3D Printed Poly(𝜀-caprolactone)/Hydroxyapatite Scaffolds for Bone Tissue Engineering: A Comparative Study on a Composite Preparation by Melt Blending or Solvent Casting Techniques and the Influence of Bioceramic Content on Scaffold Properties.

Bone tissue engineering has been developed in the past decades, with the engineering of bone substitutes on the vanguard of this regenerative approach. Polycaprolactone-based scaffolds are fairly applied for bone regeneration, and several composites have been incorporated so as to improve the scaffolds' mechanical properties and tissue in-growth. In this study, hydroxyapatite is incorporated on polycaprolactone-based scaffolds at two different proportions, 80:20 and 60:40. Scaffolds are produced with two different blending methods, solvent casting and melt blending. The prepared composites are 3D printed through an extrusion-based technique and further investigated with regard to their chemical, thermal, morphological, and mechanical characteristics. In vitro cytocompatibility and osteogenic differentiation was also assessed with human dental pulp stem/stromal cells. The results show the melt-blending-derived scaffolds to present more promising mechanical properties, along with the incorporation of hydroxyapatite. The latter is also related to an increase in osteogenic activity and promotion. Overall, this study suggests polycaprolactone/hydroxyapatite scaffolds to be promising candidates for bone tissue engineering, particularly when produced by the MB method.

Rat Olfactory Mucosa Mesenchymal Stem/Stromal Cells (OM-MSCs): A Characterization Study.

Stem/stromal cell-based therapies are a branch of regenerative medicine and stand as an attractive option to promote the repair of damaged or dysfunctional tissues and organs. Olfactory mucosa mesenchymal stem/stromal cells have been regarded as a promising tool in regenerative therapies because of their several favorable properties such as multipotency, high proliferation rate, helpful location, and few associated ethical issues. These cells are easily accessible in the nasal cavity of most mammals, including the rat, can be easily applied in autologous treatments, and do not cope with most of the obstacles associated with the use of other stem cells. Despite this, its application in preclinical trials and in both human and animal patients is still limited because of the small number of studies performed so far and to the nonexistence of a standard and unambiguous protocol for collection, isolation, and therapeutic application. In the present work a validation of a protocol for isolation, culture, expansion, freezing, and thawing of olfactory mucosa mesenchymal stem/stromal cells was performed, applied to the rat model, as well as a biological characterization of these cells. To investigate the therapeutic potential of OM-MSCs and their eventual safe application in preclinical trials, the main characteristics of OMSC stemness were addressed.

Processing, Characterization, and in Vivo Evaluation of Poly(l-lactic acid)-Fish Gelatin Electrospun Membranes for Biomedical Applications.

The development of biomaterials for application in advanced therapies requires thorough characterization of its biological behavior, which ultimately entails in vivo compatibility and performance assays. Electrospun fiber membranes of poly(l-lactic acid) (PLLA) and fish gelatin blends were produced and characterized, coupling the biomechanical features of PLLA with gelatin (GEL) biocompatibility. Fiber diameter was not affected by polymer blending, whereas the swelling degree increased with increasing GEL contents for values up to 566 ± 13%, behaving as a superhydrophilic material. Human umbilical cord-derived mesenchymal stem cells (hUC-MSCs) adhesion was favored in the PLLA-GEL membranes, and cell viability was not affected after 7 days in culture. Membranes were then evaluated for in vivo biocompatibility through subcutaneous implantation in a rat model, for up to 15 days. No significant differences between the biological behavior of PLLA, PLLA-GEL, and GEL electrospun membranes at 15 days postimplantation were verified, with attained inflammation scores supporting an acceptable tissue response, deeming them fit for further biological assays. This work demonstrates that fiber blends of PLLA and GEL present promising in vitro and in vivo characteristics to be explored for tissue engineering.