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L, Raicevic N, Nikolic Z, Trajkovic V: Distinct cytotoxic mechanism of pristine versus hydroxylated fullerene. Toxicol Sci 2006, 91:173–183.CrossRef 46. Meng Epigenetics inhibitor H, Xing G, Sun B, Zhao F, Lei H, Li W, Song Y, Chen Z, Yuan H, Wang X, Long J, Chen C, Liang X, Zhang N, Chai Z, Zhao Y: Potent angiogenesis inhibition by the particulate form of fullerene derivatives. ACS Nano 2010, 4:2773–2783.CrossRef Competing interests The authors declare that they have no competing interests. Authors’ contributions MW prepared

the angiogenesis assay, carried out the experimental analysis and drafted the manuscript. MW and MG performed the in ovo experiments. SJ made the TEM observations. MP carried out the immunobloting experiments. AC and ES supervised the work and PND-1186 in vitro finalized the manuscript. All authors read and approved MK-8931 mouse the final manuscript.”
“Background Efficient light emission from Si-based structures and devices has drawn worldwide attention with the aim of developing an integrated optoelectronic platform on Si [1–6]. Such light emitters present an attractive application not only for inter-/intrachip optical interconnects but also, e.g., micro-displays and biological detection. Among the different

approaches, rare-earth ion-based materials are very promising candidates due to their outstanding optical properties. Recently, it has been demonstrated that erbium silicate has one order of magnitude higher optically active rare-earth ions than those CYTH4 done through doping, without clustering or precipitation [7–10]. This may open new and interesting perspectives for rare-earth applications in photonics. Among the various rare earths, Eu ions also have been attracting great interest in optoelectronic application because of its intense and stable emission in the visible region. Compared with other trivalent rare-earth ions, Eu2+ emission intensity is several orders stronger because of dipole-allowed transition. This makes for the successful application of Eu2+ in phosphors [11, 12], and electroluminescent devices, by incorporating Eu2+ (such as those doped in SiO2 and Eu silicate), have been demonstrated [13–15]. Bellocchi et al. have shown that the external quantum efficiency of Eu2SiO4 can be reached at about 10%, making Eu silicate of great interest for photonic application [16].