Analysis of the Adherence of Dental Pulp Stem Cells on Two-Dimensional and Three-Dimensional Silk Fibroin-Based Biomaterials.

Among various biomaterials used as scaffolds in tissue engineering, silk fibroin is a highly attractive material. A scaffold should be biocompatible and nontoxic, with optimal physical features and mechanical properties. For this reason, tissue-engineering approaches in regenerative medicine have focused on investigating the biocompatibility of possible biomaterials by analyzing cell-scaffold interaction properties. The aim of the present study was to examine the biocompatibility of silk fibroin as a film (two-dimensional [2D]) and a scaffold (three-dimensional [3D]) after being cellularized with human dental pulp stem cells (hDPSCs). Human dental pulp stem cells were isolated from healthy patients aged between 18 and 31 years. Further, silk fibroin-based 2D films and 3D scaffolds were prepared. Human dental pulp stem cells were directly seeded onto the biomaterial surfaces and their proliferation, adherence, and cell morphology were analyzed after 24, 120, and 168 hours. Additionally, the characteristics of the silk fibroin 2D films and 3D scaffolds before and after cell seeding were analyzed by scanning electron microscopy. After the initial 24 hours, silk fibroin-based 3D scaffolds displayed more adhered cells with a suitable fibroblastic morphology than those displayed on the 2D films. After longer culture times, hDPSCs proliferated sufficiently to cover the entire surface of the 3D silk fibroin scaffold, whereas the 2D films were only partially covered. Our results indicate the good in vitro biocompatibility of silk fibroin-based biomaterials, especially when 3D scaffolds rather than 2D films are used.

Silk-Fibroin and Graphene Oxide Composites Promote Human Periodontal Ligament Stem Cell Spontaneous Differentiation into Osteo/Cementoblast-Like Cells.

Graphene represents one of the most interesting additions to the tissue engineering toolbox. Novel graphene-based composites are required to improve the beneficial graphene properties in terms of tridimensional polymeric structure, conferring a higher mechanical strength and favoring the differentiation of human mesenchymal stem cells. Here, we have demonstrated in a wide range of composite combinations, the successful use of graphene and silk-fibroin constructs for future bioengineering applications in the field of clinical regenerative dentistry using human periodontal ligament stem cells. Our results provide exciting new data for the development of suitable scaffolds that allow good cell engrafting, preservation of cell viability and proliferation, promotion of spontaneous osteoblastic differentiation, and importantly, stimulation of a higher cementum physiological synthesis than using other different available biomaterials.