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by Keyword: 3D model


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Rubi-Sans, G., Castaño, O., Cano, I., Mateos-Timoneda, M. A., Perez-Amodio, S., Engel, E., (2020). Engineering cell-derived matrices: From 3D models to advanced personalized therapies Advanced Functional Materials 30, (44), e2000496

Regenerative medicine and disease models have evolved in recent years from two to three dimensions, providing in vitro constructs that are more similar to in vivo tissues. By mimicking native tissues, cell-derived matrices (CDMs) have emerged as new modifiable extracellular matrices for a variety of tissues, allowing researchers to study basic cellular processes in tissue-like structures, test tissue regeneration approaches, and model disease development. In this review, different fabrication techniques and characterization methods of CDMs are presented and examples of their application in cell behavior studies, tissue regeneration, and disease models are provided. In addition, future guidelines and perspectives in the field of CDMs are discussed.

Keywords: 3D models, Biomaterials, Cell-derived matrices, Extracellular matrix, Personalized therapies


Almici, Enrico, Caballero, David, Montero, Joan, Samitier, Josep, (2020). Engineering cell-derived matrices with controlled 3D architectures for pathophysiological studies Methods in Cell Biology (ed. Caballero, David, Kundu, Subhas C., Reis, Rui Luís), Academic Press (Cambridge, USA) 156, 161-183

The composition and architecture of the extracellular matrix (ECM) and their dynamic alterations, play an important regulatory role on numerous cellular processes. Cells embedded in 3D scaffolds show phenotypes and morphodynamics reminiscent of the native scenario. This is in contrast to flat environments, where cells display artificial phenotypes. The structural and biomolecular properties of the ECM are critical in regulating cell behavior via mechanical, chemical and topological cues, which induce cytoskeleton rearrangement and gene expression. Indeed, distinct ECM architectures are encountered in the native stroma, which depend on tissue type and function. For instance, anisotropic geometries are associated with ECM degradation and remodeling during tumor progression, favoring tumor cell invasion. Overall, the development of innovative in vitro ECM models of the ECM that reproduce the structural and physicochemical properties of the native scenario is of upmost importance to investigate the mechanistic determinants of tumor dissemination. In this chapter, we describe an extremely versatile technique to engineer three-dimensional (3D) matrices with controlled architectures for the study of pathophysiological processes in vitro. To this aim, a confluent culture of “sacrificial” fibroblasts was seeded on top of microfabricated guiding templates to induce the 3D ECM growth with specific isotropic or anisotropic architectures. The resulting matrices, and cells seeded on them, recapitulated the structure, composition, phenotypes and morphodynamics typically found in the native scenario. Overall, this method paves the way for the development of in vitro ECMs for pathophysiological studies with potential clinical relevance.

Keywords: Extracellular matrix, Cell-derived matrix, 3D model, Biomimicry, Anisotropy