Usefulness of intraoperative fluorescence imaging to evaluate local anatomy in hepatobiliary surgery

BACKGROUND/PURPOSE: One of the major complications encountered in hepatobiliary surgery is the incidence of bile duct and blood vessel injuries. It is sometimes difficult during surgery to evaluate the local anatomy corresponding to hepatic arteries and bile ducts. We investigated the potential utility of an infrared camera system as a tool for evaluating local anatomy during hepatobiliary surgery. METHODS: An infrared camera system was used to detect indocyanine green fluorescence in vitro. We also employed this system for the intraoperative fluorescence imaging of the arteries and biliary system in a pig. Further, we evaluated blood flow in the hepatic artery, portal vein, and liver parenchyma during a human liver transplant and we investigated local anatomy in patients undergoing cholecystectomy. RESULTS: Fluorescence confirmed that indocyanine green was distributed in serum and bile. In the pig study, we confirmed the fluorescence of the biliary system for more than 1 h. In the liver transplant recipient, blood flow in the hepatic artery and portal vein was confirmed around the anastomosis. In most of the patients undergoing cholecystectomy, fluorescence was observed in the gallbladder, cystic and common bile ducts, and hepatic and cystic arteries. CONCLUSIONS: Intraoperative fluorescence imaging in hepatobiliary surgery facilitates better understanding of the anatomy of arteries, the portal vein, and bile ducts.     

Rare Portal Venous Anomaly in a Living Liver Donor: A Case Report

Knowledge of the anatomy of the portal system is essential for safe liver resection. We report a very rare anatomic anomaly of the portal system in a living liver donor. A 24-year-old female living liver donor was found to have anomalies of the portal system on preoperative contrast-enhanced computed tomography. The ventral branch of the right anterior segment arose from the transverse portion of the left portal vein. The gallbladder and round ligament were positioned normally. Intraoperative cholangiography for evaluation of biliary anatomy revealed very low confluence of the right and left hepatic ducts. All the bile ducts from the right lobe merged into the right hepatic duct. A right lobe graft was performed, including the ventral area of the right anterior segment. The portal branch of the ventral area of the right anterior segment could be transected extrahepatically. In the recipient operation, each of the right main portal branches, including the right posterior segment branch and the dorsal branch of the right anterior segment, and the ventral branch of the right anterior segment, were anastomosed to the right and left branches of the portal vein, respectively, of the recipient. The transected right hepatic duct of the graft was anastomosed with the recipient's common hepatic duct. Sixteen years after the liver transplant, the recipient continues to do well and has good portal flow.     

Surgical anatomy of the left lateral segment as applied to living-donor and split-liver transplantation: a clinicopathologic study

OBJECTIVE: To evaluate intrahepatic vascular and biliary anatomy of the left lateral segment (LLS) as applied to living-donor and split-liver transplantation. SUMMARY BACKGROUND DATA: Living-donor and split-liver transplantation are innovative surgical techniques that have expanded the donor pool. Fundamental to the application of these techniques is an understanding of intrahepatic vascular and biliary anatomy. METHODS: Pathologic data obtained from cadaveric liver corrosion casts and liver dissections were clinically correlated with the anatomical findings obtained during split-liver, living-donor, and reduced-liver transplants. RESULTS: The anatomical relation of the left bile duct system with respect to the left portal venous system was constant, with the left bile duct superior to the extrahepatic transverse portion of the left portal vein. Four specific patterns of left biliary anatomy and three patterns of left hepatic venous drainage were identified and described. CONCLUSIONS: Although highly variable, the biliary and hepatic venous anatomy of the LLS can be broadly categorized into distinct patterns. The identification of the LLS duct origin lateral to the umbilical fissure in segment 4 in 50% of cast specimens is significant in the performance of split-liver and living-donor transplantation, because dissection of the graft pedicle at the level of the round ligament will result in separate ducts from segments 2 and 3 in most patients, with the further possibility of an anterior segment 4 duct. A connective tissue bile duct plate, which can be clinically identified, is described to guide dissection of the segment 2 and 3 biliary radicles.     

Surgical anatomy of the bile ducts at the hepatic hilum as applied to living donor liver transplantation

OBJECTIVE: To evaluate anatomic variations of the biliary tree as applied to living donor liver transplantation. SUMMARY BACKGROUND DATA: Anatomic variability is the rule rather than the exception in liver surgery. However, few studies have focused on the anatomic variations of the biliary tree in living donor liver transplantation in relation to biliary reconstruction. METHODS: From November 1992 to June 2002, 165 patients underwent major hepatectomy with extrahepatic bile duct resection; right-sided hepatectomy in 110 patients and left-sided hepatectomy in 55. Confluence patterns of the intrahepatic bile ducts at the hepatic hilum in the surgical specimens were studied. RESULTS: Confluence patterns of the right intrahepatic bile ducts were classified into 7 types. The right hepatic duct was absent in 4 of the 7 types and in 29 (26%) of the 110 livers. Confluence patterns of the left intrahepatic bile ducts were classified into 4 types. The left hepatic duct was absent in 1 of the 4 types and in 1 (2%) of the 55 livers. CONCLUSIONS: In harvesting the right liver from a donor without a right hepatic duct, 2 or more bile duct stumps will be present in the plane of transection in the graft in 3 patterns based on their relation to the portal vein. Accurate knowledge of the variations in the hepatic confluence is essential for successful living donor liver transplantation.     

Liver transplant donor candidates: associations between vascular and biliary anatomic variants.

Our objective was to investigate the coexistence of vascular and biliary anatomic variants, the latter of which are known to increase the risk of biliary complications in living liver donor transplantation. A total of 108 consecutive liver donor candidates were examined by magnetic resonance (MR) imaging that included 2 MR cholangiography methods, T2-weighted MR cholangiography and mangofodipir-enhanced T1-weighted three-dimensional (3D) MR cholangiography, as well as gadolinium-enhanced MR angiography and venography of the liver. Images were interpreted by at least 2 investigators in consensus for definition of hepatic arterial, portal venous, and biliary anatomy. A subset of 51 subjects underwent laparotomy for right hepatectomy. Of the 108 subjects examined, 50 (46%) demonstrated normal hepatic artery, portal vein, and biliary anatomy. Variants of the hepatic artery were found in 27 of 108 (25%) subjects, of the portal vein in 12 of 108 (11%) subjects, and of the bile ducts in 30 of 108 (28%) subjects. Of the 27 subjects with hepatic arterial variants, 8 (30%) also had variant biliary anatomy. The association between hepatic arterial variants and biliary variants was not statistically significant (P >.5). However, of the 12 subjects with portal vein variants, 7 (58%) had biliary variants, and in 6 of 7 cases, the right posterior hepatic duct was anomalous. By chi-square analysis, the association between portal venous and biliary variants was significant (P =.012). In conclusion, over half of subjects with portal vein variants were found to have anomalous biliary anatomy, which always involved the hepatic ducts of the right lobe. The association between portal venous and biliary variants is statistically significant, while there is no significant association between hepatic arterial and biliary variants.     

Anatomic variations in right liver living donors

BACKGROUND: Anatomic knowledge is crucial in right liver living donor transplantation. STUDY DESIGN: We reviewed radiologic and surgical findings in right liver donors. Arterial and portal anatomy was assessed in 96 donors, biliary anatomy in 77, and hepatic venous anatomy in 65. RESULTS: Portal vein (PV): 86.4% had classic anatomy; 6.3% had a trifurcated PV; 7.3% had a right anterior PV taken off the left PV. Hepatic artery (HA): 70.8% had classic anatomy; 12.5% had a left HA arising from the left gastric artery; 13.5% had a right HA arising from the superior mesenteric artery; 2.1% had a double replaced left HA and right HA; and in 1.0% the common HA arose from the superior mesenteric artery. Biliary tree: 55.8% had normal anatomy; 14.3% had a trifurcated biliary anatomy; in 5.2% the right anterior bile duct and in 15.6% the right posterior bile duct opened into the left bile duct; in 2.6% the right anterior and in 6.5% the right posterior ducts opened into the common bile duct. Hepatic veins: S5 and S8 accessory hepatic veins had incidences of 43% and 49%, respectively. The incidence of S6 or S7 short hepatic vein was 38%. CONCLUSIONS: Anatomic variations are common but do not contraindicate donation; surgeons should be prepared to recognize and manage them.     

Preliminary study of the anatomy of the venous drainage of the intrahepatic and extrahepatic bile ducts and its relevance to the practice of hepatobiliary surgery

Background : Although there have been many studies of the arterial supply of the biliary system, attempts to study the corresponding venous drainage have been few and all have been incomplete. The purpose of the present investigation is to describe the anatomy of the venous drainage of both the intrahepatic and extrahepatic bile ducts and to determine its relevance to hepatobiliary surgery. Methods : The intrahepatic and extrahepatic venous drainage of the bile ducts was investigated in seven specimens by injecting a solution of 10% gelatin coloured with Alcian blue into the portal vein or the superior mesenteric vein to outline the venous drainage. The specimens were dissected under loop magnification and representative drawings were obtained. Results : The surface of the intrahepatic and extrahepatic bile ducts was covered by a fine venous plexus. On the surface of the supraduodenal common hepatic duct and common bile duct the venous plexus drained laterally into marginal veins, usually two in number and known as the 3 o’clock and 9 o’clock marginal veins. Inferiorly the marginal veins and the venous plexus communicated with the pancreaticoduodenal venous plexus, which in its turn drained into the posterosuperior pancreaticoduodenal vein, a branch of the superior mesenteric vein. Superiorly the marginal veins divided into a number of branches. Some branches followed the left and right hepatic ducts into the liver, communicating with the venous plexus and the adjacent branches of the portal vein. Other branches of variable size entered either segment IV or the caudate lobe or process via the hilar venous plexus. A most important finding was that even after dividing the bile duct and all communicating veins at the upper border of the duodenum, the venous plexus and the marginal veins filled normally to the level of transection. This occurred almost certainly by retrograde filling from above. Conclusion : The satisfactory results of end‐to‐end anastomosis in whole liver transplantation depends partly on the presence of adequate venous drainage. This has been amply demonstrated by the injection studies. This would indicate that the poor results of end‐to‐end repair of the bile duct after surgical trauma results from other factors such as poor technique, devascularization of the cut ends due to trauma, and carrying out the anastomosis under tension. After resection of the hilum for cholangiocarcinoma the venous drainage of the left and right hepatic ducts and their branches depends mainly on the communications between the venous plexus on the ducts and the adjacent branches of the portal vein, even at a lobular or sinusoidal level. The satisfactory results obtained after anastomosis of the left and right hepatic ducts or their branches to a Roux loop of jejunum attest to this. This applies also to the transplantation of segments II and III in paediatric patients from related adult donors and in patients receiving split liver transplants. Finally, the venous drainage at the bifurcation of the common hepatic duct has been shown to enter the caudate lobe and segment IV directly. This suggests that a hilar cholangiocarcinoma may metastasize to these segments, and perhaps partly explain the significantly better long‐term results when the caudate lobe and segment IV are resected en bloc with the cholangiocarcinoma as part of modern radical surgery for this condition.     

Bile duct varices

The diagnosis of biliary duct varices and portal vein occlusion should be considered when nodular or notched defects in the wall of the biliary duct system are shown by cholangiography or when pedunculated vascular structures in the bile ducts are seen at surgery. We present two cases of common hepatic and common bile duct varices due to portal vein occlusion.     

64排螺旋CT扫描数据的肝脏及腹腔血管三维重建的研究

目的 探讨利用64排螺旋CT扫描数据进行肝脏及其内部管道和腹腔血管的计算机辅助三维重建的准确性及临床意义.方法 利用64排螺旋CT薄层扫描正常人肝脏二维图像数据集,采用自主研发的医学图像处理系统对二维图像数据进行肝脏及其肝内管道、腹腔血管系统三维可视化重建,并对重建肝脏模型的体积与肝脏实际体积以及重建门静脉与64排螺旋CT后处理工作站采用容积再现法重建的门静脉进行对比研究.结果 肝动脉、门静脉和肝静脉系统三维效果逼真,立体感强,可任意角度旋转、观察;能够显示肝内各主要管道系统的空间位置关系,并准确地反映肝脏实际体积及肝内管道系统的真实情况.通过调节肝脏的透明度可同时显示肝脏和肝内动静脉、门静脉分支和腹腔动脉系统.计算机重建后的门静脉与螺旋CT后处理工作站容积再现法重建的门静脉完全一致.结论 计算机辅助的三维肝脏及其管道和腹腔血管系统能准确反映人体的真实结构,为肝脏的虚拟手术设计提供了可靠和真实的虚拟器官和血管系统.     

Single imaging modality evaluation of living donors in liver transplantation: magnetic resonance imaging.

BACKGROUND: Liver graft size, anatomy of the bile duct and the vascular inflow and outflow are essential for living related liver transplantation (LRLT). Preoperative delineation of those variations that would change the operative procedure to achieve a successful result especially in an emergency condition. PURPOSE: Our aim was to develop a rapid and noninvasive imaging diagnostic method for the detection of anatomical variants that is mandatory for a safe operation when selecting potential liver transplant living donors. We used a different magnetic resonance (MR) imaging technique, which enabled to us to exploit the anatomical landmark of the liver, signal enhancement of blood flow in the abdomen, and the intrahepatic biliary routes inside the liver. Then, with the help of Advantage Window workstation reconstruction, the reconstructed single vascular or biliary systems were displaced in a three-dimensional fashion and the whole examination finished within 30 min. METHODS: Modification of the standard MR technique was performed on a superconductive 1.5T whole body image scanner, MR arteriogaphy, venography, and cholangiography with three-dimensional reconstruction in evaluating the anatomy of the hepatic arteries, hepatic veins, portal venous system, bile ducts, and liver size in potential liver transplant living donors. These anatomical structures were compared with traditional imaging methods. RESULTS: In all 38 cases, as well as delineation of the portal vein detail to the segmental level was satisfactorily obtained in this MR study. The images were well displayed in a three-dimensional fashion, which had good correlation with images from traditional imaging modalities and operative findings. In 86.8% cases, the MR arteriography was well matched with the celiac angiography. Of those 17 operative cases, estimation of liver volume was well correlated with the liver graft within 3.9-12.5% variation. In the major hepatic vein, we obtained 100% accuracy and 88.2% in the minor branches. Of 12 donors received intraoperative cholangiography during liver donation, good correlation of biliary anatomy was achieved. One donor was excluded from graft donation due to the complicated arterial supply to the left liver. According to the anatomical variation, surgical procedures in graft harvesting and anastomosis were readjusted and no major complications were found in those donors and all recipients survived after liver transplantation. CONCLUSION: MR volumetry, venography, angiography, and cholangiography with three-dimensional reconstruction is sufficient for all major imaging evaluation. It may replace the traditional conventional catheter angiography, computed tomography, sonography and endoscopic retrograde cholangiography as a single investigation in the evaluation of the potential liver transplant donors. Angiography is only valuable in suboptimal cases and intraoperative cholangiography is only performed in biliary ductile variants.     

Hilar cholangiocarcinoma—surgical anatomy and curative resection

We have studied the surgical anatomy of the intrahepatic bile duct, hepatic hilus, and caudate lobe based on intraoperative findings and selective cholangiography of surgical patients and resected specimens, and have established the cholangiographic anatomy of the intrahepatic subsegmental bile duct. Thorough knowledge of the three-dimensional anatomy of the subsegmental bile duct, hepatic hilus, and caudate lobe is indispensable for curative surgery of hilar cholangiocarcinoma. We designed and actually performed 15 kinds of hepatic segmentectomies with caudate lobectomy and extrahepatic bile buct resection in 100 consecutive patients, with curative resection being possible in 82 patients. Postoperative survival after curative resection of hilar cholangiocarcinoma was better than expected, and the 5-year survival rates for all 82 patients with curative resection and for 55 patients with curative surgery without portal vein resection were 31% and 43%, respectively. Hepatic segmentectomy with caudate lobectomy and extrahepatic bile duct resection should be designed not only in accordance with the preoperative diagnosis of tumor extension into the intrahepatic bile ducts but also so that curative surgery for advanced hilar cholangiocarcinoma can be performed.     

Infraportal bile duct of the caudate lobe: a troublesome anatomic variation in right-sided hepatectomy for perihilar cholangiocarcinoma

OBJECTIVE: We present our experiences with infraportal bile duct of the caudate lobe (B1) and discuss surgical implications of this rare variation. SUMMARY BACKGROUND DATA: Although various authors have investigated biliary anatomy at the hepatic hilum, an infraportal B1 (joining the hepatic duct caudally to the transverse portion of the left portal vein) has not been reported. METHODS: Between January 1981 and December 2005, 334 patients underwent hepatectomy combined with caudate lobectomy for perihilar cholangiocarcinoma. Four of them (1.2%) had infraportal B1 and were investigated clinicoanatomically. RESULTS: All infraportal B1 were B1l, draining Spiegel's lobe; no infraportal B1r (draining the paracaval portion) or B1c ducts (draining the caudate process) were found. The infraportal B1l joined the common hepatic duct or the left hepatic duct. Three patients underwent right trisectionectomy with caudate lobectomy; for one, in whom preoperative diagnosis was possible, combined portal vein resection and reconstruction were performed before caudate lobectomy to resect the caudate lobe en bloc without division of infraportal B1. For the other 2 patients, the infraportal B1 was divided to preserve the portal vein, and then the caudate lobe was resected en bloc. The fourth patient underwent right hepatectomy with right caudate lobectomy; the cut end of the infraportal B1 showed no cancer by frozen section, so the bile duct was ligated and divided to preserve the left caudate lobe. CONCLUSION: Infraportal B1 can cause difficulties in performing right-sided hepatectomy with caudate lobectomy or harvesting the left side of the liver with the left caudate lobe for transplantation. Hepatobiliary and transplant surgeons should carefully evaluate biliary anatomy at the hepatic hilum, keeping this variation in mind.     

Anatomy of the hepatic hilar area: the plate system

To surgically manage hilar bile duct carcinoma successfully, it is important to be familiar with the principal anatomical variations of the biliary and vascular components of the plate system in the hepatic hilar area, because all the variations in the bile ducts and vessels occur in the plate system. The plate system consists of bile ducts and blood vessels surrounded by a sheath. There are three plates in the hilar area: the hilar plate, the cystic plate, and the umbilical plate. The bile duct and blood vessel branches penetrate the plate system and form Glisson's capsule in all segments of the liver, except for the medial segment. The right hepatic duct is usually (in 53%–72% of individuals) formed by the union of the anterior segmental duct and the posterior segmental duct in the hilar area. However, three other variations have been found in which these segmental ducts do not form the right hepatic duct. Few anatomical variations have been identified in the left hepatic duct, but confusion arises because of the variations in the medial segment ducts (B4) which join the left hepatic duct at different sites. In 35.5% of individuals they join the hepatic duct in the vicinity of the hilar confluence (type I B4 anatomy), and in 64.5% of individuals they join the left hepatic duct some distance away from the confluence (type II B4 anatomy). Because B4 is very close to the hilar confluence in type I, hilar bile duct carcinoma can easily invade B4 and, for that reason, for curative resection of hilar bile duct carcinoma, resection of S4a (the inferior part of the medial segment) should be considered along with the resection of extrahepatic bile duct and caudate lobe. Variations in the portal vein and hepatic artery are found in 16%–26% and 31%–33% of individuals, respectively. Because a considerable number of anatomical variations in the bile ducts and vessels persist in the hilar area, and the reported proportions of the different variations vary, it is necessary to have a good knowledge of the plate system and the variations in the bile ducts and blood vessels in the hilar area to perform safe and curative surgery for hilar bile duct carcinoma. Received: June 3, 2000 / Accepted: July 20, 2000     

Surgical anatomy of the hepatic hilar area

It is important to understand the main variations of the biliary and vascular elements inside the plate system for hilar bile duct carcinoma because all variations of these elements occur in this plate system. The plate system consists of the hilar plate, cystic plate, and umbilical plate which cover the extrahepatic vascular system and are fused with the hepatoduodenal ligament. The bile duct and vascular system that penetrate the plate system form Glisson's capsule in the liver, but the caudate branch and the medial segmental branch are exceptions. The bile duct and hepatic artery accompanying the plate system can be exfoliated from the portal vein with numerous lymph ducts and nerves. The bile ducts in the right hepatic lobe are classified into 4 types, and the standard type is present in 53-72% of cases. In the left bile duct, the medial segmental bile duct is connected in the vicinity of the hilar area in 35.5% of cases, and these cases should be treated the same as the caudate lobe in hilar bile duct carcinoma. Generally, there is little main variation of the portal vein (16-26%), but more variation in the hepatic artery (31-33%). During surgery for hilar bile duct carcinoma, it is important to observe the plate system and the many variations of the bile duct and vascular system.     

The surgical anatomy of the porta hepatis

The anatomy of the porta hepatis, with particular emphasis on the hilar relationships of the bile ducts to the portal vein, has been investigated in 30 fresh cadaver specimens. Meticulous dissertion delineated three major types of anatomic variations. Type A, the most common, revealed a left hepatic duct which, when it branched, sent its largest and major tributary beneath the portal vein to the lateral segment of the left lobe. Type B was characterized by the major division of the left hepatic duct running parallel to the portal vein into the hepatic sulcus. In Type C the divisions were of equal caliber. These observations should assist the surgeon in dissections of the hepatic ducts above their confluence.     

Extended liver resection for hilar cholangiocarcinoma

Liver resection for hilar cholangiocarcinoma should be designed for individual patients, based on both precise diagnosis of cancer extent and accurate evaluation of hepatic functional reserve. Therefore we have developed various types of hepatic segmentectomy. Combined caudate lobectomy is essential in every patient with separated hepatic confluence. So-called extensive hepatectomy, resection of 50% or more of the hepatic mass, includes right lobectomy and right or left trisegmentectomy. Right lobectomy with caudate lobectomy is indicated when the progression of cancer is predominant in the right anterior and posterior segmental bile ducts. The plane of liver transection is along the Cantlie line, and the left hepatic duct is divided just at the right side of the umbilical portion of the left portal vein. Right trisegmentectomy with caudate lobectomy is performed in carcinoma which involves the right hepatic ducts in continuity with the left medial segmental bile duct. The umbilical portion of the left portal vein is freed from the umbilical plate by dividing the small portal branches arising from the cranial side of the umbilical portion. Then the left lateral segmental bile ducts are exposed and divided at the left side of the umbilical portion of the left portal vein. Left trisegmentectomy with caudate lobectomy is suitable for carcinoma which involves the left intrahepatic bile duct in continuity with the right anterior segmental bile duct. Liver transection is advanced along the right portal fissure. The right posterior segmental bile duct is usually divided distal to the confluence of the inferior and superior branches.     

肝内胆管手术入路的解剖及临床应用

目的 探讨显露肝内叶、段胆管的手术入路。方法 研究30例成人肝脏标本的肝内叶、段胆管与血管的毗邻关系。结果 左右肝管均位于肝脏脏面门静脉门静脉左右干的前上缘,左内叶、右前叶胆管位于相应门静脉的前内侧。右后叶胆管位于门静脉右面支或右前叶下段支脏面深侧者占73％（22／30）;位于门静脉右后支脏面深侧或后上缘者占80％（24／30）。左外叶胆管位于门静脉矢状部脏面深侧者占93％（28／30）。选择经肝的脏面显露肝门、左右肝管,经肝的膈面显露肝内叶、段胆管相结合的手术入路,治疗复杂性肝内胆管结石并狭窄患者38例,均获成功。结论 经肝的脏面与膈面相结合的手术入路,比较容易显露和切开肝内胆管及其狭窄段、便于取出结石。     

三维可视化技术在外科诊治Mirizzi综合征中的应用

目的 应用三维可视化技术，探讨三维成像对Mirizzi综合征外科诊治的指导意义。方法 选取嵊州市人民医院2015年9月1日至2019年10月31日7例Mirizzi综合征患者的原始腹部增强CT扫描数据，导入Mimics软件，对胆管、胆囊、结石、门静脉、肝静脉、肝固有动脉、左右肝动脉、肝脏及胰腺等组织器官进行三维重建，并进行术前规划。结果 7例Mirizzi综合征患者均完成三维重建和术前规划，并顺利进行手术治疗。重建的三维图像清晰逼真，立体感强，可从任意角度、任意方位观察周围各组织器官的解剖关系。结论 三维可视化技术可在术前了解胆道情况，评估胆管缺损，模拟胆管成形，避免损伤血管，规划手术路径，指导手术操作，在Mirizzi综合征的外科诊治中具有较高的临床实用价值。