In vivo bone regeneration induced by a scaffold of chitosan/dicarboxylic acid seeded with human periodontal ligament cells

Chitosan/dicarboxylic acid (CS/DA) scaffold has been developed as a bone tissue engineering material. This study evaluated a CS/DA scaffold with and without seeded primary human periodontal ligament cells (hPDLCs) in its capacity to regenerate bone in calvarial defects of mice. The osteogenic differentiation of hPDLCs was analyzed by bone nodule formation and gene expression. In vivo bone regeneration was analyzed in mice calvarial defects. Eighteen mice were divided into 3 groups: one group with empty defects, one group with defects with CS/DA scaffold, and a group with defects with CS/DA scaffold and with hPDLCs. After 6 and 12 weeks, new bone formation was assessed using microcomputed tomography (Micro-CT) and histology. CS/DA scaffold significantly promoted in vitro osteoblast-related gene expression (RUNX2, OSX, COL1, ALP, and OPN) by hPDLCs. Micro-CT revealed that CS/DA scaffolds significantly promoted in vivo bone regeneration both after 6 and 12 weeks (p < 0.05). Histological examination confirmed these findings. New bone formation was observed in defects with CS/DA scaffold; being similar with and without hPDLCs. CS/DA scaffolds can be used as a bone regenerative material with good osteoinductive/osteoconductive properties

Ring-opening polymerization of lactones using binaphthyl-diyl hydrogen phosphate as organocatalyst and resulting monosaccharide functionalization of polylactones

International audienceno abstrac

Produção e caracterização de microesferas de quitosana modificadas quimicamente Production and characterization of chemically modified chitosan microspheres

Microesferas de quitosana podem ser empregadas na área de biomaterias, em processos biotecnológicos e como adsorventes. Neste trabalho, foi empregada a técnica de atomização e coagulação para produção dessas microesferas, que permitiu o controle dos parâmetros de operação e por conseqüência a obtenção de microesferas de tamanho e faixas de tamanho específicos. Após a sua obtenção, as microesferas foram modificadas quimicamente com objetivo de estudar as resistências térmica, mecânica e química. Para isso foram empregadas três rotas distintas: a-) reticulação com glutaraldeído; b-) reticulação com epicloridrina e c-) acetilação. As microesferas preparadas apresentaram distribuição de tamanho da ordem de 140 µm com desvio padrão de 11,9 µm. Após as modificações químicas, as microesferas apresentaram temperatura de degradação térmica em torno de 300 ºC, aumento da estabilidade química à solução de HCl, e diminuição da resistência mecânica.<br>Chitosan microspheres can be used as biomaterial, in biotechnology processes and as adsorbents. This work is concerned with the production of chitosan microspheres using spraying and coagulation processes, which allows us to control the operating parameters and to produce chitosan microspheres of several ranges and sizes. The microspheres were modified chemically in order to study their thermal, mechanical and chemical resistance. The methods used were: 1) crosslinking with glutaraldehyde; 2) crosslinking with epichlorohydrin; 3) acetylation. The microspheres obtained presented mean particle size of 140 µm and standard deviation of 11.9 µm. The modified microspheres showed thermal degradation around 300 ºC, an increase of chemical stability using HCl solution and a decrease of mechanical resistance