Polarized nuclear imaging and spectroscopy systems and methods are disclosed. In some embodiments, nuclei of a radioactive substance are polarized such that the spins of the nuclei are oriented in a specific direction, to generate a polarized radioactive tracer with anisotropic gamma ray emission. The radioactive substance is selected such that the degree of anisotropy is enhanced. A tracer is introduced into a living subject for delivery to a target area of interest in the subject. The tracer is delivered such that nuclear spin relaxation of the tracer is inhibited during transport of the tracer to the target area of interest. Gamma rays from the gamma ray emission are detected, and based on the detected gamma rays and properties associated with the anisotropic gamma ray emission, imaging data and/or spectroscopic data are obtained that are associated with the tracer in the subject. In some embodiments, a radioactive substance is delivered to a target area of interest in the subject and the nuclei of the radioactive substance are polarized following delivery of the radioactive substance to the target area of interest, such that the spins of the nuclei are oriented in a specific direction, to generate a polarized radioactive tracer with anisotropic gamma ray emission. Gamma rays are detected from the gamma ray emission, and based on the detected gamma rays and properties associated with the anisotropic gamma ray emission, imaging data and/or spectroscopic data are obtained that are associated with the tracer in the subject.

Methods for determining systemic biodistribution characteristics of intravitrially administered medicaments. In some embodiments, radiolabeled agents or medicaments, such as I-124 labeled bevacizumab, ranibizumab and aflibercept, was imaged utilizing PET/CT in a non-human primate model, with radioactivity emission measurements made to determine the intravitreal half-lives of each agent and to determine the differences of radioactivity uptake in non-ocular organs.

In the microsphere preparation for chemoembolization therapy and nuclear medicine imaging of tumor, and a preparation method thereof, the microsphere is formed by means of using a polyvinyl alcohol derivative as a framework material and polymerizing, crosslinking and curing same with an N-acryl amino acid monomer. The microsphere can label radionuclide iodine and can also absorb load chemotherapeutic drugs.

A metal nuclide-loaded carbon microsphere (CMS), and a preparation method and a use thereof are provided. The preparation method includes: subjecting a metal ion and a small organic molecule to a reaction in an aqueous solution to obtain a complex; allowing a CMS to adsorb the complex; and subjecting the CMS adsorbing the complex to a first treatment. The metal nuclide-loaded CMS prepared by the method can stably exist in an aqueous solution at a temperature of lower than 180° C. and a pressure of lower than 10 MPa and has a metal nuclide dissolution rate of lower than 0.1% in the aqueous solution. After the prepared metal nuclide-loaded CMS is subjected to moist-heat sterilization at 121° C. for 15 min, a radionuclide release rate is still lower than 0.1%, which can significantly reduce the safety risk of the radioactive microsphere product in clinical use.

The method is capable of effectively labeling the nanodiamonds with radioactive gallium and can be operated at room temperature, and therefore is convenient to operate and does not require further purification to obtain the nanodiamonds labelled with radioactive gallium with a purity of at least 99%

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.

The present invention relates to improved radiopharmaceutical compositions in sealed containers, where the container closure has an ETFE (ethylene-tetrafluoroethylene copolymer) coating. Also disclosed are kits for radiopharmaceutical preparation using the sealed containers, as well as methods of preparation of radiopharmaceuticals using the sealed containers.

E-selectin ligands which are useful for the synthesis of E-selectin ligand-bearing carriers, wherein said E-selectin ligand-bearing carriers are directly or indirectly linked to or associated with at least one therapeutic agent, diagnostic agent, imaging agent, or radiopharmaceutical are described herein.

A method of determining a concentration of a chemical substance in a body of a patient includes adding an additive quantity of an additive material to a base quantity of a chemical substance to obtain a mixed composition having a predetermined density and delivering the mixed composition to the body of the patient. The method also includes obtaining an image of at least a portion of the body of the patient and determining a concentration of the chemical substance in the at least a portion of the body of the patient based on the image and the predetermined density of the mixed composition.

The disclosure relates to compositions comprising (i) at least one fluorocarbon, (ii) at least one fluorous hydroxamic acid chelator, and in some instances, (iii) at least one radioisotope. The disclosure also relates to methods for using such compositions, methods of making such compositions, and kits for making such compositions.