Induced differentiation and molecular characterization of monocytes-derived multipotential cells generated from commonly discarded leukapheresis filters.

Monocyte-derived multipotential cells (MOMCs) are a subpopulation of monocytes that appear to be capable of differentiating into many cell populations, thus MOMCs can be an ideal autologous transplantable cell source for regenerative medicine. In this study, we generated MOMCs from leukapheresis filters, evaluated their ability to differentiate to endothelium and osteocytes and performed their molecular characterization. For this purpose, leukapheresis filters were collected from a hospital blood donation department and used for leukocytes isolation. The isolated leukocytes were cultured in a medium supplemented with SDF-1a for MOMCs generation. We evaluated the expression of the multipotency genes ZNF217, ZNF878, ESRRB, SALL4, KLF4, SOX2, NANOG, OCT4, GAPDH, CD34 and c- MYC in MOMCs with real-time reverse transcription PCR (qRT-PCR) and the differentiation capacity of MOMCs to osteocytes and endothelium with qRT-PCR. The results suggest that MOMCs can be generated using leukocytes isolated from leukapheresis filters in the presence of SDF-1a. Furthermore, MOMCs expressed all the tested factors responsible to activate the networks of pluripotency of cells and can differentiate into endothelium and osteocytes. Therefore, the blood donors could benefit and be rewarded with the potential use of their own immune system cells for future treatment in the frame of personalized regenerative medicine.

Differentiation Capacity of Monocyte-Derived Multipotential Cells on Nanocomposite Poly(e-caprolactone)-Based Thin Films.

Background: Μonocyte-derived multipotential cells (MOMCs) include progenitors capable of differentiation into multiple cell lineages and thus represent an ideal autologous transplantable cell source for regenerative medicine. In this study, we cultured MOMCs, generated from mononuclear cells of peripheral blood, on the surface of nanocomposite thin films. Methods: For this purpose, nanocomposite Poly(e-caprolactone) (PCL)-based thin films containing either 2.5 wt% silica nanotubes (SiO2ntbs) or strontium hydroxyapatite nanorods (SrHAnrds), were prepared using the spin-coating method. The induced differentiation capacity of MOMCs, towards bone and endothelium, was estimated using flow cytometry, real-time polymerase chain reaction, scanning electron microscopy and fluorescence microscopy after cells' genetic modification using the Sleeping Beauty Transposon System aiming their observation onto the scaffolds. Moreover, Wharton's Jelly Mesenchymal Stromal Cells were cultivated as a control cell line, while Human Umbilical Vein Endothelial Cells were used to strengthen and accelerate the differentiation procedure in semi-permeable culture systems. Finally, the cytotoxicity of the studied materials was checked with MTT assay. Results: The highest differentiation capacity of MOMCs was observed on PCL/SiO2ntbs 2.5 wt% nanocomposite film, as they progressively lost their native markers and gained endothelial lineage, in both protein and transcriptional level. In addition, the presence of SrHAnrds in the PCL matrix triggered processes related to osteoblast bone formation. Conclusion: To conclude, the differentiation of MOMCs was selectively guided by incorporating SiO2ntbs or SrHAnrds into a polymeric matrix, for the first time.