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Core–Shell Spheroid‐Laden Microgels Crosslinked under Biocompatible Conditions for Probing Cancer‐Stromal Communication

Hongjia Zhu, Lianne W. Y. Roode, Aled Parry, Nadia A. Erkamp, Marc Rodriguez‐Garcia, Masako Narita, Masako Narita, Yi Shen, Yangteng Ou, Zenon Toprakcioglu, Masashi Narita, Masashi Narita, Tuomas P. J. Knowles

2022Advanced NanoBiomed Research10 citationsDOIOpen Access PDF

Abstract

Multicellular cancer spheroids (MCSs) have emerged as a promising in vitro model that recaptures many features of solid tumours in vivo. To generate cancer spheroids, cells are encapsulated in microgels with high throughput. While the biophysical properties of the cancer spheroid and biomaterial influence the function and behavior of the cells, characterization of these properties remains largely unexplored. In addition, many existing techniques lack control over cell positioning, resulting in the formation of spheroids with large variability. Herein, a versatile, microfluidic platform for generating biocompatible core–shell microgels with uniform cancer spheroids is reported. In addition, an in situ micromechanics measuring device to determine the stiffness of individual artificial cancer niches is used. The power of the microfluidics‐based method by making MCS‐laden microgels to model the interactions of stromal cancer cells is demonstrated. Together with in vivo data, it is shown that tumor cell proliferation is promoted by cocultured fibroblasts.

Topics & Concepts

SpheroidBiocompatible materialStromal cellCancer cellMaterials scienceNanotechnologyIn vivoMicrofluidicsBiomaterialCancerBiophysicsChemistryBiomedical engineeringIn vitroBiologyCancer researchMedicineGeneticsBiotechnologyBiochemistry3D Printing in Biomedical ResearchCancer Cells and MetastasisCellular Mechanics and Interactions