Over the last 50 years, biomaterials, prostheses and implants saved and prolonged the life of millions of humans around the globe. The main clinical complications for current biomaterials and artificial organs still reside in an interfacial mismatch between the synthetic surface and the natural living tissue surrounding it. Today, nanotechnology, nanomaterials and surface modifications provides a new insight to the current problem of biomaterial complications, and even allows us to envisage strategies for the organ shortage. Advanced tools and new paths towards the development of functional solutions for cardiovascular clinical applications are now available. In this talk, the potential of nanostructured metallic degradable metals to provide innovative solutions at medium term for the cardiovascular field will be depicted. Focus will be on Fe-based biodegradable metals with exceptional resistance, ductility and elasticity, for pushing innovative vascular applications. The intrinsic goal of this talk is to present an extremely personal look at how biodegradable metals can impact materials, surfaces and interfaces, and how the resulting unique properties allowed biomedical functional applications to progress, from their introduction, to the promising future that biodegradable metals may or may not hold for improving the quality of the life of millions worldwide.
First works focuses on the characterization (physical and biological) of this biomaterial. Current work had studied osteoinductive and osteoconductive capacity of these hydrogels. Bone is a dynamic and vascularized tissue that has the ability of naturally healing upon damage. Nevertheless, in the case of critical size defects this potential is impaired. Present approaches mainly consider autografts and allografts, which presents several limitations. Bone Tissue Engineering (BTE) is based on the use of 3D matrices to guide both cellular growth, differentiation to promote bone regeneration. Hence, matrices can contain biological materials such as cells and growth factors. Our project aims to design a hydrogel for BTE, particularly for bone lesion filling. We previously showed that a porous 3D hydrogel, Glycosyl-Nucleoside-Fluorinated (GNF) is: 1) non-cytotoxic to clustered human Adipose Mesenchymal Stem Cells (hASCs), 2) bioinjectable and 3) biodegradable. Therefore, this novel class of hydrogels show promise for the development of therapeutic solutions for BTE [1]. The hypothesis of this research was that improving the capacity to promote the adhesion of cells by adding collagen gel matrices and bone morphogenic protein 2 (BMP-2) to improve the bone regenerative potential of this gel. Collagen is a protein matrix well known for its cytocompatibility [2]. BMP-2, have been shown ability to induce bone formation in combination with an adequate matrix [3]. Thereby, the overall aim of this work was to design, develop and validate a new composite hydrogel for BTE. GNF was prepared as previously described in detail[1], at a concentration of 3% (w/v). Type I-collagen gel was prepared from rat-tail tendons at a concentration of 4 g/L [2]. hASCs were isolated from human adipose tissue in our laboratory. To establish a suitable microenvironment for cell proliferation and differentiation cells were seeded in collagen and then GNF gel was added and the resulting mixture was blended, BMP-2 (InductOs ® Kit) is added to this preparation (5µm BMP-2/ml). Fluorometry was used to follow BMP2 release Adding collagen hydrogel improve cell adhesion, survivals and proliferation rather than simple GNF hydrogel. This novel gel composite has the ability to sustain hASCs adhesion and differentiation towards the osteoblastic lineage (positive ALP cells). Fluorometry showed the ability of our hydrogel to prolong the residence of BMP-2 ( Adding collagen to GNF allowed to obtain gels showing satisfactory cell-behaviour. In parallel, the presence of GNF hydrogel helps to improve mechanical properties of the biomaterial (hydrogel stability and controlled release of BMP-2). The first
