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.

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 method of making a nanoparticle complex wherein the nanoparticle complex comprises a ligand and a metal cation. The disclosure also provides nanoparticle complexes, methods of treating a disease in a patient utilizing the nanoparticle complexes, methods of identifying a disease in a patient utilizing the nanoparticle complexes, and kits involving the nanoparticle complexes.

Provided herein are therapeutic nanoparticles having a diameter of between 10 nm to 30 nm, and containing a polymer coating, and a nucleic acid containing a sequence complementary to a sequence within a micro-RNA identified as having a role in cancer cell metastasis or anti-apoptotic activity in a cancer cell (e.g., miR-10b) or a sequence within an mRNA encoding a pro-apoptotic protein that is covalently linked to the nanoparticle. Also provided are pharmaceutical compositions containing these therapeutic nanoparticles. Also provided herein are methods of decreasing cancer cell invasion or metastasis in a subject having a cancer and methods of treating a metastatic cancer in a lymph node in a subject that require the administration of these therapeutic nanoparticles to a subject.

A multi-component nanochain for use in diagnostic and therapeutic applications includes at least three nanoparticles linked together to form the nanochain. At least one nanoparticle of the nanochain has an asymmetric surface chemistry defined by asymmetrically disposed first linkers and second linkers. The nanoparticles are linked to form the nanochain by linking first linkers and/or second linkers disposed on separate nanoparticles.

The present disclosure is directed generally to gold/lanthanide nanoparticle conjugates, such as gold/gadolinium nanoparticle conjugates, nanoparticle conjugates including polymers, nanoparticle conjugates conjugated to targeting agents and therapeutic agents, and their use in targeting, treating, and/or imaging disease states in a patient.

A real-time method to monitor and harvest stem cells is provided in the present invention. In particular, the present invention provides a real-time method to monitor and harvest neural stem cells. The present invention has applications in providing an individualized cell replacement therapy for patient in need thereof. More specifically, the present invention has applications in performing real-time monitoring and harvesting of neural stem cells using magnetic resonance imaging (MRI).

A biocompatible magnetic material containing an iron oxide nanoparticle and one or more biocompatible polymers, each having formula (I) below, covalently bonded to the iron oxide nanoparticle:

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in which each of variables R, L, x, and y is defined herein, the biocompatible magnetic material contains 4-15% Fe(II) ions relative to the total iron ions. Also disclosed in a method of preparing the biocompatible magnetic material.

The present invention provides nanocarrier compositions, for example, copper sulfide perfluorocarbon nanocarrier compositions, and methods of making the same. The compositions are useful for imaging, diagnostics, therapy and for other uses.

Biocompatible polymeric nanoparticles may include: a biocompatible polymer and/or functional metal nanostructures. The biocompatible polymer may be a polyhydroxyalkanoate (PHA). The functional metal nanostructures may include at least one noble metal, at least one magnetic metal oxide, or mixtures thereof. The biocompatible polymeric nanoparticles may have an average size less than or equal to 200 nanometers (nm).