A device and method for radioembolization in the treatment of cancer cells in the body. In preferred embodiments, a radiomicrosphere is formed from a resin where an alpha emitting isotope is used for tumoricidal purposes. As the alpha emitter decays, daughters of the alpha decay are captured by the resin. In accordance with the preferred embodiments, the resin is polyfunctional where the resin has at least three different types of functional groups for cation binding. In preferred embodiments, the three functional groups bonded to the resin include a carboxylic acid group, a diphosphonic acid group, and a sulfonic acid group. In further embodiments, the device comprises at least two isotopes; wherein a first isotope is for therapeutic purposes and a second isotope is for dosimetric purposes. The second isotope is a positron emitter for PET based dosimetry. In preferred embodiments, a post-treatment radiation absorbed dose is determined using the present invention, allowing both treatment and treatment efficacy to be provided to a cancer patient.

Among the various aspects of the present disclosure is the provision of compositions of imaging agents and methods for use in detecting, monitoring, and evaluating CCR2 associated diseases, disorders, and conditions.

The present invention is a method and device for treating solid tumors utilizing shear thinning biomaterials compositions containing beta- or alpha emitting radiation sources, polymer matrix, and/or radiopaque agent. The novel radioactive composition which is disclosed here, can be injected percutaneously or via transcatheter vascular route into the target environment for the locoregional treatment. This invention is comprised of a shear thinning biomaterial which, when combined with a radioactive isotope source, can provide a therapeutic dose of radiation locally to the tumor site minimizing the risk of damage to surrounding tissue. The device may be used either as the primary tumor treatment or for treatment of residual cancer cells after excision of the primary tumor. The present invention provides a method for making the shear thinning radioactive biomaterial composition, as well as a method for utilizing the composition as a part of the treatment method.

The present invention is related to a radiolabeled active targeting pharmaceutical composition, including: a bioconjugate and a radionuclide, wherein the bioconjugate includes a biomolecule and a metal nanoparticle, wherein the biomolecule has an affinity for receptors on the surface of a cell membrane and is selected from the group consisting of a peptide and a protein. The present invention further provides a method for evaluating a thermal adjuvant therapy for tumors and a kit thereof. The above-mentioned pharmaceutical composition is applied to evaluate a tumor accumulation time, so as to establish the optimal policy for a radiofrequency- or laser-induced thermal adjuvant therapy for tumors.

A method for forming encapsulated gold nanoparticles mixes mangiferin into a liquid medium to form a reducing agent solution. Gold salts are mixed into the reducing agent solution. Reaction of the gold salts is permitted, in the absence of any other reducing agent, to form a nanoparticle solution of stabilized, biocompatible gold nanoparticles coated with mangiferin. The gold salts can consist of AuCl4, or can consist of radioactive gold salts. A cancer therapy method injects a solution of mangiferin encapsulated gold nanoparticles directly into a solid tumor. A solution consisting of an aqueous or alcoholic medium and mangiferin encapsulated gold nanoparticles is provided. The mangiferin encapsulated gold nanoparticles can have core sizes of ˜5-20 nm and total sizes of ˜20-120 nm.

A nanoparticle is provided. The nanoparticle includes a magnetic core including a magnetic nanocrystal, a fluorophore coupled to the magnetic core, at least one chelating compound coupled to the magnetic core, the at least one chelating compound being a compound that chelates copper-64 (.sup.64Cu), a compound that chelates technetium-99m (.sup.99mTc), or a combination thereof, and an iodine chelator coupled to the magnetic core. Methods of making the nanoparticle and of using the nanoparticle as a multi-modal contrast agent are also provided.

A plurality of artificial red blood cell particles includes each particle of the plurality being substantially monodisperse and each particle having a largest common linear dimension of about 5 μm to about 10 μm. The particles can also have a modulus configured such that a particle of the plurality of particles can pass through a tube having an inner diameter of less than about 3 μm.

The present invention is, in general, directed to nanoparticles for the delivery of agents to glioblastoma tumors. More particularly, the present invention relates to nanoparticle conjugates that deliver and release agents to a glioblastoma tumor. The invention is also directed to methods of delivering agents to glioblastoma tumors.

The present disclosure, among other things, provides new technologies for preparation of medical isotope labeled metal(loid) chalcogen nanoparticles for use in medical imaging and/or therapeutic applications. Provided technologies show a number of advantages as compared with previously available options for preparing and utilizing medical isotopes, including, for example, they utilize metal(loid) chalcogen nanoparticles that serve as universal binders (e.g., via covalent or non-covalent (e.g., chelate) bonds) for medical isotopes to provide medical isotope labeled metal(loid) chalcogen nanoparticles. Surprisingly, the same metal(loid) chalcogen nanoparticles may be used to bind (e.g., covalent or non-covalent e.g., chelation) bonding) a wide variety of different useful medical isotopes without the use of traditional chelating agents.

Iron garnet nanoparticles and or iron garnet particles containing various activatable nuclides, such as holmium-165 (.sup.165Ho) and dysprosium-164 (.sup.164Dy), are disclosed in this application. The iron garnet (e.g., HoIG and DyIG) nanoparticles and iron garnet particles can prepared using hydroxide co-precipitation methods. In some embodiments, radiosensitizers can be loaded on radioactive magnetic nanoparticles or radioactive iron garnet particles and, optionally, coated with suitable lipid bilayers. Methods of using the disclosed nanoparticles and particles for mediating therapeutic benefit in diseases responsive to radiation therapy are also provided. Another aspect of the invention provides films, electrospun fabrics or bandage coverings for the delivery of radiation to the site of a skin lesion amenable to treatment with radiation (e.g., skin cancers or psoriasis).