The invention provides a scanning suspension comprising a particle which is capable of at least in part disturbing a magnetic field, wherein said particle comprises a diameter of at least 1 μm, and use thereof for obtaining a scanning image. Preferably, said particle comprises holmium and a composition capable of essentially maintaining its structure during irradiation. A particle of the invention is suitable for preparing a kit of parts, comprising a diagnostic and a therapeutic composition which both comprise particles of the invention with essentially the same chemical structure, wherein said therapeutic composition is more radioactive than said diagnostic composition. Said kit of parts is especially suitable for treatment of a tumor. First, the distribution of a particle of the invention within an individual can be determined with a scanning image obtained with said scanning composition. Subsequently, a radioactive therapeutic composition can be administered, wherein a suitable dose of said therapeutic composition is derived from said scanning image.

The present invention provides a method for the generation of .sup.223Ra of pharmaceutically tolerable purity comprising i) preparing a generator mixture comprising .sup.227Ac, .sup.227Th and .sup.223Ra; ii) loading said generator mixture onto a strong base anion exchange resin; iii) eluting said .sup.223Ra from said strong base anion exchange resin using a first mineral acid in an alcoholic aqueous solution to give a first eluted .sup.223Ra solution; iv) loading the .sup.223Ra of the first eluted .sup.223Ra solution onto a strong acid cation exchange resin; and v) eluting the .sup.223Ra from said strong acid cation exchange resin using a second mineral acid in aqueous solution to provide a second eluted solution. The invention additionally provides products of corresponding purity and/or products obtained or obtainable by such a method.

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.

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.

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.

A system for in vivo location determination of a balloon catheter according to an embodiment of the present disclosure includes a detector configured to detect proximity of a radioactive material, a guide wire provided to be inserted into a body, an intermediate member which has a radioactive material detected by the detector, and is configured to be inserted into the body along the guide wire to set an insertion length at which the radioactive material is detected by the detector, and a balloon catheter which is inserted into the body along the guide wire, and is inserted into the body by the set insertion length.

An implantable device comprising a nanochanneled membrane is described. The device uses nanofluidics to control the delivery of diagnostic and/or therapeutic agents intratumorally. The devices can be used for chemotherapy, radiosensitization, immunomodulation, and imaging contrast.

The invention provides a system for the in vivo treatment of diseased tissue, the system comprising a first longitudinally extending surface and a second longitudinally extending surface coaxial to the first longitudinally extending surface to form a medicament carrying vehicle, wherein the vehicle defines a tunnel adapted to allow physiological fluid to pass through the vehicle. Also provided is method for treating, in vivo, diseased tissue, the method comprising inserting a housing into a tumor excision site and removably sliding a medicament vehicle within the vehicle so as to be encapsulated by the housing.

A nuclear medicine infusion system (10) may be used to generate and infuse radioactive liquid into a patient undergoing a diagnostic imaging procedure. In some examples, the infusion system includes a frame (30) that carries a radioisotope generator (52) that generates radioactive eluate via elution. The frame may also carry a beta detector (58) and a gamma detector (60). The beta detector can be positioned to measure beta emissions emitted from the radioactive eluate supplied by the generator. The gamma detector can be positioned to measure gamma emissions emitted from a portion of the radioactive eluate to evaluate a safety of the radioactive eluate delivered by the infusion system.

An apparatus includes a support, including an outer surface and configured for insertion into a body of a subject. The apparatus further includes multiple atoms of a radionuclide, which radioactively decays to produce a daughter radionuclide, coupled to the outer surface, and a layer of a polymer, which covers the atoms so as to protect the atoms from being washed away, yet allows diffusion of the daughter radionuclide through the layer. Other embodiments are also described.