Robotic Klatskin Type 3A Resection with Biliary Reconstruction: Description of Surgical Technique and Outcomes of Initial Series.

INTRODUCTION: Minimally invasive resection for perihilar cholangiocarcinoma is an emerging technique that requires both mastery in minimally invasive liver resection and biliary reconstruction. Due to technical difficulties in biliovascular dissection, radical portal lymphadenectomy and the need for fine suturing during bilioenteric anastomosis, this type of resection is generally not performed laparoscopically, even at high-volume, liver-surgery centers.1-3 In modern literature, a detailed, operative description of robotic technique for this operation with outcome data is lacking. This video article demonstrates a pure robotic Klatskin Type 3A resection with clinical outcomes of our initial series. VIDEO: A 77-year-old man presented with jaundice and findings of bilateral, intrahepatic, ductal dilation (Right > Left). Radiological imaging showed a type 3A Klatskin tumor with associated thrombosis of the right, anterior portal vein. A further endoscopic evaluation with cholangioscopy confirmed a high-grade Bismuth 3A biliary malignant stricture. Endoscopic drainage was achieved with placement of two, 7-French, 15-cm, plastic, endobiliary stents. A 3-D anatomical liver reconstruction showed a 2-cm mass located in the area of right, anterior, sectoral, Glissonean pedicle with standardized, future, liver-remnant (left hepatic lobe) volume of 50%. The patient was placed supine on the operating table. General endotracheal anesthesia was administered. After exclusion of metastatic peritoneal disease with diagnostic laparoscopy, cholecystectomy and systematic radical portal lymphadenectomy were first completed with a goal to obtain more than six lymph nodes. After appropriate portal lymphadenectomy, the common bile duct was isolated and transected at the level of pancreatic head. The plastic, endobiliary stents were removed, and a distal common bile duct margin was sent for a frozen-section examination to rule out distal extension of the cholangiocarcinoma. A small, accessory, right, hepatic artery lateral to the main portal vein was ligated with locking clips and removed together with the adjacent nodes and lymphatic bearing tissues. The intrapancreatic portion of the distal common bile duct was suture closed once the distal common bile duct margin was confirmed to be negative for neoplasia by the frozen-section examination. The proximal bile-duct dissection commenced cephalad toward the hilar bifurcation. Once the biliary bifurcation has been adequately dissected and detached from the hilar plate, the distal, left, hepatic duct was then transected near the base of the umbilical fissure to gain an R-0 resection margin. A second frozen-section specimen was obtained from the left, hepatic duct cut edge to ensure an absence of infiltrating tumor cells on the future, bile-duct remnant side. Division of short, hepatic veins off the inferior vena cava (IVC) were next completed. Once the line of hepatic-parenchymal transection was confirmed by using indocyanine green administration, the right hepatic artery and portal vein were ligated and clipped. The liver, parenchymal transection began with a crush-clamp technique utilizing robotic, fenestrated bipolar forceps and a vessel-sealing device. Preservation of the middle hepatic vein is always the preferred technique to avoid congestion of the left medial sector of the liver. The entire right hepatic lobe and the caudate lobe were removed en bloc. A large, Makuuchi ligament was isolated and divided by using a robotic, vascular-load stapler once the liver is open-booked. Finally, the root of the right hepatic vein was exposed and transected flush to the IVC by using another load of robotic vascular stapler. The biliary reconstruction then began by creating a 60-cm, roux limb for a hepaticojejunostomy bilioenteric anastomosis. A side-to-side, stapled jejunojejunostomy was created by using two applications for robotic 45-mm, blue load staplers. The common enterotomy was closed with running barbed sutures. The roux limb was then transposed retrocolically toward the porta hepatis. A single end-to-side hepaticojejunostomy anastomosis was created with running absorbable 4-0 barbed sutures. Finally, a closed suction abdominal drain was placed before closing. RESULTS: The operative time was approximately 8 hours with 150 ml of blood loss. The postoperative course was unremarkable. The final pathology report confirmed a moderately differentiated perihilar cholangiocarcinoma with negative resection margins. Ten lymph nodes were harvested. No nodal metastasis or lymphovascular invasion was found. Since 2021, we have undertaken robotic resection of Klatskin 3A tumor in four patients with a median age of 70 years. All patients presented with jaundice, and they mainly underwent preoperative biliary drainage using ERCP. The median operative duration was 508 minutes with estimated blood loss of 150 ml. R-0 resection margins were obtained in all patients. One patient suffered from postoperative complications requiring treatment of line sepsis using intravenous antibiotics. We did not find a 90-day mortality in this series. At a median follow-up period of 15 months, all of the patients were alive without any evidence of disease recurrence. CONCLUSIONS: Robotic resection of Type 3A Klatskin tumor is safe and feasible with appropriate experience in robotic hepatobiliary surgery, as demonstrated in this video article.

Robotic Left Hepatectomy for Hemorrhagic Hepatocellular Adenoma: The Role of Robotic Surgery in a Semi-Acute Setting.

Hepatocellular adenomas are benign liver tumors, more frequently seen in young women with a history of long-standing use of estrogenic hormonal contraception. An acute rupture of these adenomas can be the first sign of symptoms; however, they can be life-threatening. The definitive management of hepatic adenoma is liver resection for those larger than 4 cm as this cutoff size is known to be associated with an exponential risk of harboring malignancy and an increased risk for intratumor bleeding. Once intratumor hemorrhage occurs however, the management of hepatic adenoma becomes much more timely critical. In this study, we describe the use of robotic liver resection for the management of hemorrhagic hepatocellular adenoma in a semi-acute setting. We also include a series of robotic hepatic adenoma resection completed in our hepatobiliary program since 2016, which demonstrated the safety, feasibility, and reproducibility of robotic technique in treating hepatic adenoma.

Robotic Type 3B Klatskin Tumor Resection: Technique of Unification Ductoplasty for Roux-en-Y Biliary Reconstruction.

BACKGROUND: Application of robotic platform for perihilar cholangiocarcinoma is an emerging technique requiring expertise in both minimally invasive hepatic resection and biliary reconstruction. Due to oncological principles of trying to achieve tumor-free margins during cholangiocarcinoma operation, surgeons often find multiple sectoral bile ducts above the hilar plate that need to be reconstructed. Creating multiple oligomilimeter hepaticojejunostomy anastomoses is not only technically very challenging but also associated with an increased risk for postoperative bile leak and subsequent anastomotic stricture mandating reinterventions. METHODS: Technical maneuvers to reduce the number of biliary anastomosis had been previously described in open surgical literature. Minimally invasive technique such as simple unification ductoplasty, however, has not been described laparoscopically or robotically. RESULTS: We demonstrated a successful unification ductoplasty during a robotic type 3B Klatskin tumor resection according to Bismuth-Corlette classification. Creation of multiple anastomoses in this type of operation was able to be avoided. CONCLUSION: Robotic platform facilitates ductoplasty for biliary reconstruction during Klatskin tumor resection.

Fluorescence-Guided Robotic Segment 8 Superior Liver Resection. Technical Approach to Sectoral Inflow Occlusion.

In the past decade, precision hepatectomy which requires the understanding of segmental and subsegmental liver anatomy has gained popularity due to its parenchymal-sparing benefits. The importance of this concept has led liver surgeons to a consensus conference and its guideline in regards to precision anatomy in minimally invasive liver resection, held in Tokyo in 2020. A precise control of the sectoral hepatic artery and portal vein allows for a bloodless liver resection, without the use of Pringle maneuver. In the literature, technical description of the right anterior portal pedicle dissection during minimally invasive robotic liver surgery is limited. In this study, we therefore demonstrate such a technique using fluorescence guidance during robotic segment 8 superior liver resection.

Robotic Systematic Portal Lymphadenectomy. Description of Surgical Technique.

Portal lymphadenectomy is an integral part of gallbladder, intrahepatic cholangiocarcinoma, and perihilar cholangiocarcinoma resection to improve staging and prognostication. This is also believed by many oncologists to potentially serve as therapy to remove cancer containing nodes. While the current guideline requires removal of at least 6 portal lymphnodes, many surgeons face technical difficulty in performing the systematic portal lymphadenectomy especially in minimally invasive fashion. The anatomical complexity of biliovascular structures within the porta hepatis contributes to this technical challenge. In this video, we demonstrate our robotic technique of systematic portal lymphadenectomy for the treatment of gallbladder cancer.

Open Parenchymal Sparing Posterosuperior Liver Tumor Resection for Colorectal Liver Metastasis With Proximity to Hepatic Veins.

Liver resection for stage 4 colorectal cancer with liver metastasis is the standard of care, in combination with systemic chemotherapy. R-0 complete resection for colorectal liver metastasis is a curative-intent operation, which is considered the only chance for cure in this disease. The location and proximity of the tumor to major intrahepatic vessels such as hepatic and portal vein determine technical difficulty. Tumors located in the posterosuperior segments of the liver (segments 7 and 8) are technically challenging to resect using a minimally invasive fashion; therefore, conventional open resection is still the technique of choice today. In this video, we demonstrated our approach of an open parenchymal-sparing posterosuperior liver resection for a colorectal liver metastasis.