TY - JOUR
T1 - Robotic Diagnostic Cerebral Angiography
T2 - A Multicenter Experience of 113 Patients
AU - Robotics Working Group
AU - Beaman, Charles
AU - Gautam, Ayushi
AU - Peterson, Catherine
AU - Kaneko, Naoki
AU - Ponce, Luciano
AU - Saber, Hamidreza
AU - Khatibi, Kasra
AU - Morales, Jose
AU - Kimball, David
AU - Lipovac, Jacob Ridge
AU - Narsinh, Kazim H.
AU - Baker, Amanda
AU - Caton, M. Travis
AU - Smith, Eric R.
AU - Nour, May
AU - Szeder, Viktor
AU - Jahan, Reza
AU - Colby, Geoffrey P.
AU - Cord, Branden J.
AU - Cooke, Daniel L.
AU - Tateshima, Satoshi
AU - Duckwiler, Gary
AU - Waldau, Ben
N1 - Publisher Copyright:
© Author(s) (or their employer(s)) 2024. No commercial re-use. See rights and permissions. Published by BMJ.
PY - 2024/6/17
Y1 - 2024/6/17
N2 - Background Neurointerventional robotic systems have potential to reduce occupational radiation, improve procedural precision, and allow for future remote teleoperation. A limited number of single institution case reports and series have been published outlining the safety and feasibility of robot-assisted diagnostic cerebral angiography. Methods This is a multicenter, retrospective case series of patients undergoing diagnostic cerebral angiography at three separate institutions - University of California, Davis (UCD); University of California, Los Angeles (UCLA); and University of California, San Francisco (UCSF). The equipment used was the CorPath GRX Robotic System (Corindus, Waltham, MA). Results A total of 113 cases were analyzed who underwent robot-assisted diagnostic cerebral angiography from September 28, 2020 to October 27, 2022. There were no significant complications related to use of the robotic system including stroke, arterial dissection, bleeding, or pseudoaneurysm formation at the access site. Using the robotic system, 88 of 113 (77.9%) cases were completed successfully without unplanned manual conversion. The principal causes for unplanned manual conversion included challenging anatomy, technical difficulty with the bedside robotic cassette, and hubbing out of the robotic system due to limited working length. For robotic operation, average fluoroscopy time was 13.2 min (interquartile range (IQR), 9.3 to 16.8 min) and average cumulative air kerma was 975.8 mGY (IQR, 350.8 to 1073.5 mGy). Conclusions Robotic cerebral angiography with the CorPath GRX Robotic System is safe and easily learned by novice users without much prior manual experience. However, there are technical limitations such as a short working length and an inability to support 0.035"wires which may limit its widespread adoption in clinical practice.
AB - Background Neurointerventional robotic systems have potential to reduce occupational radiation, improve procedural precision, and allow for future remote teleoperation. A limited number of single institution case reports and series have been published outlining the safety and feasibility of robot-assisted diagnostic cerebral angiography. Methods This is a multicenter, retrospective case series of patients undergoing diagnostic cerebral angiography at three separate institutions - University of California, Davis (UCD); University of California, Los Angeles (UCLA); and University of California, San Francisco (UCSF). The equipment used was the CorPath GRX Robotic System (Corindus, Waltham, MA). Results A total of 113 cases were analyzed who underwent robot-assisted diagnostic cerebral angiography from September 28, 2020 to October 27, 2022. There were no significant complications related to use of the robotic system including stroke, arterial dissection, bleeding, or pseudoaneurysm formation at the access site. Using the robotic system, 88 of 113 (77.9%) cases were completed successfully without unplanned manual conversion. The principal causes for unplanned manual conversion included challenging anatomy, technical difficulty with the bedside robotic cassette, and hubbing out of the robotic system due to limited working length. For robotic operation, average fluoroscopy time was 13.2 min (interquartile range (IQR), 9.3 to 16.8 min) and average cumulative air kerma was 975.8 mGY (IQR, 350.8 to 1073.5 mGy). Conclusions Robotic cerebral angiography with the CorPath GRX Robotic System is safe and easily learned by novice users without much prior manual experience. However, there are technical limitations such as a short working length and an inability to support 0.035"wires which may limit its widespread adoption in clinical practice.
KW - angiography
KW - device
KW - technique
KW - technology
UR - http://www.scopus.com/inward/record.url?scp=85166422257&partnerID=8YFLogxK
U2 - 10.1136/jnis-2023-020448
DO - 10.1136/jnis-2023-020448
M3 - Article
C2 - 37468266
AN - SCOPUS:85166422257
SN - 1759-8478
VL - 16
SP - 726
EP - 730
JO - Journal of NeuroInterventional Surgery
JF - Journal of NeuroInterventional Surgery
IS - 7
ER -