Researchers have developed a 3D culture model of small vascular tissue using a self-folding graphene-based porous film. This model replicates the structural features of a small artery and can help in understanding intercellular communications in physiological and pathological conditions.
In vitro vessel-mimicking models have been spotlighted as a powerful tool for investigating cellular behaviours in vascular development and diseases. However, it is still challenging to create micro-scale tubular tissues while mimicking the structural features of small arteries. Here, we propose a 3D culture model of small vascular tissue using a self-folding graphene-based porous film. Vascular endothelial cells were encapsulated within the self-folding film to create a cellular construct with a controlled curvature radius ranging from 10 to 100 mu m, which is comparable to the size of a human arteriole. Additionally, vascular endothelial cells and smooth muscle cells were separately co-cultured on the inner and outer surfaces of the folded film, respectively. The porous wall worked as a permeable barrier between them, affecting the cell-cell communications like the extracellular layer in the artery wall. Thus, the culture model recapitulates the structural features of a small artery and will help us better understand intercellular communications at the artery wall in physiological and pathological conditions. We co-cultured endothelial and smooth muscle cells in a self-folding porous film to create a vessel-like in vitro model. The tunability of the geometries including curvature and pore size enables us to emulate the geometries of a small artery.
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