MnO(2) nanoflakes coated on carbon nanohorns (CNHs) has been synthesized via a facile solution method and evaluated as anode for lithium-ion batteries. By using CNHs as buffer carrier, MnO(2)/CNH composite displays an excellent capacity of 565 mA h/g measured at a high current density of 450 mA/g after 60 cylces.
A versatile strategy to endow dental implants with long-term antibacterial ability without compromising the cytocompatibility is highly desirable to combat implant-related infection. Silver nanoparticles (Ag NPs) have been utilized as a highly effective and broad-spectrum antibacterial agent for surface modification of biomedical devices. However, the high mobility and subsequent hazardous effects of the particles on mammalian cells may limit its practical applications. Thus, Ag NPs were immobilized on the surface of sand-blasted, large grit, and acid-etched (SLA) titanium by manipulating the atomic-scale heating effect of silver plasma immersion ion implantation. The silver plasma immersion ion implantation-treated SLA surface gave rise to both good antibacterial activity and excellent compatibility with mammalian cells. The antibacterial activity rendered by the immobilized Ag NPs was assessed using Fusobacterium nucleatum and Staphylococcus aureus , commonly suspected pathogens for peri-implant disease. The immobilized Ag NPs offered a good defense against multiple cycles of bacteria attack in both F. nucleatum and S. aureus , and the mechanism was independent of silver release. F. nucleatum showed a higher susceptibility to Ag NPs than S. aureus , which might be explained by the presence of different wall structures. Moreover, the immobilized Ag NPs had no apparent toxic influence on the viability, proliferation, and differentiation of rat bone marrow mesenchymal stem cells. These results demonstrated that good bactericidal activity could be obtained with very small quantities of immobilized Ag NPs, which were not detrimental to the mammalian cells involved in the osseointegration process, and promising for titanium-based dental implants with commercial SLA surfaces.
Surface energy of implant material is one of the important factors in the process of osseointegration. How surface energy regulates the signaling pathway of osteoblasts, however, is not well understood. Cell adhesion is one of the first steps essential to subsequent proliferation and differentiation of bone cells before tissue formation. Our present study was designed to investigate how surface energy may influence the early adhesion of human alveolar osteoblasts (AOBs). Substrates applied were two groups of titanium disks: (1) hydrophobic sandblasted and acid-etched (SLA) surfaces; (2) chemically modified hydrophilic SLA (modSLA) ones. Cell morphology and cell attachment were examined by scanning electron microscopy (SEM). Defined cytoskeletal actin organization was immunohistochemically examined using confocal laser scanning microscopy. RT-PCR was applied to detect and to compare the expression of focal adhesion kinase (FAK) of osteoblasts cultured on the two groups of substrates. The attachment rates of AOBs cultured on modSLA substrates were significantly higher than the cells on SLA ones within 3 h. AOBs on modSLA developed more defined actin stress fibers after 6 h of attachment. FAK expression was comparably higher on modSLA after 6 h. Within the limitation of the current study, higher surface energy of titanium surfaces enhanced the cell adhesion in the early stage of cell response and may work through influencing the expression of adhesion-associated molecules.
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