ABSTRACT
There remains a lack of understanding of how wound closure methods perform comparatively when exposed to patient-induced movement during healing and how they may contribute to bacterial infiltration in the wound site. The present study attempts to objectively quantify this gap. The study evaluates bacterial penetration and subsequent symptoms of infection of traditional sutures and an emerging tape-based, zip-type wound closure technology under physiologically relevant loading. In an in vivo model to simulate real-world conditions, the latter demonstrates better performance compared to commonly used sutures, holding the wound intact and minimizing bacterial penetration when subjected to simulated patient movement-induced stress.
ABSTRACT
To date, there is still a lack of understanding of how wound closure methods perform comparatively under daily bodily movement during the course of healing and how they affect the mechanics of healing. The present study is a first step in understanding and objectively quantifying the gap. The study provides both a new method of metrology for noninvasive evaluation of skin mechanics at the onset of wound healing and an emerging tape-based wound closure technology. The latter shows better performance with respect to commonly used staples and sutures, holding the wound intact and providing uniform mechanical support across the incision.
ABSTRACT
BACKGROUND: The advancement of natural orifice translumenal endoscopic surgery (NOTES) depends on the availability of a suitable platform. A 2008 Natural Orifice Surgery Consortium for Assessment and Research (NOSCAR) Working Group identified access, navigation, maneuverability, and stability to withstand instrument forces as the essential requirements for a successful NOTES platform [1]. No single NOTES platform can adequately achieve all four of these key capabilities. In this study, the authors tested a novel flexible endoscopic robotic platform in a cadaver to determine how it performs with respect to these specific requirements. METHODS: A highly maneuverable multichannel flexible robotic endoscopic platform developed for NOTES was used transgastrically in an adult cadaver to test the platform's ability to reach multiple intraabdominal targets. The device was under the control of the surgeon throughout the test. The surgeon was blinded to a control laparoscopic view. At each target organ, the platform was maneuvered via a joystick to provide different camera views and tool access orientation appropriate for the surgical tasks of each procedure. Standard endoscopic tools were used in the platform's two working channels to demonstrate the platform's ability to withstand the forces generated during tissue manipulation and clipping. RESULTS: The platform reached each target organ site without difficulty, relying on the endoscopic view only. The platform's unique ability to maintain stability in two- and three-dimensional space resisted forces exerted by tools in the tool channels used for tissue manipulation and clipping. Endoscopic visualization allowed the surgeon to reposition the platform easily to gain a different camera view or tool access orientation about an organ (see video in Supplementary material). CONCLUSION: The authors demonstrated that the four capabilities identified by NOSCAR can be provided by the flexible robotic endoscopic platform. These essential capabilities for the clinical implementation of NOTES were addressed specifically by this platform. The provision of these capabilities in a single device may further the advancement and adoption of NOTES.
