Litcius/Paper detail

Editor's Choice – Radiation Dose Reduction During Contralateral Limb Cannulation Using Fiber Optic RealShape Technology in Endovascular Aneurysm Repair

Jurre Klaassen, Constantijn E.V.B. Hazenberg, Trijntje Bloemert-Tuin, Suzan C. A. Wulms, Martin Teraa, Joost A. van Herwaarden

2023European Journal of Vascular and Endovascular Surgery12 citationsDOIOpen Access PDF

Abstract

Objective The increasing number of endovascular procedures has resulted in an increasing radiation burden, in particular for the treatment team. Fiber Optic RealShape (FORS) technology uses laser light instead of fluoroscopy to visualise endovascular guidewire and catheters. These devices can be used during the navigational part of procedures, such as cannulation of the contralateral limb (CL) in endovascular aneurysm repair (EVAR). The aim of this study was to describe the effect of using FORS on radiation dose during CL cannulation in standard EVAR. Methods This was a non-randomised, retrospective comparison study of prospectively collected, single centre data from FORS guided EVAR compared with a conventional fluoroscopy only guided EVAR cohort. A total of 27 FORS guided cases were matched 1:1 based on sex, age, and body mass index (BMI) with 27 regular (fluoroscopy only) EVARs. This study primarily focused on (1) technical success of FORS and (2) navigation time and radiation dose (cumulative air kerma [CAK], air-kerma area product [KAP], and fluoroscopy time [FT]) during cannulation of the CL. In addition, overall procedure time and radiation dose of the complete EVAR procedure were studied. Results In 22 (81%) of the 27 FORS guided cases the CL was successfully cannulated using FORS. All radiation dose parameters were significantly lower in the FORS group (CAK, p < .001; KAP, p = .009; and FT, p < .001) for an equal navigation time (p = .95). No significant differences were found when comparing outcomes of the complete procedure. Conclusion Use of FORS technology significantly reduces radiation doses during cannulation of the CL in standard EVAR. The increasing number of endovascular procedures has resulted in an increasing radiation burden, in particular for the treatment team. Fiber Optic RealShape (FORS) technology uses laser light instead of fluoroscopy to visualise endovascular guidewire and catheters. These devices can be used during the navigational part of procedures, such as cannulation of the contralateral limb (CL) in endovascular aneurysm repair (EVAR). The aim of this study was to describe the effect of using FORS on radiation dose during CL cannulation in standard EVAR. This was a non-randomised, retrospective comparison study of prospectively collected, single centre data from FORS guided EVAR compared with a conventional fluoroscopy only guided EVAR cohort. A total of 27 FORS guided cases were matched 1:1 based on sex, age, and body mass index (BMI) with 27 regular (fluoroscopy only) EVARs. This study primarily focused on (1) technical success of FORS and (2) navigation time and radiation dose (cumulative air kerma [CAK], air-kerma area product [KAP], and fluoroscopy time [FT]) during cannulation of the CL. In addition, overall procedure time and radiation dose of the complete EVAR procedure were studied. In 22 (81%) of the 27 FORS guided cases the CL was successfully cannulated using FORS. All radiation dose parameters were significantly lower in the FORS group (CAK, p < .001; KAP, p = .009; and FT, p < .001) for an equal navigation time (p = .95). No significant differences were found when comparing outcomes of the complete procedure. Use of FORS technology significantly reduces radiation doses during cannulation of the CL in standard EVAR.

Topics & Concepts

FluoroscopyMedicineKermaEndovascular aneurysm repairSurgeryNuclear medicineDose area productRadiologyRadiation doseDosimetryAneurysmAbdominal aortic aneurysmAortic aneurysm repair treatmentsOptical Imaging and Spectroscopy TechniquesPhotoacoustic and Ultrasonic Imaging