Coaxial electrospun PCL/Gelatin-MA fibers as scaffolds for vascular tissue engineering.

Coaxial electrospinning is a technique that allows the production of nanofibers with a core-shell structure. Such fibers present several advantages as materials for the preparation of scaffolds, namely due to the possibility of combining a core with the desired mechanical properties with a shell prepared from biocompatible materials that will establish proper interactions with the host. Herein, core-shell fibrous meshes, composed of a polycaprolactone (PCL) core and a functionalized gelatin shell, were prepared by coaxial electrospinning and then photocrosslinked under UV light aiming to be used in vascular tissue regeneration. The suitability of the meshes for the pretended biomedical application was evaluated by assessing their chemical/physical properties as well as their haemo and biocompatibility in vitro. The obtained results revealed that meshes' shell prepared with a higher content of gelatin showed fibers with diameters presenting a unimodal distribution and a mean value of 600nm. Moreover, those fibers with higher content of gelatin also displayed lower water contact angles, and therefore higher hydrophilicities. Such features are crucial for the good biologic performance displayed by these meshes, when in contact with blood and with Normal Human Dermal Fibroblasts cells.

Production and characterization of polycaprolactone- hyaluronic acid/chitosan- zein electrospun bilayer nanofibrous membrane for tissue regeneration.

A bilayered electrospun membrane was produced in this study, using the electrospinning technique, to be applied as a skin substitute. The upper layer of the membrane was comprised by hyaluronic acid and polycaprolactone in order to provide mechanical support and also to act as a physical barrier against external threats. Chitosan and zein were used to produce the bottom layer that was loaded with salicylic acid, in order to confer anti-inflammatory and antimicrobial activity to this layer. The physicochemical properties of the membranes were determined and the obtained results showed that the produced electrospun membrane display an ideal porosity, appropriate mechanical properties, controlled water loss and a suitable salicylic acid release profile. In addition, membranes did not exhibit any toxic effects for human fibroblast cells, since cells were able to adhere, spread and proliferate. Furthermore, no biofilm formation was noticed on membranes' surface along the experiments. In conclusion, the gathered data reveal that this electrospun membrane has suitable properties to be used as a wound dressing.

3D Printed scaffolds with bactericidal activity aimed for bone tissue regeneration.

Nowadays, the incidence of bone disorders has steeply ascended and it is expected to double in the next decade, especially due to the ageing of the worldwide population. Bone defects and fractures lead to reduced patient's quality of life. Autografts, allografts and xenografts have been used to overcome different types of bone injuries, although limited availability, immune rejection or implant failure demand the development of new bone replacements. Moreover, the bacterial colonization of bone substitutes is the main cause of implant rejection. To vanquish these drawbacks, researchers from tissue engineering area are currently using computer-aided design models or medical data to produce 3D scaffolds by Rapid Prototyping (RP). Herein, Tricalcium phosphate (TCP)/Sodium Alginate (SA) scaffolds were produced using RP and subsequently functionalized with silver nanoparticles (AgNPs) through two different incorporation methods. The obtained results revealed that the composite scaffolds produced by direct incorporation of AgNPs are the most suitable for being used in bone tissue regeneration since they present appropriate mechanical properties, biocompatibility and bactericidal activity.