Evaluation of differentiated bone cells proliferation by blue shark skin collagen via biochemical for bone tissue engineering
Elango, J.; Lee, J.W.; Wang, S.; Henrotin, Y.; de Val, J.E.M.S.; Regenstein, J.M.; Lim, S.Y.; Bao, B.; Wu, W. (2018). Evaluation of differentiated bone cells proliferation by blue shark skin collagen via biochemical for bone tissue engineering. Mar. Drugs 16(10): 350. https://dx.doi.org/10.3390/md16100350 In: Marine Drugs. Molecular Diversity Preservation International (MDPI): Basel. ISSN 1660-3397; e-ISSN 1660-3397, more | |
Keyword | | Author keywords | blue shark collagen; osteogenic activity; Runx2; differentiatedmesenchymal stem cell; osteoblast; proliferation |
Authors | | Top | - Elango, J.
- Lee, J.W.
- Wang, S.
| - Henrotin, Y., more
- de Val, J.E.M.S.
- Regenstein, J.M.
| |
Abstract | Collagen from a marine resource is believed to have more potential activity in bone tissue engineering and their bioactivity depends on biochemical and structural properties. Considering the above concept, pepsin soluble collagen (PSC) and acid soluble collagen (ASC) from blue shark (Prionace glauca) skin were extracted and its biochemical and osteogenic properties were investigated. The hydroxyproline content was higher in PSC than ASC and the purified collagens contained three distinct bands α1, α2, and β dimer. The purity of collagen was confirmed by the RP-HPLC profile and the thermogravimetric data showed a two-step thermal degradation pattern. ASC had a sharp decline in viscosity at 20–30 °C. Scanning electron microscope (SEM) images revealed the fibrillar network structure of collagens. Proliferation rates of the differentiated mouse bone marrow-mesenchymal stem (dMBMS) and differentiated osteoblastic (dMC3T3E1) cells were increased in collagen treated groups rather than the controls and the effect was dose-dependent, which was further supported by higher osteogenic protein and mRNA expression in collagen treated bone cells. Among two collagens, PSC had significantly increased dMBMS cell proliferation and this was materialized through increasing RUNX2 and collagen-I expression in bone cells. Accordingly, the collagens from blue shark skin with excellent biochemical and osteogenic properties could be a suitable biomaterial for therapeutic application. |
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