Exploring the Hierarchical Structure and Alignment of Wood Cellulose Fibers for Bioinspired Anisotropic Polymeric Composites.

Materials found in nature have their properties tuned by the chemical composition and hierarchical organization of their structures. Wood is one example of natural material which has properties tuned by its multi-scale hierarchical organization. The cellulose microfibril angle is critical for physical and mechanical properties of wood. On the other hand, polymeric composites containing fibrillar additives, like cellulose fibers, are widespread and have exceptional mechanical properties, which enable them to be used as structural materials. However, obtaining polymer composites with well-aligned cellulose fibers is a challenging task. This work aims to explore the hierarchical structure and alignment of cellulose fibers from wood in polymeric composites with anisotropic mechanical properties, inspired by what trees naturally do. In this sense, cellulosic material from wood was analyzed on a multi-scale; impregnation with polyethylene and densification were performed to form composites; and their mechanical properties were correlated with fiber angles in composite specimens. Moreover, polymer addition to the cellulosic backbone has tremendously increased the material resistance to wetting and chemical oxidation.

Evaluation of the sintering temperature on the mechanical behavior of ß-tricalcium phosphate/calcium silicate scaffolds obtained by gelcasting method.

Scaffolds have been studied during the last decades as an alternative method to repair tissues. They are porous structures that act as a substrate for cellular growth, proliferation and differentiation. In this study, scaffolds of ß-tricalcium phosphate with calcium silicate fibers were prepared by gel casting method in order to be characterized and validated as a better choice for bone tissue treatment. Gel-casting led to scaffolds with high porosity (84%) and pores sizes varying from 160 to 500 µm, which is an important factor for the neovascularization of the growing tissue. Biocompatible and bioactive calcium silicate fibers, which can be successfully produced by molten salt method, were added into the scaffolds as a manner to improve its mechanical resistance and bioactivity. The addition of 5 wt% of calcium silicate fibers associated with a higher sintering temperature (1300 °C) increased by 64.6% the compressive strength of the scaffold and it has also led to the formation of a dense and uniform apatite layer after biomineralization assessment.