Abstract: Provided are nanoparticle conjugates comprising a drug encapsulated in a gelatin nanoparticle the surface of which is functionalized with an antibody to which a siRNA is linked. Methods with the nanoconjugates for treating diseases are provided as well.

Abstract: Provided are nanoparticle conjugates comprising a drug encapsulated in a gelatin nanoparticle the surface of which is functionalized with an antibody to which a siRNA is linked. Methods with the nanoconjugates for treating diseases are provided as well.

Abstract: A multidimensional nanoconstruct includes a three-dimensional thiolated protein, gelatin or polymer nanoparticle and exposed metallic nanoparticles bonded to outer surfaces of the particle. In a method of formation, number of metallic nanoparticles that attach to the carrier nanoparticle is controlled via microfluidics or via controlling the reactivity of the metallic nanoparticle and carrier nanoparticle.

Abstract: A method produces polymer nanoparticles. Polymer solution is sprayed through a nozzle toward a collector. An electric field is created at the nozzle, such as by a voltage is applied to the nozzle to create the electric field. The voltage applied to the nozzle is from ˜10 (Kilovolt) to ˜30 (Kilovolt), distance from nozzle tip to collector is from ˜1 (centimeter) to ˜10 (centimeter) and the polymer concentration from ˜0.01% to ˜0.5% w/w. Preferably a grounded liquid collectors is used. The invention provides biocompatible monodisperse polymer nanoparticles having a size of less than ˜300 nm, preferably less than ˜150 nm. Payloads can be associated, and maintain efficacy, including more than one payload such as therapeutic agents and diagnostic agents on the same particles. Preferred particles are poly(methyl methacrylate) (PMMA-COOH) or acrylate analogues.

Abstract: A device including a micro component having an external surface and a permeable nanofiber covering on at least a portion of the external surface of the micro component. A cooled micro component system further includes a droplet spray system for spraying liquid droplets onto the nanofiber covering to cool the micro component. In an example method for cooling a micro component, droplet spray is directed onto a nanofiber covering that covers at least a portion of the micro component. The directing is controlled to permit efficient spreading and evaporation of liquid permeating the nanofiber covering. In example embodiments nanofibers of the permeable nanofiber covering are metalized to provide a rougher surface (e.g., a nano-textured metal layer).