A biocompatible curable composition and a method of detecting a border of a tumor, a tissue of interest, or both including injecting the biocompatible curable composition and contacting the border of a tumor or a tissue, the biocompatible curable composition crosslinks to form a three-dimensional cured nanocomposite, and imaging the three-dimensional (3D) cured nanocomposite, and imaging the 3D cured nanocomposite by at least one of MRI, CT, ultrasound, and X-ray, to detect the border of the tumor or the tissue of interest or track tumor motion during radiotherapy treatment. The biocompatible curable composition comprising an organic polymer having a hydrolysable functional group, a metallic nanoparticle, and a polar or a non-polar solvent. A brachytherapy strand consisting of a biocompatible curable composition and a radio-isotope seed. The biocompatible curable composition is shaped into an elongated cylinder and forms a 3D cured nanocomposite with a radio-isotope seed embedded.

The present disclosure provides peptide constructs for diagnostic imaging and therapeutic applications, using pegylated peptides which exhibit specific binding for a target molecule of interest, such as a biomarker of a disease or disorder.

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.

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.

Compounds comprising R-G-Cysteic Acid (i.e., R-G-NH—CH(CH.sub.2—SO.sub.3H)COOH or Arg-Gly-NH—CH(CH.sub.2—SO.sub.3H)COOH) and derivatives thereof, including pharmaceutically acceptable salts, hydrates, stereoisomers, multimers, cyclic forms, linear forms, drug-conjugates, pro-drugs and their derivatives. Also disclosed are methods for making and using such compounds including methods for inhibiting integrins including but not necessarily limited to α.sub.5β.sub.1-Integrin, α.sub.vβ.sub.3-Integrin and α.sub.vβ.sub.5-Integrin, inhibiting cellular adhesion to RGD binding sites, preventing or treating viral or other microbial infections, inhibiting angiogenesis in tumors, retinal tissue or other tissues or delivering other diagnostic or therapeutic agents to RGD binding sites in human or animal subjects.

An ophthalmic radiation device using a polymeric radiation-source implemented as either a polymer molecularly bonded with a radioisotope or a polymeric encasement of a radioisotope.

An ophthalmic radiation device using a polymeric radiation-source implemented as either a polymer molecularly bonded with a radioisotope or a polymeric encasement of a radioisotope.

Disclosed are compositions and methods for targeted treatment of TLR9-expressing cancers. In particular, molecules containing a TLR9 targeting ligand, such as a CpG oligodeoxynucleotide, that target cytotoxic agents to TLR9-expressing malignant cells are disclosed. Compositions and methods are disclosed for targeted treatment of cancer or cancer-stem cells with extracellular TLR9 expression, such as primary human MDS progenitors and hematopoietic stem cell (HSC). In particular, molecules containing TLR9 targeting ligands that target cytotoxic agents to TLR9-expressing malignant cells are disclosed.

Disclosed are compositions and methods for targeted treatment of TLR9-expressing cancers. In particular, molecules containing a TLR9 targeting ligand, such as a CpG oligodeoxynucleotide, that target cytotoxic agents to TLR9-expressing malignant cells are disclosed. Compositions and methods are disclosed for targeted treatment of cancer or cancer-stem cells with extracellular TLR9 expression, such as primary human MDS progenitors and hematopoietic stem cell (HSC). In particular, molecules containing TLR9 targeting ligands that target cytotoxic agents to TLR9-expressing malignant cells are disclosed.

The invention provides a method for the formation of a tissue-targeting thorium complex, said method comprising; a) forming an octadentate chelator comprising four hydroxypyridinone (HOPO) moieties, substituted in the N-position with a methyl group, and a coupling moiety terminating in a carboxylic acid group; b) coupling said octadentate chelator to at least one tissue-targeting moiety targeting HER2; and c) contacting said tissue-targeting chelator with an aqueous solution comprising an ion of at least one alpha-emitting thorium isotope. A method of treatment of a neoplastic or hyperplastic disease comprising admistration of such a tissue-targeting thorium complex, as well as the complex and corresponding pharmaceutical formulations are also provided.