Mammalian liver possesses an extraordinary capacity for compensatory growth in response to conditions that induce cell loss by physical, infectious, or toxic injury. In normal animals and humans, it is a tightly regulated process of both hypertrophy and hyperplasia involving different liver cell populations and a finely tuned interplay between growth factors, cytokines, extracellular matrix components and other regulators. The regeneration response is maximal when two-thirds of the liver is resected. When a lesser amount of parenchyma is removed, residual liver grows more slowly. Resections exceeding two-thirds of the liver mass also retard and diminish both DNA synthesis and mitotic activity and subtotal (90%) hepatectomy invariably results in the death of rats without regeneration. The underlying mechanisms of liver growth inhibition are poorly understood. In particular, only a few studies exist that provide insight into the mechanisms that control regeneration after extensive hepatocyte loss. In this regard, the role of growth-regulatory factors and other compounds that accumulate in the blood circulation as a result of hepatic insufficiency and liver cell death remains unclear. We have initiated studies of these mechanisms and demonstrated that in rats with low (10%) hepatocyte mass, a marked and sustained elevation of blood IL-6, HGF and TGF-b1 levels was associated with lack of hepatocyte proliferation and suppression of Stat3 DNA binding. While searching for the possible cause of inhibited IL-6/Stat3 signaling, we found that IL-6 receptor (IL-6R & gp130) was preserved, that nuclear Stat3 protein content was lowered, and that IL-6/Stat3 pathway inhibitors (SOCS-1, PIAS3) were induced during the pre-replicative Go-G1 period.