A targeted radiopharmaceutical of chemical Formula I, below, is disclosed wherein Q.sup.+3 is a

##STR00001## trivalent radioactive isotope ion; M is a proton (H+), an ammonium ion or an alkali metal ion; “g” is a number that is 1 to about 12; the boxed mAb MNPR-101 represents the chemically-bonded humanized mAb MNPR-101; and Y− is an optional anion present in an amount needed to balance the ionic charge. A pharmaceutical composition that comprises a theranostic effective amount of a Formula I targeted radiopharmaceutical dissolved or dispersed in a pharmaceutically acceptable diluent is also disclosed, as are a method for treating and/or diagnosing a mammalian host having a disease, disorder or condition characterized by undesired angiogenesis, tumor growth and/or tumor metastasis. A targeted pro-radiopharmaceutical construct similar to that of Formula I but without the radioisotope (Formula III) is also contemplated.

A method of preparing a radioactive yttrium phosphate particle suspension.

Systems, kits and methods for preparing an injection system and/or treating target lesions with a selective internal radiation therapy which includes a double-barrel syringe loaded with a two-component tissue glue and radioisotope loaded microspheres. The microspheres are loaded into the syringe based on the size of the target location and are administered with a needle or dual-lumen catheter. Dosing regimens for treating breast cancer lesions or surgical beds up to 130 mm in diameter and hepatocellular carcinoma lesions up to 50 mm are included.

Pharmaceutical compositions for preventing or reducing kidney injury are disclosed, where the pharmaceutical compositions include (1) siRNAs non-covalently conjugated to functionalized single walled carbon nanotubes (f-SWCNTs) and (2) a pharmaceutically acceptable carrier, where the siRNAs inhibit expression of one or more genes selected from the group consisting of MEP1B and p53 genes.

The present invention relates to an isolated cellular targeted delivery system comprising a CD45+ leukocyte cell comprising within said cell a complex of one or more iron binding proteins and an active pharmaceutically active substance and/or label as well as methods for producing such isolated cellular targeted delivery system and uses of such system for prophylaxis, therapy, diagnosis or theragnosis, in particular for prophylactic or therapeutic vaccination, therapy of cancer, particularly metastatic cancer or inflammatory diseases.

A method of treating a bacterial infection in a subject includes administering at least a first finely divided (particulate) material, which may have at least a second material, the first material is not bioresorbable or very slowly bioresorable and the second material or materials are bioresorbable at a higher rate than the first material, allowing a certain period of time to pass in order to provide for the first particulate material to be exposed to the body and/or second material or materials to be wholly or partly absorbed by the body of the subject, and administering one or more pharmaceutically active compounds. The first material is optionally pre-loaded or soaked with one or more pharmaceutically active compounds, and the second material is optionally pre-loaded or soaked with one or more pharmaceutically active compounds. The pharmaceutically active compound is a compound capable of treating or ameliorating a bacterial infection.

The present invention provides a fluorescent silica-based nanoparticle that allows for precise detection, characterization, monitoring and treatment of a disease such as cancer. The nanoparticle has a range of diameters including between about 0.1 nm and about 100 nm, between about 0.5 nm and about 50 nm, between about 1 nm and about 25 nm, between about 1 nm and about 15 nm, or between about 1 nm and about 8 nm. The nanoparticle has a fluorescent compound positioned within the nanoparticle, and has greater brightness and fluorescent quantum yield than the free fluorescent compound. The nanoparticle also exhibits high biostability and biocompatibility. To facilitate efficient urinary excretion of the nanoparticle, it may be coated with an organic polymer, such as poly(ethylene glycol) (PEG). The small size of the nanoparticle, the silica base and the organic polymer coating minimizes the toxicity of the nanoparticle when administered in vivo. In order to target a specific cell type, the nanoparticle may further be conjugated to a ligand, which is capable of binding to a cellular component associated with the specific cell type, such as a tumor marker. In one embodiment, a therapeutic agent may be attached to the nanoparticle. To permit the nanoparticle to be detectable by not only optical fluorescence imaging, but also other imaging techniques, such as positron emission tomography (PET), single photon emission computed tomography (SPECT), computerized tomography (CT), bioluminescence imaging, and magnetic resonance imaging (MRI), radionuclides/radiometals or paramagnetic ions may be conjugated to the nanoparticle.

An isotope production system, emanation generator, and process are disclosed for production of high-purity radioisotopes. In one implementation example, high-purity Pb-212 and/or Bi-212 isotopes are produced suitable for therapeutic applications. In one embodiment the process includes transporting gaseous radon-220 from a radium-224 bearing generator which provides gas-phase separation of the Rn-220 from the Ra-224 in the generator. Subsequent decay of the captured Rn-220 accumulates high-purity Pb-212 and/or Bi-212 isotopes suitable for direct therapeutic applications. Other high-purity product isotopes may also be prepared.

Provided is a microsphere including a glass sphere core. The glass sphere core includes a first nuclide, a second nuclide and a diffusion region extending inwardly from an outer surface of the glass sphere core, with the second nuclide distributed in the diffusion region. The first nuclide and the second nuclide become radioactive after being activated by neutrons to produce radiations including β-rays or γ-rays, or simultaneously β-rays and γ-rays. A preparation method of a microsphere is also provided.

A method of preparing a radioactive yttrium salt particle suspension comprising multiple steps comprising: using a hydrothermal process wherein a solution of soluble yttrium salt, from the group of yttrium chloride, yttrium nitrate, yttrium sulfate, and yttrium bromide is combined with a solution of sodium phosphate having a stoichiometric excess of phosphate and a preferred pH when combined.