J Opt Soc Am A 2005, 22:1844–1849 CrossRef 9 Pietarinen J, Kalim

J Opt Soc Am A 2005, 22:1844–1849.CrossRef 9. Pietarinen J, Kalima V, Pakkanen TT, Kuittinen M: Improvement of UV-moulding accuracy by heat and solvent Copanlisib assisted process. Microelectron Eng 2008, 85:263–270.CrossRef 10. Nagpal P, Lindquist NC, Oh SH, Norris DJ: Ultrasmooth patterned metals for plasmonics and metamaterials. Science 2009, 325:594–597.CrossRef Competing interests The authors declare that they have no competing interests. Authors’ contributions The structures

were fabricated by JR, the numerical work was carried out by JR and HJH, the experimental part was performed by JR and SR, and the manuscript was written by JT, JR, HJH, and SR. All authors read and approved the final manuscript.”
“Background Typically, toxins from venomous species such as cone snails, spiders, and snakes are investigated as possible drug leads for ion channel blockers. selleck kinase inhibitor Converting these toxins to drugs represents a considerable challenge [1]. For example, disulfide bridges in these peptides, abundant in all toxins, are vulnerable to scrambling and reduction in certain extracellular environments and therefore must be replaced [1–4]. Nanomaterials designed to mimic the main features of these complex toxin structures present exciting opportunities to specifically target a particular ion channel subtype and may alleviate some of the

challenges of these peptides. Increasing attention is being given to fullerenes for biological applications including antiviral and antibacterial agents, antioxidants, vectors for

drug/gene delivery, photodynamic therapy, enzyme inhibitors, and diagnostics (e.g., magnetic resonance imaging) [5, 6]. For example, fullerene derivatives have been shown to bind to and inhibit the Ricolinostat order activity of HIV protease [7]. Fullerenes consist of a hollow carbon cage Etomidate structure formed by 20 to as many as 300 carbon atoms [8, 9]. The most abundantly produced are those with 60 and 70 carbon atoms. Fullerenes are insoluble in aqueous solution and aggregate easily. Therefore, there has been significant work into making these structures soluble so that they can be utilized for their potential biomedical applications. One method which increases their solubility is chemical functionalization with moieties such as amino acids and carboxylic acid [5]. Fullerene chemistry has been intensely developed, and the main efforts are now devoted to broaden their application [6]. In 2003, Park et al. [10] identified non-functionalized carbon nanotubes and C60 fullerenes as a novel class of ion channel blockers. Their experiments on various biological ion channels demonstrated that these nanostructures indiscriminately interfere with the activity of potassium channels depending on their geometric structure and size. Similarly, experiments by Chhowalla et al. [11] and Xu et al.

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