Robotic endoscopic surgery in a porcine model of the infant neck.

Minimally invasive surgery is rapidly becoming the desired surgical standard, especially for pediatric patients. Infants and children are a particular technical challenge, however, because of the small size of target anatomical structures and the small surgical workspace. Computer-assisted robot-enhanced surgical telemanipulators may overcome these challenges by facilitating surgery in a small workspace. We studied the feasibility of performing robotic endoscopic neck surgery on a porcine model of the human infant neck. The study design was a prospective, feasibility pilot study of a small cohort for proof of concept and for a survival model. Sixteen non-survival piglets weighing 4.5-10 kg were used to develop the surgical approach and operative technique. Eight piglets aged 3-6 weeks old and weighing 4.0-9.1 kg underwent survival thyroidectomy by a cervical endoscopic approach using the Zeus surgical robot, which includes the Aesop endoscope holder and "Microwrist" microdissecting instruments. We succeeded in performing endoscopic robotic neck surgery on a piglet as small as 4 kg, in an operative pocket as small as 2 cm(3). Total incision length for all three ports was ≤23 mm. There were no major complications, no major robotic instrument malfunctions or breakages, and no procedures required conversion to open surgery. These results support the feasibility of robotic endoscopic neck surgery on a neck the size of a human infant's.

Totally minimally invasive robot-assisted unstented pyeloplasty using the Zeus Microwrist Surgical System: an animal study.

BACKGROUND: Minimally invasive pyeloplasty is a difficult procedure even for an expert laparoscopic surgeon. The major difficulty is associated with the limitations of intracorporeal suturing and knot tying. Surgical robots, which hold minimally invasive surgical instruments, have wrists and provide tremor filtration and motion scaling that might be expected to facilitate complex procedures in newborns. METHODS: Seven survival piglets (4.0-7.5 kg) underwent a totally minimally invasive robot-assisted unstented pyeloplasty employing the Zeus Robotic Microwrist System. The ureter was transected at the level of the ureteropelvic junction and 8 mm was resected. The unstented anastomosis was fashioned with running suture and intracorporeal knot tying. The animals were recovered and intravenous urography was performed at 1 month. After sacrifice, the anastomosis and the kidney were evaluated grossly and histologically for leak, caliber, and healing. RESULTS: All animals survived the procedure without postoperative complications. The mean robotic setup time was 19 minutes (range, 10-30 min), mean anastomosis time 51 minutes (range, 39-63 min), and mean total operation time 76 minutes (range, 57-87 min). The urography showed hydronephrosis in the first animal. The other 6 animals had no abnormalities. Histopathology demonstrated severe hydronephrosis in the first pig and moderate hydronephrosis in the sixth and seventh. All other animals had no sign of hydronephrosis. All anastomoses were well healed and intact. CONCLUSIONS: Robot-assisted laparoscopic pyeloplasty is a technically feasible procedure with acceptable morbidity in an animal model. The robotic technology enhances surgical dexterity and precision. Robotic assistance can increase the applicability of minimally invasive surgery to complex procedures in children.

Robotics in pediatric surgery: perspectives for imaging.

Robotic surgery will give surgeons the ability to perform essentially tremorless microsurgery in tiny spaces with delicate precision and may enable procedures never before possible on children, neonates, and fetuses. Collaboration with radiologists, engineers, and other scientists will permit refinement of image-guided technologies and allow the realization of truly remarkable concepts in minimally invasive surgery. While robotic surgery is now in clinical use in several surgical specialties (heart bypass, prostate removal, and various gastrointestinal procedures), the greatest promise of robotics lies in pediatric surgery. We will briefly review the history and background of robotic technology in surgery, discuss its present benefits and uses and those being explored, and speculate on the future, with attention to the current and potential involvement of imaging modalities and the role of image guidance.