Elaboration and evaluation of alginate foam scaffolds for soft tissue engineering

Controlling microarchitecture in polymer scaffolds is a priority in material design for soft tissue applications. This paper reports for the first time the elaboration of alginate foam-based scaffolds for mesenchymal stem cell (MSC) delivery and a comparative study of various surfactants on the final device performance. The use of surfactants permitted to obtain highly interconnected porous scaffolds with tunable pore size on surface and in cross-section. Their mechanical properties in compression appeared to be adapted to soft tissue engineering. Scaffold structures could sustain MSC proliferation over 14 days. Paracrine activity of scaffold-seeded MSCs varied with the scaffold structure and growth factors release was globally improved in comparison with control alginate scaffolds. Our results provide evidence that exploiting different surfactant types for alginate foam preparation could be an original method to obtain biocompatible scaffolds with tunable architecture for soft tissue engineering

Laser transmission welding as an assembling process for high temperature electronic packaging.

Higher efficiency, power density, reliability and longer lifetime of power electronic devices would stem from progresses in material science. In this work, we propose to use a high performance thermoplastic polymer PAEK as packaging box to extend the operating temperature above 200°C. More, the laser transmission welding process has been applied to PAEK to join the two-part module. In order to validate this assembling process, the temperature distribution inside the specimens was measured during laser transmission welding. The assembly consists of a quasi-amorphous sample as the upper part and a semi-crystalline sample as the lower part. The temperature fields were measured by infrared thermography with the camera sensor perpendicular to the welded interface. With an energy beam of 28 J.mm-2 and irradiation time of 15 s, we have noticed that the maximum temperature inside the sample is kept far from the PAEK degradation one. Moreover, the temperature at the interface reaches the melting temperature thus assuring enough mobility for polymeric chains to get adhesion at the interface. The location and size of the heat-affected zone has been determined. Finally, some frames were machined and successfully welded

058 The ongoing MESAMI translational research program

PurposeDespite the improvement of pharmacological and surgical therapies, the mortality related to ischemic heart failure remains high. During the last years, bone marrow-mesenchymal stem cell (BM-MSC) therapy has been proposed as a novel approach for the prevention and therapy of heart failure. Intramyocardial injection allows concentration of grafted cells within the injured zone. However, a major problem of with intraparenchymal route of administration is the early death of most of grafted cells. The goal of the MESAMI program is to evaluate the effect of intramyocardial administration of BM-MSC preconditioned or not with the pineal hormone melatonin in ischemic cardiomyopathy.Methods and ResultsOur preclinical investigations have designed a preconditioning strategy of BM-MSCs with the melatonin that significantly increases survival and efficacy of grafted cells in animal models of myocardial ischemia. Melatonin treatment significantly ameliorates the beneficial effects of BM-MSC on the recovery of cardiac function. In the mean time, we started a phase I clinical trial in patients with severe ischemic cardiomyopathy and no option of revascularization, using the NOGA XP system to guide injections into the myocardium. Based on our basic research results, we are developing a multicenter phase II trial on the effects of intramyocardial administration of melatonin-preconditioned BM-MSC in patients with chronic ischemic cardiomyopathy.ConclusionThe ongoing MESAMI program is representative of a translational research program in France

Evaluation of polyelectrolyte complex-based scaffolds for mesenchymal stem cell therapy in cardiac ischemia treatment

Three-dimensional (3D) scaffolds hold great potential for stem cell-based therapies. Indeed, recent results have shown that biomimetic scaffolds may enhance cell survival and promote an increase in the concentration of therapeutic cells at the injury site. The aim of this work was to engineer an original polymeric scaffold based on the respective beneficial effects of alginate and chitosan. Formulations were made from various alginate/chitosan ratios to form opposite-charge polyelectrolyte complexes (PECs). After freeze-drying, the resultant matrices presented a highly interconnected porous microstructure and mechanical properties suitable for cell culture. In vitro evaluation demonstrated their compatibility with mesenchymal stell cell (MSC) proliferation and their ability to maintain paracrine activity. Finally, the in vivo performance of seeded 3D PEC scaffolds with a polymeric ratio of 40/60 was evaluated after an acute myocardial infarction provoked in a rat model. Evaluation of cardiac function showed a significant increase in the ejection fraction, improved neovascularization, attenuated fibrosis as well as less left ventricular dilatation as compared to an animal control group. These results provide evidence that 3D PEC scaffolds prepared from alginate and chitosan offer an efficient environment for 3D culturing of MSCs and represent an innovative solution for tissue engineering

Evaluation of polyelectrolyte complex-based scaffolds for mesenchymal stem cell therapy in cardiac ischemia treatment

b s t r a c t Three-dimensional (3D) scaffolds hold great potential for stem cell-based therapies. Indeed, recent results have shown that biomimetic scaffolds may enhance cell survival and promote an increase in the concentration of therapeutic cells at the injury site. The aim of this work was to engineer an original polymeric scaffold based on the respective beneficial effects of alginate and chitosan. Formulations were made from various alginate/chitosan ratios to form opposite-charge polyelectrolyte complexes (PECs). After freeze-drying, the resultant matrices presented a highly interconnected porous microstructure and mechanical properties suitable for cell culture. In vitro evaluation demonstrated their compatibility with mesenchymal stell cell (MSC) proliferation and their ability to maintain paracrine activity. Finally, the in vivo performance of seeded 3D PEC scaffolds with a polymeric ratio of 40/60 was evaluated after an acute myocardial infarction provoked in a rat model. Evaluation of cardiac function showed a significant increase in the ejection fraction, improved neovascularization, attenuated fibrosis as well as less left ventricular dilatation as compared to an animal control group. These results provide evidence that 3D PEC scaffolds prepared from alginate and chitosan offer an efficient environment for 3D culturing of MSCs and represent an innovative solution for tissue engineering

Nouvelles architectures de convertisseurs électroniques de puissance utilisant des transformateurs intercellulaires

ID = 559National audienc

Etude et realisation d'une alimentation de tube a ondes progressives

SIGLEAvailable from INIST (FR), Document Supply Service, under shelf-number : T83324 / INIST-CNRS - Institut de l'Information Scientifique et TechniqueFRFranc

Dimensionnement de transformateurs intercellulaires pour un convertisseur flyback multicellulaire de forte puissance

ID = 558National audienc

FilSiC – De l'épitaxie au module de puissance

National audienceLes domaines de la mobilité et de la distribution d'énergie électrique nécessitent des convertisseurs statiques de plus en plus fortes puissances avec de meilleurs rendements et la capacité de fonctionner à plus hautes températures. Le programme FilSiC, porté par plusieurs PME et laboratoires complémentaires, a pour ambition de développer une filière de composants de puissance Haute Tension en SiC dont le premier résultat est une diode 3300V présentée ici