Bone marrow mesenchymal stem cells (BMSCs) have great potential in tissue engineering and clinical therapy, and various methods for isolation and cultivation of BMSCs have been reported. However, the best techniques are still uncertain. Therefore, we sought the most suitable among the four most common methods for BMSC separation from rabbits. BMSCs were obtained from untreated whole bone marrow (BM) adherent cultures, 3 volumes of red blood cells (RBC) lysed with ammonium chloride, 6 volumes of RBC lysed with ammonium chloride, and Ficoll density gradient centrifugation. Then, isolated BMSCs were evaluated with respect to primary cell yield, number of CFU-F colonies, proliferative capacity, cell phenotype, and chondrogenic differentiation potential. Our data show that BMSCs were successfully isolated by all four methods, and each method was similar with regard to cell morphology, phenotype, and differentiation potential. However, BMSCs from untreated whole BM adherent cultures had greater primary cell yields, larger colonies, and the shortest primary culture time (P<0.05). Moreover, the 4th generation of cultured cells had the strongest proliferative activity, the fastest growth rate and the most numerous cells compared with other cell passage generations (P<0.05). In conclusion, untreated whole BM adherent cultures are best for rabbit BMSC isolation and the 4th generation of cells has the strongest proliferation capacity.
3D printing technology has various advantages, and the incorporation of bioactive substances into the 3D printed scaffold provides the biological and architectural characteristics of the scaffolds, which is very important for obtaining a good osseointegration effect. In this relation, this study prepared a novel porous hollow cage poly(lactic acid) (PLA) 3D printed scaffold and combined recombinant human bone morphogenetic protein-2 (rhBMP-2) and/or mesenchymal stem cells (MSCs) with Biogel composed of gelatin and alginate. Then, the scaffolds were used to evaluate the resulting bone regeneration through both in vitro and in vivo tests. The experimental group was divided into four groups as follows: only PLA scaffold (PLA); PLA scaffold filled with BMP-2 loaded on Biogel (P-BG-B2); PLA scaffold filled with MSCs encapsulated Biogel (P-BG-M); PLA scaffold filled with both BMP-2 and MSCs loaded on Biogel (P-BG-B2-M). Then in vitro results showed that the PLA-Biogel-based scaffold increased cell proliferation, and the P-BG-B2-M group showed a higher alkaline phosphatase activity and bone-related gene expression than was seen with the P-BG-M group at all the time points. It was shown that four weeks post-operative micro-CT analysis showed that within the defect site the P-BG-B2 group had a significantly higher percent bone volume (BV/TV) than the PLA group and P-BG-M group. And, out of the defect site, the P-BG-B2-M group BV/TV was shown significantly higher than the PLA group (p < 0.05). Histologically, defects in the P-BG-B2-M group showed a homogeneous new bone distribution, however the P-BG-B2 group and P-BG-M group presented a notably higher bone formation in the internal region than in the proximal region of the bone defect site. In conclusion, the 3D PLA-Biogel-based scaffold adapted rhBMP-2 and MSCs with carrier PLA showed good biocompatibility and high possibility as an effective and satisfactory bone graft material.
In this study, the paracrine effect between adipose-derived mesenchymal stem cells (ADSCs) and osteoblasts was investigated in collagen-based three-dimensional (3D) scaffolds.
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