Comparative Study on the Effect of the Different Harvesting Sources of Demineralized Bone Particles on the Bone Regeneration of a Composite Gellan Gum Scaffold for Bone Tissue Engineering Applications.

Bone is the rigid tissue that constitutes the skeleton. The material for bone regeneration has to provide the mechanical stability by maintaining the mechanical loads both in the rest conditions and during the body movements. Bone is dynamic tissue constantly reshaped by the action of cells (osteoblasts and osteoclasts). This activity is normally enough to heal bone injuries; however, in several conditions, when bone is subjected to fatal damages, self-renewal is difficult, if not even impossible, and a medical treatment is required. The transplantation of a biomaterial is one of the common surgical procedures to overcome critical injuries. In this study, we exploited the effect of the use of different sources of demineralized bone powder (DBP) in combination with gellan gum (GG) to form a GG-DBP hydrogel scaffold with the purpose of regenerating the bone tissue. DBP was extracted from the femurs of two typologies of Gallus gallus domesticus (the Yeonsan Ogye, a traditional and rare black chicken from Korea, and the Cornish cross, the most common breeds for industrial meat production) and the Pekin duck. The composite scaffold has been tested both in vitro and in vivo. In vitro studies using rat bone marrow-derived mesenchymal stem cells (rBMSCs) confirmed the cellular suitability of bone-specific gene expression for seeded GG-DBP scaffolds, differentiation capacity, and marked upregulation. The scaffold containing a DBP derived from the Yeonsan Ogye (YO) bone showed higher levels of cell proliferation and osteogenic differentiation in comparison with the scaffold with the DBP obtained from the other studied sources. These results have been related with the higher amount of melanin, studied by fluorescence, of the YO DBP compared to Cornish cross and Pekin duck. Overall, this study clearly shows the use of YO DBP as a promising material in bone tissue regeneration.

Development of fluorescein isothiocyanate conjugated gellan gum for application of bioimaging for biomedical application.

Herein, gellan gum (GG), a nature-derived polysaccharide, was applied to combine fluorescein isothiocyanate (FITC) to fabricate a bio-imaging material. The synthesis process of the FITC grafted GG (GG-F) and manufacturing method of GG-F scaffolds are presented. Chemical, physicochemical, and mechanical properties were characterized. In vitro study and in vivo study by implanting the GG-F scaffolds under the subcutaneous area of the nude mice were carried out to verify biocompatibility and safety of the material. The emission of the FITC was confirmed with high-resolution confocal laser scanning microscope (SR CLMS) and fluorescence in vivo imaging (FOBI). The results exhibited well-synthesized GG-F and the manufactured GG-F scaffolds showed similar property of GG scaffolds which confirms that the chemical modification does not affect the property of GG scaffolds. The in vitro and in vivo study exhibited biocompatibility of the GG-F material. Overall, the properly blended GG-F in GG did not influence the characteristics of the pristine GG except for the chemical property. Therefore, the GG-F can be applied for the future analysis in verifying the mechanism of GG characters and can be a promising candidate for bio-imaging.

Osteochondral and bone tissue engineering scaffold prepared from Gallus var domesticus derived demineralized bone powder combined with gellan gum for medical application.

Osteochondral (OC) lesions can occur in the knee and ankle. Such lesions induce a fracture in the cartilage protecting the bone joints. Cartilage tissue shows limited self-regeneration ability, hence the tissue is avascular and lack of vascular innervation, while the bone is a unique organ with the capacity to self-repair of small defects. In this present study, we have prepared a scaffold using demineralized bone powder (DBP) extracted from Gallus gallus var domesticus (GD), and Gellan gum (GG) for OC tissue regeneration. They were characterized for their chemical, physical, mechanical and biological properties using different available techniques, in vitro bioactivity was performed in simulated body fluid for 14 days confirming the formation of bone-like apatite. The in vitro biocompatibility was analyzed using chondrocyte cells and osteogenic and chondrogenic marker gene expression using RT-PCR, in vivo experiments performed by implanting scaffold in rabbit and characterized by histology and immunofluorescent stainings. The obtained results indicated that the prepared pores scaffold was biocompatible, and promote OC regeneration and integration of newly formed tissues with the host tissues in a rabbit. The prepared 1% DBP/GG scaffold can be used as a potential and promising alternate material for OC regeneration.