The sample with the number 410 was took from forensic medicine of examination at 6/4/2004. Case report: a rare amatomic change of liver arteries, among which 2 supplying blood for right part of liver, 2 other for left, 2 for bile sac-vascularization for the liver made from main liver artery and from a branch of diathesis artery. In the operation of endoscopic biliary cysticotomia, 2 arteries can be displayed, hemostatic manipulation can damage the right duct of the liver or the main liver duct, in case of removal liver samples, 2 arterial anastomosis must be made.
Hepatic Artery ; Liver ; Anatomy

OBJECTIVETo construct a three-dimensional (3D) model of arteries supplying the extrahepatic bile duct with a new segmentation algorithm based on submillimeter CT data.

METHODSThe new image segmentation algorithm based on interactive volume rendering was integrated into Medical Image Three-Dimensional Visualization System (MI-3DVS) as an intersected plug-in. The abdominal submillimeter CTA data of 10 patients were imported into MI-3DVS and the 3D model of the extrahepatic bile duct and its supplying arteries were constructed. The 3D model was zoomed in, zoomed out and spinned for observation and analysis of the arteries supplying the extrahepatic bile duct.

RESULTSThe 3D models of the blood supply to extrahepatic bile duct allowed stereoscopic, and accurate display of the fourth- and fifth-level branches of the hepatic artery, the second-level branches of the cystic artery, the pancreatic duodenal artery arch and the retroportal artery. The 3D models also provided a clear vision of the biliary structures including the hepatobiliary tract, the left and right hepatic ducts, gallbladder, the liver duct, and the common bile duct.

CONCLUSIONBased on the segmentation method of interactive volume rendering, the CT data of the arterioles supplying the extrahepatic bile duct can be extracted and segmented for 3D reconstruction to display the three-dimensional anatomical structures of the extrahepatic bile duct and its supplying arteries.

Bile Ducts, Extrahepatic ; anatomy & histology ; Hepatic Artery ; anatomy & histology ; Humans ; Imaging, Three-Dimensional ; Liver ; blood supply ; Models, Anatomic

Liver transplantation is the only solution for end-stage liver diseases. The common hepatic artery (CHA) arises from the coeliac trunk (CT), and the right (RHA) and left hepatic (LHA) arteries are its terminal branches. An abnormal arterial pattern would influence the surgical outcome. The anterior layer of the lesser omentum of a female cadaver was cleaned to identify the CHA, which was traced backwards for its origin and toward the porta hepatis for its terminal branches. In this case, the replaced RHA originated from the CT and ran posterior to the portal vein and the common bile duct. The replaced LHA arose from the left gastric artery. The CHA originated from the CT and branched out as the middle hepatic and gastroduodenal arteries. The replaced RHA and LHA with alteration in relation to the neighbouring structures is a complex and rare variant. Knowledge of this uncommon arterial anomaly is beneficial for hepatobiliary surgeons.
Cadaver ; Education, Medical ; Female ; Hepatic Artery ; anatomy & histology ; pathology ; Humans ; Liver ; blood supply ; surgery ; Models, Anatomic

OBJECTIVETo construct a three-dimensional (3D) liver model of Wuzhishan mini-pig for virtual liver surgeries.

METHODSThe biliary tree and hepatic arteries of Wuzhishan mini-pig were perfused with perchloroethylene and ethyl acetate along mixed with lead oxide, and the hepatic vein and portal vein were perfused with a mixture of dental base acrylic resin and lead oxide. The sectional images were acquired using a 64-slice spiral CT, and the 3D models of the portal vein, hepatic vein, biliary tree, hepatic arteries, and liver parenchyma were reconstructed using Mimics software; the resection image of the liver was also designed. The intrahepatic vascular cast was prepared by corroding the soft tissue with hydrochloric acid.

RESULTS AND CONCLUSIONThe intrahepatic vascular cast obtained fully retained the vascular architecture and displayed the fifth- and sixth-level branches of the hepatic vein and portal vein and the third- and fourth-level branches of the artery and bile duct. The 3D model of liver allowed stereoscopic and accurate display of the third- and fourth-level branches of the hepatic vein and portal vein and the second- and third-level branches of the artery and bile duct. The 3D model showed fewer branches but represented the structural distribution identical to the cast. The 3D model could clearly display the spatial relationship between the vasculature and the soft tissue in virtual resection of the liver tissues, and thus provides a useful model for training of laparoscopic liver resection.

Animals ; Bile Ducts ; Hepatic Artery ; Hepatic Veins ; Imaging, Three-Dimensional ; Liver ; anatomy & histology ; Models, Anatomic ; Portal Vein ; Swine ; Swine, Miniature ; Tomography, Spiral Computed

OBJECTIVETo study the value of three-dimensional (3D) visualization, 3D printing and 3D laparoscopy (3-3D techniques) in the diagnosis and surgical treatment of hepatic tumors.

METHODSFrom November 2013 to January 2015, 22 patients with hepatic tumors admitted in our department underwent abdominal thin-slice CT scanning. The CT images were imported into Medical Image three Dimensional Visualization System (MI-3DVS) for 3D reconstruction. Standard Template Library (STL) files were exported for 3D printing. The hepatic vascular classification and predicted liver resection were performed with the aid of MI-3DVS system. The 3D models were then printed and virtual liver resections were executed accordingly. Based on these preoperative surgical planning data, we performed anatomical hepatectomy using 3D laparoscopy, and the intraoperative blood loss, volume of virtual and actual liver resection and postoperative hospital stay were recorded.

RESULTSAccording to Michels's classifications, 19 patients had type I, 2 had type II, and 1 had type VIII hepatic arteries; based on Cheng classifications, the portal vein was classified into type I in 17 cases, type II in 2 cases, and type III in 2 cases, and type IV in 1 case; according to Nakamura classifications, the right hemiliver hepatic vein was classified into type I in 10 cases, type II in 7 cases, and type III in 5 cases. In the virtual operations, the mean volume of liver resected was 490 ± 228 ml and the mean remnant liver volume was 885 ± 139 ml, with a remnant to functional liver volume ratio of (71 ± 11)%. The 3D printed models stereoscopically displayed the location of the liver tumors and adjacent liver vascular structure clearly. Laparoscopic hepatectomy was performed successfully in 20 patients guided by the 3-3D techniques, and the other 2 patients required convertion to open hepatectomy. The mean operation time was 186 ± 92 min, the intraoperative blood loss was 284 ± 286 ml, the mean actual liver resection volume was 491 ± 192 ml, and the mean postoperative hospital stay of the patients was 8.6 ± 3.7 days.

CONCLUSIONSThe 3-3D technique can facilitate the evaluation of preoperative risk and critical anatomical structures and navigate the surgical procedure in real time in anatomical hepatectomy for hepatic tumors.

Blood Loss, Surgical ; Hepatectomy ; Hepatic Artery ; anatomy & histology ; Hepatic Veins ; anatomy & histology ; Humans ; Imaging, Three-Dimensional ; Laparoscopy ; Liver Neoplasms ; diagnosis ; surgery ; Portal Vein ; Printing, Three-Dimensional ; Tomography, X-Ray Computed

INTRODUCTIONKnowledge of anatomical variations of the great vessels of the abdomen, including the coeliac trunk, is important for clinicians planning surgical intervention and radiological imaging. The present study aimed to record the prevalence of variations in the vascular pattern of branches of the coeliac trunk in cadavers.

METHODSA total of 50 properly embalmed and formalin-fixed cadavers from the Indian population were selected for the study. Dissection included surgical incision, followed by mobilisation of the anatomical viscera, to observe and record the branching pattern of the coeliac trunk.

RESULTSThe left gastric, common hepatic and splenic arteries were found to arise from the coeliac trunk in 86% of cadavers. In 76% of cadavers, the origin of the gastric artery was proximal to the bifurcation of the coeliac trunk into the common hepatic and splenic arteries. In one case, all three branches arose directly from the abdominal aorta, and the origin of the splenic artery was 1 cm distal to the origin of the left gastric and common hepatic arteries. In another case, the common hepatic and left gastric arteries arose from the coeliac trunk, and the origin of the splenic artery was 1.5 cm distal to the abdominal aorta.

CONCLUSIONVessel ligation and anastomosis are important in surgical procedures like liver transplantation, and background knowledge of the different vascular patterns of branches of the coeliac trunk is vital. The findings of our study could help to minimise complications related to abdominal surgery, including bleeding and necrosis, and facilitate better and more accurate radiological interpretations.

Adult ; Aged ; Anastomosis, Surgical ; Aorta, Abdominal ; anatomy & histology ; surgery ; Cadaver ; Celiac Artery ; anatomy & histology ; surgery ; Female ; Hepatic Artery ; anatomy & histology ; surgery ; Humans ; Liver ; blood supply ; surgery ; Liver Transplantation ; methods ; Male ; Middle Aged ; Splenic Artery ; anatomy & histology ; surgery ; Vascular Surgical Procedures ; methods ; Young Adult

OBJECTIVETo investigate the variations type of hepatic artery and discuss the method of how to protect hepatic artery from injury during the quick harvest of the donor liver.

METHODSA retrospective review of the variations of hepatic arteries of the donor livers and the course of excision and reconstruction of 200 donor livers was performed, and the aberrance and reconstruction method of hepatic arteries were summarized.

RESULTS37 out of 200 hepatic arteries varied and 2 patients suffered biliary complications because of improper preservation of aberrant hepatic arteries.

CONCLUSIONSMost aberrant liver arteries come from superior mesenteric artery or left gastric artery. Proper quick harvest of multiple organs is the basis of the integrity of hepatic arteries, and all the aberrance must be reconstructed.

Female ; Hepatic Artery ; anatomy & histology ; surgery ; Humans ; Kidney Transplantation ; Liver Transplantation ; methods ; Male ; Retrospective Studies ; Tissue and Organ Harvesting ; methods ; Transplantation, Homologous

The shortage of organ donors has stimulated interest in the possibility of using animal organs for transplantation into humans. In addition, pigs are now considered to be the most likely source animals for human xenotransplantation because of their advantages over non-human primates. However, the appropriate standard values for estimations of the liver of micropigs have not been established. The determination of standard values for the micropig liver using multi-detector row computed tomography (MDCT) would help to select a suitable donor for an individual patient, determine the condition of the liver of the micropigs and help predict patient prognosis. Therefore, we determined the standard values for the livers of micropigs using MDCT. The liver parenchyma showed homogenous enhancement and had no space-occupying lesions. The total and right lobe volumes of the liver were 698.57 +/- 47.81 ml and 420.14 +/- 26.70 ml, which are 51.74% and 49.35% of the human liver volume, respectively. In micropigs, the percentage of liver volume to body weight was approximately 2.05%. The diameters of the common hepatic artery and proper hepatic artery were 6.24 +/- 0.20 mm and 4.68 +/- 0.13 mm, respectively. The hepatic vascular system of the micropigs was similar to that of humans, except for the variation in the length of the proper hepatic artery. In addition, the diameter of the portal vein was 11.27 +/- 0.38 mm. In conclusion, imaging evaluation using the MDCT was a reliable method for liver evaluation and its vascular anatomy for xenotransplantation using micropigs.
Animals ; Female ; Hepatic Artery/anatomy & histology ; Humans ; Imaging, Three-Dimensional/methods/*veterinary ; Liver/*anatomy & histology/blood supply ; Liver Transplantation/*methods ; Living Donors ; Male ; Portal Vein/anatomy & histology ; Swine ; Swine, Miniature/*anatomy & histology ; Tomography, X-Ray Computed/methods/*veterinary ; Transplantation, Heterologous/*methods