Fabrication of a Coculture Organoid Model in the Biomimetic Matrix of Alginate to Investigate Breast Cancer Progression in a TAMs-Leading Immune Microenvironment.

The current research models of breast cancer are usually limited in their capacity to recapitulate the tumor microenvironment in vitro. The lack of an extracellular matrix (ECM) oversimplifies cell-cell or cell-ECM cross-talks. Moreover, the lack of tumor-associated macrophages (TAMs), that can comprise up to 50% of some solid neoplasms, poses a major problem for recognizing various hallmarks of cancer. To address these concerns, a type of direct breast cancer cells (BCCs)-TAMs coculture organoid model was well developed by a sequential culture method in this study. Alginate cryogels were fabricated with appropriate physical and mechanical properties to serve as an alternative ECM. Then, our previous experience was leveraged to polarize TAMs inside of the cryogels for creating an in vitro immune microenvironment. The direct coculture significantly enhanced BCCs organoid growth and cancer aggressive phenotypes, including the stemness, migration, ECM remodeling, and cytokine secretion. Furthermore, transcriptomic analysis and protein-protein interaction networks implied certain pathways (PI3K-Akt pathway, MAPK signaling pathway, etc.) and targets (TNF, PPARG, TLR2, etc.) during breast cancer progression in a TAM-leading immune microenvironment. Future studies to advance treatment strategies for BCC patients may benefit from using this facile model to reveal and target the interactions between cancer signaling and the immune microenvironment.

A 3D-printed scaffold-based osteosarcoma model allows to investigate tumor phenotypes and pathogenesis in an in vitro bone-mimicking niche.

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Physical confinement in alginate cryogels determines macrophage polarization to a M2 phenotype by regulating a STAT-related mRNA transcription pathway.

The immunologic response is considered to play a pivotal role in the application of biomaterial implants, and intrinsic properties of biomaterials can significantly modulate the anti-inflammatory effects. However, how physical confinement influences M2 polarization of macrophages and the relevant mechanisms have not been clearly elucidated. In this study, pore size and porosity in cryogels can be mediated by utilizing alginates with different viscosities. Cryogels of small pore size and low porosity can restrict M2 polarization of macrophages in vitro, judging from cell morphology, secretion of cytokines and expression of key M2-related genes. In comparison, cryogels of large pore size or high porosity can induce M2 polarization in vivo, resulting in the anti-inflammation effects. High-throughput RNA-seq analysis demonstrates that the mRNA surveillance pathway is key in the polarization process, and four primary transcription factors (PPAR-γ, STAT6, NF-κB, and STAT1) participate probably by competition in DNA binding to regulate M2-related gene expression. This study confirms that enough physical space inside is necessary to promote M2 polarization for the anti-inflammatory performance, which can be applied widely in the fields of tissue engineering and regenerative medicine.