Fully biologic endothelialized-tissue-engineered vascular conduits provide antithrombotic function and graft patency

Jinkyu Park; Muhammad Riaz; Lingfeng Qin; Wei Zhang; Luke Batty; Saba Fooladi; Mehmet H. Kural; Xin Li; Hangqi Luo; Zhen Xu; Juan Wang; Kimihiko Banno; Sean X. Gu; Yifan Yuan; Christopher W. Anderson; Matthew W. Ellis; Jiahui Zhou; Jiesi Luo; Xiangyu Shi; Jae Hun Shin; Yufeng Liu; Seoyeon Lee; Mervin C. Yoder; Robert W. Elder; Michael Mak; Stephanie Thorn; Albert Sinusas; Peter J. Gruber; John Hwa; George Tellides; Laura E. Niklason; Yibing Qyang

doi:10.1016/j.stem.2024.11.006

Fully biologic endothelialized-tissue-engineered vascular conduits provide antithrombotic function and graft patency

Jinkyu Park
, Muhammad Riaz
, Lingfeng Qin
, Wei Zhang
, Luke Batty
, Saba Fooladi
, Mehmet H. Kural
, Xin Li
, Hangqi Luo
, Zhen Xu
, Juan Wang
, Kimihiko Banno
, Sean X. Gu
, Yifan Yuan
, Christopher W. Anderson
, Matthew W. Ellis
, Jiahui Zhou
, Jiesi Luo
, Xiangyu Shi
, Jae Hun Shin

Yufeng Liu, Seoyeon Lee, Mervin C. Yoder, Robert W. Elder, Michael Mak, Stephanie Thorn, Albert Sinusas, Peter J. Gruber, John Hwa, George Tellides, Laura E. Niklason, Yibing Qyang

Pharmacological Sciences

Yale University
Hallym University
Indiana University Bloomington

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

18 Scopus citations

Abstract

Tissue-engineered vascular conduits (TEVCs), often made by seeding autologous bone marrow cells onto biodegradable polymeric scaffolds, hold promise toward treating single-ventricle congenital heart defects (SVCHDs). However, the clinical adoption of TEVCs has been hindered by a high incidence of graft stenosis in prior TEVC clinical trials. Herein, we developed endothelialized TEVCs by coating the luminal surface of decellularized human umbilical arteries with human induced pluripotent stem cell (hiPSC)-derived endothelial cells (ECs), followed by shear stress training, in flow bioreactors. These TEVCs provided immediate antithrombotic function and expedited host EC recruitment after implantation as interposition inferior vena cava grafts in nude rats. Graft patency was maintained with no thrombus formation, followed by complete replacement of host ECs. Our study lays the foundation for future production of fully biologic TEVCs composed of hiPSC-derived ECs as an innovative therapy for SVCHDs.

Original language	English
Pages (from-to)	137-143.e6
Journal	Cell Stem Cell
Volume	32
Issue number	1
DOIs	https://doi.org/10.1016/j.stem.2024.11.006
State	Published - Jan 2 2025

Keywords

endothelial cell
flow bioreactor
human induced pluripotent stem cell
shear stress training
single ventricle congenital heart defect
tissue-engineered vascular conduit

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10.1016/j.stem.2024.11.006

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Park, J., Riaz, M., Qin, L., Zhang, W., Batty, L., Fooladi, S., Kural, M. H., Li, X., Luo, H., Xu, Z., Wang, J., Banno, K., Gu, S. X., Yuan, Y., Anderson, C. W., Ellis, M. W., Zhou, J., Luo, J., Shi, X., ... Qyang, Y. (2025). Fully biologic endothelialized-tissue-engineered vascular conduits provide antithrombotic function and graft patency. Cell Stem Cell, 32(1), 137-143.e6. https://doi.org/10.1016/j.stem.2024.11.006

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title = "Fully biologic endothelialized-tissue-engineered vascular conduits provide antithrombotic function and graft patency",

abstract = "Tissue-engineered vascular conduits (TEVCs), often made by seeding autologous bone marrow cells onto biodegradable polymeric scaffolds, hold promise toward treating single-ventricle congenital heart defects (SVCHDs). However, the clinical adoption of TEVCs has been hindered by a high incidence of graft stenosis in prior TEVC clinical trials. Herein, we developed endothelialized TEVCs by coating the luminal surface of decellularized human umbilical arteries with human induced pluripotent stem cell (hiPSC)-derived endothelial cells (ECs), followed by shear stress training, in flow bioreactors. These TEVCs provided immediate antithrombotic function and expedited host EC recruitment after implantation as interposition inferior vena cava grafts in nude rats. Graft patency was maintained with no thrombus formation, followed by complete replacement of host ECs. Our study lays the foundation for future production of fully biologic TEVCs composed of hiPSC-derived ECs as an innovative therapy for SVCHDs.",

keywords = "endothelial cell, flow bioreactor, human induced pluripotent stem cell, shear stress training, single ventricle congenital heart defect, tissue-engineered vascular conduit",

author = "Jinkyu Park and Muhammad Riaz and Lingfeng Qin and Wei Zhang and Luke Batty and Saba Fooladi and Kural, \{Mehmet H.\} and Xin Li and Hangqi Luo and Zhen Xu and Juan Wang and Kimihiko Banno and Gu, \{Sean X.\} and Yifan Yuan and Anderson, \{Christopher W.\} and Ellis, \{Matthew W.\} and Jiahui Zhou and Jiesi Luo and Xiangyu Shi and Shin, \{Jae Hun\} and Yufeng Liu and Seoyeon Lee and Yoder, \{Mervin C.\} and Elder, \{Robert W.\} and Michael Mak and Stephanie Thorn and Albert Sinusas and Gruber, \{Peter J.\} and John Hwa and George Tellides and Niklason, \{Laura E.\} and Yibing Qyang",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier Inc.",

year = "2025",

month = jan,

day = "2",

doi = "10.1016/j.stem.2024.11.006",

language = "English",

volume = "32",

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Park, J, Riaz, M, Qin, L, Zhang, W, Batty, L, Fooladi, S, Kural, MH, Li, X, Luo, H, Xu, Z, Wang, J, Banno, K, Gu, SX, Yuan, Y, Anderson, CW, Ellis, MW, Zhou, J, Luo, J, Shi, X, Shin, JH, Liu, Y, Lee, S, Yoder, MC, Elder, RW, Mak, M, Thorn, S, Sinusas, A, Gruber, PJ, Hwa, J, Tellides, G, Niklason, LE & Qyang, Y 2025, 'Fully biologic endothelialized-tissue-engineered vascular conduits provide antithrombotic function and graft patency', Cell Stem Cell, vol. 32, no. 1, pp. 137-143.e6. https://doi.org/10.1016/j.stem.2024.11.006

TY - JOUR

T1 - Fully biologic endothelialized-tissue-engineered vascular conduits provide antithrombotic function and graft patency

AU - Park, Jinkyu

AU - Riaz, Muhammad

AU - Qin, Lingfeng

AU - Zhang, Wei

AU - Batty, Luke

AU - Fooladi, Saba

AU - Kural, Mehmet H.

AU - Li, Xin

AU - Luo, Hangqi

AU - Xu, Zhen

AU - Wang, Juan

AU - Banno, Kimihiko

AU - Gu, Sean X.

AU - Yuan, Yifan

AU - Anderson, Christopher W.

AU - Ellis, Matthew W.

AU - Zhou, Jiahui

AU - Luo, Jiesi

AU - Shi, Xiangyu

AU - Shin, Jae Hun

AU - Liu, Yufeng

AU - Lee, Seoyeon

AU - Yoder, Mervin C.

AU - Elder, Robert W.

AU - Mak, Michael

AU - Thorn, Stephanie

AU - Sinusas, Albert

AU - Gruber, Peter J.

AU - Hwa, John

AU - Tellides, George

AU - Niklason, Laura E.

AU - Qyang, Yibing

PY - 2025/1/2

Y1 - 2025/1/2

N2 - Tissue-engineered vascular conduits (TEVCs), often made by seeding autologous bone marrow cells onto biodegradable polymeric scaffolds, hold promise toward treating single-ventricle congenital heart defects (SVCHDs). However, the clinical adoption of TEVCs has been hindered by a high incidence of graft stenosis in prior TEVC clinical trials. Herein, we developed endothelialized TEVCs by coating the luminal surface of decellularized human umbilical arteries with human induced pluripotent stem cell (hiPSC)-derived endothelial cells (ECs), followed by shear stress training, in flow bioreactors. These TEVCs provided immediate antithrombotic function and expedited host EC recruitment after implantation as interposition inferior vena cava grafts in nude rats. Graft patency was maintained with no thrombus formation, followed by complete replacement of host ECs. Our study lays the foundation for future production of fully biologic TEVCs composed of hiPSC-derived ECs as an innovative therapy for SVCHDs.

AB - Tissue-engineered vascular conduits (TEVCs), often made by seeding autologous bone marrow cells onto biodegradable polymeric scaffolds, hold promise toward treating single-ventricle congenital heart defects (SVCHDs). However, the clinical adoption of TEVCs has been hindered by a high incidence of graft stenosis in prior TEVC clinical trials. Herein, we developed endothelialized TEVCs by coating the luminal surface of decellularized human umbilical arteries with human induced pluripotent stem cell (hiPSC)-derived endothelial cells (ECs), followed by shear stress training, in flow bioreactors. These TEVCs provided immediate antithrombotic function and expedited host EC recruitment after implantation as interposition inferior vena cava grafts in nude rats. Graft patency was maintained with no thrombus formation, followed by complete replacement of host ECs. Our study lays the foundation for future production of fully biologic TEVCs composed of hiPSC-derived ECs as an innovative therapy for SVCHDs.

KW - endothelial cell

KW - flow bioreactor

KW - human induced pluripotent stem cell

KW - shear stress training

KW - single ventricle congenital heart defect

KW - tissue-engineered vascular conduit

UR - https://www.scopus.com/pages/publications/85213233068

U2 - 10.1016/j.stem.2024.11.006

DO - 10.1016/j.stem.2024.11.006

M3 - Article

C2 - 39644899

AN - SCOPUS:85213233068

SN - 1934-5909

VL - 32

SP - 137-143.e6

JO - Cell Stem Cell

JF - Cell Stem Cell

IS - 1

ER -

Fully biologic endothelialized-tissue-engineered vascular conduits provide antithrombotic function and graft patency

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Keywords

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