The disclosure is directed in part to polymerizable compositions that can incorporate a radioactive source and be used to treat subjects with certain conditions, and methods of producing and use thereof.

A device having a biocompatible polymer as a body and regularly spaced radiation seeds and regularly spaced magnetic materials disposed of within the body of the biocompatible polymer, or uniformly distributed liquid radiation and magnetic fluid materials within a polymer slab, hollow thick wall polymer shell, or thin wall polymer balloon, as suitable for surgical placement within a resection cavity for treatment of at-risk tissue in the tumor margin with local hyperthermia in combination with radiation and potentially also with chemotherapy and/or immunotherapy that is slowly released from the biocompatible polymer.

The present invention provides a method for selective delivery of a therapeutic or diagnostic agent to a targeted organ or tissue by implanting a biocompatible solid support in the patient being linked to a first binding agent, and administering a second binding agent to the patient linked to the therapeutic or diagnostic agent, such that the therapeutic or diagnostic agent accumulates at the targeted organ or tissue.

A device having a biocompatible polymer as a body and regularly spaced radiation seeds and regularly spaced magnetic materials disposed of within the body of the biocompatible polymer, or uniformly distributed liquid radiation and magnetic fluid materials within a polymer slab, hollow thick wall polymer shell, or thin wall polymer balloon, as suitable for surgical placement within a resection cavity for treatment of at-risk tissue in the tumor margin with local hyperthermia in combination with radiation and potentially also with chemotherapy and/or immunotherapy that is slowly released from the biocompatible polymer.

The present disclosure provides bioorthogonal compositions for delivering agents in a subject. The disclosure also provides methods of producing the compositions, as well as methods of using the same.

The present invention provides a method for selective delivery of a therapeutic or diagnostic agent to a targeted organ or tissue by implanting a biocompatible solid support in the patient being linked to a first binding agent, and administering a second binding agent to the patient linked to the therapeutic or diagnostic agent, such that the therapeutic or diagnostic agent accumulates at the targeted organ or tissue.

An injectable depot formulation includes a biocompatible polymer, an organic solvent combined with the biocompatible polymer to form a viscous gel, and a small molecule drug incorporated in the viscous gel such that the formulation exhibits an in vivo release profile having a C.sub.max to C.sub.min ratio of less than 200 and a lag time less than 0.2

Compositions comprising a red blood cell (RBC) having non-toxically coupled thereto a nanoparticle having a low shear modulus or low Young's modulus of less than 10 MPa and containing a drug are provided. In one embodiment, the nanoparticles are optionally coated with protein. In another embodiment, the nanoparticle has no cell-specific targeting moiety or tissue-specific targeting moiety or organ-specific targeting moiety associated therewith. Methods of delivering selected drugs to target organs use these compositions both in vivo and ex vivo treatment of disease and for imaging.

An injectable depot formulation includes a biocompatible polymer, an organic solvent combined with the biocompatible polymer to form a viscous gel, and a small molecule drug incorporated in the viscous gel such that the formulation exhibits an in vivo release profile having C.sub.max to C.sub.min ratio less than 200 and lag time less than 0.2.

Provided herein are in vivo gelling ophthalmic pre-formulations forming a biocompatible retinal patch comprising at least one nucleophilic compound or monomer unit, at least one electrophilic compound or monomer unit, and optionally a therapeutic agent and/or viscosity enhancer. In some embodiments, the retinal patch at least partially adheres to the site of a retinal tear. Also provided herein are methods of treating retinal detachment by delivering an in vivo gelling ophthalmic pre-formulation to the site of a retinal tear in human eye, wherein the in vivo gelling ophthalmic pre-formulation forms a retinal patch.