Resectability and Vascular Management of Retroperitoneal Gynecological Malignancies: A Large Single-institution Case–Series

Patients and Methods

After obtaining Institutional Review Board approval (study protocol reference number 31883/17, 16 March 2017), clinical charts of women with gynecological cancers consecutively admitted to the Division of Gynecologic Oncology, “Agostino Gemelli” Foundation University Hospital, Rome, Italy, between January 2015 and January 2017, were retrospectively analyzed. Patients' demographics, pre-operative, surgical, and postoperative data were collected. Only patients submitted to major gynecological oncologic surgery were considered for this study. Major surgical procedures were taken into consideration when pelvic and/or para-aortic lymphadenectomy and/or bowel resection and/or diaphragmatic stripping/ resection and/or omentectomy and/or peritonectomy and/or urological surgery were performed. Tumor size, the extension to pelvic anatomical structures, and absence of distant metastatic disease were assessed by preoperative imaging (CT, MRI, and PET-CT scans).

More in depth, the vascular pre-operative evaluation was performed through a high-resolution CT scan with slice thickness greater than 1.00 mm and a good injection quality in arterial and venous time series. A 3D-Workstations, allowing multiplanar, curvilinear and 3D reconstructions of pre-operative images, are routinely used.

The involvement of the large vascular structures (common and/or external iliac vessels, aorta and/or vena cava) was pre-operatively assessed according to our Institutional categorization (i.e. Tinelli's score, named after our consultant vascular surgeon) after CT examination (4). It was assumed the need of vascular reconstruction for preoperative T4 (Figure 1).

Vascular procedures considered for the analysis were divided into minor (i.e., sutures of vascular damage) and major (tangential resections, major vessels' resections, graft selection/sizing and reconstruction with conduit).

Agreeing to internal policy, a priori all women with a performance status ≥3 according to ECOG (i.e. Eastern Cooperative Oncology Group) were excluded from the major vascular surgery and/or other major surgical procedures (12), but could undergo other needed procedures according to surgeons and anesthesiologist's judgments.

The type of residual tumor after resection was defined based on the status of the final pathologic margins: R0, microscopically negative; R1, microscopically positive; and R2, macroscopically (grossly) positive. All cases were performed as a multidisciplinary surgical effort (i.e. a gynecologic oncologist worked with surgeons from the urology, vascular, and plastic services, as well as a radiation oncologist if needed). In no case, the vascular impairment has been considered a priori a judgment of inoperability.

Surgical technique. Tumors were resected with a meticulous dissection with vessels respect when was possible (Figure 2). Alternatively, an en bloc resection together with blood vessels was performed according to the type of vascular involvement and the surgical standards (9). Blood flow was restored concerning the site of resection, the degree of the vascular damage and collateral blood flow (e.g. venous drainage). Arterial reconstructions were usually performed by the appropriate method, such as primary anastomosis, reinsertion, autologous vein (reversed great saphenous vein) was always used when possible or synthetic prostheses (expanded polytetrafluoroethylene [ePTFE] or Dacron), preferably in an anatomic position.

A ligature of vena cava before the renal confluence was performed when more of 2/3 of circumference was affected in the impossibility of a primary anastomosis. For localized defects of the inferior vena cava, we performed a venoplasty (longitudinal suture). Veins obstructed by thrombosis were not reconstructed (ligation of the proximal and distal venous stump). Patients routinely received prophylactic antibiotic treatment (cephalosporin, generally cefazolin) both preoperatively and postoperatively; in case of bowel resection another antibiotic was added (i.e. metronidazole). Bowel preparations were not routinely administered. Silver-containing prostheses or grafts with antibiotic pre-treatment were preferred in case of synchronous large bowel resection in the absence of autologous vein. After intestinal anastomosis, gloves were changed and protecting towels as well as instruments replaced. Perioperatively, a low-dose regimen of heparin was administered (unfractionated heparin intraoperatively and low-molecular-weight heparin in the postoperative phase) and a full-length compression stocking. Operative time was calculated starting from the skin incision to the end of all surgical procedures. Postoperative complications were obtained from the records of all hospital admissions, discharge summaries, and office visits up to 180 days post-surgery. Complications were graded using the Memorial Sloan Kettering Cancer Center grading system (13). Briefly, Grade 1 (G1) complications required oral medications or bedside interventions, Grade 2 (G2) complications required intravenous medications, enteral or parenteral nutrition, or chest tube insertion, Grade 3 (G3) complications required surgical or radiological intervention, intubation, or therapeutic endoscopy. Grade 4 (G4) complications produced a chronic disability requiring major rehabilitation or organ resection. Grade 5 (G5) complications resulted in death. A major complication was defined as any G3-G5 complication.

An interdisciplinary tumor board was established to evaluate whether additional therapeutic modalities such as radiotherapy or chemotherapy were required.

After discharge, women were regularly seen during the observation period at our outpatient clinic. The standard vascular follow-up was at 30 days and six months postoperatively and yearly after that. Patients were also seen according to the routine oncologic follow-up schedule. They were questioned about symptoms suggesting graft thrombosis, including pain and discomfort. Clinical examinations were usually combined with duplex ultrasonography to evaluate the patency of arterial and venous reconstructions. Besides, CT follow-up examinations for tumor staging were used to assess the patency of arterial and venous reconstructions.

Statistical analysis. Disease-free survival (DFS) was defined as the interval from the diagnosis to recurrence/progression of disease. Overall survival (OS) and DFS were estimated using the Kaplan–Meier method. Due to the small number of patients and the heterogeneity of the disease in our study, no statistical tests were performed to compare the survival of the different subgroups. All statistical tests were two-sided and differences were considered significant at a level of p<0.05. The SPSS statistical software program, version 17.0 (SPSS Inc., Chicago, IL, USA) was used.