Pancreatoduodenectomy with portal-superior mesenteric vein resection and reconstruction can provide radical surgical opportunities for patients with venous invasion and enable them to benefit from the surgery. With the development of minimally invasive concepts and surgical techniques, laparoscopic and robot-assisted pancreatoduodenectomy with portal-superior mesenteric vein resection and reconstruction is being increasingly widely carried out. This surgical procedure is highly technically demanding, and the perioperative management of patients is complex. However, there is a lack of high-quality and high-level evidence-based clinical studies in this regard. In order to better standardize the clinical application of laparoscopic or robot-assisted pancreatoduodenectomy with portal-superior mesenteric vein resection and reconstruction in China, the Study Group of Minimally Invasive Treatment for Pancreatic Cancer in China Anti-Cancer Association, guided by problems and based on evidence, formed 17 recommendations through full discussions among experts. The recommendations involve the safety, oncological benefits, and perioperative patient management of the minimally invasive approach to pancreatoduodenectomy with portal-superior mesenteric vein resection and reconstruction.
Humans ; Pancreaticoduodenectomy/methods* ; Mesenteric Veins/surgery* ; Laparoscopy ; Portal Vein/surgery* ; Robotic Surgical Procedures ; Pancreatic Neoplasms/surgery* ; Consensus

Hereditary protein S deficiency (PSD) is an autosomal dominant disorder caused by mutations in the PROS1 gene which can cause venous thrombosis. Individuals with PSD usually present with recurrent deep vein thrombosis and/or pulmonary embolism, but thrombosis may occur at unusual sites, such as the mesenteric and portal veins. Here we report a case of hereditary protein S deficiency patient with predominant mesenteric venous thrombosis. A 57-year-old man was admitted for abdominal pain and bilateral lower limber swelling. His sister had a history of thrombotic disease. On admission, His temperature was 37.4 ℃, the pulse was regular, and the blood pressure was 130/79 mmHg. Abdominal examination showed right lower abdomen tenderness, rebound tenderness and suspected muscle rigidity. Abdominal computed tomography (CT) angiography found that the patient had superior mesenteric venous thrombosis (MVT) and perforation of intestine. Vascular ultrasound of lower limb indicated bilateral deep venous thrombosis. Although treatment of fasting, water restriction, parenteral nutrition solution, acid suppression, anti-biotic treatment and low molecular weight heparin for anticoagulation were given, abdominal pain were not relieved. Small intestine resection and anastomosis was done after. Pathology of intestine did not show changes indicative of vasculitis. To investigate the cause of multiple thrombosis, a work-up for hypercoagulability (protein C and S activities, antithrombin, lupus anticoagulant, anti-cardiolipin antibody, anti-β2 glycoprotein Ⅰ antibody) was done and the result showed increased dRVVT ratio and the significantly decreased protein S levels. Anti-phospholipid syndrome (APS) was suspected because of the thrombosis and positive lupus anticoagulant, but at the time of the test the patient was on oral anticoagulants which might influence the result of lupus anticoagulant. The lupus anticoagulant was normal after discontinuing oral anticoagulants and APS was excluded. Because of his personal and family history of thrombotic disease, a hereditary thrombophilia was suspected and a laboratory analysis showed a reduced protein S activity. Further examination of the whole exome sequencing indicated a heterozygous mutation in the PROS1 gene. He was diagnosed with hereditary protein S deficiency and was started on anticoagulant therapy with rivaroxaban. He had been followed up for 1 year, and his condition kept stable without newly developed thrombosis or bleeding.
Humans ; Male ; Protein S Deficiency/genetics* ; Middle Aged ; Venous Thrombosis/etiology* ; Mesenteric Veins ; Protein S/genetics* ; Mutation ; Abdominal Pain/etiology*

Objective: Due to its various anatomical variations and numerous branches, the gastrocolic vein trunk (Henle trunk) is the most common site to develop bleeding and other complications in laparoscopic right hemicolectomy for colon cancer. This study aims to investigate the role of ileocolic vein (ICV) joining with Henle trunk, a rare anatomical variation. Methods: A rare case whose ICV was newly found to involve in the formation of Henle trunk during laparoscopic resection of right hemicolon cancer was reported as right gastroepiploic vein+ right colic vein+superior right colic vein+ICV. This anatomical variation was confirmed by multi-slice spiral CT coronal two-dimensional reconstruction of right hemicolon angiography. The literatures about ICV participating in formation of Henle trunk were systematically searched from PubMed, The Cochran Library, CNKI net and Wanfang database, and the occurrence probability and composition of its anatomical variation were analyzed. Results: This was a 47-year-old female patient who underwent laparoscopic right hemicolectomy. When the vessels were dissected during operation, it was found that ICV did not accompany the ileocolic artery, but directly flowed into Henle trunk. Two-dimensional reconstructed CT images of right hemicolon vessels showed that the composition of Henle trunk was rarely varied, which was composed of right gastroepiploic vein, right colonic vein, superior right colonic vein and ICV. Five literatures were enrolled from literature retrieval. A total of 12 cases with ICV participating in the construction of Henle trunk were reported, with a probability of 0.27%-6.31% and 6 forms of the formation of Henle trunk. In this case, Henle trunk was made up of right gastroepiploic vein, right colonic vein, upper right colonic vein and ICV, which was reported for the first time. Conclusions: ICV involving in Henle trunk is a rare vascular variation, and this type of variation should be fully recognized. Careful dissection during operation is necessary to prevent intraoperative bleeding caused by improper operation.
Anatomic Variation ; Colectomy ; Colonic Neoplasms/surgery* ; Female ; Humans ; Laparoscopy ; Mesenteric Veins ; Middle Aged

Colon cancer is very rarely accompanied by tumor thrombosis of the superior mesenteric vein (SMV). A 46-year-old patient had been diagnosed with SMV tumor thrombosis related to colon cancer without hepatic metastasis and underwent right hemicolectomy with SMV tumor thrombectomy. Tumor thrombosis was pathologically confirmed as metastatic colon cancer. There has been no recurrence for 12 months with 12 cycles of adjuvant-chemotherapy.
Colon, Ascending ; Colonic Neoplasms ; Humans ; Mesenteric Veins ; Middle Aged ; Neoplasm Metastasis ; Recurrence ; Thrombectomy ; Thrombosis

OBJECTIVE: Para-aortic lymphadenectomy was the cornerstone of gynecologic oncology surgery. In endometrial cancer, the quality of para-aortic lymphadenectomy had direct impact on survival of patient. The launch of robot assisted laparoscopy started in 2005 in France, and in 2008 a transperitoneal para-aortic lymphadenectomy was described [1]. With the increase of robots, the robot assisted laparoscopy became more and more popular, hence the need of video tutorial to help less experienced surgeon in this surgical procedure [2]. METHODS: We proposed a description in 10 key steps, of a transperitoneal para-aortic lymphadenectomy by robot assisted laparoscopy (Da Vinci® Si or Xi Robot Surgical System; Intuitive Surgical Inc., Sunnyvale, CA, USA), without other surgical procedure. RESULTS: The 10 steps are: Step 1: port placement and Da Vinci robot positioning Step 2: identification of the right ureter Step 3: identification of the left renal vein Step 4: latero-caval and aorto-caval lymph nodes dissection Step 5: identification of the left ureter Step 6: creation of peritoneal tent Step 7: identification of the inferior mesenteric artery Step 8: latero-aortal lymph nodes dissection Step 9: pre-sacral lymph nodes dissection Step 10: extraction of bags with specimen and surgical textile CONCLUSION: A standardization of transperitoneal para-aortic lymphadenectomy by robot-assisted laparoscopy is the basis of teaching and learning process. Also it increases the quality of surgery, and consequently decreases the risk of complications.
Endometrial Neoplasms ; Female ; France ; Humans ; Laparoscopy ; Learning ; Lymph Node Excision ; Lymph Nodes ; Mesenteric Artery, Inferior ; Renal Veins ; Textiles ; Ureter

Nutcracker syndrome (NCS) is a syndrome caused by compression of the left renal vein (LRV), between the abdominal aorta and the superior mesenteric artery, resulting in hypertension of the LRV and hematuria. Doppler ultrasonography (US) has been commonly used for the diagnosis of NCS. However, several technical issues, such as Doppler angle and sample volume, need to be considered to obtain satisfactory results. In addition, morphologic changes of the LRV and a jetting phenomenon across the aortomesenteric portion of the LRV on contrast-enhanced computed tomography (CECT) are diagnostic clues of NCS. With proper Doppler US and CECT, NCS can be diagnosed noninvasively.
Aorta, Abdominal ; Diagnosis ; Hematuria ; Hypertension ; Mesenteric Artery, Superior ; Renal Veins ; Tomography, X-Ray Computed ; Ultrasonography, Doppler

Nutcracker syndrome is a phenomenon that the left renal vein (LRV) is pressed between the superior mesenteric artery (SMA) and the aorta. Clinical characteristics include gross or microscopic hematuria, orthostatic proteinuria, abdominal pain, and back pain. It occurs due to LRV squeezing caused by narrowed aortomesenteric angle. SMA syndrome is a disease that the third part of the duodenum is prone to intestinal obstruction by narrowed angle between the SMA and the abdominal aorta. Clinical symptoms include postprandial abdominal distension, epigastric pain, nausea, and vomiting. SMA syndrome and nutcracker syndrome have common features that result from narrowed aortomesenteric angle. However, it is very rare for both syndromes to occur simultaneously, so the two syndromes are regarded as separate diseases. This is a report on a case of nutcracker syndrome with SMA syndrome in a child who presented gross hematuria, recurrent abdominal pain and vomiting. To our knowledge, nutcracker syndrome simultaneous with SMA syndrome has not been previously reported in pediatric patient, especially with an exhibition of gross hematuria. This case suggests that the simultaneous presence of SMA syndrome with the same pathogenesis needs to be considered when nutcracker syndrome is suspected in pediatric patients with hematuria.
Abdominal Pain ; Aorta ; Aorta, Abdominal ; Back Pain ; Child ; Duodenum ; Hematuria ; Humans ; Intestinal Obstruction ; Mesenteric Artery, Superior ; Nausea ; Proteinuria ; Renal Veins ; Superior Mesenteric Artery Syndrome ; Vomiting

The authors report a rare variation of the coeliac trunk, renal and testicular vasculature in a 27-year-old male cadaver. In the present case, the coeliac trunk and superior mesenteric artery was replaced by a modified coeliacomesenteric trunk formed by hepato-gastric and superior mesenteric arteries. Here the hepato-gastric artery or trunk contributed towards the total hepatic inflow as well as a gastro-duodenal artery. A separate right gastric artery and an additional superior pancreatico-duodenal artery was also found in addition with a retro-aortic left renal vein and a bilateral double renal arterial supply. The aforementioned coeliac trunk variation, to our knowledge, has never been reported before and this variation combined with the renal vasculature requires careful surgical consideration.
Adult ; Arteries ; Cadaver ; Humans ; Male ; Mesenteric Artery, Superior ; Renal Veins

Vessel identification and dissection are the key processes of laparoscopic complete mesocolic excision (CME). Vascular injury will lead to complications such as prolonged operative time, intraoperative hemorrhage and ischemia of anastomotic stoma. Superior mesenteric artery (SMA), superior mesenteric vein(SMV), gastrointestinal trunk, left colic artery(LCA), sigmoid artery and marginal vessels in the mesentery have been found with possibility of heteromorphosis, which requires better operative techniques. Surgeons should recognize those vessel heteromorphosis carefully during operations and adjust strategies to avoid intraoperative hemorrhage. Preoperative abdominal computed tomography angiography(CTA) with three-dimensional reconstruction can find vessel heteromorphosis within surgical area before operation. Adequate dissection of veins instead of violent separation will decrease intraoperative bleeding and be helpful for dealing with the potential hemorrhage. When intraoperative hemorrhage occurs, surgeons need to control the bleeding by simple compression or vascular clips depending on the different situations. When the bleeding can not be stopped by laparoscopic operation, surgeons should turn to open surgery without hesitation.
Colonic Neoplasms ; surgery ; Dissection ; Hemorrhage ; prevention & control ; Humans ; Laparoscopy ; Mesenteric Artery, Inferior ; Mesenteric Veins ; Mesocolon ; surgery

OBJECTIVETo compare the difference of the diameters of superior mesenteric vein (SMV) and gastrocolic trunk (GCT) between patients with cecum-ascending colon cancer and normal individuals, and to assess the diagnostic value of the diameters of SMV and GCT in cecum-ascending colon cancer.

METHODSPreoperative imaging data of 60 patients with primary cecum-ascending colon cancer confirmed by postoperative pathology at the First Affiliated Hospital of Sun Yat-sen University from June 2014 to December 2016 were retrospectively analyzed. The diameters of SMV and GCT were measured on preoperative CT images. SMV was measured at about 2 cm below the junction of SMV and splenic vein. GCT was measured at 1 cm near the proximal junction of right colon vein, right gastroepiploic vein and anterior pancreaticoduodenal vein. Another 60 people receiving pelvic CT examination without organ illness were collected as control. The diameter differences of SMV and GCT between cancer group and control group were compared. The diagnostic value of the diameters of SMV and GCT in cecum-ascending colon cancer was evaluated by receiver operating characteristic (ROC) curves.

RESULTSAmong 60 cases of cecum-ascending colon cancer, 36 were males and 24 were females with median age of 48 years (range 28-84); 13 were cecum cancer, 47 were ascending colon cancer; 11 had no lymph node and liver metastasis, 40 had lymph node metastasis, 9 had liver metastasis (all with lymph node metastasis). Compared to control group, the diameters of SMV and GCT in cancer group were significantly longer [SMV:(11.2±1.3) mm vs. (9.5±1.7) mm, t=6.04, P<0.001; GCT:(5.5±0.9) mm vs. (3.5±1.0) mm, t=11.51, P<0.001]. However, there were no statistically significant differences in diameters of SMV and GCT among hepatic metastasis, lymph node metastasis and no metastasis cancer groups (all P>0.05). The ROC curve analysis showed that the area under the curve of SMV diameter was 0.777, and the optimal cut-off point was 10.5 mm in the diagnosis of cecum-ascending colon cancer, with the sensitivity and specificity of 95.0%(57/60) and 46.7%(28/60) respectively. The area under the curve of GCT diameter was 0.923, and the optimal cut-off point was 4.5 mm in the diagnosis of cecum-ascending colon cancer, with sensitivity and specificity of 88.3%(53/60) and 85.0%(51/60) respectively.

CONCLUSIONThe dilation of the SMV and GCT may be used as warning factors for cecum-ascending colon cancer, especially the diameter of GCT.

Adult ; Aged ; Aged, 80 and over ; Cecum ; Colon, Ascending ; pathology ; Colonic Neoplasms ; pathology ; Female ; Humans ; Male ; Mesenteric Veins ; anatomy & histology ; Middle Aged ; Retrospective Studies