Litcius/Paper detail

Epicardial slices: an innovative 3D organotypic model to study epicardial cell physiology and activation

Davide Maselli, Rolando S. Matos, Robert D. Johnson, Ciro Chiappini, Patrizia Camelliti, Paola Campagnolo

2022npj Regenerative Medicine17 citationsDOIOpen Access PDF

Abstract

The epicardium constitutes an untapped reservoir for cardiac regeneration. Upon heart injury, the adult epicardium re-activates, leading to epithelial-to-mesenchymal transition (EMT), migration, and differentiation. While interesting mechanistic and therapeutic findings arose from lower vertebrates and rodent models, the introduction of an experimental system representative of large mammals would undoubtedly facilitate translational advancements. Here, we apply innovative protocols to obtain living 3D organotypic epicardial slices from porcine hearts, encompassing the epicardial/myocardial interface. In culture, our slices preserve the in vivo architecture and functionality, presenting a continuous epicardium overlaying a healthy and connected myocardium. Upon thymosin β4 treatment of the slices, the epicardial cells become activated, upregulating epicardial and EMT genes, resulting in epicardial cell mobilization and differentiation into epicardial-derived mesenchymal cells. Our 3D organotypic model enables to investigate the reparative potential of the adult epicardium, offering an advanced tool to explore ex vivo the complex 3D interactions occurring within the native heart environment.

Topics & Concepts

In vivoMesenchymal stem cellCell biologyRegeneration (biology)BiologyEx vivoNeuroscienceCellEpithelial–mesenchymal transitionAnatomyTransition (genetics)GeneBiochemistryBiotechnologyGeneticsCongenital heart defects researchTissue Engineering and Regenerative MedicineMagnetic Bearings and Levitation Dynamics