Intrahepatic circulation in liver disease

Using the multiple indicator dilution approach, events occurring in the microvascular bed can be characterized in experimental animals with different types of cirrhosis and in man. Intrahepatic shunts can be found shunting blood away from sinusoids in both cirrhotic patients and cirrhotic animals. Such shunts were present in about one-third of cirrhotic patients with portal hypertension, and occurred mainly between the portal vein and hepatic veins. In cirrhotics, portohepatic anastomoses are usually large in diameter (more than 20 micron in diameter). Collagenization of the space of Disse and the progressive transformation of sinusoids into capillary-like channels decrease the extravascular space accessible to albumin and probably to other large molecules and protein-bound substances. However, unlike findings obtained in well-capillarized organs, these sinusoidal changes do not appear to limit the diffusion of sucrose, water, and lipophilic substances, such as lidocaine in the extravascular and intracellular spaces. The pattern observed for labeled sucrose curves following hepatic artery injection in cirrhotic patients could be secondary to the passage through the dense peribiliary capillary plexus originating from the enlarged arterial bed in cirrhosis. The difference in the perfusion of cirrhotic nodules with regard to the portal venous and hepatic artery routes introduces important new concepts in the overall mechanism of the elimination of endogenous and exogenous substances by the cirrhotic liver: blood entering the liver by the two afferent vessels will not flow through the same vascular bed before reaching the efferent hepatic veins.     

Significance of hepatic arterial responsiveness for adequate tissue oxygenation upon portal vein occlusion in cirrhotic livers

We investigated sinusoidal blood flow and hepatic tissue oxygenation during portal vein occlusion in cirrhotic rat livers to examine the effect of cirrhosis on the properties of hepatic microvascular blood flow regulation. After 8 weeks of CCl4/phenobarbital sodium treatment to induce cirrhosis Sprague-Dawley rats were prepared surgically to allow assessment of portal venous and hepatic arterial inflow using miniaturized flow probes with simultaneous analysis of hepatic microcirculation and tissue oxygenation by fluorescence microscopy and polarographic oxymetry. Age-matched noncirrhotic animals served as controls. Upon portal vein occlusion in cirrhotic livers (flow reduction to < 20%), hepatic arterial blood flow increased 1.5-fold (61 +/- 8 ml/min per 100 g liver) of baseline (40 +/- 7 ml/min per 100 g liver), reflecting an appropriate hepatic arterial buffer response (HABR), similarly as seen in control livers. The net result was a reduction in total liver inflow from 90 +/- 12 to 72 +/- 11 ml/min per 100 g liver, which was associated with a significant decrease in both sinusoidal red blood cell velocity and volumetric blood flow to approx. 71% and 76% of baseline values. However, portal vein occlusion did not cause a deterioration in hepatic tissue pO2 (11 +/- 3 vs. 10 +/- 3 mmHg at baseline). Sinusoidal diameters were found unchanged, disproving a major role of the sinusoidal tone in the regulation of HABR. Microvascular response of cirrhotic livers did not generally differ from that in noncirrhotic livers upon portal inflow restriction. We conclude that HABR in cirrhotic livers operates sufficiently to meet the liver tissue oxygen demand, most probably by an increased relative contribution of arterial perfusion of hepatic sinusoids.     

On the pathogenesis of portal hypertension in cirrhosis of the liver

To investigate the localization of increased vascular resistance in the cirrhotic liver, blood pressures at key points in hepatic vascular pathways were measured in the cirrhotic rat produced by carbon tetrachloride injections. Blood pressures in the portal vein, the terminal portal venule, the terminal hepatic venule and the inferior vena cava were 110, 68, 28 and 20 mm H2O respectively in normal rats, and 211, 112, 34 and 24 mm H2O respectively in rats with liver cirrhosis. These values suggested that the increased vascular resistance in the cirrhotic liver was in the intrahepatic portal vein and the sinusoids, and not in the intrahepatic hepatic vein, although marked distortion of the intrahepatic hepatic vein branches was found in the cirrhotic liver. The increase in sinusoidal vascular resistance was associated with sinusoidal stenoses and a decrease in the sinusoidal space due to the hepatic cell swelling, and that in the intrahepatic portal vein might result from distortion of the peripheral branches of the vein.     

Hepatic microvascular features in experimental cirrhosis: a structural and morphometrical study in CCl4-treated rats

BACKGROUND/AIMS: In this study, a detailed morphometrical analysis of the hepatic microvasculature in the different zones of hepatic parenchyma was performed in normal and cirrhotic rat liver (CCl4-induced). The aims were to detect, in CCl4-induced cirrhosis, the real presence of the "capillarization" of hepatic sinusoids and to assess alterations of the sinusoid/parenchyma ratio within the nodule. METHODS: Cirrhosis was promoted by controlled intragastric CCl4 administration. Scanning electron microscopy of the vascular corrosion cast technique associated with light microscopy and transmission electron microscopy were used. RESULTS: Evidence of connective tissue in the space of Disse was found only in sinusoids located near portal tracts or large fibrotic areas, and this was also confirmed by laminin immunohistochemistry. In contrast, all the intranodular sinusoids lacked real basal membrane and connective fibers in the space of Disse and, displayed normal fenestrations. The parenchymal area, sinusoidal area, mean sinusoidal area, sinusoidal perimeter, hepatocyte area and the reciprocal ratios were all considered in the morphometrical analysis. The sinusoids were of uniform size in the periportal, periseptal and pericentral areas of the cirrhotic liver without the typical zonal differences of the normal liver. The areas occupied by sinusoids per unit of parenchyma and the sinusoid/hepatocyte interfaces disposable for metabolic exchanges were markedly smaller (p<0.01) in cirrhotic than normal liver. CONCLUSION: Our findings indicate that capillarization of hepatic sinusoids occurs only in very limited regions of the cirrhotic parenchyma, and thus this phenomenon does not have relevant functional consequences. Furthermore, the cirrhotic parenchyma appears not to be supplied by sinusoids and lacks features of zonation, which is a condition that could play a major role in the development and progression of liver failure.     

Relation of sinusoidal stenoses following hepatocyte swelling to hepatic vascular resistance in experimental liver cirrhosis

To investigate the significance of sinusoidal stenoses and a decrease in the sinusoidal bed due to hepatic cell swelling as a factor increasing hepatic vascular resistance in liver cirrhosis, hepatic vascular resistance in choline-deficient diet-induced cirrhotic rats was measured by an isolated liver perfusion method. In the cirrhotic rats, the swollen hepatic cells resulting from accumulation of fat droplets narrowed the sinusoids and decreased the sinusoidal bed. Consequently, the hepatic vascular resistance was increased by 2.7 times normal (8.60 +/- 2.32 mm H2O.ml-1.min; controls, 3.13 +/- 0.67 mm H2O.ml-1.min), and portal hypertension was also recognized (188.1 +/- 26.3 mm H2O; controls, 114.2 +/- 12.8 mm H2O). In the cirrhotic rats fed with ordinary rat pellets for 2 months, however, the sinusoidal stenoses and the decreased sinusoidal bed recovered to nearly normal as a result of disappearance of the fat droplets in the hepatic cells. The increased hepatic vascular resistance was decreased to 1.5 times normal (4.68 +/- 0.82 mm H2O.ml-1.min), and the elevated portal vein pressure was reduced (141.5 +/- 17.4 mm H2O). These findings clearly demonstrate that an important factor leading to an increase in hepatic vascular resistance is sinusoidal stenoses and a decrease in the sinusoidal bed resulting from swollen hepatic cells.     

慢性乙型肝炎及肝硬化患者肝脏微循环改变

为探讨慢性乙型肝炎（慢乙肝）及肝硬化患者的肝脏微循环状态。对141例慢乙肝、12例肝硬化患者和2例正常人的肝组织进行HE染色,光镜观察,并对其中53例慢乙肝和2例肝硬化患者的肝组织进行了电镜观察。结果显示,正常人的肝窦腔通畅,无狭窄和闭塞,无红细胞聚集现象。慢乙肝患者86.52%有肝窦腔狭窄,60.28%肝窦腔内见红细胞聚集,34.04%肝窦腔内有血栓形成;电镜观察见94.34%的患者肝窦内皮细胞窗孔减小减少,33.96%有基底膜形成,24.53%狄氏腔内出现胶原纤维。肝硬化患者肝组织结构紊乱,肝腺泡消失,假小叶形成。提示慢乙肝患者存在肝脏微循环障碍,肝硬化时肝脏微循环结构丧失。     

Role of Intrahepatic Portal-Systemic Shunts in the Reduction of Portal Blood Supply to Liver Cells in Cirrhosis

To assess the role of intrahepatic portal-systemic shunts in the reduction of portal blood supply to the liver cells in cirrhosis, we measured portal venous flow (blood flow in the portal trunk) by the pulsed Doppler flowmeter and intrahepatic portal-systemic shunt index from the counts over the lungs and liver in both the anterior and posterior projections after instillation of 99mTc-macroaggregated albumin in the portal vein, and calculated portal sinusoidal flow (blood flow into the sinusoids via the portal vein), using the equation, (sequence; see text) in 47 patients with posthepatitic cirrhosis, and measured portal venous flow in 63 healthy adults in whom portal sinusoidal flow should be comparable to portal venous flow. Portal sinusoidal flow was significantly reduced in cirrhotics with an intrahepatic portal-systemic shunt index averaging 24%, whereas portal venous flow was similar in the cirrhotics and control. There was a significant inverse correlation between intrahepatic portal-systemic shunt index and portal sinusoidal flow. When cirrhotics were divided into three stages, based on Child's grading, intrahepatic portal-systemic shunt index was significantly increased in the group order of Child's A (8 +/- 9%), Child's B (27 +/- 22%), and Child's C patients (46 +/- 19%), and portal sinusoidal flow was decreased in the same order. Portal sinusoidal flow was significantly reduced in Child's B and Child's C patients, but not in Child's A patients, compared with the control. In conclusion, intrahepatic portal-systemic shunts may play a role, at least in part, in the reduction of portal blood supply to the liver cells in patients with advanced stage of posthepatitic cirrhosis when large intrahepatic portal-systemic shunts develop.     

Histochemical properties of vascular and sinusoidal endothelial cells in liver diseases

Liver biopsy specimens with or without liver diseases were examined immunohistochemically to determine the distribution of endothelial cell markers, factor VIII-related antigen (FVIII-RAg), Ulex europaeus agglutinin I (UEA-I) lectin and PAL-E. We also investigated the localization of laminin, a component of the basement membrane. In normal livers, FVIII-RAg, UEA-I and laminin were negative in sinusoidal endothelial cells, but positive in blood vascular endothelia of the portal area. The antigen detected by PAL-E was distributed in venous endothelial cells. PAL-E did not label endothelial cells of the artery. In the lobule, immunoreactivity with PAL-E was weakly detected only in some sinusoids of the periportal area. In chronic active hepatitis and liver cirrhosis, FVIII-RAg and UEA-I stained endothelial cells of neovasculatures in the enlarged portal areas of the fibrous septum surrounding pseudolobules. Some sinusoidal endothelial cells in cirrhotic livers were reactive to UEA-I and FVIII-RAg, whereas PAL-E-positive cells were found rarely in the pseudolobules. In carcinomatous sinusoidal endothelial cells, FVIII-RAg, UEA-I and PAL-E were strongly stained. Laminin underlay these carcinomatous sinusoids. These suggest capillarization of sinusoids in hepatocellular carcinoma. The histochemical approach using endothelial cell markers could be a practical tool in the diagnosis of hepatocellular carcinoma.     

Hagen-Poiseuille’s law:The link between cirrhosis,liver stiffness,portal hypertension and hepatic decompensation

The onset of hepatic decompensation in cirrhosis heralds an accelerated downhill course with poor outcome. The sole predictor of this decompensationin cirrhosis is increased hepatic vein to portal vein gradient hepatic venous pressure gradient(HVPG). Surrogate markers of liver function or hepatic reserve appear to be less relevant. The hepatic sinusoids become less elastic and more rigid as liver fibrosis and cirrhosis progress. We propose that the HagenPoiseuille’s law,which applies to rigid,but not elastic vessels,determines the pressure-flow characteristics in the sinusoids. In the rigid cirrhotic liver,HVPG rises dramatically with any change in net surface area or radius,r4 of the vasculature that follows surgical resection. This review relates liver stiffness to the risk of decompensation in patients with cirrhosis. The liver has a unique dual blood supply comprising a low pressure portal vein and high pressure hepatic artery. We compare the complexity of autoregulation in the normal elastic liver with that in the rigid cirrhotic liver. Therapeutic modalities to reduce portal pressure may reduce the risk of hepatic decompensation and improve outcomes in cirrhosis.     

Histochemical properties of vascular and sinusoidal endothelial cells in liver diseases.

Liver biopsy specimens with or without liver diseases were examined immunohistochemically to determine the distribution of endothelial cell markers, factor VIII-related antigen (FVIII-RAg). Ulex europaeus agglutinin I (UEA-I) lectin and PAL-E. We also investigated the localization of laminin, a component of the basement membrane. In normal livers, FVIII-RAg, UEA-I and laminin were negative in sinusoidal endothelial cells, but positive in blood vascular endothelia of the portal area. The antigen detected by PAL-E was distributed in venous endothelial cells. PAL-E did not label endothelial cells of the artery. In the lobule, immunoreactivity with PAL-E was weakly detected only in some sinusoids of the periportal area. In chronic active hepatitis and liver cirrhosis, FVIII-RAg and UEA-I stained endothelial cells of neovasculatures in the enlarged portal areas of the fibrous septum surrounding pseudolobules. Some sinusoidal endothelial cells in cirrhotic livers were reactive to UEA-I and FVIII-RAg, whereas PAL-E-positive cells were found rarely in the pseudolobules. In carcinomatous sinusoidal endothelial cells, FVIII-RAg, UEA-I and PAL-E were strongly stained. Laminin underlay these carcinomatous sinusoids. These suggest capillarization of sinusoids in hepatocellular carcinoma. The histochemical approach using endothelial cell markers could be a practical tool in the diagnosis of hepatocellular carcinoma.     

Vascular changes in the cirrhotic liver as studied by the injection technic

Summary The hepatic vasculature was studied in 9 normal livers, 1 fatty liver, 7 livers with portal cirrhosis, and 3 with postnecrotic cirrhosis (one each of the granular, coarsely nodular, and lobar type). Injection-corrosion cast and latex-injection technics were employed to determine the gross alterations in the vascular architecture, the anatomical evidence for the existence of intrahepatic shunts, the degree of venous compression by regenerative nodules, and the source of the blood supply to the regenerative nodules.An increased prominence of the hepatic arterial system and a reduction in the size of the portal venous bed were observed in both portal and postnecrotic cirrhosis. Vascular distortion was more pronounced in coarsely nodular postnecrotic cirrhosis than in portal cirrhosis. Only scanty and unconvincing evidence of intrahepatic vascular communications was found and the occurrence of physiologically significant shunts in the specimens studied is doubtful.Compression of the smaller and, to a lesser degree, the larger portal and hepatic venous branches was a regular accompaniment of both types of cirrhosis.In all cirrhotic livers, the vascular elements were confined almost entirely to the fibrous septa and the regenerative nodules were poorly supplied by either afferent system. The findings would indicate that the blood supply to the regenerative nodule comes from both the portal vein and the hepatic artery. In contrast to the normal, however, the hepatic artery plays a major role in supplying the parenchyma in both forms of cirrhosis.Supported in part by Contract DA 49-007-MD-592, U. S. Army Medical Research and Development Command, Office of the Surgeon General, Washington, D. C.     

Localization of increased hepatic vascular resistance in liver cirrhosis

To determine the localization of increased vascular resistance in cirrhotic liver, blood pressures were measured by a direct cannulation method at several key points in the hepatic vascular pathway in normal and cirrhotic rats. Cirrhosis was produced by feeding a choline-deficient diet. Blood pressures in normal rats were 110 mm H2O in the portal vein, 68 mm H2O in the terminal portal venule, 28 mm H2O in the terminal hepatic venule and 20 mm H2O in the inferior vena cava. In cirrhotic rats, blood pressures in the portal vein and the terminal portal venule were 173 and 100 mm H2O, respectively, while those in the terminal hepatic venule and the inferior vena cava were elevated only slightly above normal. These hemodynamic data suggest that an increase in vascular resistance in cirrhotic liver is present in the intrahepatic portal vein and sinusoids, but not in intrahepatic hepatic vein. In cirrhotic liver, stenosis and distortion were found in peripheral branches of the portal vein, and sinusoidal stenoses and a decrease in sinusoidal space were recognized. Accordingly, it is suggested that the increase in vascular resistance in the intrahepatic portal vein and sinusoids correlate with these structural changes. Although severe stenoses and distortion were found in hepatic vein branches, it was thought that they do not contribute to portal hypertension because of lack of increase in vascular resistance in the intrahepatic hepatic vein.     

The methionine connection: homocysteine and hydrogen sulfide exert opposite effects on hepatic microcirculation in rats

Increased intrahepatic resistance in cirrhotic livers is caused by endothelial dysfunction and impaired formation of two gaseous vasodilators, nitric oxide (NO) and hydrogen sulfide (H(2)S). Homocysteine, a sulfur-containing amino acid and H(2)S precursor, is formed from hepatic methionine metabolism. In the systemic circulation, hyperhomocystenemia impairs vasodilation and NO production from endothelial cells. Increased blood levels of homocysteine are common in patients with liver cirrhosis. In this study, we demonstrate that acute liver perfusion with homocysteine impairs NO formation and intrahepatic vascular relaxation induced by acetylcholine in methoxamine-precontracted normal livers (7.3% +/- 3.0% versus 26% +/- 2.7%; P < 0.0001). In rats with mild, diet-induced hyperhomocystenemia, the vasodilating activity of acetylcholine was markedly attenuated, and incremental increases in flow induced a greater percentage of increases in perfusion pressure than in control livers. Compared with normal rats, animals rendered cirrhotic by 12 weeks' administration of carbon tetrachloride exhibited a greater percentage of increments in perfusion pressure in response to shear stress (P < 0.05), and intrahepatic resistance to incremental increases in flow was further enhanced by homocysteine (P < 0.05). In normal hyperhomocysteinemic and cirrhotic rat livers, endothelial dysfunction caused by homocysteine was reversed by perfusion of the livers with sodium sulfide. Homocysteine reduced NO release from sinusoidal endothelial cells and also caused hepatic stellate cell contraction; this suggests a dual mechanism of action, with the latter effect being counteracted by H(2)S. CONCLUSION: Impaired vasodilation and hepatic stellate cell contraction caused by homocysteine contribute to the dynamic component of portal hypertension.     

Hemodynamic consequences of portal decompression: which is the optimal shunt?

Increased sinusoidal resistance in cirrhosis results in a decrease of the portal and a compensatory increase of the arterial blood supply to the liver. With increasing vascular resistance and development of extrahepatic collaterals stagnation and even reversion of the portal blood flow may occur. In the latter condition, the arterial blood leaves the liver through two routes: 1) through the sinusoids and the hepatic veins, and 2) through the portal vein. Experimental and clinical studies revealed that the arterio-portal pathway is metabolically inferior to the regular arterio-hepatic-venous pathway. This suggests a decrease in liver function with an increased incidence of hepatic encephalopathy (HE) in patients with reversed portal blood flow. Based on these findings, surgical shunts may be classified according to their effect on the arterial liver perfusion. The end-to-side shunt and the distal splenorenal shunt (DSRS) do not cause diversion of the arterial liver perfusion. In contrast, side-to-side shunts, with the portal vein available as an outflow tract, consistently lead to diversion of the arterial blood supply resulting in reversed portal blood flow. Thus, side-to-side shunts are supposed to have an increased incidence of HE due to decreased liver function. This hypothesis is supported by 7 controlled and randomized studies which reveal comparable results of end-to-side shunts and DSRS but significant disadvantages of side-to-side shunts compared to DSRS.     

Impact of cirrhosis on the development of experimental hepatic metastases by B16F1 melanoma cells in C57BL/6 mice

Metastases rarely occur in human livers with cirrhosis in clinical studies. We postulated that this phenomenon would also occur in experimental cirrhosis. Cirrhosis was established in C57BL/6 mice by carbon tetrachloride (CCl(4)) gastrogavage. B16F1 melanoma cells were injected into the mesenteric vein to induce hepatic metastases. Contrary to our postulate, there was greater than 4-fold increase in metastasis in animals with cirrhosis compared to controls. Intravital videomicroscopy showed that the hepatic sinusoids were narrower and more tumor cells were retained in the terminal portal vein (TPV) in cirrhotic livers. Immunohistochemistry demonstrated that the expression of vascular adhesion molecules was significantly increased in cirrhosis. Using confocal microscopy and the fluorescent nitric oxide (NO) probe 4,5-diaminofluorescein diacetate, a significantly lower level of NO release was detected in livers with cirrhosis both in basal conditions and after tumor cell arrest. Eight hours after mesenteric vein tumor cell injection, the percentage of apoptotic tumor cells in the sinusoids was 17% +/- 2% in livers with cirrhosis and 30% +/- 5% in normal livers. More mitotic and Ki-67 labeled tumor cells were seen in livers with cirrhosis. In conclusion, the changes in architecture and adhesion molecule expression in livers with cirrhosis may cause more tumor cells to arrest in the TPV. Lower levels of NO production may reduce apoptosis of B16F1 cells in livers with cirrhosis. As a result, these changes may promote the growth of metastasis in this cirrhotic model.     

Hepatic venous pressure gradient measurement: Time to learn!

Portal hypertension is a clinical syndrome defined by a pathological increase in portal pressure. The development of cirrhosis of the liver is characterized by clinical manifestations related to portal hypertension like esophageal varices, ascites, bleeding, and encephalopathy. Direct measurement of portal pressure is invasive, inconvenient, and clinically impractical. Currently, the most commonly used parameter is the Hepatic Venous Pressure Gradient (HVPG), i.e., the difference between the wedged (WHVP) and the free hepatic venous pressures. HVPG represents the gradient between pressures in the portal vein and the intra-abdominal portion of inferior vena cava. When blood flow in a hepatic vein is stopped by a wedged catheter, the proximal static column of blood transmits the pressure from the preceding communicated vascular territory (hepatic sinusoids) to the catheter. Thus, WHVP reflects hepatic sinusoidal pressure and not the portal pressure itself. In the normal liver, due to pressure equilibration through interconnected sinusoids, wedged pressure is slightly lower than portal pressure, though this difference is clinically insignificant. In liver cirrhosis, the static column created by balloon inflation cannot be decompressed at the sinusoidal level due to disruption of the normal intersinusoidal communications; therefore, WHVP gives an accurate estimation of portal pressure in cirrhosis. The normal HVPG value is between 1 to 5 mmHg. Pressure higher than this defines the presence of portal hypertension, regardless of clinical evidence. HVPG >/= 10 mmHg (termed clinically significant portal hypertension) is predictive of the development of complications of cirrhosis, including death. HVPG above 12 mmHg is the threshold pressure for variceal rupture. The main advantages of HVPG are its simplicity, reproducibility, and safety. This review summarizes the technique of the HVPG measurement.     

Increased hepatic platelet activating factor (PAF) and PAF receptors in carbon tetrachloride induced liver cirrhosis

BACKGROUND AND AIMS: The liver is a major site for the synthesis and actions of platelet activating factor (PAF), a potent hepatic vasoconstrictor and systemic vasodilator. As PAF is implicated in portal hypertension and hyperdynamic circulation associated with liver cirrhosis, we characterised changes in the hepatic PAF system in experimental cirrhosis. METHODS: In rats made cirrhotic by carbon tetrachloride (CCl(4)) administration for eight weeks, we determined hepatic levels of PAF and its cognate receptor, and the effects of PAF and PAF antagonist (BN52021) on portal and arterial pressure. RESULTS: Compared with control rats, cirrhotic rats had higher hepatic PAF levels, higher apparent hepatic efflux of PAF, and higher PAF levels in arterial blood (p<0.01, p<0.01, p<0.05, respectively). Relative to controls, cirrhotic livers had elevated hepatic PAF receptors (by mRNA and protein levels and [(3)H]PAF binding), higher (p<0.01) baseline hepatic portal pressure, and an augmented (p = 0.03) portal pressure response to PAF infusion (1 microg/kg). Portal infusion of BN52021 (5 mg/kg) showed that elevated endogenous PAF was responsible for 23% of the cirrhotic portal pressure increase but made no contribution to systemic hypotension. Finally, increased PAF receptor density was observed in the contractile perisinusoidal stellate cells isolated from cirrhotic livers relative to those from control livers. CONCLUSIONS: In cirrhosis, increased hepatic release of PAF elevates systemic PAF; in combination with upregulated hepatic PAF receptors in stellate cells, this contributes to portal hypertension.     

Role of thrombosis in the pathogenesis of congestive hepatic fibrosis (cardiac cirrhosis)

The pathogenesis of congestive cirrhosis is generally thought to be a reaction of the hepatic stroma to hypoxia, pressure, or necrosis. This does not explain the poor correlation between symptoms and severity of fibrosis and the irregular distribution of fibrosis within the liver. We have observed healed hepatic vein (HV) thrombosis in patients with congestive heart failure (CHF). The purposes of this study were to document hepatic vascular lesions in autopsy livers of patients with chronic CHF, to determine the role of these lesions in the pathogenesis of congestive cirrhosis, and to refine the definition of congestive cirrhosis. Twenty-five livers were studied, 13 with multiple large blocks 4 × 5 cm. Sections were graded for parenchymal fibrous septa, sinusoidal fibrosis, and intimal fibrosis of portal veins (PVs) and HVs. Fibrous septa were found in livers of 7 of 13 patients with CHF and in none of 12 controls without CHF (P = .007). Parenchymal fibrosis was highly variable in distribution, often with severe septation in some areas and nearly normal morphology in others. Intimal fibrosis and obstruction of small- and mediumHVs were found only in livers of patients with CHF. The vascular lesions were confined to regions with fibrous septation and had morphology suggestive of organized thrombosis. Acute thrombi in sinusoids were noted in livers of 4 patients with CHF and in livers of 2 patients without CHF. These findings support the hypothesis that congestive cirrhosis is a response to intrahepatic thrombosis. The pattern of disease suggests that thrombus begins in sinusoids, occasionally propagates to HVs, and causes secondary local PV thrombosis, ischemia, parenchymal extinction, and fibrosis.     

Hepatic circulation in cirrhosis

Using the multiple indicator dilution approach, events occurring in the microvascular bed can be characterized and are compatible with the two kinds of anatomical alterations in cirrhotic livers: capillarization and intrahepatic shunts. The combination of these two kinds of alteration contributes to the progressive limitation of the blood-liver exchange. The decreased ability of the liver to clear endogenous and exogenous substrates in cirrhosis is generally thought to result from a reduction of liver cell mass and/or function. Our data suggest that abnormalities in the hepatic uptake of these substrates may also contribute to the impaired liver function in cirrhosis. Capillarization of the hepatic sinusoid is of particular importance in the overall process of elimination while intrahepatic shunts, when present, further exacerbate the functional effects of capillarization.     

Enhanced expressions of apelin on proliferative hepatic arterial capillaries in human cirrhotic liver

Aim: Apelin (APLN), the endogenous ligand of angiotensin-like receptor 1 (APJ), is a peptide necessary for embryonic and tumor angiogenesis. Little is known about the localization and changes of APLN expression including the sinusoids in human cirrhotic liver, which might contribute to portal hypertension. This study was designed to elucidate the localization and change of APLN expression in human liver during the progression of cirrhosis. Methods: Twelve normal liver specimens, eight specimens of Child–Pugh grade A cirrhosis, and 10 specimens of Child–Pugh grade C cirrhosis were studied. APLN protein and gene expression was examined by immunohistochemistry, western blotting, immunoelectronic microscopy, and laser captured microdissection (LCM) followed by polymerase chain reaction (PCR) in sinusoid. Results: In control liver tissue, APLN was localized mainly on arterial endothelial cells and hepatic arterioles in the portal tract. In cirrhotic liver tissue, aberrant APLN expression was observed in periportal capillary endothelial cells corresponding to capillarized sinusoids, and in proliferated arterial capillaries in the fibrotic septa. Significant overexpression of APLN at protein level in cirrhotic liver was demonstrated by western blotting (P < 0.01 Child–Pugh A and C versus control, P < 0.01 Child–Pugh A versus C). APLN mRNA expression in the sinusoid was confirmed by LCM-PCR. Conclusion: In humans, APLN protein and gene were overexpressed in cirrhotic liver compared with normal liver, and the magnitude increased as cirrhosis progressed. Especially in end-stage cirrhosis, APLN was strongly expressed in proliferated arterial capillaries directly connected with the sinusoids, suggesting a role of APLN in the proliferation of arterial capillaries in cirrhosis.