Composite membranes of poly(lactic acid) with zinc-added bioactive glass as a guiding matrix for osteogenic differentiation of bone marrow mesenchymal stem cells.

This study aims to produce a degradable and bone-bioactive membrane for guiding bone regeneration by combining a degradable polymer, poly(lactic acid) (PLA), with a bioactive inorganic zinc-containing bioactive glass (ZnBG). The in vitro osteogenic development of rat bone marrow mesenchymal stem cells (rBMSCs) upon different membrane substrates (pure PLA control, PLA-BG, and PLA-ZnBG) was investigated in terms of bone cell phenotype syntheses and mineralization. Results showed significantly stimulated production of alkaline phosphatase and osteocalcin at days 14 and 21 in the membranes containing BG and ZnBG, with more in the samples containing ZnBG. The addition of ZnBG in PLA allowed the rBMSCs to express a high level of bone sialoprotein as confirmed by immunostaining. Cellular mineralization of the secreted extracellular matrix showed a significantly higher Ca level on the BG- and ZnBG-added membrane than on the PLA, and the more so in the ZnBG-added one. Based on the in vitro assessments using rBMSCs, the ZnBG-added PLA is considered to be of potential use in guiding active bone regeneration within the periodontal pocket.

Collagen three-dimensional hydrogel matrix carrying basic fibroblast growth factor for the cultivation of mesenchymal stem cells and osteogenic differentiation.

Three-dimensional (3D) collagen hydrogels have been extensively used for cell culture experiments and are more closely representative of in vivo conditions than monolayer (2D) culture. Here we cultured rat bone marrow-derived mesenchymal stem cells (MSCs) in collagen hydrogels containing varying concentrations of basic fibroblast growth factor (bFGF) to examine the effect of bFGF on MSC proliferation and osteogenic differentiation in 3D culture. The optimal bFGF concentration that promoted the greatest degree of cell proliferation and expression of the early osteogenic induction marker alkaline phosphatase was also determined. Subsequent quantitative real-time polymerase chain reaction analysis of gene expression demonstrated that bFGF promoted significant upregulation of the bone-related genes: collagen type I, osteopontin (OPN), bone sialoprotein (BSP), and osteocalcin (OCN) for periods of up to 21 days. Immunofluorescence staining and fluorescence-activated cell sorting analysis further supported the enhanced osteogenic differentiation of cells as a greater proportion of cells were found to express OPN. Matrix mineralization within the collagen hydrogels was enhanced in the presence of bFGF, as assessed by calcium detection using von Kossa staining. These results clearly demonstrate a positive effect of bFGF on proliferation and osteogenic induction of MSCs in 3D collagen hydrogels when applied at the appropriate concentration. Moreover, collagen hydrogel constructs containing MSCs and appropriate growth factor stimulus might be a potentially useful biological tool for 3D bone tissue engineering.

Effects on growth and osteogenic differentiation of mesenchymal stem cells by the zinc-added sol-gel bioactive glass granules.

Responses of mesenchymal stem cells (MSCs) cultured with zinc-added (2 and 5%) bioactive glass granules were evaluated in terms of cell growth and osteogenic differentiation. MSCs were cultured with different quantities (3, 10 and 30) of glass granules for up to 21 days in the osteogenic medium. Cell growth was stimulated by a small quantity of glasses, particularly those that contained zinc. Osteogenic differentiation, as assessed by alkaline phosphatase activity (ALP) activity, was significantly enhanced by the glasses, particularly with large quantities of glass and for prolonged culturing. Expression of bone-sialo protein (BSP) was significantly up-regulated around the bioactive glass granules. Moreover, the zinc addition significantly altered the ALP and BSP depending on the culture time and glass quantity. Cellular mineralization was improved in all glass samples, and particularly in the 2% zinc-glass. Taken together, the zinc addition to bioactive glass induced the MSCs growth and their osteogenic differentiation, at least to the level of zinc-free glass, and with even higher level observed depending on the quantity and culture time. These findings indicate that the zinc addition to bioactive glass may be useful in development of biomaterials for the stimulation of adult stem cell in bone tissue engineering.

Osteoclastic cell behaviors affected by the α-tricalcium phosphate based bone cements.

Calcium phosphate cements (CPCs) have recently gained great interest as injectable bone substitutes for use in dentistry and orthopedics. α-tricalcium phosphate (α-TCP) is a popularly used precursor powder for CPCs. When mixed with appropriate content of liquid and kept under aqueous conditions, α-TCP dissolves to form a calcium-deficient hydroxyapatite and then hardens to cement. In this study, α-TCP based cement (CP) and its composite cement with chitosan (Ch-CP) were prepared and the osteoclastic responses to the cements and their elution products were evaluated. Preliminary evaluation of the cements revealed that the CP and Ch-CP hardened within ~10 min at an appropriate powder-to-liquid ratio (PL) of 3.0. In addition, CP and Ch-CP were transformed into an apatite phase following immersion in a saline solution. Moreover, the osteoblastic cells were viable on the cements for up to 10 days. Mouse-derived bone marrow cells were isolated and activated with osteoclastic differentiation medium, and the effects of the CP and Ch-CP substrates and their ionic eluants on the osteoclastic activity were investigated. Osteoclastic cells were viable for up to 14 days on both types of cements, maintaining a higher cell growth level than the control culture dish. Multi-nucleated osteoclastic cells that were tartrate-resistant acid phosphatase (TRAP)-positive were clearly observed when cultured on the cement substrates as well as treated with the cement eluants. The TRAP activity was found to be significantly higher in cells influenced by the cement substrates and their eluants with respect to the control culture dish (Ch-CP > CP ≫ control). Overall, the osteoclastic differentiation was highly stimulated by the α-TCP based experimental cements in terms of both the substrate interaction and their elution products.

Novel scaffolds of collagen with bioactive nanofiller for the osteogenic stimulation of bone marrow stromal cells.

The properties of scaffolds and their roles in regulating functions of tissue cells are considered to be of utmost importance in the successful recovery of damaged tissues. Herein, novel scaffolds of collagen and bioactive inorganic nanofiller were produced for bone tissue engineering. In addition, the in vitro responses of bone marrow-derived stromal cells (BMSCs) on these scaffolds were investigated. Glasses with bioactive compositions were prepared in nanofibrous form and homogenized with a collagen to produce hybridized porous scaffolds. The glass fibrous filaments with diameters of a few hundred nanometers were embedded well within the collagen network, characterizing a typical nanocomposite. The scaffolds showed the characteristics of a hydrogel with remarkable water uptake and swelling degree, which were similar to those of the pure collagen. In addition, the scaffolds induced the precipitation of bone-like minerals on the surface under a body-simulating medium, showing the sign of in vitro bone bioactivity. BMSCs adhered and spread well over the scaffold surface and migrated deep into the scaffold network. The osteogenic marker, alkaline phosphatase, was strongly expressed on the hybrid scaffolds, with the level higher than that on pure collagen. Overall, the collagen-inorganic nanofiller scaffolds are considered to find potential utility in bone tissue engineering.