A radiotherapy treatment system and method used for conducting radiographic X-ray imaging on a target organ during radiographic treatment. The system comprises (a) an x-ray beam source configurable to deliver an X-ray beam to a target organ, (b) optical means for converging and shaping said beam to a cone-shaped X-ray beam of photons which hit the target organ simultaneously, (c) multiple high-Z nanoparticles attachable to the target organ, said high-Z nanoparticles absorbing said X-ray radiation and emitting X-ray fluorescence (XRF) photons, (d) at least one XRF detector for detecting said XRF photons ejecting out of a patient's body, and (e) control means for controlling the radiotherapy treatment procedure.

The x-ray beam is focusable on a section in the target organ where the concentration of said high-Z nanoparticles leading to a desirable emission of said XRF photons, and in case the emission of said XRF photons decreases, the x-ray beam is movable to refocus on the section in the target organ where the emission of said XRF photons is desirable.

Provided is a lung disease drug delivery carrier. The lung disease drug delivery carrier includes a disc particle having a diameter of 2 μm to 4 μm. The disc particle is injected into the human body. The disc particle includes a polymer selected from the group consisting of polyglycolic acid (PGA), polylactide (PLA), polyglycolide (PG), polyphosphazene, polyiminocarbonate, polyphosphoester, polyanhydride, polyorthoester, and combinations thereof, polylactide-co-glycolide (PLGA), and a drug. The disc particle is decomposed after 24 hours after being injected into the human body and delivers or releases the drug into a lung. The lung disease drug delivery carrier is accumulated in the lung, and the lung disease includes pulmonary fibrosis.

Process for preparation of polymeric nanoparticles that chelate radioactive isotopes and have their surface modified with specific molecules targeting PSMA receptor on the surface of cancer cells, with a targeting agent modified by a linker molecule attaching to free aldehyde groups present in the dextran chain. Polymeric nanoparticles that chelate radioactive isotopes synthesized according to the claimed process for use in therapy and diagnostics of prostate cancer and metastatic cancer cells as well as other affected cells for which the nanoparticles show the affinity.

Silica nanorings, methods of making silica nanorings, and uses of silica nanorings. The silica nanorings may be PEGylated. The silica nanorings may be surface functionalized, which 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 surface selective functionalization. The silica nanorings may be used in various diagnostic and/or treatment methods.

A radioactive thermogel suspension, including a thermogel and a plurality of insoluble radioactive isotope phosphate particles, such as yttrium phosphate, suspended in the thermogel. The thermogel is PLGA-g-PEG. The thermogel contains less than 65 ppm stannous octanoate. The plurality of radioactive yttrium phosphate particles are between 0.03 .Math.m and 10 .Math.m in diameter. The plurality of radioactive yttrium phosphate particles are generally spherical. The YPO.sub.4 particle concentration is in the range of 3 mg/ml to 100 mg/ml.

A method of preparing a .sup.64Cu-BaBaSar-RGD.sub.2 solution is provided. The method includes lyophilizing a solution of BaBaSar-RGD.sub.2 and adding a .sup.64Cu solution to the lyophilized BaBaSar-RGD.sub.2.

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.

The disclosure pertains to a strontium-90 sealed radiological or radioactive source, such as may be used with treatment of the eye or other medical or industrial processes. The sealed radiological source includes a radiological insert within an encapsulation. The encapsulation may include increased shielding in the center thereof.

Implantable materials may be used in an iatrogenic site. Applications include radioopaque materials for fiducial marking.

The present disclosure is generally related to methods, systems and devices for direct production of a radioisotope-based cancer treatment pharmaceutical directly from a corresponding non-radioactive drug molecule precursor by irradiating the non-radioactive drug molecule precursor using neutrons produced by an electronic neutron generator array or other neutron generator sources.