Development and Evaluation of a Robotic System for Safe Cardiac Sheath Delivery

Weizhao Wang; Carlo Saija; Zhouyang Xu; Aya Zeidan; Joshua Wilcox; Tiffany Patterson; Simon Redwood; Shuangyi Wang; Kawal Rhode; Richard Housden

doi:10.1109/TBME.2025.3553014

Development and Evaluation of a Robotic System for Safe Cardiac Sheath Delivery

Weizhao Wang, Carlo Saija, Zhouyang Xu, Aya Zeidan, Joshua Wilcox, Tiffany Patterson, Simon Redwood, Shuangyi Wang, Kawal Rhode, Richard Housden

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Abstract

OBJECTIVE: This study aimed to develop and evaluate a 3-degree-of-freedom (DoF) robotic system for the safe delivery of cardiac sheaths through challenging anatomical structures, including the fossa ovalis and pathways with tight curves.

METHODS: The robot and its kinematic model were built on a previously proposed single-DoF actuation module and bending model. A sheath delivery strategy (SDS) was developed, combining two control methods: tip position control to approach an optimal entry point and point-constrained control to maintain consistent navigation through this point, minimizing tissue contact. Technical performance was evaluated through trajectory-following and point-crossing tests, followed by feasibility experiments in a simulated scenario. Trials were conducted by three cardiologists using a validated phantom model under fluoroscopic guidance, comparing SDS with joint control (JC) and manual control (MC).

RESULTS: Average root mean square errors were 2.10 mm for tip position control and 1.86 mm for point-constrained control. SDS outperformed MC with significantly shorter trajectory lengths and lower root mean square jerk. Compared to JC, SDS reduced sheath-induced movements (an indirect measure of force) and increased retraction success rates at the fossa ovalis.

CONCLUSION: The proposed robotic system reduced tissue wall contact compared to JC and provided smoother, more controlled operations than MC, ensuring safer and more effective delivery through confined pathways.

SIGNIFICANCE: This work contributes to advancing robotic-assisted cardiac sheath delivery, providing a reliable and safer method for navigating challenging anatomical structures.

Original language	English
Journal	IEEE Transactions on Biomedical Engineering
Volume	PP
DOIs	https://doi.org/10.1109/TBME.2025.3553014
Publication status	E-pub ahead of print - 21 Mar 2025

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Development_and_Evaluation_of_a_Robotic_System_for_Safe_Cardiac_Sheath_DeliveryFinal published version, 9.77 MBLicence: CC BY

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title = "Development and Evaluation of a Robotic System for Safe Cardiac Sheath Delivery",

abstract = "OBJECTIVE: This study aimed to develop and evaluate a 3-degree-of-freedom (DoF) robotic system for the safe delivery of cardiac sheaths through challenging anatomical structures, including the fossa ovalis and pathways with tight curves.METHODS: The robot and its kinematic model were built on a previously proposed single-DoF actuation module and bending model. A sheath delivery strategy (SDS) was developed, combining two control methods: tip position control to approach an optimal entry point and point-constrained control to maintain consistent navigation through this point, minimizing tissue contact. Technical performance was evaluated through trajectory-following and point-crossing tests, followed by feasibility experiments in a simulated scenario. Trials were conducted by three cardiologists using a validated phantom model under fluoroscopic guidance, comparing SDS with joint control (JC) and manual control (MC).RESULTS: Average root mean square errors were 2.10 mm for tip position control and 1.86 mm for point-constrained control. SDS outperformed MC with significantly shorter trajectory lengths and lower root mean square jerk. Compared to JC, SDS reduced sheath-induced movements (an indirect measure of force) and increased retraction success rates at the fossa ovalis.CONCLUSION: The proposed robotic system reduced tissue wall contact compared to JC and provided smoother, more controlled operations than MC, ensuring safer and more effective delivery through confined pathways.SIGNIFICANCE: This work contributes to advancing robotic-assisted cardiac sheath delivery, providing a reliable and safer method for navigating challenging anatomical structures.",

author = "Weizhao Wang and Carlo Saija and Zhouyang Xu and Aya Zeidan and Joshua Wilcox and Tiffany Patterson and Simon Redwood and Shuangyi Wang and Kawal Rhode and Richard Housden",

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T1 - Development and Evaluation of a Robotic System for Safe Cardiac Sheath Delivery

AU - Wang, Weizhao

AU - Saija, Carlo

AU - Xu, Zhouyang

AU - Zeidan, Aya

AU - Wilcox, Joshua

AU - Patterson, Tiffany

AU - Redwood, Simon

AU - Wang, Shuangyi

AU - Rhode, Kawal

AU - Housden, Richard

PY - 2025/3/21

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N2 - OBJECTIVE: This study aimed to develop and evaluate a 3-degree-of-freedom (DoF) robotic system for the safe delivery of cardiac sheaths through challenging anatomical structures, including the fossa ovalis and pathways with tight curves.METHODS: The robot and its kinematic model were built on a previously proposed single-DoF actuation module and bending model. A sheath delivery strategy (SDS) was developed, combining two control methods: tip position control to approach an optimal entry point and point-constrained control to maintain consistent navigation through this point, minimizing tissue contact. Technical performance was evaluated through trajectory-following and point-crossing tests, followed by feasibility experiments in a simulated scenario. Trials were conducted by three cardiologists using a validated phantom model under fluoroscopic guidance, comparing SDS with joint control (JC) and manual control (MC).RESULTS: Average root mean square errors were 2.10 mm for tip position control and 1.86 mm for point-constrained control. SDS outperformed MC with significantly shorter trajectory lengths and lower root mean square jerk. Compared to JC, SDS reduced sheath-induced movements (an indirect measure of force) and increased retraction success rates at the fossa ovalis.CONCLUSION: The proposed robotic system reduced tissue wall contact compared to JC and provided smoother, more controlled operations than MC, ensuring safer and more effective delivery through confined pathways.SIGNIFICANCE: This work contributes to advancing robotic-assisted cardiac sheath delivery, providing a reliable and safer method for navigating challenging anatomical structures.

AB - OBJECTIVE: This study aimed to develop and evaluate a 3-degree-of-freedom (DoF) robotic system for the safe delivery of cardiac sheaths through challenging anatomical structures, including the fossa ovalis and pathways with tight curves.METHODS: The robot and its kinematic model were built on a previously proposed single-DoF actuation module and bending model. A sheath delivery strategy (SDS) was developed, combining two control methods: tip position control to approach an optimal entry point and point-constrained control to maintain consistent navigation through this point, minimizing tissue contact. Technical performance was evaluated through trajectory-following and point-crossing tests, followed by feasibility experiments in a simulated scenario. Trials were conducted by three cardiologists using a validated phantom model under fluoroscopic guidance, comparing SDS with joint control (JC) and manual control (MC).RESULTS: Average root mean square errors were 2.10 mm for tip position control and 1.86 mm for point-constrained control. SDS outperformed MC with significantly shorter trajectory lengths and lower root mean square jerk. Compared to JC, SDS reduced sheath-induced movements (an indirect measure of force) and increased retraction success rates at the fossa ovalis.CONCLUSION: The proposed robotic system reduced tissue wall contact compared to JC and provided smoother, more controlled operations than MC, ensuring safer and more effective delivery through confined pathways.SIGNIFICANCE: This work contributes to advancing robotic-assisted cardiac sheath delivery, providing a reliable and safer method for navigating challenging anatomical structures.

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Development and Evaluation of a Robotic System for Safe Cardiac Sheath Delivery

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