Objective To explore adaptive condition of preparation of animal model and afford reliable and stable model animal for further research on clinical diagnosis and treatment of cavernous transformation of portal vein (CTPV) by establishment of animal model by partial portal vein stenosis. Methods According to different straight blunttip needles used, 80 healthy Sprague-Dawley rats were randomly averagely divided into 4 groups: sham operation group, gauge 19 (19G) group, gauge 21 (21G) group and gauge 23 (23G) group. Six weeks after model making, pressure measurement and angiography of portal vein and pathological examination of portal vein and its surrounding tissues were used to evaluate portal hypertension and CTPV. Results Six weeks after model making no rat died in sham operation group, while the numbers of died rats in 19G group, 21G group and 23G group were 2, 4 and 16, respectively. No portal hypertension was displayed in sham operation group and 19G group 6 weeks after model making. Portography showed that the portal vein seemed smooth without variceal and dilatation in sham operation group and 19G group. Pathological examination demonstrated that the portal vein walls were not enlarged, endothelial cells were smooth. The smooth muscles of middle membrane were not thickened and adventitia was intact. Portal pressure increased and CTPV formed in 21G group and 23G group 6 weeks after model making. Portography showed that collateral circulation formed around portal vein in 21G group and 23G group. The vessel lumens with different size and irregular shapes were displayed by pathological examination. Within the narrow fibrous septum between there were the lumens the fat cells, scattered lymphocytes and mast cells, etc. The portal vein walls were enlarged notably, endothelial cells were damaged, the smooth muscle of middle membrane were thickened, thrombosis were formed. Conclusion Establishment of CTPV animal models by partial portal vein stenosis is a reliable method. 21G blund-tip needles fits well in the preparation of CTPV, which is reliable and stable with lower mortality.
Objective To review the advancement of surgical therapy for cavernous transformation of portal vein. Methods The relevant literatures on therapy for cavernous transformation of portal vein in recent years were collected and reviewed. Results The main symptoms of the patients are repeated haematemesis and hemafecia, hypersplenotrophy and hypersplenia. Most cases can be detected by ultrasonography or portal venography. Splenectomy and by-pass technique plus disconnection are the preferred operation. Conclusion Therapy for cavernous transformation of portal vein will be further developed.
【Abstract】Objective To investigate the appropriate reconstruction techniques of multidetectorrow spiral CT angiography (MDCTA) to depict the collateral vessels in cavernous transformation of the portal vein (CTPV) caused by tumor thrombosis of hepatocellular carcinoma (HCC). Methods MDCTA scanning was performed during the portal venous phase after intravenous contrast materials in 18 HCC patients with CTPV induced by tumor thrombosis. Raw data were reconstructed with thin slice thickness followed by 2D and 3D angiographic reconstruction methods, including maximum intensity projection(MIP), shade surface display (SSD) and volume rendering technique(VRT). Results MDCTA with MIP reconstruction accurately depicted both the tumor thrombus within the portal vein and the collateral vessels of CTPV including the biliary (cystic vein and pericholedochal veinous plexus) and the gastric (left and right gastric veins) branches. However, VRT and SSD methods did poorly in showing the tumor thrombus and the collateral vessels. Conclusion MDCTA with MIP reconstruction is the method of choice to evaluate the collateral vessels of CTPV.
Objective To observe the expression levels of nuclear factor kappa B (NF-κB), vascular endothelial growth factor (VEGF), and CD31 in portal vein and surrounding tissues of rats during the formation process of cavernoustransformation of portal vein (CTPV), and try to search the relationship between NF-κB, VEGF, and the angiogenesisof portal areas, as well as the significance and the role of NF-κB and VEGF in the formation process of CTPV. Methods One hundred and ten Sprague-Dawley (SD) rats were randomly (random number method) divided into sham operation group and model group. The partial constriction operations on portal vein were performed in model rats with a blunt 21Gcaliber to establish CTPV animal models (model group), while the exploratory operations on portal vein, not constriction,were performed in rats of sham operation group. All specimens (portal vein and surrounding tissues) were fixed in formalinand made into paraffin blocks. Each specimen was tested by immunohistochemistry for the expressions of NF-κB, VEGF, and CD31, then optical density (OD) of NF-κB expression and the mean integral optical density (IOD) of VEGF expressionwere measured by using Image Pro Plus 6.0 software, and microvessel density (MVD) was calculated under microscope. Results Nucleoplasm ratio of OD value of NF-κB, mean IOD value of VEGF, and MVD value in 1, 2, 3, 4, and 6 weeks after operation didn’t significantly differed from that of before operation in sham operation group (P>0.05), but higher at all time points after operation in model group (P<0.01). Compared with sham operation group, nucleoplasm ratio of OD value of NF-κB, mean IOD value of VEGF, and MVD value were significantly higher in 1, 2, 3, 4, and 6 weeks after operation in model group (P<0.01). NF-κB and VEGF, NF-κB and MVD, VEGF and MVD were positively correlated with each other (r=0.654 6,P<0.01;r=0.620 7, P<0.01;r=0.636 9, P<0.01) in model group. Conclusion NF-κB and VEGF may relate to the formation of CTPV, and may involve in the angiogenesis.
Objective To explore feasibility and safety of ex vivo liver resection and autotransplantation in treating end-stage hepatic alveolar echinococcosis combined with secondary cavernous transformation of portal vein. Methods The patient was diagnosed with the end-stage hepatic alveolar echinococcosis combined with secondary cavernous transformation of portal vein. The ultrasonography, computed tomography, and magnetic resonance imaging were used to access the characteristics of the lesions and the extent of involvement of the portal vein and its branches. The liver model was reconstructed using a three-dimensional imaging data analysis system (EDDA Technology, Inc. USA), the remnant liver volume and the extent of involvement of the first hepatic hilum were recorded. Then the multidisciplinary team repetitively discussed the risks and procedures involved in the surgery. Finally, the ex vivo liver resection and autotransplantation was proposed. Results The preoperative evaluation showed the patient had a large intrahepatic lesion which severely invaded the retrohepatic inferior vena cava, the right hepatic vein, and the middle hepatic vein and were completely occluded, the left hepatic vein was partially invaded, and the portal vein was spongiform. The remnant liver volume was 912 mL, the ratio of residual liver volume to standard liver volume was 0.81. The preoperative liver function Child-Pugh score was grade A. The ex vivo liver resection and autotransplantation was successfully managed according to the expected schedule. The autografts (made by patient’s great saphenous vein) were used to reconstruct the hepatic vein and portal vein, and the retrohepatic inferior vena cava was not reconstructed. The patient recovered well and was discharged on day 20 after the operation. Conclusions Ex vivo liver resection and autotransplantation could successfully be applied in treating patient with end-stage hepatic alveolar echinococcosis combined with secondary cavernous transformation of portal vein. Adequate preoperative assessment and management of the first hepatic hilum are key to this operation.
ObjectiveTo summarize the treatment and experience of percutaneous transhepatic portal vein recanalization by endovascular approach for treatment of cavernous transformation of the portal vein (CTPV) in a child. MethodThe clinical data of a child with idiopathic CTPV who underwent percutaneous transhepatic portal vein recanalization by endovascular approach were retrospectively analyzed. ResultsWe described a novel percutaneous transhepatic portal vein recanalization approach that had successfully treated a child with idiopathic CTPV following a multidisciplinary team evaluation. The operation time was 1.5 h and blood loss was approximately 1 mL. The child recovered uneventfully at 9-month follow-up, without any clinical evidence of CTPV complications. ConclusionIn light of our successful management, we can envision that the portal vein recanalization is an important therapeutic supplement for treating CTPV and will result in a paradigm change.
ObjectiveTo summarize the clinical experience of retropancreatic tunnel established by superior mesenteric vein-approach in a child with cavernous transformation of the portal vein (CTPV) during Rex bypass. MethodThe retropancreatic tunnel was created by the superior mesenteric vein-approach during Rex bypass in a child with CTPV who was admitted to our hospital in September, 2023. Clinical data were retrospectively analyzed. ResultsFor the 4-year-old male child who was diagnosed with CTPV, after the establishment of the retropancreatic tunnel by superior mesenteric vein-approach, the portal vein was quickly identified, thus simplifying the portal dissection. The operation time of Rex bypass was about 8 hours, and intraoperative blood loss was about 60 mL. After a 3-month follow-up, the child recovered well with patent bypass vessels. ConclusionThe surgical strategy proposed by our team can simplify the Rex bypass, resulting in more rapid and safe access to the vascular anastomosis site.