Table 1.
Osteogenic potential of graphene in bone tissue engineering scaffolds.
| Material | Analysis | Outcomes | Reference |
|---|---|---|---|
| rGO-Chitosan | SEM, Alizarin Red staining, and immunofluorescence | The differentiation on rGO-chitosan substrate was higher than the ones obtained on the chitosan Substrate and polystyrene regardless of the use of osteogenic induction media. | [53] |
| rGO-PEDOT | Immunofluorescence staining, Alizarin Red S staining | The multifunctional rGO-PEDOT bioelectronic interface was used for manipulating attachment and orientation of MSC. The device acted as a drug releasing model under electrical modulation. | [92] |
| GO | Immunofluorescence, microcomputed tomography, and Goldner trichrome | The osteogenetic differentiation of human BMMSCs on Ti/GO substrate was higher compared to Ti substrate. | [31] |
| GONR, rGONR | Immunofluorescence staining and Alizarin Red staining | Graphene nanogrids increase the osteogenic differentiation of BMSC; the differentiation coincides with the patterns of the nanogrids. | [88] |
| CVD | Immunofluorescence staining | The cells adhered and proliferated more on CVD-grown graphene than on SiO2 substrates. | [93] |
| CVD, GO | Immunofluorescence staining and Alizarin Red staining | Graphene was capable of preconcentrating osteogenic differentiation factors. GO strongly enhances adipogenic differentiation. | [87] |
| CVD | Cell viability assay, immunofluorescence staining, and Alizarin Red staining | CVD-grown graphene allowed the proliferation of MSC and increased the differentiation towards osteoblast. | [32] |
| 3DGp | Immunofluorescence staining and SEM | 3DGp maintains MSC viability and promotes osteogenic differentiation without the use of chemical inducers. | [89] |
| CaS-G | MTT, SEM, and RT-PCR | Cell adhesion was enhanced by adding 1.5% of graphene to the material as compared to the calcium silicate alone. | [94] |
| SGH | MTT, H & E, immunofluorescence staining, and Alizarin staining | The self-supporting graphene hydrogel (SGH) film allows cell adhesion and proliferation and accelerates the osteogenic differentiation without chemical inducer. | [95] |
| GO-CaP | Alizarin Red S staining RT PCR and immunofluorescence | The GO-CaP nanocomposite exhibited superior osteoinductivity compared to individual or combined effects of GO and CaP. | [91] |
| Carbon nanotubes and graphene | SEM, Elisa, and H & E staining | Cells in PLLA composite scaffolds containing 3 wt % of graphene presented higher expression of osteogenesis-related proteins, calcium deposition, and the formation of type I collagen. | [96] |
| Graphene hydrogel | MTT and SEM | Graphene 3D hydrogel allows cell proliferation and attachment confirming the biocompatibility of the graphene hydrogel scaffolds. | [97] |
Source: Reference [98] (copyright 2015, Stem Cells International).