Abstract: Methods and compositions using an inhibitor of EGFR signaling for prevention or an inhibitor of EGFR signaling and a nucleic acid molecule encoding an atonal-associated factor for treatment of hearing loss are described.

Abstract: Methods of preparing Si-based anode slurries and anode made thereof are provided. Methods comprise coating silicon particles within a size range of 300-700 nm by silver and/or tin particles within a size range of 20-500 nm, mixing the coated silicon particles with conductive additives and binders in a solvent to form anode slurry, and preparing an anode from the anode slurry. Alternatively or complementarily, silicon particles may be milled in an organic solvent, and, in the same organic solvent, coating agent(s), conductive additive(s) and binder(s) may be added to the milled silicon particles—to form the Si-based anode slurry. Alternatively or complementarily, milled silicon particles may be mixed, in a first organic solvent, with coating agent(s), conductive additive(s) and binder(s)—to form the Si-based anode slurry. Disclosed methods simplify the anode production process and provide equivalent or superior anodes.

Abstract: Methods of preparing Si-based anode slurries and anode made thereof are provided. Methods comprise coating silicon particles within a size range of 300-700 nm by silver and/or tin particles within a size range of 20-500 nm, mixing the coated silicon particles with conductive additives and binders in a solvent to form anode slurry, and preparing an anode from the anode slurry. Alternatively or complementarily, silicon particles may be milled in an organic solvent, and, in the same organic solvent, coating agent(s), conductive additive(s) and binder(s) may be added to the milled silicon particles—to form the Si-based anode slurry. Alternatively or complementarily, milled silicon particles may be mixed, in a first organic solvent, with coating agent(s), conductive additive(s) and binder(s)—to form the Si-based anode slurry. Disclosed methods simplify the anode production process and provide equivalent or superior anodes.

Abstract: The present invention provides electrochemical energy storage devices, comprising at least one electrochemical cell comprising a first porous electrode, a second porous electrode, an aqueous or non-aqueous electrolyte being in contact with said first porous and second porous electrodes and a porous separator separating the first porous electrode from the second porous electrode, wherein: (a) the electrolyte comprises a first dissolved salt comprising a trivalent post-transition metal cation; and/or (b) the first porous electrode, the second porous electrode or both electrodes comprise submicron particles of a precipitated salt comprising a cation selected from the group consisting of Pb2+, Sn2+, and Sb2+; and/or (c) the second porous electrode comprises pyrite (FeS2) submicron particles. Further provided are methods of formation of the electrochemical energy storage devices.