Background. We developed a sliding-loop technique that narrowed both sides of the parenchyma in a porcine model and compared it with the conventional sliding-clip technique. Methods. Three pigs (30-40 kg) were reused following another experiment conducted by the same researchers. Bilateral kidneys were harvested within 30 minutes after euthanasia. Two partial nephrectomies per kidney were performed on opposite surfaces. All kidney defects were of the same size (diameter of 2.5-3 cm with a depth of 1.0-1.5 cm). The sliding-clip technique and sliding-loop technique were performed separately. In the sliding-loop technique, we created a 1-cm loop at the end of a Vicryl and placed a tetrafluoroethylene polymer pledget in front of the knots passing through the needle. The needle then crossed the loop after passing through the renal parenchyma. A Weck clip was placed and slid on one side to tighten the suture. Tightening was controlled with an equivalent force using a digital push-pull gauge. Three stitches were placed at each renorrhaphy site. The distance between repaired renal surfaces was measured at 5 different points (3 suture sites and 2 middle sites between sutures). Results. The results of the 2 techniques were compared by using the independent t test. The mean distance between renal surfaces was significantly narrower in the sliding-loop technique than in the conventional technique (1.80 ± 1.08 mm vs 5.28 ± 2.46 mm, P < .001). Conclusion. In the porcine model, the sliding-loop technique more effectively closed the partial nephrectomy defects compared with the conventional sliding-clip technique.
GhaniKRSukumarSSammonJDRogersCGTrinhQDMenonM. Practice patterns and outcomes of open and minimally invasive partial nephrectomy since the introduction of robotic partial nephrectomy: results from the nationwide inpatient sample. J Urol. 2014;191:907-912.
2.
MirheydarHSParsonsJK. Diffusion of robotics into clinical practice in the United States: process, patient safety, learning curves, and the public health. World J Urol. 2013;31:455-461.
3.
TanHJWolfJSJrYeZHafezKSMillerDC. Population level assessment of hospital based outcomes following laparoscopic versus open partial nephrectomy during the adoption of minimally invasive surgery. J Urol. 2014;191:1231-1237.
4.
SammonJPetrosFSukumarS. Barbed suture for renorrhaphy during robot-assisted partial nephrectomy. J Endourol. 2011;25:529-533.
5.
BhayaniSBFigenshauRS. The Washington University Renorrhaphy for robotic partial nephrectomy: a detailed description of the technique displayed at the 2008 World Robotic Urologic Symposium. J Robot Surg. 2008;2:139-140.
BenwayBMCabelloJMFigenshauRSBhavaniSB. Sliding-clip renorrhaphy provides superior closing tension during robot-assisted partial nephrectomy. J Endourol. 2010;24:605-608.
8.
BenwayBMWangAJCabelloJMBhavaniSB. Robotic partial nephrectomy with sliding-clip renorrhaphy: technique and outcomes. Eur Urol. 2009;55:592-599.
9.
LaneBRGillIS. 7-year oncological outcomes after laparoscopic and open partial nephrectomy. J Urol. 2010;183:473-479.
10.
KhalifehAAutorinoRHillyerSP. Comparative outcomes and assessment of trifecta in 500 robotic and laparoscopic partial nephrectomy cases: a single surgeon experience. J Urol. 2013;189:1236-1242.
11.
MoriyamaHTomitaSWatanabeG. Dynamic evaluation of the loop technique using the U-Clip. Asian Cardiovasc Thorac Ann. 2014;22:160-164.
12.
BansalSRothenbergSS. Evaluation of laparoscopic management of recurrent gastroesophageal reflux disease and hiatal hernia: long term results and evaluation of changing trends. J Pediatr Surg. 2013;49:72-75.
13.
JonathanMBenwayBM. Robot-assisted partial nephrectomy. Minimal Invasive Urol, Springer, New York, 2015:79-88.
14.
ShikanovSWilleMLargeM. Knotless closure of the collecting system and renal parenchyma with a novel barbed suture during laparoscopic porcine partial nephrectomy. J Endourol. 2009;23:1157-1160.
