Described herein are compositions comprising, a polymer; a non-physiological solution; and a visualization agent; wherein the polymer is soluble in the non-physiological solution and insoluble at physiological conditions. Methods of preparing the compositions are disclosed as well as methods of using these compositions to treat vascular conditions.

Polymeric compositions are described comprising a biocompatible polymer including a biodegradable linkage to a visualization agent and a non-physiological solution; wherein the biocompatible polymer is soluble in the non-physiological solution and insoluble in a physiological solution. Methods of forming the solutions and polymers are disclosed as well as methods of therapeutic use.

In some aspects, the present disclosure pertains to a system for forming a radiopaque product that comprises an iodinated compound comprising one or more diene containing moieties and a multi-arm polymer comprising a plurality of dienophile containing moieties, wherein the diene containing moieties of the iodinated compound couple with the dienophile containing moieties of the multi-arm polymer through a Diels-Alder reaction. Other aspects of the disclosure pertain to crosslinked networks that are formed by combining such an iodinated compound with such a multi-arm polymer, whereupon the diene containing moieties couple with the dienophile containing moieties through a Diels-Alder reaction. Still other aspects of the disclosure pertain to methods of treatment comprising administering to a subject a mixture that comprises such an iodinated compound and such a multi-arm polymer, whereupon the diene containing moieties couple with the dienophile containing moieties by undergoing a Diels-Alder reaction after administration.

Radiopaque hydrogels, in particular radiopaque hydrogel microspheres, comprising a polymer having 1,2-dil or 1,3-diol groups acetalized with radiopaque species.

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.

Radiopaque polymer compositions and methods for making the compositions are provided. These radiopaque polymer compositions include polymer compositions comprising a crosslinked polymer network, the network comprising a first repeating unit derived from a monofunctional monomer and a second repeating unit derived from a multifunctional non-iodinated monomer wherein neither of the two monomers is fluorinated. Devices formed from radiopaque polymer compositions are also provided.

Described herein are compositions comprising, a polymer; a non-physiological solution; and a visualization agent; wherein the polymer is soluble in the non-physiological solution and insoluble at physiological conditions. Methods of preparing the compositions are disclosed as well as methods of using these compositions to treat vascular conditions.

Described herein are compositions comprising, a polymer; a non-physiological solution; and a visualization agent; wherein the polymer is soluble in the non-physiological solution and insoluble at physiological conditions. Methods of preparing the compositions are disclosed as well as methods of using these compositions to treat vascular conditions.

Radiopaque monomers, polymers, and microspheres are disclosed herein. Methods of using the radiopaque monomers, polymers, and microspheres are disclosed herein. Methods of manufacturing radiopaque monomers, polymers, and microspheres are disclosed herein.

Implantable materials may be used in an iatrogenic site. Applications include radioopaque materials for fiducial marking.