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Multicellular ovarian cancer spheroids: novel 3D model to mimic tumour complexity

Inken Flörkemeier, Lisa K. Antons, Jörg Weimer, Nina Hedemann, Christoph Rogmans, Sandra Krüger, Regina Scherließ, Astrid Dempfle, Norbert Arnold, Nicolaì Maass, Dirk Bauerschlag

2024Scientific Reports21 citationsDOIOpen Access PDF

Abstract

In vitro, spheroid models have become well established in cancer research because they can better mimic certain characteristics of in vivo tumours. However, interaction with the tumour microenvironment, such as cancer-associated fibroblasts, plays a key role in tumour progression. We initially focused on the interaction of tumour cells with fibroblasts. To model this interaction, we developed a spheroid model of ovarian cancer and fibroblasts. To this end, ovarian cancer cell lines and ex vivo primary cells were simultaneously and sequentially seeded with fibroblasts in a scaffold-free system at different ratios and subsequently characterized with respect to changes in morphology, proliferation, and viability. We demonstrated that co-cultures are able to form by far more compact spheroids, especially in cells that form aggregates in mono-culture. In addition, the co-cultures were able to increase proliferation and sensitivity to cisplatin. Simultaneous seeding led fibroblasts invade the core in both cell lines and primary cells. These results show differences in formation, firmness, and size between co-culture and mono-culture. Our model is designed to better represent and characterize the mutual influencing factors of fibroblasts and tumour cells. Fibroblast-supplemented multicellular spheroids are a valuable tool for tumour microenvironment interaction and new drug discovery.

Topics & Concepts

Multicellular organismSpheroidOvarian cancerComputational biologyCancerBiologyComputer scienceCancer researchBioinformaticsGeneticsCell cultureCellMathematical Biology Tumor GrowthOvarian cancer diagnosis and treatmentCancer Cells and Metastasis