Abstract: The present invention relates to a bio-functionalized fibrous structure with a core/shell architecture for partial or total repair of human tendons or ligaments. The architecture based on a core/shell system grants to the fibrous structure a specific physical and mechanical behaviour when it is repeatedly mechanically loaded, as happens with a native tendon or ligament in constant usage in the human body. The core is based on several sub-components, namely braided structures parallelly assembled, which are enclosed by a braided shell. Additionally, a selective bio-functionalization of the two parts of the core/shell structure can be applied in order to selectively improve or avoid the in vivo cell adhesion.

Abstract: The disclosed subject matter refers to hydroxyapatite and bioglass-based pellets of homogeneous size and spherical shape, whose interconnective porous structure, in the micrometer range, allows for an enhanced osteoconductivity and osteointegration, with specific application as a synthetic bone graft and to the respective production process. The production process is based on the pharmaceutical technology of extrusion and spheronization employing a porogenic agent and applying a sinterization stage in the presence of a vitreous liquid phase, which reverts on behalf of a higher reproducibility, superior yield and greater production capacity.

Abstract: The disclosed invention is based on hydroxyapatite, biocompatible glass and silicon, aiming to develop an improved bone substitute, which presents higher mechanical resistance, bioactivity and osteoregeneration, and susceptible of being used in several medical and surgical fields, with application in the treatment of bone disease caused by trauma or genetic factors, as osteoconductive support for cellular growth. The abovementioned bone substitute comprises hydroxyapatite, a biocompatible glass of the P2O5—CaO system in a percentage up to 10 wt % relatively to the hydroxyapatite weight, and a silicon source in a concentration up to 10 wt % relatively to hydroxyapatite and biocompatible glass weight.