Primary graft nonfunction and Kupffer cell activation after liver transplantation from non-heart-beating donors in pigs.

More extensive use of non-heart-beating donors (NHBD) could reduce mortality on liver transplantation waiting lists, but this is associated with more primary nonfunction (PNF). We assessed which parameters are involved in the development of PNF in livers from NHBD in a previously validated pig liver transplantation model, in which livers were transplanted after exposure to incremental periods of warm ischemia. The risk of PNF was unacceptably high (>50%) when livers were exposed to >30 minutes' warm ischemia before a short cold ischemic period. This study examined how PNF is affected by Kupffer cell activation (beta-galactosidase), the generation of cytokines tumor necrosis factor alpha and interleukin 6, antioxidant mechanisms (ascorbic acid, alpha-tocopherol, reduced glutathione), circulating redox-active iron, and sinusoidal endothelial cell function (hyaluronic acid clearance). Kupffer cells were more activated in PNF recipients, as suggested by higher beta-galactosidase levels (15 minutes after reperfusion), and secondarily, by higher production of tumor necrosis factor alpha and interleukin 6 (180 minutes after reperfusion). In addition, alpha-tocopherol and reduced glutathione were lower, and ascorbic acid and redox-active iron higher in PNF recipients. Finally, PNF grafts displayed progressively decreasing hyaluronic acid clearance (suggesting sinusoidal endothelial cell dysfunction) and parenchymal edema. Consequently, a reduced-flow phenomenon was documented. In grafts from NHBD that are destined to fail, beta-galactosidase activity (a surrogate of Kupffer cell activation) is higher, proinflammatory cytokines are overproduced, some antioxidant mechanisms fail, and circulating redox-active iron is more rapidly released. A no-flow phenomenon is eventually observed in these failing grafts.

Livers from non-heart-beating donors tolerate short periods of warm ischemia.

BACKGROUND: In contrast with kidneys, transplantation of livers originating from non-heart-beating donors remains rare, mainly because warm ischemia causes a higher rate of potentially lethal primary graft nonfunction. Little is known on the tolerance of liver grafts to warm ischemia. No techniques are available to assess the viability of ischemic livers before implantation. Therefore, experimental models are needed to address these questions before non-heart-beating liver transplantation can be more widely applied. This study aims to develop a reproducible large animal model of liver transplantation using non-heart-beating donors and, in this model, to define the tolerance of the liver to warm ischemia. METHODS: Pigs weighing 25to 30 kg are used. In donors, cardiac arrest is caused by ventricular fibrillation. After increasing lengths of warm ischemia (0, 15, 30, 45, and 60 min), the liver is flushed in situ with 4 degrees C histidine tryptophan ketoglutarate preservation solution and procured. The liver is transplanted after a 4-hour cold storage period. RESULTS: Control livers (no warm ischemia) and livers exposed to 15 minutes of warm ischemia function normally after transplantation, whereas all livers submitted to 60 minutes of warm ischemia display primary nonfunction and cause recipient death. Graft function and survival are occasionally observed after 30 and 45 minutes of warm ischemia. CONCLUSIONS: A reproducible model of non-heart-beating liver transplantation is described. We found that the liver tolerates 15 minutes of warm ischemia. This preclinical model is a valid tool to develop techniques to predict the quality of ischemic livers before implantation and to design interventional strategies to improve the tolerance of the liver to warm ischemia.

Expression of hepatitis C virus core protein impairs DNA repair in human hepatoma cells.

Several studies have documented the important association between hepatitis C virus (HCV) infection and hepatocellular carcinoma. The mechanisms involved are still unknown and could involve viral proteins. We investigated the effect of HCV-core protein on DNA repair after UV-induced DNA damage. Therefore, we developed and characterized stably transfected HepG2 cell lines that express HCV-core protein as demonstrated by immunohistochemistry. These cells were significantly less capable to repair the DNA damage than control cells. This suppression of DNA repair by HCV-core protein renders the cells more sensitive to acquire mutations that in combination with enhanced in vivo cell turnover in the infected liver might increase the likelihood of malignant transformation of HCV-infected cells by other viral factors or upon exposure to environmental factors (food, drugs, smoking, alcohol, etc.). Interestingly, expression of the full-length HCV core did increase the cell doubling time in one of the cell lines we had developed that could not be attributed to an increase in apoptosis or change in telomerase activity in these cells.

Primary human hepatocytes are protected against prolonged and repeated exposure to ethanol by silibinin-dihemisuccinate.

AIMS AND METHODS: We investigated the effect of silibinin-C-2',3'-dihydrogensuccinate (SDH) on primary human hepatocytes when exposed to ethanol for 14 days. At regular intervals, the medium was refreshed and liver enzymes and secreted protein in the medium were determined. RESULTS: The ethanol-induced release of lactate dehydrogenase (at 34 mM ethanol) was completely blocked by 20 microM SDH. SDH itself stimulated fibrinogen release and had no toxic effect. CONCLUSIONS: We can conclude that SDH has a beneficial effect on human hepatocytes when exposed to ethanol in vitro.