Thermally Drawn Laser-Profiled Electrode Catheters For Next Generation Tracking Using Bioelectric Navigation (2504.19326v1)

Abstract: Navigating medical instruments safely and accurately inside a patient's vascular tree has been a long-standing challenge for interventional radiologists and vascular surgeons. While x-ray fluoroscopy remains the gold standard for instrument tracking, intermittent contrast injections for angiographic imaging with fixed frames are used to ensure accurate placement of stent grafts, balloons or other endovascular devices. The latter has limitations in placement accuracy, especially when the patient anatomy deforms due to device interaction. Meanwhile, prolonged exposure to ionizing radiation poses health risks for clinicians, requiring the use of cumbersome lead vests, and contrast injections raise concern about contrast-associated acute kidney injury. Bioelectric Navigation, a non-fluoroscopic tracking modality, aims to provide an alternative by utilizing weak electric currents to locally sense anatomical features in the vasculature surrounding the catheter. In this work, we introduce a new class of electrode catheters to serve as a basis of bioelectrically trackable devices. The catheters are fabricated using a combination of rapid prototyping, thermal drawing, and laser micro-machining. We specifically manufacture a 6Fr catheter incorporating 16 electrodes, and evaluate the device on its mechanical and electrical properties. We also introduce an algorithm to track the catheter's location along the centerline of an abdominal aneurysm phantom. We report its tracking accuracy as well as its usability evaluated by an expert endovascular surgeon, demonstrating the strong potential of this technology for its integration into the existing clinical workflow.