Vaccinia virus complement control protein (VCP) improves kidney structure and function following ischemia/reperfusion injury in rats.

Renal transplantation is often confronted with ischemia reperfusion (I/R) injury that accounts for a delayed recovery of the graft. This surgically and biologically induced injury often results in activation of the complement system. The vaccinia virus complement control protein (VCP) down-regulates both the classical and alternative complement pathways by preventing the formation of C3b, a component where both pathways converge. The aim of the study was to investigate the effect of VCP on renal I/R injury. Long Evans rats were subjected to laparotomy, mobilization of the right kidney in unilateral ischemia, and both kidneys in bilateral ischemia. The renal arteries were clamped for 60 min followed by 24 h reperfusion time. The animals were randomly allocated to receive recombinant VCP (rVCP), natural VCP, and humanized recombinant VCP (hrVCP) combination, vehicle (PBS), or sham group. Blood samples were collected for biochemical studies, and the kidneys were removed for histopathologic and immunohistochemical studies. The biochemical studies in the bilateral ischemia showed that the PBS group displayed 1.5-fold and 5-fold increases in the urea and creatinine concentrations, respectively, compared with the VCP/hrVCP groups. In both models, the histopathologic study revealed focal necrosis of the tubular epithelial cells in the rVCP or VCP/hrVCP treated animals compared with the diffuse and markedly elevated field scores in the PBS controls. The immunohistochemical study showed significant C3 deposition in the renal tubules of the PBS controls compared with the rVCP or VCP/hrVCP groups, suggesting that rVCP, VCP/hrVCP reduced I/R injury by inhibiting the biosynthesis of C3.

Non-toxicity of IV injected perfluorocarbon oxygen carrier in an animal model of liver regeneration following surgical injury.

Lethal dose experiments in animals have demonstrated that second-generation perfluorocarbon oxygen carriers are remarkably non-toxic. However, this non-toxicity has not previously been demonstrated in a liver failure scenario. A surgical liver damage and regeneration model in rats was selected using a well-controlled cross tabulated study design. A large number of physiological, biochemical, and hematological parameters were measured. No indications were found that intravenously injected perfluorooctyl bromide emulsion was toxic at the concentrations employed, in either healthy or severe liver injury scenarios. Neither was there any significant impact on the rate of liver regeneration following the injuries. Bearing in mind prior human clinical studies, it is therefore safe to assume that perfluorocarbon emulsions are also non-toxic in bioartificial liver treatments.

Effect of rapamycin on hepatic osteodystrophy in rats with portasystemic shunting.

AIM: To study if T-cell activation related to portasystemic shunting causes osteoclast-mediated bone loss through RANKL-dependent pathways. We also investigated if T-cell inhibition using rapamycin would protect against bone loss in rats. METHODS: Portasystemic shunting was performed in male Sprague-Dawley rats and rapamycin 0.1 mg/kg was administered for 15 wk by gavage. Rats received powderized chow and supplemental feeds to prevent the effects of malnutrition on bone composition. Weight gain and growth was restored after surgery in shunted animals. At termination, biochemical parameters of bone turnover and quantitative bone histology were assessed. Markers of T-cell activation, inflammatory cytokine production, and RANKL-dependent pathways were measured. In addition, the roles of IGF-1 and hypogonadism were investigated. RESULTS: Portasystemic shunting caused low turnover osteoporosis that was RANKL independent. Bone resorbing cytokine levels, including IL-1, IL-6 and TNFalpha, were not increased in serum and TNFalpha and RANKL expression were not upregulated in PBMC. Portasystemic shunting increased the circulating CD8+ T-cell population. Rapamycin decreased the circulating CD8+ T-cell population, increased CD8+ CD25+ T-regulatory cell population and improved all parameters of bone turnover. CONCLUSION: Osteoporosis caused by portasystemic shunting may be partially ameliorated by rapamycin in the rat model of hepatic osteodystrophy.