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.

The present invention provides a nanoparticle, comprising: a core, wherein the core comprises at least one iron oxide; a shell surrounding the core, wherein the shell comprises at least one polymer; and at least one targeting moiety attached to the shell, wherein the nanoparticle does not comprise boron, for use in methods for detecting and treating cancer in a subject.

Symmetrically and asymmetrically branched homopolymers are modified at the surface level with functional groups that enable forming aggregates with water insoluble or poorly water soluble pharmaceutically active agents (PAA). The aggregates formed are specifically induced by interaction of PAA and homopolymer and are different from aggregates that are formed by the polymer alone in the absence of the PAA or by the PAA alone in the absence of the polymer. Such aggregates can be used to improve drug solubility, stability, delivery and efficacy.

Symmetrically and asymmetrically branched homopolymers are modified at the surface level with functional groups that enable forming aggregates with water insoluble or poorly water soluble pharmaceutically active agents (PAA). The aggregates formed are specifically induced by interaction of PAA and homopolymer and are different from aggregates that are formed by the polymer alone in the absence of the PAA or by the PAA alone in the absence of the polymer. Such aggregates can be used to improve drug solubility, stability, delivery and efficacy.

Embodiments of the present disclosure provide for contrast agents, methods of making contrast agents, and methods of using contrast agents, and the like.

Provided herein are protein contrast agents and targeted protein contrast agents, formulations thereof, and methods of use, including but not limited to, as a magnetic resonance imaging contrast agent.

Deuterated polymer-biomolecule conjugates and the synthesis and use of deuterated polymer-biomolecule conjugates for detecting the location of specific molecules, e.g., cell surface molecules, in a subject, and for imaging various processes within the body, for detecting the location of molecules associated with disease pathology, and for monitoring disease progression are disclosed.

The disclosure discloses an amphiphilic polymer nano micelle containing poly-3,4-dihydroxyphenylalanine chelated ferric ions, in which ferric ions are chelated with a catechol structure on a side chain of a biodegradable poly-3,4-dihydroxyphenylalanine block. The disclosure also provides a method for preparing the above micelle, comprising: complexing an amphiphilic polymer containing poly-3,4-dihydroxyphenylalanine with a ferric ion compound, and obtaining the amphiphilic polymer nano micelle containing poly-3,4-dihydroxyphenylalanine chelated ferric ions through a solvent replacement method. The micelle prepared by the disclosure is used as a Fe.sup.3+ magnetic resonance Ti imaging contrast agent, which can avoid toxic or side effects caused by a traditional gadolinium reagent, has a longitudinal relaxation rate of 5.6 mM.sup.1.Math.s.sup.1, can cycle for 150 min in a mice body, and has an obvious imaging effect and a far higher comprehensive performance than that of a commercial gadolinium contrast agent, and as well as a promising application prospect.

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.

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.