The present invention relates to an emulsion composition for chemoembolization comprising a nanoparticle comprising a drug and a biocompatible polymer, a water-soluble contrast agent and a water-insoluble contrast agent, and a water-insoluble drug as well as an aqueous drug can be administered in a form of stable emulsion, and drugs are slowly released, thereby enhancing the effect of chemoembolization.

This invention concerns imageable, radiopaque embolic beads, which are particularly useful for monitoring embolization procedures. The beads comprise iodine containing compounds which are covalently incorporated into the polymer network of a preformed hydrogel bead. The beads are prepared by activating pre-formed hydrogel beads towards nucleophilic attack and then covalently attaching iodinated compounds into the polymer network. The radiopaque beads may be loaded with chemotherapeutic agents and used in methods of embolizing hyperplastic tissue or solid tumors.

The present disclosure describes an imaging composition including porous silicon microparticles, and more particularly, to a biological tissue imaging composition including a composite in which oxidized porous silicon microparticles and silver nanoparticles are combined. Since a biological tissue imaging agent of the present invention, which includes a composite of oxidized porous silicon microparticles and silver nanoparticles, continuously provides an image signal without spreading in the body as compared to conventional imaging agents, it is possible to increase surgical stability by accurately identifying target tissues in vivo in an affected area.

Described herein are iodine-based particles which can be used as contrast agents for x-ray radiology. Also described herein are methods, software modules and hardware modules for imaging iodine-based particles.

Multivalent CT or MR contrast agents and methods of making and using thereof are described herein. The agents contain a moiety, such as a polymer, that provides multivalent attachment of CT or MR contrast agents. Examples include, but are not limited to, multivalent linear polymers, branched polymers, or hyperbranched polymers, such as dendrimers, and combinations thereof. The dendrimer is functionalized with one or more high Z-elements, such as iodine. The high Z-elements can be covalently or non-covalently bound to the dendrimer. The dendrimers are confined in order to enhance CT contrast. In some embodiments, the moiety is confined by encapsulating the dendrimers in a material to form particles, such as nanoparticles. In other embodiments, the dendrimer is confined by conjugating the moiety to a material, such as a polymer, which forms a gel upon contact with bodily fluids.

The present invention relates to compositions and methods for imaging and treating various diseases and disorders, including cancers. The composition of the invention can include a plurality of biodegradable micro-beads, each embedding a plurality of nano-beads, further including a polymer, a radionuclide, a radionuclide chelator, a radioligand, a chemotherapeutic agent, and a cell-penetrating peptide. Upon injection into a blood vessel supplying a cancer tumor, the micro-beads lodge into the tumor and degrade, releasing the nano-beads with a therapeutic or diagnostic agent. The compositions and methods of the invention provide a more homogeneous and deeper distribution of radiation or chemotherapeutic agents throughout the target tumor. The micro-beads provide a local, sustained, and controlled delivery nano-beads including therapeutic or diagnostic agents.

The present invention relates to nanoparticles of a metal chosen from among platinum, bismuth or a mixture thereof, which are functionalised at their surface by functionalised polyethylene glycol, comprising in particular at least one OH, COOH, NH.sub.2 or SH functional group, and to their method of preparation, which comprises of the following steps: a) Mixing a precursor of nanoparticles with a functionalised polyethylene glycol, in particular comprising at least one OH, COOH, NH.sub.2 or SH functional group, in water; b) Exposing the mixture to ionising radiation.

Described herein are iodine-based particles which can be used as contrast agents for x-ray radiology. Also described herein are methods, software modules and hardware modules for imaging iodine-based particles.

Described herein are iodine-based particles which can be used as contrast agents for x-ray radiology. Also described herein are methods, software modules and hardware modules for imaging iodine-based particles.

Multivalent CT or MR contrast agents and methods of making and using thereof are described herein. The agents contain a moiety, such as a polymer, that provides multivalent attachment of CT or MR contrast agents. Examples include, but are not limited to, multivalent linear polymers, branched polymers, or hyperbranched polymers, such as dendrimers, and combinations thereof. The dendrimer is functionalized with one or more high Z-elements, such as iodine. The high Z-elements can be covalently or non-covalently bound to the dendrimer. The dendrimers are confined in order to enhance CT contrast. In some embodiments, the moiety is confined by encapsulating the dendrimers in a material to form particles, such as nanoparticles. In other embodiments, the dendrimer is confined by conjugating the moiety to a material, such as a polymer, which forms a gel upon contact with bodily fluids.