A composition including magnetic nanoparticles for use in the treatment of a tissue volume including pathological cells in an individual, wherein a portion only of the tissue volume is occupied by the magnetic nanoparticles upon administration of the composition to the individual and the magnetic nanoparticles are excited by radiation.

Disclosed herein are kits and methods for preparing radiopharmaceuticals. The kits and methods of the present disclosure can prepare the radiopharmaceuticals without using a heater and computer monitoring equipment. The kit includes a frozen crystal reaction vial, a reagent vial and a labeling holder, wherein the labeling holder contains a heating bag that can heat up to a high temperature of at least 95° C. by adding an aqueous solution.

Described herein are methods of treating cancer by inducing favorable effects on tumor microenvironment (e.g., including macrophage polarization, cytokine profile, and/or immunophenotype) via administration of nanoparticles (e.g., silica-based ultra-small nanoparticles and nanoparticle conjugates such as nanoparticle drug conjugates). In certain embodiments, the methods may be used in concert with, or as part of, checkpoint inhibition therapy (e.g., anti-PD1) or radiotherapy, or a combination of both radiotherapy and checkpoint inhibitor therapy.

Described are methods for preparing radionuclides, such as radionuclides having a high specific activity. The disclosed methods include irradiating target nuclide materials, in solution, with a neutron source. The radionuclides can be separated from the target nuclide material by providing a solid carbon nanostructured material, as a suspension of solids, proximal to the target nuclide material in solution and using the recoil to drive adsorption of the radionuclide onto the solid carbon nanostructured material to transfer the radionuclides from the liquid phase (in solution) to the solid phase (adsorbed to the suspended solid carbon nanostructured material). One or more surfactants can be incorporated into the solution to facilitate formation of a stable suspension of the solid carbon nanostructured material.

Selenium (Se) nanostructures are synthesized using bacteria, and the synthetic method provides options for specific functionalization of the nanostructures, targeting, as well as options for crystal form of and for additives to the composition. In addition to drug delivery and imaging options, the synthesized Se nanostructures provide methods of inhibiting drug resistant bacterial cells and cancer cells without cytotoxicity towards normal human cells and dermal fibroblasts. The green chemistry methods for synthesizing Se nanostructures do not produce toxic byproducts and do not require toxic reagents in comparison to traditional chemical synthetic methods for making Se nanostructures, while simultaneously producing new therapeutic benefits and treatments.

Silica nanorings, methods of making silica nanorings, and uses of silica nanorings. The silica nanorings may be surface selective functionalization, with one or more polyethylene glycol (PEG) group(s), one or more display group(s), one or more functional group(s), or a combination thereof. The silica nanorings may have a size of 5 to 20 nm. The silica nanorings may be made using micelles. The absence or presence of the micelles during PEGylation and/or functionalization allows for the surface selective functionalization. The silica nanorings may be used in various diagnostic and/or treatment methods.

A glass material that includes: from about 0.55 to about 0.85 mole fraction of SiO.sub.2; from about 0.01 to about 0.23 mole fraction of Na.sub.2O, K.sub.2O, or a combination of Na.sub.2O and K.sub.2O; from about 0.05 to about 0.28 mole fraction of: Y.sub.2O.sub.3, BaO, or a combination of Y.sub.2O.sub.3 and BaO; and optionally Ta.sub.2O.sub.5. In the glass material, the sum of the Y.sub.2O.sub.3, the BaO and the optional Ta.sub.2O.sub.5 is from about 0.10 to about 0.31 mole fraction. The glass material may be in the form of microspheres. The microspheres may be used for vascular embolization and/or radiologic imaging.

Provided herein are methods for decreasing the toxicity of advanced ablative cancer therapies on neighboring organs. The methods herein provide spacing between single or multiple tumor cites and immediate healthy organs while maintaining or increasing patient quality of life. Such toxicity isolation can be performed by inserting a spacer around the one or more tumor cites, which can be performed concurrently with fiducial marker placement.

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.

The invention provides a compound having the following structure:
T-DOTA-R,
wherein T is a carbohydrate polymer, R is a radioactive isotope, DOTA is a chelator of R, and T is covalently bond to DOTA. In one embodiment, the carbohydrate polymer is hyaluronic acid (HA). The compound or HA is used alone as a polymer or incorporated into a hydrogel for treating body cavity cancer, comprising administering an effective amount of the compound or hydrogel. The invention also provides a method for treating body cavity or soft tissue cancer comprising: introducing into the affected area a thermo reversible gel comprising the compound or HA, allowing the radioactive isotope to emit a therapeutic radiation to affected regions; and, after a predetermined time, optionally removing the gel from the body cavity with a cold rinse to liquefy the gel and allow it to exit the body cavity.