Soft robotic platform for controlled, progressive and reversible aortic constriction in a small animal model
Soft robotic platform for controlled, progressive and reversible aortic constriction in a small animal model
Our understanding of cardiac remodeling processes due to left ventricular pressure overload derives largely from animal models of aortic banding. However, these studies fail to simultaneously enable control over disease progression and reversal, hindering their clinical relevance. Here, we describe a method for controlled, progressive, and reversible aortic banding based on an implantable expandable actuator that can be finely controlled to modulate aortic banding and debanding in a rat model. Through catheterization, imaging, and histologic studies, we demonstrate that our model can recapitulate the hemodynamic and structural changes associated with pressure overload in a controllable manner. We leverage the ability of our model to enable non-invasive aortic debanding to show that these changes can be partly reversed due to cessation of the biomechanical stimulus. By recapitulating longitudinal disease progression and reversibility, this model could elucidate fundamental mechanisms of cardiac remodeling and optimize timing of intervention for pressure overload.
Roche, Ellen
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Rosalia, Luca
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Wang, Sophie
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Ozturk, Caglar
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Huang, Wei
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Bonnemain, Jean
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Beatty, Rachel
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Duffy, Garry
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Nguyen, Christopher
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19 July 2023
Roche, Ellen
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Rosalia, Luca
e3f00c11-aa4f-4454-ba25-cd0fd5cfb20a
Wang, Sophie
f9873600-3507-4a6f-93b0-a96069aba629
Ozturk, Caglar
70bbd3bd-fc56-48e8-8b5e-00d5270c1526
Huang, Wei
bd1464ed-9914-4bab-8eb0-37e1bd50f9bf
Bonnemain, Jean
3af327cb-2132-4569-abba-6347a3f8b3f7
Beatty, Rachel
2fab5236-6c17-4b2f-8772-57bef0510da7
Duffy, Garry
b44b5f75-0cd6-4f3e-9b07-e3b0c543af67
Nguyen, Christopher
bd447bb3-25fa-4e85-a4b5-2b291bfa2b61
[Unknown type: UNSPECIFIED]
Abstract
Our understanding of cardiac remodeling processes due to left ventricular pressure overload derives largely from animal models of aortic banding. However, these studies fail to simultaneously enable control over disease progression and reversal, hindering their clinical relevance. Here, we describe a method for controlled, progressive, and reversible aortic banding based on an implantable expandable actuator that can be finely controlled to modulate aortic banding and debanding in a rat model. Through catheterization, imaging, and histologic studies, we demonstrate that our model can recapitulate the hemodynamic and structural changes associated with pressure overload in a controllable manner. We leverage the ability of our model to enable non-invasive aortic debanding to show that these changes can be partly reversed due to cessation of the biomechanical stimulus. By recapitulating longitudinal disease progression and reversibility, this model could elucidate fundamental mechanisms of cardiac remodeling and optimize timing of intervention for pressure overload.
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Published date: 19 July 2023
Identifiers
Local EPrints ID: 490864
URI: http://eprints.soton.ac.uk/id/eprint/490864
PURE UUID: 0fc96269-4b9d-42d1-94ca-1b6d73fca67d
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Date deposited: 07 Jun 2024 16:37
Last modified: 08 Jun 2024 02:11
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Contributors
Author:
Ellen Roche
Author:
Luca Rosalia
Author:
Sophie Wang
Author:
Caglar Ozturk
Author:
Wei Huang
Author:
Jean Bonnemain
Author:
Rachel Beatty
Author:
Garry Duffy
Author:
Christopher Nguyen
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