An improved model of acute liver failure based on transient ischemia of the liver

HYPOTHESIS: A reproducible and potentially reversible model of acute liver failure in the pig is feasible based on transient ischemia of the liver. DESIGN: To determine the shortest period of liver ischemia sufficient to cause 100% mortality, ischemia of the liver was induced for different lengths of time, starting with 6 hours. If the pig survived, ischemia time was prolonged for 2 hours in the next animal. In the first group, the common bile duct was not tightened. In the second group, the common bile duct was tightened. SETTING: The Laboratory for Hepatopathophysiology, Catholic University, Leuven, Belgium. PARTICIPANTS: Female stress-negative Belgian Landrace pigs weighing 18 to 22 kg. INTERVENTIONS: During preparatory surgery, all ligaments around the liver and connective tissue around the liver hilum were transected and an end-to-side portacaval shunt was made. Vessel loops were placed around the branches of the hepatic artery and bile duct. Three days later, in fully awake pigs, the loops were tightened. MAIN OUTCOME MEASURES: Mortality. Development of acute liver failure was determined based on neurologic, biochemical, and pathological variables. RESULTS: When occluded for 10 hours, all pigs in group 2 (n = 5) [corrected] died between 12 and 17 hours after the induction of ischemia. All pigs developed typical acute liver failure. Tissue specimens showed 90% necrosis of the liver parenchyma. CONCLUSION: A highly reproducible and potentially reversible model of acute liver failure in the large animal has been established.status: publishe

Demonstration of the efficiency of a bioartificial liver in a reversible large animal model of acute liver failure

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Aplastic anemia after transplantation for non-A, non-B, non-C fulminant hepatic failure: case report and review of the literature

Aplastic anemia is a rare complication of liver transplantation (<1%). However, an increasing number of cases of aplastic anemia have been recently reported when liver transplantation is performed for non-A, non-B, non-C fulminant hepatic failure. The aim of this study is to reevaluate the importance and the incidence of aplastic anemia after liver transplantation for non-A, non-B, non-C fulminant hepatic failure, and to propose preventive measures, diagnostic and management guidelines to try to reduce the incidence, morbidity and mortality associated with this complication. In this report a case of aplastic anemia after liver transplantation for non-A, non-B, non-C fulminant hepatic failure is described. In addition, the pertinent literature on aplastic anemia after liver transplantation, since the first description of that complication in 1987, is reviewed. A 20-year-old woman developed aplastic anemia 14 weeks after liver transplantation for fulminant non-A, non-B, non-C hepatitis. After failure of G-CSF treatment, she was treated with intensive immunosuppression (FK 506, ATG, high-dose steroids). She is well 1 year post-transplantation, with normal liver tests and with bone marrow recovery. Through a Medline literature search (1988-1999), we identified 30 additional cases of aplastic anemia following liver transplantation for non-A, non-B, non-C fulminant hepatic failure. Of all liver transplantations performed for that indication at five participating centers, the mean incidence of aplastic anemia was 23.2%. Mean age was 10 years (1.2-29) and the male/female ratio was 4.6. For treating aplastic anemia, different modalities were used: ATG ( n=12), ALG ( n=1), OKT 3 ( n=1), G-CSF ( n=6), a 6-HLA-compatible bone marrow transplantation ( n=3), and none ( n=12). The mortality rate remains high (39%), with infections and bleeding as the two most frequent causes of death. Based on this literature review, we conclude that aplastic anemia is a relatively common complication of liver transplantation for non-A, non-B, non-C fulminant hepatic failure in children and young adults. An unknown viral agent operating through immune-mediated mechanisms is probably responsible. The myelotoxic environment inherent to transplantation (e.g. azathioprine, trimethoprim) probably has a cumulative effect. Preventive measures (e.g. not using myelotoxic drugs) should be adopted in high-risk children and young adults transplanted for non-A, non-B, non-C fulminant hepatic failure. Early detection of bone marrow depression, a low threshold for performing a bone marrow biopsy, and prompt treatment are pivotal. Intensive standard supportive care with broad-spectrum antibiotics and anti-fungal agents is essential during phases of pancytopenia. Although spontaneous recovery has been described under maintenance immunosuppression, increased immunosuppression, in particular with ATG, may reverse the aplastic anemia and promote bone marrow recovery. In unresponsive patients, six-HLA-identical bone marrow transplantation has been successful.status: publishe