AI Article Synopsis
- Bottom-up tissue engineering offers advantages over top-down methods by improving mass transfer control and creating functional tissue structures.
- These technologies include both mesoscale and microscale approaches, such as cell sheets, hydrogels, 3D printing, inkjet printing, and laser-assisted bioprinting, allowing precise manipulation of cells.
- The review emphasizes the potential of combining these techniques for creating realistic tissue models in lab settings or for use in clinical applications.
Article Abstract
Bottom-up tissue engineering technologies address two of the main limitations of top-down tissue engineering approaches: the control of mass transfer and the fabrication of a controlled and functional histoarchitecture. These emerging technologies encompass mesoscale (e.g. cell sheets, cell-laden hydrogels and 3D printing) and microscale technologies (e.g. inkjet printing and laser-assisted bioprinting), which are used to manipulate and assemble cell-laden building blocks whose thicknesses correspond to the diffusion limit of metabolites, and present the capacity for cell patterning with microscale precision, respectively. Here, we review recent technological advances and further discuss how these technologies are complementary, and could therefore be combined for the biofabrication of organotypic tissues either in vitro, thus serving as realistic tissue models, or within a clinic setting.
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| http://dx.doi.org/10.1016/j.tibtech.2010.12.008 | DOI Listing |
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