Uta Dahmen

Synergistic effects of a novel nanoporous stent coating and tacrolimus on intima proliferation in rabbits

To overcome the problem of in‐stent restenosis, the concept of local delivery of antiproliferative or immunosuppressive drugs has been introduced into interventional cardiology. Local drug delivery can be achieved by drug‐eluting stents coated with polymer surfaces used for controlled drug release. However, several polymer coatings have shown an induction of inflammatory response and increased neointima formation. In the present study, the effect of a new inorganic ceramic nanoporous aluminum oxide (Al2O3) coating on neointima proliferation and its suitability as a carrier for the immunosuppressive drug tacrolimus have been investigated. 316 L stainless steel coronary stents were coated with a 500 nm thin nanoporous aluminum oxide layer. This ceramic nanolayer was used as a carrier for tacrolimus. Bare stents (n = 6), ceramic coated stents (n = 6), and ceramic coated stents loaded with 60 (n = 7) and 120 μg (n = 6) tacrolimus were implanted in the common carotid artery of New Zealand rabbits. The ceramic coating caused no significant reduction of neointimal thickness after 28 days. Loading the ceramic stents with tacrolimus led to a significant reduction of neointima thickness by 52% for 60 μg (P = 0.047) and 56% for 120 μg (P = 0.036) as compared to the bare stents. The ceramic coating alone as well as in combination with tacrolimus led to a reduced infiltration of lymphocytes and macrophages in the intima in response to stent implantation. Ceramic coating of coronary stents with a nanoporous layer of aluminum oxide in combination with tacrolimus resulted in a significant reduction in neointima formation and inflammatory response. The synergistic effects of the ceramic coating and tacrolimus suggest that this new approach may have a high potential to translate into clinical benefit. Catheter Cardiovasc Interv 2003;60:399–407.

Marginal Hepatectomy in the Rat: From Anatomy to Surgery

Objective:Based on the 3-dimensional visualization of vascular supply and drainage, a vessel-oriented resection technique was optimized. The new surgical technique was used to determine the maximal reduction in liver mass enabling a 50% 1-week survival rate. Background Data:Determination of the minimal liver mass is necessary in clinical as well as in experimental liver surgery. In rats, survival seems to depend on the surgical technique applied. Extended hepatectomy with removal of 90% of the liver mass was long regarded as a lethal model. Introduction of a vessel-oriented approach enabled long-term survival in this model. Methods:The lobar and vascular anatomy of rat livers was visualized by plastination of the whole organ, respectively, by corrosion casts of the portal vein, hepatic artery and liver veins. The three-dimensional models were used to extract the underlying anatomic structure. In 90% partial hepatectomy, the liver parenchyma was clamped close to the base of the respective liver lobes (left lateral, median and right, liver lobe). Piercing sutures were placed through the liver parenchyma, so that the stem of portal vein and the accompanying hepatic artery but also the hepatic vein were included. Results:A 1-week survival rate of 100% was achieved after 90% hepatectomy. Extending the procedure to 95% resection by additional removal of the upper caudate lobe led to a 1-week survival rate of 66%; 97% partial hepatectomy, accomplished by additional resection of the lower caudate lobe only leaving the paracaval parts of the liver behind, resulted in 100% lethality within 4 days. Conclusions:Using a anatomically based, vessel-oriented, parenchyma-preserving surgical technique in 95% liver resections led to long-term survival. This represents the maximal reduction of liver mass compatible with survival.

Urinary ethyl glucuronide testing detects alcohol consumption in alcoholic liver disease patients awaiting liver transplantation

This study compared measurement of urinary ethyl glucuronide (EtG), a conjugated minor ethanol metabolite with a longer detection window than ethanol itself, with breath alcohol testing and self‐report as ways to disclose recent drinking by 18 liver transplant candidates with an alcoholic liver disease diagnosis that underwent an addiction group therapy program. At each therapy session, patients were questioned about any alcohol consumption in the intervening time, and they also performed a mandatory breath alcohol test, while observed urine samples for measurement of EtG were delivered on a voluntary basis. None of the patients ever admitted to intake of alcohol, and only 1 of 127 breath alcohol tests turned out positive. However, 9 patients showed positive EtG results in 24 (49%) of 49 urine samples. The individual frequency of urine samples being positive for EtG ranged from 22% to 100% with a mean value of 57%. Because 6 patients refused to provide urine on a total of 18 occasions, alcohol use might have been even more common. These results underscore the uncertainty of self‐report data and the low sensitivity of breath alcohol testing as ways to disclose recent drinking, and underline the necessity of introducing sensitive and specific objective measures of recent alcohol consumption, such as EtG, in the transplantation setting. Liver Transpl 13:757–761, 2007.

A biphasic model for sinusoidal liver perfusion remodeling after outflow obstruction

Liver resection can lead to focal outflow obstruction due to transection of hepatic veins. Outflow obstruction may cause additional damage to the small remnant liver. Drainage of the obstructed territories is reestablished via dilatation of sinusoids. Subsequently, sinusoidal canals are formed draining the blood from the obstructed territory to the neighboring unobstructed territories. We raised the phenomenological hypothesis that the blood pressure gradient is the main driving force for the formation of sinusoidal vascular canals. We generated a biphasic mechanical model to describe this vascular remodeling process in relation to the variable pressure gradient. Therefore, we introduced a transverse isotropic permeability relation as well as an evolutional optimization rule to describe the relationship between pressure gradient and the direction of the sinusoidal blood flow in the fluid phase. As a next step, we developed a framework for the calculation concept including the representation of the governing weak formulations. Then, we examined a representative numerical example with simulation of the blood flow under both conditions, the physiological situation as well as after outflow obstruction. Doing so, we were able to reproduce numerically the experimentally observed process of reestablishing hepatic venous drainage via redirection of blood flow and formation of new vascular structures in respect to the fluid flow. The calculated results support the hypothesis that the reorientation of blood flow mainly depends on the pressure gradient. Further investigations are needed to determine the micromechanical influences on the reorientation of the sinusoids.

Oxidation of HMGB1 Causes Attenuation of Its Pro-Inflammatory Activity and Occurs during Liver Ischemia and Reperfusion

High mobility group box 1 (HMGB1) is a nuclear transcription factor. Once HMGB1 is released by damaged cells or activated immune cells, it acts as danger molecule and triggers the inflammatory signaling cascade. Currently, evidence is accumulating that posttranslational modifications such as oxidation may modulate the pro-inflammatory potential of danger signals. We hypothesized that oxidation of HMGB1 may reduce its pro-inflammatory potential and could take place during prolonged ischemia and upon reperfusion. Liver grafts were cold preserved for 24 h and flushed with saline in hourly intervals to collect the effluent. Liver grafts, cold-preserved for 6 h, were transplanted into syngeneic recipients to obtain serum and liver samples 24 h after initiation of reperfusion. Addition of the effluent to a macrophage culture induced the synthesis of tumor necrosis factor-alpha (TNF-α) and interleukin (IL)-6. The stimulatory activity of graft effluent was reduced after depletion of HMGB1 via immunoprecipitation. Oxidation of the effluent HMGB1 using H2O2 attenuated its stimulatory activity as well. Liver transplantation of cold preserved grafts caused HMGB1 translocation and release as determined by immunohistochemistry and ELISA-assay, respectively. Using Western blot with non-reducing conditions revealed the presence of oxidized HMGB1 in liver samples obtained after 12 h and in effluent samples after 16 h of cold preservation as well as in liver and serum samples obtained 24 h after reperfusion. These observations confirm that post-translational oxidation of HMGB1 attenuates its pro-inflammatory activity. Oxidation of HMGB1 as induced during prolonged ischemia and by reoxygenation during reperfusion in vivo might also attenuate its pro-inflammatory activity. Our findings also call for future studies to investigate the mechanism of the inhibitory effect of oxidized HMGB1 on the pro-inflammatory potential.

Recovery of liver perfusion after focal outflow obstruction and liver resection.

Background. Live liver donation requires extended liver resection in the donor with transection of the middle hepatic vein. This leads to focal outflow obstruction in the remnant liver or the partial graft. This study was designed to characterize the pathophysiological correlate of focal outflow obstruction in a small-for-size liver and its course of recovery in a rat model. Methods. Ligation of the right median hepatic vein was combined with 50% hepatectomy. Microcirculation was visualized by orthogonal polarization spectroscopy after each operative step and before killing on days 1, 2, and 7. Histologic evaluation included morphological assessment, immunohistochemical determination of proliferation using BrdU, and laminin and von Willebrand factor expression, which both indicate vascularization of sinusoids. Results. After ligation of the right median hepatic vein, congestion was visible and no sinusoidal blood flow was detected in the obstruction zone. By day 1 confluent centrilobular necrosis developed. Sinusoidal perfusion in the obstruction zone recovered partially. Many dilated vascularized sinusoidal canals connecting the obstruction zone with the normal zone were visible. Proliferative activity in the obstruction zone was markedly reduced compared with the normal zone. By day 7, liver parenchyma in the obstruction zone looked normal as did sinusoidal perfusion. In the border zone, few dilated vascular canals were apparent. Conclusion. Confluent centrilobular necrosis in the early postoperative phase, resulting from focal outflow obstruction, may be crucial for the development of a small-for-size syndrome. The exclusion of the outflow-obstructed zone from the functional liver mass during preoperative radiological risk assessment seems to be the logical consequence. Recovery of focal outflow obstruction occurs spontaneously by means of dilated sinusoids in the border zone, forming vascularized sinusoidal canals, which could serve as intrahepatic anastomosis.

Combination of an Antiviral Drug and Immunomodulation against Hepadnaviral Infection in the Woodchuck Model

ABSTRACT The essential role of multispecific immune responses for the control of hepatitis B virus (HBV) infection implies the need of multimodal therapeutic strategies for chronic HBV infection, including antiviral chemotherapy and immunomodulation. This hypothesis was tested in the woodchuck model by a combination of lamivudine pretreatment and subsequent immunizations of woodchucks chronically infected with woodchuck hepatitis virus. The immunizations were performed with DNA vaccines or antigen-antibody immune complexes (IC)/DNA vaccines. Immunizations with IC/DNA vaccines led to an anti-woodchuck hepatitis virus surface antibody response and significant reductions of viral load and antigenemia, suggesting that such a strategy may be effective against chronic HBV infection.

Helper-Dependent Adenoviral Vector-Mediated Delivery of Woodchuck-Specific Genes for Alpha Interferon (IFN-α) and IFN-γ: IFN-α but Not IFN-γ Reduces Woodchuck Hepatitis Virus Replication in Chronic Infection In Vivo

ABSTRACT Alpha interferon (IFN-α) and IFN-γ are able to suppress hepadnavirus replication. The intrahepatic expression of high levels of IFN may enhance the antiviral activity. We investigated the effects of woodchuck-specific IFN-α (wIFN-α) and IFN-γ(wIFN-γ) on woodchuck hepatitis virus (WHV) replication in vivo by helper-dependent adenoviral (HD-Ad) vector-mediated gene transfer. The expression of biologically active IFNs was demonstrated in vitro after transduction of woodchuck cells with HD-Ad vectors encoding wIFN-α (HD-AdwIFN-α) or wIFN-γ (HD-AdwIFN-γ). The transduction efficacy of the HD-Ad vector in woodchuck liver in vivo was tested with a vector expressing green fluorescence protein (GFP). Immunohistochemical staining of liver samples on day 5 after injection showed expression of GFP in a high percentage of liver cells surrounding the central vein. The transduction of livers of WHV carriers in vivo with HD-AdwIFN-α or HD-AdwIFN-γ induced levels of biologically active IFN, which could be measured in the sera of these animals. Expression of wIFN-α in the liver reduced intrahepatic WHV replication and WHV DNA in sera of about 1 log step in two of two woodchucks. Transduction with HD-AdwIFN-γ, however, reduced WHV replicative intermediates only slightly in two of three animals, which was not accompanied with significant changes in the WHV DNA in sera. We demonstrated for the first time the successful HD-Ad vector-mediated transfer of genes for IFN-α and IFN-γ in vivo and timely limited reduction of WHV replication by wIFN-α, but not by wIFN-γ.

Cholestasis-induced adaptive remodeling of interlobular bile ducts

Cholestasis is a common complication in liver diseases that triggers a proliferative response of the biliary tree. Bile duct ligation (BDL) is a frequently used model of cholestasis in rodents. To determine which changes occur in the three‐dimensional (3D) architecture of the interlobular bile duct during cholestasis, we used 3D confocal imaging, surface reconstructions, and automated image quantification covering a period up to 28 days after BDL. We show a highly reproducible sequence of interlobular duct remodeling, where cholangiocyte proliferation initially causes corrugation of the luminal duct surface, leading to an approximately five‐fold increase in surface area. This is analogous to the function of villi in the intestine or sulci in the brain, where an expansion of area is achieved within a restricted volume. The increase in surface area is further enhanced by duct branching, branch elongation, and loop formation through self‐joining, whereby an initially relatively sparse mesh surrounding the portal vein becomes five‐fold denser through elongation, corrugation, and ramification. The number of connections between the bile duct and the lobular bile canalicular network by the canals of Hering decreases proportionally to the increase in bile duct length, suggesting that no novel connections are established. The diameter of the interlobular bile duct remains constant after BDL, a response that is qualitatively distinct from that of large bile ducts, which tend to enlarge their diameters. Therefore, volume enhancement is only due to net elongation of the ducts. Because curvature and tortuosity of the bile duct are unaltered, this enlargement of the biliary tree is caused by branching and not by convolution. Conclusion: BDL causes adaptive remodeling that aims at optimizing the intraluminal surface area by way of corrugation and branching. (Hepatology 2016;63:951–964)

Ischemic preconditioning protects against liver ischemia/reperfusion injury via heme oxygenase-1-mediated autophagy

Objectives:Ischemic preconditioning exerts a protective effect in hepatic ischemia/reperfusion injury. The exact mechanism of ischemic preconditioning action remains largely unknown. Recent studies suggest that autophagy plays an important role in protecting against ischemia/reperfusion injury. However, the role of autophagy in ischemic preconditioning–afforded protection and its regulatory mechanisms in liver ischemia/reperfusion injury remain poorly understood. This study was designed to determine whether ischemic preconditioning could protect against liver ischemia/reperfusion injury via heme oxygenase-1-mediated autophagy. Design:Laboratory investigation. Setting:University animal research laboratory. Subjects:Male inbred Lewis rats and C57BL/6 mice. Interventions:Ischemic preconditioning was produced by 10 minutes of ischemia followed by 10 minutes of reperfusion prior to 60 minutes of ischemia. In a rat model of hepatic ischemia/reperfusion injury, rats were pretreated with wortmannin or rapamycin to evaluate the contribution of autophagy to the protective effects of ischemic preconditioning. Heme oxygenase-1 was inhibited with tin protoporphyrin IX. In a mouse model of hepatic ischemia/reperfusion injury, autophagy or heme oxygenase-1 was inhibited with vacuolar protein sorting 34 small interfering RNA or heme oxygenase-1 small interfering RNA, respectively. Measurements and Main Results:Ischemic preconditioning ameliorated liver ischemia/reperfusion injury, as indicated by lower serum aminotransferase levels, lower hepatic inflammatory cytokines, and less severe ischemia/reperfusion-associated histopathologic changes. Ischemic preconditioning treatment induced autophagy activation, as indicated by an increase of LC3-II, degradation of p62, and accumulation of autophagic vacuoles in response to ischemia/reperfusion injury. When ischemic preconditioning–induced autophagy was inhibited with wortmannin in rats or vacuolar protein sorting 34–specific small interfering RNA in mice, liver ischemia/reperfusion injury was worsened, whereas rapamycin treatment increased autophagy and mimicked the protective effects of ischemic preconditioning. Furthermore, ischemic preconditioning increased heme oxygenase-1 expression. The inhibition of heme oxygenase-1 with tin protoporphyrin IX in rats or heme oxygenase-1-specific small interfering RNA in mice decreased ischemic preconditioning–induced autophagy and diminished the protective effects of ischemic preconditioning against ischemia/reperfusion injury. Conclusions:Ischemic preconditioning protects against liver ischemia/reperfusion injury, at least in part, via heme oxygenase-1-mediated autophagy.