Dynamic Rigidity Control for Supportive Sheaths in Endovascular Procedures

Michael Y. Qiu; Vinay Chandrasekaran; Chase M. Hartquist; Halle R. Lowe; Charles B. Suskin; Sheridan Lee; Juan Becerra-Garcia; Jin Vivian Lee; De Vaughn B. Rucker; Michelle R. Connor; Sophia R. Pyeatte; Mohamed S. Zaghloul; Santiago Elizondo Benedetto; Eric C. Leuthardt; Mohamed A. Zayed; Joshua W. Osbun; Guy M. Genin

doi:10.1115/1.4068225

Dynamic Rigidity Control for Supportive Sheaths in Endovascular Procedures

Michael Y. Qiu
, Vinay Chandrasekaran
, Chase M. Hartquist
, Halle R. Lowe
, Charles B. Suskin
, Sheridan Lee
, Juan Becerra-Garcia
, Jin Vivian Lee
, De Vaughn B. Rucker
, Michelle R. Connor
, Sophia R. Pyeatte
, Mohamed S. Zaghloul
, Santiago Elizondo Benedetto
, Eric C. Leuthardt
, Mohamed A. Zayed
, Joshua W. Osbun
, Guy M. Genin

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Endovascular procedures require sheaths with contradictory mechanical properties: flexibility for navigation through tortuous vessels, yet rigidity for device delivery. Current approaches rely on multiple device exchanges, increasing procedural time, and complication risks. Here we present a novel endovascular sheath design scheme with dynamically controllable flexural rigidity along its entire length. The device incorporates axially aligned metal string arrays between inner and outer lumens, enabling transition between flexible and rigid states through suction actuation. Three-point bend testing demonstrated that actuation increases flexural rigidity from the range associated with diagnostic catheters to that associated with support sheaths. In simulated contralateral access procedures, the device reduced access time to 1/3 of the time required when using conventional approaches. in vivo porcine studies validated the sheath’s ability to navigate tortuous anatomy in its flexible state and successfully support advancement of increasingly rigid therapeutic devices when actuated. Technology enables single-sheath delivery of treatment, potentially reducing procedural complexity, decreasing complication rates, and improving patient outcomes across various endovascular interventions. This design represents a promising approach to combining catheter and sheath design that benefits both peripheral and neurovascular procedures.

Original language	English
Article number	071006
Journal	Journal of Biomechanical Engineering
Volume	147
Issue number	7
DOIs	https://doi.org/10.1115/1.4068225
State	Published - Jul 1 2025

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Qiu, M. Y., Chandrasekaran, V., Hartquist, C. M., Lowe, H. R., Suskin, C. B., Lee, S., Becerra-Garcia, J., Lee, J. V., Rucker, D. V. B., Connor, M. R., Pyeatte, S. R., Zaghloul, M. S., Benedetto, S. E., Leuthardt, E. C., Zayed, M. A., Osbun, J. W., & Genin, G. M. (2025). Dynamic Rigidity Control for Supportive Sheaths in Endovascular Procedures. Journal of Biomechanical Engineering, 147(7), Article 071006. https://doi.org/10.1115/1.4068225

@article{e5abe19c28694696a2a01b7b8cc09296,

title = "Dynamic Rigidity Control for Supportive Sheaths in Endovascular Procedures",

abstract = "Endovascular procedures require sheaths with contradictory mechanical properties: flexibility for navigation through tortuous vessels, yet rigidity for device delivery. Current approaches rely on multiple device exchanges, increasing procedural time, and complication risks. Here we present a novel endovascular sheath design scheme with dynamically controllable flexural rigidity along its entire length. The device incorporates axially aligned metal string arrays between inner and outer lumens, enabling transition between flexible and rigid states through suction actuation. Three-point bend testing demonstrated that actuation increases flexural rigidity from the range associated with diagnostic catheters to that associated with support sheaths. In simulated contralateral access procedures, the device reduced access time to 1/3 of the time required when using conventional approaches. in vivo porcine studies validated the sheath{\textquoteright}s ability to navigate tortuous anatomy in its flexible state and successfully support advancement of increasingly rigid therapeutic devices when actuated. Technology enables single-sheath delivery of treatment, potentially reducing procedural complexity, decreasing complication rates, and improving patient outcomes across various endovascular interventions. This design represents a promising approach to combining catheter and sheath design that benefits both peripheral and neurovascular procedures.",

author = "Qiu, \{Michael Y.\} and Vinay Chandrasekaran and Hartquist, \{Chase M.\} and Lowe, \{Halle R.\} and Suskin, \{Charles B.\} and Sheridan Lee and Juan Becerra-Garcia and Lee, \{Jin Vivian\} and Rucker, \{De Vaughn B.\} and Connor, \{Michelle R.\} and Pyeatte, \{Sophia R.\} and Zaghloul, \{Mohamed S.\} and Benedetto, \{Santiago Elizondo\} and Leuthardt, \{Eric C.\} and Zayed, \{Mohamed A.\} and Osbun, \{Joshua W.\} and Genin, \{Guy M.\}",

note = "Publisher Copyright: {\textcopyright} 2025 by ASME.",

year = "2025",

month = jul,

day = "1",

doi = "10.1115/1.4068225",

language = "English",

volume = "147",

journal = "Journal of Biomechanical Engineering",

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Qiu, MY, Chandrasekaran, V, Hartquist, CM, Lowe, HR, Suskin, CB, Lee, S, Becerra-Garcia, J, Lee, JV, Rucker, DVB, Connor, MR, Pyeatte, SR, Zaghloul, MS, Benedetto, SE, Leuthardt, EC , Zayed, MA , Osbun, JW & Genin, GM 2025, 'Dynamic Rigidity Control for Supportive Sheaths in Endovascular Procedures', Journal of Biomechanical Engineering, vol. 147, no. 7, 071006. https://doi.org/10.1115/1.4068225

TY - JOUR

T1 - Dynamic Rigidity Control for Supportive Sheaths in Endovascular Procedures

AU - Qiu, Michael Y.

AU - Chandrasekaran, Vinay

AU - Hartquist, Chase M.

AU - Lowe, Halle R.

AU - Suskin, Charles B.

AU - Lee, Sheridan

AU - Becerra-Garcia, Juan

AU - Lee, Jin Vivian

AU - Rucker, De Vaughn B.

AU - Connor, Michelle R.

AU - Pyeatte, Sophia R.

AU - Zaghloul, Mohamed S.

AU - Benedetto, Santiago Elizondo

AU - Leuthardt, Eric C.

AU - Zayed, Mohamed A.

AU - Osbun, Joshua W.

AU - Genin, Guy M.

PY - 2025/7/1

Y1 - 2025/7/1

N2 - Endovascular procedures require sheaths with contradictory mechanical properties: flexibility for navigation through tortuous vessels, yet rigidity for device delivery. Current approaches rely on multiple device exchanges, increasing procedural time, and complication risks. Here we present a novel endovascular sheath design scheme with dynamically controllable flexural rigidity along its entire length. The device incorporates axially aligned metal string arrays between inner and outer lumens, enabling transition between flexible and rigid states through suction actuation. Three-point bend testing demonstrated that actuation increases flexural rigidity from the range associated with diagnostic catheters to that associated with support sheaths. In simulated contralateral access procedures, the device reduced access time to 1/3 of the time required when using conventional approaches. in vivo porcine studies validated the sheath’s ability to navigate tortuous anatomy in its flexible state and successfully support advancement of increasingly rigid therapeutic devices when actuated. Technology enables single-sheath delivery of treatment, potentially reducing procedural complexity, decreasing complication rates, and improving patient outcomes across various endovascular interventions. This design represents a promising approach to combining catheter and sheath design that benefits both peripheral and neurovascular procedures.

AB - Endovascular procedures require sheaths with contradictory mechanical properties: flexibility for navigation through tortuous vessels, yet rigidity for device delivery. Current approaches rely on multiple device exchanges, increasing procedural time, and complication risks. Here we present a novel endovascular sheath design scheme with dynamically controllable flexural rigidity along its entire length. The device incorporates axially aligned metal string arrays between inner and outer lumens, enabling transition between flexible and rigid states through suction actuation. Three-point bend testing demonstrated that actuation increases flexural rigidity from the range associated with diagnostic catheters to that associated with support sheaths. In simulated contralateral access procedures, the device reduced access time to 1/3 of the time required when using conventional approaches. in vivo porcine studies validated the sheath’s ability to navigate tortuous anatomy in its flexible state and successfully support advancement of increasingly rigid therapeutic devices when actuated. Technology enables single-sheath delivery of treatment, potentially reducing procedural complexity, decreasing complication rates, and improving patient outcomes across various endovascular interventions. This design represents a promising approach to combining catheter and sheath design that benefits both peripheral and neurovascular procedures.

UR - https://www.scopus.com/pages/publications/105005565172

U2 - 10.1115/1.4068225

DO - 10.1115/1.4068225

M3 - Article

C2 - 40094461

AN - SCOPUS:105005565172

SN - 0148-0731

VL - 147

JO - Journal of Biomechanical Engineering

JF - Journal of Biomechanical Engineering

IS - 7

M1 - 071006

ER -

Dynamic Rigidity Control for Supportive Sheaths in Endovascular Procedures

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