A 3D Bioprinted In Vitro Model of Pulmonary Artery Atresia to Evaluate Endothelial Cell Response to Microenvironment

Martin L. Tomov; Lilanni Perez; Liqun Ning; Huang Chen; Bowen Jing; Andrew Mingee; Sahar Ibrahim; Andrea S. Theus; Gabriella Kabboul; Katherine Do; Sai Raviteja Bhamidipati; Jordan Fischbach; Kevin McCoy; Byron A. Zambrano; Jianyi Zhang; Reza Avazmohammadi; Athanasios Mantalaris; Brooks D. Lindsey; David Frakes; Lakshmi Prasad Dasi; Vahid Serpooshan; Holly Bauser-Heaton

doi:10.1002/adhm.202100968

A 3D Bioprinted In Vitro Model of Pulmonary Artery Atresia to Evaluate Endothelial Cell Response to Microenvironment

Martin L. Tomov, Lilanni Perez, Liqun Ning, Huang Chen, Bowen Jing, Andrew Mingee, Sahar Ibrahim, Andrea S. Theus, Gabriella Kabboul, Katherine Do, Sai Raviteja Bhamidipati, Jordan Fischbach, Kevin McCoy, Byron A. Zambrano, Jianyi Zhang, Reza Avazmohammadi, Athanasios Mantalaris, Brooks D. Lindsey, David Frakes, Lakshmi Prasad DasiVahid Serpooshan, Holly Bauser-Heaton

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

13 Scopus citations

Abstract

Vascular atresia are often treated via transcatheter recanalization or surgical vascular anastomosis due to congenital malformations or coronary occlusions. The cellular response to vascular anastomosis or recanalization is, however, largely unknown and current techniques rely on restoration rather than optimization of flow into the atretic arteries. An improved understanding of cellular response post anastomosis may result in reduced restenosis. Here, an in vitro platform is used to model anastomosis in pulmonary arteries (PAs) and for procedural planning to reduce vascular restenosis. Bifurcated PAs are bioprinted within 3D hydrogel constructs to simulate a reestablished intervascular connection. The PA models are seeded with human endothelial cells and perfused at physiological flow rate to form endothelium. Particle image velocimetry and computational fluid dynamics modeling show close agreement in quantifying flow velocity and wall shear stress within the bioprinted arteries. These data are used to identify regions with greatest levels of shear stress alterations, prone to stenosis. Vascular geometry and flow hemodynamics significantly affect endothelial cell viability, proliferation, alignment, microcapillary formation, and metabolic bioprofiles. These integrated in vitro–in silico methods establish a unique platform to study complex cardiovascular diseases and can lead to direct clinical improvements in surgical planning for diseases of disturbed flow.

Original language	English (US)
Article number	2100968
Pages (from-to)	e2100968
Journal	Advanced Healthcare Materials
Volume	10
Issue number	20
DOIs	https://doi.org/10.1002/adhm.202100968
State	Published - Oct 20 2021

Keywords

3D bioprinting
anastomosis
bifurcated vessels
particle image velocimetry
pulmonary artery atresia
Bioprinting
Endothelial Cells
Models, Cardiovascular
Humans
Stress, Mechanical
Anastomosis, Surgical
Hemodynamics
Printing, Three-Dimensional
Pulmonary Artery/surgery

ASJC Scopus subject areas

Biomedical Engineering
Biomaterials
Pharmaceutical Science

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10.1002/adhm.202100968

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Tomov, M. L., Perez, L., Ning, L., Chen, H., Jing, B., Mingee, A., Ibrahim, S., Theus, A. S., Kabboul, G., Do, K., Bhamidipati, S. R., Fischbach, J., McCoy, K., Zambrano, B. A., Zhang, J., Avazmohammadi, R., Mantalaris, A., Lindsey, B. D., Frakes, D., ... Bauser-Heaton, H. (2021). A 3D Bioprinted In Vitro Model of Pulmonary Artery Atresia to Evaluate Endothelial Cell Response to Microenvironment. Advanced Healthcare Materials, 10(20), e2100968. Article 2100968. https://doi.org/10.1002/adhm.202100968

Tomov, ML, Perez, L, Ning, L, Chen, H, Jing, B, Mingee, A, Ibrahim, S, Theus, AS, Kabboul, G, Do, K, Bhamidipati, SR, Fischbach, J, McCoy, K, Zambrano, BA, Zhang, J, Avazmohammadi, R, Mantalaris, A, Lindsey, BD, Frakes, D, Dasi, LP, Serpooshan, V & Bauser-Heaton, H 2021, 'A 3D Bioprinted In Vitro Model of Pulmonary Artery Atresia to Evaluate Endothelial Cell Response to Microenvironment', Advanced Healthcare Materials, vol. 10, no. 20, 2100968, pp. e2100968. https://doi.org/10.1002/adhm.202100968

@article{469f084f3b8f482bbfabea3733963303,

title = "A 3D Bioprinted In Vitro Model of Pulmonary Artery Atresia to Evaluate Endothelial Cell Response to Microenvironment",

abstract = "Vascular atresia are often treated via transcatheter recanalization or surgical vascular anastomosis due to congenital malformations or coronary occlusions. The cellular response to vascular anastomosis or recanalization is, however, largely unknown and current techniques rely on restoration rather than optimization of flow into the atretic arteries. An improved understanding of cellular response post anastomosis may result in reduced restenosis. Here, an in vitro platform is used to model anastomosis in pulmonary arteries (PAs) and for procedural planning to reduce vascular restenosis. Bifurcated PAs are bioprinted within 3D hydrogel constructs to simulate a reestablished intervascular connection. The PA models are seeded with human endothelial cells and perfused at physiological flow rate to form endothelium. Particle image velocimetry and computational fluid dynamics modeling show close agreement in quantifying flow velocity and wall shear stress within the bioprinted arteries. These data are used to identify regions with greatest levels of shear stress alterations, prone to stenosis. Vascular geometry and flow hemodynamics significantly affect endothelial cell viability, proliferation, alignment, microcapillary formation, and metabolic bioprofiles. These integrated in vitro–in silico methods establish a unique platform to study complex cardiovascular diseases and can lead to direct clinical improvements in surgical planning for diseases of disturbed flow.",

keywords = "3D bioprinting, anastomosis, bifurcated vessels, particle image velocimetry, pulmonary artery atresia, Bioprinting, Endothelial Cells, Models, Cardiovascular, Humans, Stress, Mechanical, Anastomosis, Surgical, Hemodynamics, Printing, Three-Dimensional, Pulmonary Artery/surgery",

author = "Tomov, {Martin L.} and Lilanni Perez and Liqun Ning and Huang Chen and Bowen Jing and Andrew Mingee and Sahar Ibrahim and Theus, {Andrea S.} and Gabriella Kabboul and Katherine Do and Bhamidipati, {Sai Raviteja} and Jordan Fischbach and Kevin McCoy and Zambrano, {Byron A.} and Jianyi Zhang and Reza Avazmohammadi and Athanasios Mantalaris and Lindsey, {Brooks D.} and David Frakes and Dasi, {Lakshmi Prasad} and Vahid Serpooshan and Holly Bauser-Heaton",

note = "Funding Information: The expert technical assistance and help provided by Drs. Sassan Hashemi and Timothy Slesnick in 3D reconstruction of clinical data is acknowledged. This research was funded by the NIH grant numbers K12HD072245 and R00HL127295, Emory University School of Medicine (Pediatric Research Alliance Pilot Grant the Dean's Imagine, Innovate and Impact (I3) Research Award), and the College of Engineering at Georgia Institute of Technology, and the Marvin H. and Nita S. Floyd Research Fund Award. This research was also funded in part by R00HL138288 from the National Institutes of Health. Publisher Copyright: {\textcopyright} 2021 Wiley-VCH GmbH",

year = "2021",

month = oct,

day = "20",

doi = "10.1002/adhm.202100968",

language = "English (US)",

volume = "10",

pages = "e2100968",

journal = "Advanced Healthcare Materials",

issn = "2192-2640",

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T1 - A 3D Bioprinted In Vitro Model of Pulmonary Artery Atresia to Evaluate Endothelial Cell Response to Microenvironment

AU - Tomov, Martin L.

AU - Perez, Lilanni

AU - Ning, Liqun

AU - Chen, Huang

AU - Jing, Bowen

AU - Mingee, Andrew

AU - Ibrahim, Sahar

AU - Theus, Andrea S.

AU - Kabboul, Gabriella

AU - Do, Katherine

AU - Bhamidipati, Sai Raviteja

AU - Fischbach, Jordan

AU - McCoy, Kevin

AU - Zambrano, Byron A.

AU - Zhang, Jianyi

AU - Avazmohammadi, Reza

AU - Mantalaris, Athanasios

AU - Lindsey, Brooks D.

AU - Frakes, David

AU - Dasi, Lakshmi Prasad

AU - Serpooshan, Vahid

AU - Bauser-Heaton, Holly

N1 - Funding Information: The expert technical assistance and help provided by Drs. Sassan Hashemi and Timothy Slesnick in 3D reconstruction of clinical data is acknowledged. This research was funded by the NIH grant numbers K12HD072245 and R00HL127295, Emory University School of Medicine (Pediatric Research Alliance Pilot Grant the Dean's Imagine, Innovate and Impact (I3) Research Award), and the College of Engineering at Georgia Institute of Technology, and the Marvin H. and Nita S. Floyd Research Fund Award. This research was also funded in part by R00HL138288 from the National Institutes of Health. Publisher Copyright: © 2021 Wiley-VCH GmbH

PY - 2021/10/20

Y1 - 2021/10/20

N2 - Vascular atresia are often treated via transcatheter recanalization or surgical vascular anastomosis due to congenital malformations or coronary occlusions. The cellular response to vascular anastomosis or recanalization is, however, largely unknown and current techniques rely on restoration rather than optimization of flow into the atretic arteries. An improved understanding of cellular response post anastomosis may result in reduced restenosis. Here, an in vitro platform is used to model anastomosis in pulmonary arteries (PAs) and for procedural planning to reduce vascular restenosis. Bifurcated PAs are bioprinted within 3D hydrogel constructs to simulate a reestablished intervascular connection. The PA models are seeded with human endothelial cells and perfused at physiological flow rate to form endothelium. Particle image velocimetry and computational fluid dynamics modeling show close agreement in quantifying flow velocity and wall shear stress within the bioprinted arteries. These data are used to identify regions with greatest levels of shear stress alterations, prone to stenosis. Vascular geometry and flow hemodynamics significantly affect endothelial cell viability, proliferation, alignment, microcapillary formation, and metabolic bioprofiles. These integrated in vitro–in silico methods establish a unique platform to study complex cardiovascular diseases and can lead to direct clinical improvements in surgical planning for diseases of disturbed flow.

AB - Vascular atresia are often treated via transcatheter recanalization or surgical vascular anastomosis due to congenital malformations or coronary occlusions. The cellular response to vascular anastomosis or recanalization is, however, largely unknown and current techniques rely on restoration rather than optimization of flow into the atretic arteries. An improved understanding of cellular response post anastomosis may result in reduced restenosis. Here, an in vitro platform is used to model anastomosis in pulmonary arteries (PAs) and for procedural planning to reduce vascular restenosis. Bifurcated PAs are bioprinted within 3D hydrogel constructs to simulate a reestablished intervascular connection. The PA models are seeded with human endothelial cells and perfused at physiological flow rate to form endothelium. Particle image velocimetry and computational fluid dynamics modeling show close agreement in quantifying flow velocity and wall shear stress within the bioprinted arteries. These data are used to identify regions with greatest levels of shear stress alterations, prone to stenosis. Vascular geometry and flow hemodynamics significantly affect endothelial cell viability, proliferation, alignment, microcapillary formation, and metabolic bioprofiles. These integrated in vitro–in silico methods establish a unique platform to study complex cardiovascular diseases and can lead to direct clinical improvements in surgical planning for diseases of disturbed flow.

KW - 3D bioprinting

KW - anastomosis

KW - bifurcated vessels

KW - particle image velocimetry

KW - pulmonary artery atresia

KW - Bioprinting

KW - Endothelial Cells

KW - Models, Cardiovascular

KW - Humans

KW - Stress, Mechanical

KW - Anastomosis, Surgical

KW - Hemodynamics

KW - Printing, Three-Dimensional

KW - Pulmonary Artery/surgery

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U2 - 10.1002/adhm.202100968

DO - 10.1002/adhm.202100968

M3 - Article

C2 - 34369107

AN - SCOPUS:85112661731

SN - 2192-2640

VL - 10

SP - e2100968

JO - Advanced Healthcare Materials

JF - Advanced Healthcare Materials

IS - 20

M1 - 2100968

ER -

A 3D Bioprinted In Vitro Model of Pulmonary Artery Atresia to Evaluate Endothelial Cell Response to Microenvironment

Abstract

Keywords

ASJC Scopus subject areas

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