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

The invention discloses non-iodinated radiopaque microbeads that may be used in image guided embolization in a subject ailing with tumor. The non-iodinated radiopaque microbeads include a ceramic material doped with a CT contrast agent or a MRI contrast agent or both. The doped ceramic is blended with a polymer and the blend is electrosprayed to form the radiopaque microbeads. Further the radiopaque microbeads are radiolabeled with a radioactive isotope. Methods of synthesis of the radiopaque microspheres are also disclosed. The non-iodinated radiopaque microbeads with radiolabeling are capable of rendering an imageable computed tomography (CT) contrast or magnetic resonance imaging (MRI) contrast when administered in a subject. Also the microspheres are biodegradable and hence the treatment could be repeated in case of recurrence of the tumor in the subject.

The present invention provides an encapsulated gas or partial vacuum particle contrast media for use in CT imaging. In an exemplary embodiment, the invention provides an enteric contrast medium formulation. An exemplary formulation comprises, (a) an enteric contrast medium comprising a encapsulated gas or partial vacuum particle suspended in water. Exemplary encapsulated gas or partial vacuum particle has a specific gravity between 0.2 and 1.5. In various embodiments, the encapsulated gas or partial vacuum particle is suspended in aqueous media by an agent compatible with enteric administration of the formulation to a subject in need of such administration. In an exemplary embodiment, the contrast material is incorporated into a pharmaceutically acceptable carrier in which the material is suspended homogeneously. In an exemplary embodiment, the encapsulated gas or partial vacuum particle comprises 5% or more of the weight of the contrast material formulation. The invention also provides methods for imaging of the abdomen by dual energy CT or spectral CT contemporaneously with the delivery of the encapsulated gas or partial vacuum particle contrast material into the bowel lumen with or without the delivery of a second complementary contrast material into the blood vessels or other body compartments. The invention also provides methods for the digital separation of CT signal produced by the contrast media of the invention from the CT signal produced by other contrast media or bodily tissues to generate multiple resultant CT images with the contrast medium of the invention subtracted or highlighted.

A composite implant for providing simultaneous magnetic resonance imaging (MRI) and computed tomographic (CT) imaging contrast is disclosed. The composite implant is formed of a calcium compound in the form of nano or microparticles doped with a first dopant configured to provide MRI contrast and a second dopant configured to provide CT contrast. The calcium compound is loaded onto a polymer gel matrix and lyophilized to form a mass with 3-dimensionally interconnected porosity, configured to provide tissue integration and proliferation sites. Methods of forming the composite implant are also disclosed. The implant could be a scaffold or bead structured to enable treatment of human or animal patient for bone/cartilage injury or defect by implantation, with MRI and CT monitoring.

A method is for imaging an examination region of an object to be examined, the examination region including a first contrast medium and a second contrast medium different from the first contrast medium. In an embodiment, the method includes acquisition and generation. In the acquisition, first projection scan data is acquired in an examination region with a first energy range and second projection scan data, different from the first projection scan data, is acquired with a second energy range different from the first energy range. In the generation, a first image is generated based upon the first projection scan data and the second projection scan data and the first image has furthermore only isolated first information of the first contrast medium, only isolated second information of the second contrast medium, or isolated first information of the first contrast medium together with isolated second information of the second contrast medium.

The present disclosure provides radiopaque crosslinked acrylamide copolymers that comprise (a) a monofunctional acrylamide monomer containing one or more radiopaque atoms and/or a multifunctional acrylamide monomer containing one or more radiopaque atoms and (b) a monofunctional acrylamide monomer that does not contain one or more radiopaque atoms and/or a multifunctional acrylamide monomer that does not contain one or more radiopaque atoms, wherein the copolymer comprises at least one multifunctional acrylamide monomer. The present disclosure also provides radiopaque particulate compositions that comprise such radiopaque crosslinked acrylamide copolymers and medical procedures that comprise administering to a subject such radiopaque particulate compositions. The present disclosure further provides methods of making such radiopaque crosslinked acrylamide copolymers.

The present invention provides an encapsulated gas or partial vacuum particle contrast media for use in CT imaging. In an exemplary embodiment, the invention provides an enteric contrast medium formulation. An exemplary formulation comprises, (a) an enteric contrast medium comprising a encapsulated gas or partial vacuum particle suspended in water. Exemplary encapsulated gas or partial vacuum particle has a specific gravity between 0.2 and 1.5. In various embodiments, the encapsulated gas or partial vacuum particle is suspended in aqueous media by an agent compatible with enteric administration of the formulation to a subject in need of such administration. In an exemplary embodiment, the contrast material is incorporated into a pharmaceutically acceptable carrier in which the material is suspended homogeneously. In an exemplary embodiment, the encapsulated gas or partial vacuum particle comprises 5% or more of the weight of the contrast material formulation.

The present invention is directed towards a system and method for transarterial chemoembolization using differently sized drug-eluting microsphere beads filled with drugs and determining a delivered drug concentration using an imaging system.

The present invention provides an encapsulated gas or partial vacuum particle contrast media for use in CT imaging. In an exemplary embodiment, the invention provides an enteric contrast medium formulation. An exemplary formulation comprises, (a) an enteric contrast medium comprising a encapsulated gas or partial vacuum particle suspended in water. Exemplary encapsulated gas or partial vacuum particle has a specific gravity between 0.2 and 1.5. In various embodiments, the encapsulated gas or partial vacuum particle is suspended in aqueous media by an agent compatible with enteric administration of the formulation to a subject in need of such administration. In an exemplary embodiment, the contrast material is incorporated into a pharmaceutically acceptable carrier in which the material is suspended homogeneously. In an exemplary embodiment, the encapsulated gas or partial vacuum particle comprises 5% or more of the weight of the contrast material formulation. The invention also provides methods for imaging of the abdomen by dual energy CT or spectral CT contemporaneously with the delivery of the encapsulated gas or partial vacuum particle contrast material into the bowel lumen with or without the deliver of a second complementary contrast material into the blood vessels or other body compartments. The invention also provides methods for the digital separation of CT signal produced by the contrast media of the invention from the CT signal produced by other contrast media or bodily tissues to generate multiple resultant CT images with the contrast medium of the invention subtracted or highlighted.

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