VINE Catheter: Soft, Tip-extending, Robotic Catheters with Shape Control for Endovascular Surgery
University Of California, San Diego, La Jolla CA
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Abstract
PROJECT SUMMARY Endovascular surgeries (ES) increasingly augment or replace traditional open surgical treatment of brain, liver, heart, and vascular diseases due to their improved clinical outcomes, faster recovery times, and improved mor- tality rates. These surgeries are commonly performed by inserting endovascular equipment into the groin or arm and navigating to distal arteries through a combination of axial loading and rotation of the base of the tools, utilizing the curved tips to deï¬ect into intended locations and vessels. Despite the many beneï¬ts of endovascular surgeries, vascular anatomy, particularly for elderly patients who represent a large portion of those undergoing such procedures, can demonstrate excessive tortuosity and severe angulation, leading to high-risk , time-intensive procedures that can only be performed by a select number of expertly trained specialists. The small number of specialists results in limited access to necessary treatment, and patients are forced to either wait and travel for treatment or to not receive treatment at all. There is therefore a critical need for new endovascular robotic surgical tools that are safe, eâµective, and that enable more surgeons to successfully navigate challenging anatomies. To address this need, a new soft-robotic approach called VINE â Vascular Internal Navigation by Extension â will be used. When pressurized with ï¬uid, these VINEs navigate via extension at their tip in a man- ner analogous to how plants grow, creating shapes with complex curvatures. These VINEs are inherently safer due to their soft structure and represent a fundamentally diâµerent method of movement. The overall objective of this work is to characterize the behavior and reï¬ne the design of the VINE for ES, including the shape control methods, and to validate its e"cacy and safety. The central hypothesis is that this new method of shape control and navigation via tip-extension enables VINEs to safely and eâµectively traverse the vasculature. The central hypothesis will be tested by pursuing three speciï¬c aims: (1) characterize and reï¬ne small-scale, pre-shaped and steerable VINE designs for ES, (2) evaluate VINE e"cacy in bench-top models, and (3) validate the safety of the entire VINE system in an in vivo pig study. This work will serve as a ï¬rst step towards achieving the long-term goal of creating a soft robotic catheterization system, operable by a large number of surgeons, to increase access to high-quality surgical treatment. This work is innovative in that the proposed VINE is the ï¬rst everting, robotic catheter with shape control and represents a substantive departure from the status quo, which currently relies on pushing semi-rigid instruments from their proximal end. The expected contribution of this work is a preliminary soft, tip-extending robotic system capable of safely and eâµectively navigating around acute turns and through winding paths of the vasculature, which is signiï¬cant since it will ultimately lead to increased access to high-quality minimally invasive procedures.
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