Mimicking of Blood Flow Results in a Distinct Functional Phenotype in Human Non-Adherent Classical Monocytes.
Elisa WirthgenMelanie HornschuhIda Maria WrobelChristian ManteuffelJan DäbritzPublished in: Biology (2021)
Ex vivo culture conditions during the manufacturing process impact the therapeutic effect of cell-based products. Mimicking blood flow during ex vivo culture of monocytes has beneficial effects by preserving their migratory ability. However, the effects of shear flow on the inflammatory response have not been studied so far. Hence, the present study investigates the effects of shear flow on both blood-derived naïve and activated monocytes. The activation of monocytes was experimentally induced by granulocyte-macrophage colony-stimulating factor (GM-CSF), which acts as a pro-survival and growth factor on monocytes with a potential role in inflammation. Monocytes were cultured under dynamic (=shear flow) or static conditions while preventing monocytes' adherence by using cell-repellent surfaces to avoid adhesion-induced differentiation. After cultivation (40 h), cell size, viability, and cytokine secretion were evaluated, and the cells were further applied to functional tests on their migratory capacity, adherence, and metabolic activity. Our results demonstrate that the application of shear flow resulted in a decreased pro-inflammatory signaling concurrent with increased secretion of the anti-inflammatory cytokine IL-10 and increased migratory capacity. These features may improve the efficacy of monocyte-based therapeutic products as both the unwanted inflammatory signaling in blood circulation and the loss of migratory ability will be prevented.
Keyphrases
- blood flow
- peripheral blood
- dendritic cells
- growth factor
- endothelial cells
- inflammatory response
- single cell
- anti inflammatory
- cell therapy
- high glucose
- type diabetes
- immune response
- adipose tissue
- squamous cell carcinoma
- stem cells
- induced apoptosis
- cell proliferation
- bone marrow
- pseudomonas aeruginosa
- insulin resistance
- radiation therapy
- metabolic syndrome
- weight loss
- endoplasmic reticulum stress
- skeletal muscle
- free survival