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.     

The paracaval segments of the liver

Two segments constitute thedorsal sector: I to the left and in front of the inferior vena cava, and IX in front and to the right of the cava; they are united inferiorly by the caudate process. Segment I includes the caudate lobe, and segment IX is incorporated in the posterior surface of the right liver. Small dorsal pedicles, which are quite numerous, arise from the posterior margin of the main portal elements, and ascend upward. Segment I receives twigs from the left or right livers, many from the right lateral pedicle (67 biliary branches enter the right lateral duct, the unique duct in three cases). Segment IX consists of three subsegments. IXb lies under the interval between the middle and right superior hepatic veins, in 40% of the cases examined the veins come from the left portal vein or the bifurcation, in 6 cases the ducts enter the left hepatic duct, in 40 cases the branches extend higher than the plane of the main hepatic veins, in 18 cases reaching the upper surface of the liver. IXc is under the right hepatic vein, and IXd is to the right of a vertical plane passing by the right superior vein. Hepatic veins, enter the cava directly, sometimes the middle or the left hepatic veins.     

Anatomy of the liver

The liver is the largest organ in the body. Its gross anatomical divisions comprise the right, left, caudate and quadrate lobes, which do not correspond with its functional division into eight hepatic segments, each with their own blood supply and biliary drainage. The porta hepatis transmits the hepatic artery, portal vein and right and left hepatic ducts (the portal triad), together with lymphatic and autonomic nerves. The venous drainage of the liver, directly into the inferior vena cava, comprises the right, left and middle hepatic veins, together with the small accessory hepatic veins.     

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.     

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.     

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目的：分析10例活体肝移植术中的血管变异，总结其外科处理经验，进一步提高手术成功率，减少并发症。方法：2001年1月至12月，行活体肝移植10例，其中左半肝8例，左外叶1例，右半肝1例，供肝者均为其母，经术中B超及胆管造影以确定肝切线。供体单支肝动脉分支与受体肝动脉吻合，两支肝动脉分别与受体肝左、右动脉吻合。门静脉分支与受体门静脉主干吻合。供体肝静脉与受体下腔静脉行端侧吻合。胆管重建均采用肝管分支与受体胆总管端端吻合，置T管引流。结果：10例活体肝移植，1例因肝动脉血栓形成，术后5天需次肝移植；1例发生排斥；其余8例均康复出院，5例已上学。结论：活体肝移植术中血管重建技术是其重要环节，术前和术中了解供受体解剖变异并正确处理，可减少术后血管和胆道的并发症。     

Maintenance of the celiac trunk with the left-sided liver allograft for in situ split-liver transplantation

BACKGROUND: It has been shown that in situ split-liver transplantation (SLT) expands the cadaveric donor pool, decreases recipient waiting time, and decreases pretransplant morbidity. However, the technique as previously described requires a microvascular left hepatic artery anastomosis. In an attempt to decrease the incidence of hepatic artery thrombosis and to increase collaboration among transplant teams, in the current report, we describe a modification of the in situ SLT technique that maintains the celiac trunk with the left-sided liver allograft. METHODS: Twelve in situ split-liver procurements resulted in 24 segmental liver allografts; 11 right trisegments, 11 left lateral segments, 1 right lobe, and 1 left lobe. The common bile duct and main portal vein were maintained with the right-sided liver allograft in all cases. The right hepatic artery was divided, and the celiac trunk was maintained with the left-sided liver allograft in nine cases. In one case the left hepatic artery was divided and the celiac trunk was maintained with the right-sided allograft. Two of the 12 donors had a completely replaced left hepatic artery originating from the left gastric artery, which was divided at its origin from the celiac trunk. When the celiac trunk was maintained with the left-sided allografts, arterial reconstruction of the right-sided allograft was performed with an external iliac arterial interposition graft. Nineteen of the 24 split-liver allografts were transplanted at our center. The remaining five liver allografts were shared with regional liver transplant centers. RESULTS: In this series, 1-year actuarial patient and allograft survival rates are 100% and 96%, respectively. Hepatic artery thrombosis (HAT) did not occur in any patient receiving a left-sided split allograft in which the celiac trunk or left gastric artery was maintained; in addition, HAT did not occur in any of the right-sided allografts. HAT did occur immediately after transplantation in the one patient who was transplanted with a left lateral segment without the celiac trunk. This allograft was salvaged by early thrombectomy and interposition grafting. One patient required retransplantation, owing to portal vein thrombosis. Hepatic venous outflow obstruction did not occur in any of the patients. Two patients required reexploration in the posttransplant period because of arterial anastomotic site bleeding, and one of the left lateral segment allograft recipients had a cut-surface bile leak, which was managed nonoperatively. All of the patients are alive and well, including the five patients who received their transplants at other centers, with a median follow-up of 10 months (range, 1-27 months). CONCLUSIONS: In summary, our data demonstrate that maintaining the celiac trunk with the left-sided allograft in SLT provides excellent early survival results with low complication rates. This technical modification obviates the need for a left hepatic artery microvascular anastomosis and should lower the incidence of hepatic artery thrombosis in the small-caliber left hepatic artery. We have also shown that this technique allows sharing among liver transplant centers without compromise in patient or allograft survival rates. It is hoped that this modification in SLT will increase the number of livers split, and will promote sharing among transplant centers to truly optimize the number of liver allografts available from the cadaveric pool.     

100例门静脉右后支的走行与分布观察

目的 根据肝内门静脉的走行分布,对门静脉的右后支进行分类,为影像学和肝脏外科提供资料.方法 采用100 例正常的活体肝移植供肝影像资料,研究右后叶肝内门静脉的走行和分布.结果 100 例资料中门脉的右后支呈弓型的34 例,呈两支型的27 例,呈三支型的9 例,存在右前支变异的30 例.结论 右后叶大约有30%在解剖学上不能完全分界,不符合Couinaud 的分段方法.     

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.     

肝海绵状血管瘤血供来源研究方法的讨论

目的 探讨肝海绵状血管瘤供血来源及研究方法的科学性。方法 对５例病人,经肝右动脉支结扎后,分别行门静脉连续造影和注入亚甲兰肝染色,观察门静脉与瘤体关系;对２２例肝动脉支插管造影;２例切除肝叶经静脉行血管铸型标本观察。结果 门静脉造影在门静脉期,门静脉支被瘤体稚移,造影剂不进入瘤内;肝实质期,瘤体区形成低密度区,亚甲兰染色,仅见肝实质染色,瘤区不被染色,界限分明,血管铸型标本见瘤体完全腐蚀脱落、无静     

The feasibility of in vivo resection of the left lobe of the liver and its use for transplantation

The anatomical possibility of resecting the left lobe of the liver (segments II and III) in living subjects and using it for transplantation was evaluated. A group of 60 cadaveric livers were dissected at autopsy. The vascular and biliary elements of the left lobe were isolated and the lobe was resected and evaluated for possible grafting. The left lobe was 12-28% (mean 19.4%) of the liver mass. An extrahepatic segment of the left hepatic vein was isolated in 95% of specimens. Arterial blood supply to the left lobe consisted of a single artery (92%) or two arteries (8%). A single portal vein segment to the left lobe (type I) was found in 35% livers. Portal vein branches originated from a common orifice (type II, 35%) or separately (type III, 30%) from the left portal vein, and in these instances, preparation of a portal segment necessitated partial section of the left portal vein wall. Biliary drainage was extrahepatic in 56 livers and consisted of a single duct (type I, 78%), or two ducts (type II, 15%). The resected left lobe was evaluated as satisfactory (single hepatic vein and artery, types I or II portal vein, type I bile duct) in 48% of cases, while a less-satisfactory lobe (type III portal vein or type II bile duct) was obtained in 33%. It was found anatomically difficult or impossible to resect the left lobe for possible transplantation in 11 (19%) liver specimens.     

Anatomicopathological Study of Vascular and Biliary Systems Using Cast Samples of Fasciola‐infected Bovine Livers

In 117 livers with fascioliasis, this study was focused on the number of Fasciola, the number and intrahepatic localization of affected hepatic ducts and bile ducts, and the degree of fibrosis in the hepatic segments and bile ducts. The degree of pathological changes in bile ducts caused by fascioliasis was classified into five levels. The site of Fasciola habitation was most often the hepatic ducts of the porta hepatis: it was the left hepatic duct in 101 livers and the right hepatic duct in 88 livers. Casts were prepared by infusing synthetic resin into the hepatic arterial, portal, hepatic venous and biliary systems of 15 bovine livers with fascioliasis and then examined. In the left lobe, quadrate lobe, and caudate process where atrophic fibrosis was noted, the bile ducts became rod‐shaped by losing branches, and the samples resembled dead branches of liver. Portal branches were thinned or completely terminated with marked fibrosis. Fine and irregular newly formed bile ducts not parallel with portal branches were observed in livers with markedly chronic fascioliasis. Distal portal branches in the right lobe, caudate lobe, and papillary process showed hypertrophic proliferative changes. The arterial system was generally well developed in thickened walls of bile ducts and formed vascular beds, and surrounded the bile ducts as tubes. In livers with severe fibrosis, capillaries were markedly developed and resembled glass cotton.     

Branching patterns of the intrahepatic portal vein and hepatic segments identified by percutaneous transhepatic portography

We studied branching of the intrahepatic portal vein and hepatic segment by percutaneous transhepatic portograms in 237 patients with liver, biliary tract, or pancreatic disease. At the hilum, the pattern was normal in 74% of the patients. In the others, branching of the right posterior branch was trifurcated or independent. Caudate branches usually ramified from first-order branches, but sometimes ramified from the right posterior branch. The left portal branch divided into a laterodorsal branch (second-order) and umbilical portion, from which the lateroventral branch (third-order) and several medial branches (fourth-order) arose. It seems to be better to divide the left lobe into anterior segment (supplied by medial and a lateroventral branch) and posterior segments (supplied by a laterodorsal branch) than into the lateral and medial segments. The right anterior branch of 27% of the patients was bifurcated. In the others, there were six other patterns, with four or five fourth-order branches arising from this branch. The anterior segment should be considered having not two subsegments, but four or five small subsegments. Small branches divided off from the main trunk of the right posterior branch. In resection for hepatoma, each such branch can be thought of as one small subsegmental branch.     

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。     

Designing Triple Adult Liver Grafts From an Ideal Deceased Liver

Splitting deceased donor livers and creating 3 grafts from a whole liver may be feasible and shorten the waiting time for organ donation in patients with high mortality rates. We hypothesized that it might be reasonable to procure 3 grafts for donation from one deceased donor liver by splitting the liver into left (segment II, III, IV), right anterior (segment V, VIII), and right posterior lobes (segment VI, VII) for liver transplantation according to the portal system trifurcated variations. We designed the right anterior branch with the main portal trunk and middle hepatic artery to become inflow of right anterior lobe, the left portal vein and left hepatic artery to become the inflow of left lobe and right posterior branch, and right hepatic artery to become the inflow of right posterior lobe. We retrospectively reviewed the volumetric computed tomography and magnetic resonance cholangiopancreatography of 153 liver donors. The hepatic and portal veins, hepatic artery, and biliary system were reorganized and classified. The volumetric proportions of the liver grafts were measured. Trifurcation of the portal vein variation was found in approximately 13.7% of portal systemic variations. The left lobe accounted for 29.18% of the total liver volume, the right anterior lobe, 35.22%, and the right posterior lobe, 35.6%. We validated this principle by dissecting the explanted liver and identified the triple grafts' weights, percentages, vessels, and biliary ducts system. The splitting of deceased donor livers into 3 split liver grafts for use in liver transplantation surgery can be clinically useful.     

Orthotopic transplantation of segmental hepatic graft from living donors in the dog. Technic and results

The authors describe new technic of non-auxiliary orthotopic transplantation of segmental liver harvested from living dogs. 32 dogs were utilized. In the donor dogs, the left medial and lateral lobes were mibilized. The left portal branch, left hepatic artery, left biliary branch and the left hepatic vein were dissected free. The segmental liver graft was perfused and cooled in-situ through the left portal vein. The recipient dogs underwent two steps total hepatectomy: First the segments I, II, III, IV and V were resected. The segments VI and VII were maintained as well as the right portal vein and the retro-hepatic inferior vena cava order to keep the splanchnic and caval flux and to avoid the spleno-cavo-jugular by-pass. The segmental liver graft was then transplanted in an orthotopic position. Termino-lateral hepatico-caval anastomosis and left porto-portal anastomosis as well as arterial and biliary reconstruction were executed. All the donors survived more than 30 days. Nine recipient dogs died during the first three post-operative days from hemorrhage (3 dogs), fibrinolysis (2 dogs), primary non function of the graft (2 dogs) and hepatic artery thrombosis (1 dog). Seven recipients survived more than 30 days.     

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.     

Anatomy of the liver

This article highlights the clinically and surgically relevant aspects of the anatomy of the liver. The liver is the largest organ in the human body. It can be divided functionally into eight hepatic segments, each with their own blood supply and bile outflow. Anatomically, however, it is divided into the right, left, caudate, and quadrate lobes. The porta hepatis, effectively the hilum of the liver, receives the hepatic artery, hepatic portal vein, right and left hepatic ducts, as well as lymphatic and autonomic nerves.     

In situ splitting of the cadaveric liver for two adult recipients.

BACKGROUND: Split-liver transplantation offers a unique opportunity to expand the existing donor pool. However, it has previously been stated that due to inadequate liver volume the advantages of split-liver transplantation would be lost when attempting to split the liver for two adult recipients. In this study, we sought to determine the safety, efficacy, and applicability of split-liver transplantation in select adult liver transplant recipients. METHODS: Liver allografts for eight adult recipients were procured by in situ splitting of four adult cadaveric livers. The donor ages were 17, 19, 22, and 25 years and weights were 72, 77, 78, and 87 kg, respectively. In situ splitting resulted in three right trisegmental grafts, one right lobe graft, one left lobe graft, and three left lateral segmental grafts. The median recipient age was 49 years (range 38-61 years), whereas the median recipient weight was 84 kg (range 78-98 kg) for the right-sided grafts and 52 kg (range 51-53 kg) for recipients of the left-sided grafts. The median graft-to-recipient body weight ratio for right trisegmental, right lobe, left lobe, and left lateral segmental grafts was 1.31%, 1.26%, 1.35%, and 0.70%, respectively. RESULTS: Overall patient and graft survival in this series is 100%. All prothrombin times were normalized within 4 days of transplantation. No evidence of ascites or prolonged hyperbilirubinemia was encountered in any right- or left-sided graft recipient. The incidence of hepatic artery, portal vein, and hepatic vein thrombosis is 0%, 0%, and 0%, respectively. Hepatic arterial anastomotic bleeding and a cut surface bile leak each occurred in one patient. Median United Network for Organ Sharing (UNOS) waiting time was 242 days (range 4-454 days) for the patients to which the donor liver was allocated. In contrast, the median waiting time for the four patients receiving the extra split-liver graft was reduced significantly to 37 days (range 21-101 days) (P<0.02). CONCLUSIONS: This study demonstrates that split-liver transplantation can expand the cadaveric donor liver pool available for select adult liver transplant recipients. When both the donor organ and the transplant recipient are chosen carefully, split-liver transplantation can be safely performed without a delay in allograft function, increase in technical complications, or compromise in graft or patient survival.     

Right trisegment portal vein embolization for biliary tract carcinoma: technique and clinical utility

BACKGROUND: Right portal vein embolization has become popular in preparation for right hepatic lobectomy. However, right trisegment portal vein embolization (R3PE) is not well established. METHODS: We performed R3PE in 15 patients with biliary tract carcinoma and 1 patient with primary sclerosing cholangitis. We used 2 types of 5.5 F triple-lumen balloon catheters to embolize portal branches of the right trisegment (the left medial, the right anterior, and the right posterior segments). RESULTS: R3PE was successful in all patients without any complications. The calculated volume of the right lobe significantly (P < .01) decreased from 650 +/- 161 cm3 before embolization to 585 +/- 143 cm3 after embolization; the volume of the left lateral segment significantly (P < .0005) increased from 240 +/- 58 cm3 to 361 +/- 66 cm3. The volume of the left medial segment was unchanged. The volume gain of the left lateral segment was larger in patients with R3PE than in those patients (n = 41) with right portal vein embolization (122 +/- 39 cm3 vs 66 +/- 35 cm3; P < .0001). Two of the 16 patients underwent only laparotomy because of peritoneal dissemination, and the remaining 14 patients underwent right hepatic trisegmentectomy with caudate lobectomy. In addition, portal vein resection was also performed in 5 patients, and pancreatoduodenectomy and right hemicolectomy was performed in 3 patients. One patient died of posthepatectomy liver failure 87 days after surgery, a mortality rate of 7.1% (1/14 patients). CONCLUSIONS: R3PE is more useful than standard right portal vein embolization in preparation for right hepatic trisegmentectomy and has the potential to increase the safety of this high-risk surgery for patients with biliary tract carcinoma.