MSC-Derived EV Production in Bioreactors concentration (i.e., EV concentration in the conditioned medium) (5.7-fold increase overall) and productivity (i.e., amount of EVs generated per cell) (3-fold increase overall). BM, AT and UCM MSC cultured in the VWBR system yielded an average of 2.8 ± 0.1 × 10 11 , 3.1 ± 1.3 × 10 11 , and 4.1 ± 1.7 × 10 11 EV particles (n = 3), respectively, in a 60 mL final volume. This bioreactor system also allowed to obtain a more robust MSC-EV production, regarding their purity, compared to static culture. Overall, we demonstrate that this scalable culture system can robustly manufacture EVs from MSC derived from different tissue sources, toward the development of novel therapeutic products.
Cancer immunoediting is a dynamic process of crosstalk between tumor cells and the immune system. Herein, we explore the fast zebrafish xenograft model to investigate the innate immune contribution to this process. Using multiple breast and colorectal cancer cell lines and zAvatars, we find that some are cleared (regressors) while others engraft (progressors) in zebrafish xenografts. We focus on two human colorectal cancer cells derived from the same patient that show contrasting engraftment/clearance profiles. Using polyclonal xenografts to mimic intra-tumor heterogeneity, we demonstrate that SW620_progressors can block clearance of SW480_regressors. SW480_regressors recruit macrophages and neutrophils more efficiently than SW620_progressors; SW620_progressors however, modulate macrophages towards a pro-tumoral phenotype. Genetic and chemical suppression of myeloid cells indicates that macrophages and neutrophils play a crucial role in clearance. Single-cell-transcriptome analysis shows a fast subclonal selection, with clearance of regressor subclones associated with IFN/Notch signaling and escaper-expanded subclones with enrichment of IL10 pathway. Overall, our work opens the possibility of using zebrafish xenografts as living biomarkers of the tumor microenvironment.
Mesenchymal stromal cells (MSC) hold great promise for tissue engineering applications and cell‐based therapies. Large cell doses (>1 × 106 cells kg−1) and Good Manufacturing Practices (GMP)‐compliant processes are however required for clinical purposes. Here, a serum‐ and xenogeneic‐free (S/XF) microcarrier‐based culture system is established for the expansion of human umbilical cord matrix (UCM)‐ and adipose tissue (AT)‐derived MSC using the Vertical‐Wheel system (PBS‐0.1 MAG; PBS Biotech). UCM and AT MSC are expanded to maximum cell densities of 5.3 ± 0.4 × 105 cell mL−1 (n = 3) and 3.6 ± 0.7 × 105 cell mL−1 (n = 3), respectively, after 7 days of culture, while maintaining their identity, according to standard criteria. An economic evaluation of the process transfer from T‐flasks to PBS‐0.1 MAG shows a reduction in the costs associated with the production of a dose for an average 70 kg adult patient (i.e., 70 million cells). Costs decrease from $17.0 K to $11.1 K for UCM MSC and from $21.5 K to $11.1 K for AT MSC, proving that the transition to Vertical‐Wheel reactors provides a cost‐effective alternative for MSC expansion. The present work reports the establishment of a scalable and cost‐effective culture platform for the manufacturing of UCM and AT MSC in a S/XF microcarrier‐based system.
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