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You are researching: Epicardial Cells

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Skin Tissue Engineering Drug Delivery Biological Molecules Solid Dosage Drugs Stem Cells Personalised Pharmaceuticals Inducend Pluripotent Stem Cells (IPSCs) Drug Discovery Cancer Cell Lines Cell Type Tissue and Organ Biofabrication

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AUTHOR Bannerman, Dawn and Pascual-Gil, Simon and Wu, Qinghua and Fernandes, Ian and Zhao, Yimu and Wagner, Karl T. and Okhovatian, Sargol and Landau, Shira and Rafatian, Naimeh and Bodenstein, David F. and Wang, Ying and Nash, Trevor R. and Vunjak-Novakovic, Gordana and Keller, Gordon and Epelman, Slava and Radisic, Milica

Title Heart-on-a-Chip Model of Epicardial–Myocardial Interaction in Ischemia Reperfusion Injury [Abstract]

Year 2024

Journal/Proceedings Advanced Healthcare Materials

Reftype

DOI/URL DOI

Groups

Thermoplastics

Application

Collagen

University of Toronto

Matrigel

SEBS

Cell Type

Poly(styrene) (ethylene/butylene)–(styrene)

Fibroblasts

Epicardial Cells

CardioMyocites

Heart - Cardiac Patches Tissue Engineering

Drug Discovery

Institution

Printing Technology

Pneumatic Strand Dispenser

Biomaterial

AbstractAbstract Epicardial cells (EPIs) form the outer layer of the heart and play an important role in development and disease. Current heart-on-a-chip platforms still do not fully mimic the native cardiac environment due to the absence of relevant cell types, such as EPIs. Here, using the Biowire II platform, engineered cardiac tissues with an epicardial outer layer and inner myocardial structure are constructed, and an image analysis approach is developed to track the EPI cell migration in a beating myocardial environment. Functional properties of EPI cardiac tissues improve over two weeks in culture. In conditions mimicking ischemia reperfusion injury (IRI), the EPI cardiac tissues experience less cell death and a lower impact on functional properties. EPI cell coverage is significantly reduced and more diffuse under normoxic conditions compared to the post-IRI conditions. Upon IRI, migration of EPI cells into the cardiac tissue interior is observed, with contributions to alpha smooth muscle actin positive cell population. Altogether, a novel heart-on-a-chip model is designed to incorporate EPIs through a formation process that mimics cardiac development, and this work demonstrates that EPI cardiac tissues respond to injury differently than epicardium-free controls, highlighting the importance of including EPIs in heart-on-a-chip constructs that aim to accurately mimic the cardiac environment.