A bone biospecific agent comprises a contrast material core, which is visible using Magnetic Resonance Imaging (MRI) or Computed Tomography (CT). The contrast material core is surrounded by a polymeric shell, which is functionalised with a bone-targeting peptide. In use, the peptide targets the biospecific agent to bone. The bone biospecific agent can be used in diagnostic imaging techniques, such as MRI and CT, and in imaging bone remodelling activities, detecting and treating pathological bone conditions and/or bone repair processes. The invention extends to the diagnosis and/or treatment of bone disease and bone pathologies using the biospecific agents.

The disclosure relates to a method for creating a three-dimensional digital subtraction angiography image of a vascular system of a patient. The method includes: providing a first reconstructed three-dimensional filling image which was acquired during at least partial contrast agent filling of the vascular system with a first contrast agent; providing a second reconstructed three-dimensional filling image which was acquired during at least partial contrast agent filling of the vascular system with a second contrast agent; and subtracting the first three-dimensional filling image from the second three-dimensional filling image so that a three-dimensional subtraction angiography image is produced, wherein the first contrast agent and the second contrast agent differ in that one of the two causes increased X-ray absorption and the other causes reduced X-ray absorption relative to a vascular system without contrast agent.

Hydrogel compositions prepared from amine components and glycidyl ether components are provided which are biocompatible and suitable for use in vivo due, in part, to their excellent stability.

Ferritin or iron-based image enhancement agents identify target tissue for treatment or ablation and are heated by microwave absorption. Microwave heat substrates enhance microwave hyperthermal ablation treatment, and may be percutaneously delivered and imaged by x-ray CT during placement of the microwave treatment antenna, allowing more precise positioning and more complete ablation of a tumor site. One method of treating a target tissue uses image-guided delivery of a heat substrate with a reverse-phase change polymer, and may apply energy to fix a mass of the material in the tissue. The fixed polymer may increase hyperthermia, form a thermal boundary, or blockade a vessel or passage so as to reduce or prevent undesired conductive cooling by contiguous tissue, or may deliver a localized treatment drug at the site, upon heating or as it degrades over time.

Ferritin or iron-based image enhancement agents identify target tissue for treatment or ablation and are heated by microwave absorption. Microwave heat substrates enhance microwave hyperthermal ablation treatment, and may be percutaneously delivered and imaged by x-ray CT during placement of the microwave treatment antenna, allowing more precise positioning and more complete ablation of a tumor site. One method of treating a target tissue uses image-guided delivery of a heat substrate with a reverse-phase change polymer, and may apply energy to fix a mass of the material in the tissue. The fixed polymer may increase hyperthermia, form a thermal boundary, or blockade a vessel or passage so as to reduce or prevent undesired conductive cooling by contiguous tissue, or may deliver a localized treatment drug at the site, upon heating or as it degrades over time.

The present invention aims to dramatically increase the effect of hepatic arterial chemoembolization by developing human serum albumin-based nanoparticles, which are bioproteins that effectively carry Adriamycin in place of Adriamycin, an anticancer agent used in hepatic arterial chemoembolization. The human serum albumin nanoparticles carrying the Adriamycin not only intensively infiltrate the drug effectively into the cells but also have a synergistic effect that can induce a long-term therapeutic effect by utilizing the effect of continuous drug release from the particles.

The present invention aims to dramatically increase the effect of hepatic arterial chemoembolization by developing human serum albumin-based nanoparticles, which are bioproteins that effectively carry Adriamycin in place of Adriamycin, an anticancer agent used in hepatic arterial chemoembolization. The human serum albumin nanoparticles carrying the Adriamycin not only intensively infiltrate the drug effectively into the cells but also have a synergistic effect that can induce a long-term therapeutic effect by utilizing the effect of continuous drug release from the particles.

This invention relates to novel contrast agents for detection of diseases by using any or both or all of CT, SPECT and PET scans. Previously, there was no way to use these novel contrast agents for imaging and early detection of neurodegenerative diseases, multiple sclerosis disease, concussion, and traumatic brain injury. Also, previously, there was no way to use Computed Tomography (CT) imaging to early detect and map the neurodegenerative diseases. Embodiments of the present invention use a novel contrast agent is disclosed for early detection of diseases by using any or both or all of CT, SPECT and PET. Also, these novel contrast agents can be used for detection of amyloid beta, tau protein, alpha-synuclein protein, and aggregation proteins in neurodegenerative diseases and inflammation in many diseases such as neurodegenerative diseases, cancer and other inflammatory diseases, blood brain barrier leakage or break down, aggressive cancer tissue, brain activation in neurodegenerative diseases and other diseases, and hypoxia in tissue. Also, these novel contrast agents increase there binding in diseases compared to healthy subjects, therefore induce higher contrast in diseases such as in neurodegenerative diseases, cancer and other inflammatory diseases, blood brain barrier leakage or break down, aggressive cancer tissue, brain activation in neurodegenerative diseases and other diseases, and hypoxic tissue.

The present disclosure is directed to a class of fluorinated copolymers, such as PTFE copolymers, that can be dissolved in low toxicity solvents, such as Class III Solvents, and that enable the creation of stable water-in-solvent emulsions comprising the fluorinated copolymers dissolved in a low toxicity solvents and a hydrophilic agent (e.g., a therapeutic agent) dissolved in an aqueous solvent, such as water or saline.

The present disclosure is directed to a class of fluorinated copolymers, such as PTFE copolymers, that can be dissolved in low toxicity solvents, such as Class III Solvents, and that enable the creation of stable water-in-solvent emulsions comprising the fluorinated copolymers dissolved in a low toxicity solvents and a hydrophilic agent (e.g., a therapeutic agent) dissolved in an aqueous solvent, such as water or saline.