The present invention provides compositions relating to nanoparticles, such as nanocapsules, that selectively target cells associated with diseases or disorders (e.g., cancer cells). The present invention further relates to methods relating to the said nanoparticles for imaging, detection, and treatment of diseases or disorders in a subject. The present invention additionally provides kits that find use in the practice of the methods of the invention.

Polymeric particles are provided for use in therapeutic and/or diagnostic procedures. The particles include poly[bis(trifluoroethoxy)phosphazene and/or a derivative thereof which may be present throughout the particles or within an outer coating of the particles. The particles may also include a core having a hydrogel formed from an acrylic-based polymer. Such particles may be provided to a user in specific selected sizes to allow for selective embolization of certain sized blood vessels or localized treatment with an active component agent in specific clinical uses. Particles of the present invention may further be provided as color-coded microspheres or nanospheres to allow ready identification of the sized particles in use. Such color-coded microspheres or nanospheres may further be provided in like color-coded delivery or containment devices to enhance user identification and provide visual confirmation of the use of a specifically desired size of microspheres or nanospheres.

Mesoporous silica nanoparticles (MSNs) that may be useful as ultrasound contrast agents for detecting and treating bladder cancer are described herein. The MSNs include a lanthanide, a fluorophore, and an agent detectable by ultrasound.

The present disclosure provides a nanocapsule comprising a hydrophilic core; and a hydrophobic shell enclosing the hydrophilic core. The hydrophobic shell contains an outer layer comprising fucoidan, a middle layer comprising carotenoids and metal oxide nanoparticles, and an inner layer comprising fucoidan and contacting the hydrophilic core. The present disclosure also provides use of the nanocapsule as disclosed herein in the manufacture of a medicament for treating and/or diagnosing diseases in a subject in need thereof.

The present invention provides compositions and methods for targeting cells for therapeutic and/or diagnostic purposes, e.g., delivery of therapeutic and/or diagnostic agents to a cell. Nanoparticles and polymers functionalized with capture molecules, reporter molecules, and/or therapeutic agents are provided for the treatment or prevention of disease, including neurological diseases associated with neuroinflammation, and cancer.

Polymeric particles are provided for use in therapeutic and/or diagnostic procedures. The particles include poly[bis(trifluoroethoxy)phosphazene and/or a derivative thereof which may be present throughout the particles or within an outer coating of the particles. The particles may also include a core having a hydrogel formed from an acrylic-based polymer. Such particles may be provided to a user in specific selected sizes to allow for selective embolization of certain sized blood vessels or localized treatment with an active component agent in specific clinical uses. Particles of the present invention may further be provided as color-coded microspheres or nanospheres to allow ready identification of the sized particles in use. Such color-coded microspheres or nanospheres may further be provided in like color-coded delivery or containment devices to enhance user identification and provide visual confirmation of the use of a specifically desired size of microspheres or nanospheres.

The present invention provides methods, compositions, systems, and kits comprising core-satellite nanocomposites useful for photothermal and/or MRI applications (e.g., tumor treatment and/or imaging). In certain embodiments, the core-satellite nanocomposites comprise: i) a core nanoparticle complex comprising a biocompatible coating surrounding a nanoparticle core, and ii) at least one satellite component attached to, or absorbed to, the biocompatible coating. In some embodiments, the nanoparticle core and satellite component are composed of near-infrared photothermal agent material and/or MRI contrast agent material. In further embodiments, the satellite component is additionally or alternatively composed of near-infrared optical dye material.

Pharmaceutical composition containing poly(bile) acid (PBA) polymers for oral delivery of agent(s) show enhanced uptake by the pancreas, liver, and colon. These nanoparticles show significant retention in the pancreas and colon and are therefore useful for selective delivery. The examples demonstrate efficacy of oral administration of insulin to treat diabetes, and oral induction of tolerance by administration of insulin or ovalbumin in combination with rapamycin. Diabetic animals treated with the insulin or insulin with rapamycin showed normalization of blood glucose levels.

Disclosed herein are nanoparticle immunoconjugates useful for therapeutics and/or diagnostics. The immunoconjugates have diameter (e.g., average diameter) no greater than 20 nanometers (e.g., as measured by dynamic light scattering (DLS) in aqueous solution, e.g., saline solution). In certain embodiments, the conjugates are silica-based nanoparticles with single chain antibody fragments attached thereto.

Nanocages are formed by etching nanocubes. The nanocubes are added to an aqueous system having an amphiphilic lipid dissolved in an organic solvent (e.g. a hydrophobic alcohol) to form reverse micelles. As the water evaporates the micelles shrink as etching of the flat surface of the nanocubes occurs. In this fashion hollow nanocages are produced. In one embodiment, the nanocage is covalently attached to a polymer shell (e.g. a dextran shell).