The disclosure describes a fusogenic liposome-coated porous silicon nanoparticles for high loading efficiency of anionic payloads (small molecules, dyes, nucleic acids), and for non-endocytic delivery of hydrophilic and lipophilic payloads by membrane fusion. The liposome coating can be further modified with targeting peptides or antibodies via covalent binding chemistry between the ligands and functionalized poly(ethylene glycol). The surface moieties can be transferred to the cellular membrane surface by fusogenic uptake. The composition of the disclosure can be applied in the treatment of diseases by delivering entrapped/encapsulated payloads.

Improved RNA interference (RNAi) efficiency in insects is disclosed herein. In particular, certain embodiments of the presently-disclosed subject matter relate to use of nanoformulations of double-stranded RNA (dsRNA) to limit nuclease degradation of the dsRNA, and enhance cellular update and intracellular transport to improve delivery of the dsRNA to enhance RNAi in insects.

We have developed novel shear-thinning biomaterials using silica nanoparticles, gelatin-based polymers and polypeptides such as anti-PD-1 antibodies. Shear-thinning biomaterial technology offers enables polymers and drugs loaded inside such polymers to be easily delivered directly through catheters into target area for use, for example, in cancer therapy and immunotherapy. When a force above a certain threshold is applied to inject such materials, they “thin” and behaves as a semi-solid, allowing the material to readily flow through a catheter. When the force is removed, the material instantly becomes a soft solid with significant cohesive properties that prevent it from dislodging or breaking up.

Disclosed are methods and related compositions for concomitantly, locally administering immunosuppressants and doses of therapeutic macromolecules for reducing Type I and Type IV hypersensitivity.

Disclosed are compositions having mineral crystals and biological molecules for the delivery of the biological materials and methods for preparing mineral crystals having a biologic material.

The present technology provides nanoparticles comprising an inorganic core and NAD.sup.+ or NADH, coated with a lipid bilayer, wherein the inorganic core is selected from calcium phosphate or a metal organic framework (MOF); the MOF comprises a transition metal ion coordinated to a coordinating ligand, wherein the transition metal ion is selected from the group consisting of zinc, iron, zirconium, copper, and cobalt ions, and the coordinating ligand is selected from an imidazolate ligand or a carboxylate ligand; and the nanoparticle has an average hydrodynamic diameter of from at least 50 nm to less than 1000 nm. Pharmaceutical compositions incorporating such nanoparticles and methods of treating sepsis and/or inflammation with such particles are also provided.

The present invention provides compositions comprising energy (e.g., light) absorbing submicron particles (e.g., nanoparticles comprising a silica core and a gold shell) and methods for delivering such particles via topical application. This delivery is facilitated by application of mechanical agitation (e.g. massage), acoustic vibration in the range of 10 Hz-20 kHz, ultrasound, alternating suction and pressure, and microjets.

The disclosure provides nanoemulsion compositions and methods of making and using thereof to deliver a bioactive agent such as a nucleic acid to a subject. The nanoemulsion composition comprises a hydrophobic core based on inorganic nanoparticles in a lipid nanoparticle that allows imaging as well as delivering nucleic acids. Methods of using these particles for treatment and vaccination are also provided.

A nanoparticle comprising chemically modified heparin, wherein the heparin has been chemically modified by attaching hydrophobic moieties to functional groups of the heparin, said functional groups being selected from hydroxy groups and carboxy groups, for use in the treatment or diagnosis of a brain disorder.

The present invention relates to a composition for treating inflammatory diseases comprising germanium telluride nanosheets coated with polyvinylpyrrolidone, and the nanosheets have excellent anti-inflammatory and thus are excellent in treating inflammatory bowel disease and psoriasis.