Metal-functionalized carbon nanotubes (CNTs) have emerged as versatile nanostructures with tunable properties for energy conversion, storage, and environmental remediation.
Microtubule superstructures including doublet microtubules were constructed by displaying Tau-derived peptide on the surface of microtubules using cationic KA7 peptide.
Regular nanoparticles delivery efficiency is hindered by endosome entrapment. By modifying lipid-nanoparticles with lipopeptide CPE4 and pretreating the cells with complimentary CPK4, coiled-coil peptides induced significantly enhanced mRNA delivery in various cell lines mediated by membrane fusion.
Density functional theory is used to investigate the quantum capacitance (CQ) and surface charge storage (Q) of bare (Al12N12 (AN), Al12Pl12 (AP), B12N12 (BN), and B12P12 (BP)) and 3d transition metal (TM) (Sc–Zn)doped nanocages.
Graphdiyne (GDY) has attracted extensive attention in the field of energy storage. The effects of doping B, N, P, S atoms and adsorbing Au, Ag, Cu, Ti, Al metal atoms on the quantum capacitance of GDY are systematically investigated.