Abstract: The present invention relates to a composition that includes gadolinium particles encapsulated in microsphere shells. The composition is suitable for use as a contrast agent with a plurality of imaging modalities, including, for example, ultrasound, magnetic resonance imaging, and computed temography. The compositions also are useful for therapeutic applications, including neutron capture therapy.

Abstract: The invention relates to novel magnetic resonance imaging contrast agents and methods of detecting physiological signals or substances.

Abstract: The invention relates to novel magnetic resonance imaging contrast agents for imaging cancer.

Abstract: Linear extended polymeric paramagnetic chelates for use as MRI contrast agents are synthesized by conjugating DTPA chelator moieties to higher than 90% of the monomer residues of the polyamino acid backbone chain. The resulting polymer can be labeled with Gd, since each chelator moiety holds a Gd ion, and the resulting conformation is of an unfolded, extended linear type, capable of entering small pores and moving around obstacles in the extracellular space of tissues. The efficient production of these extended polymers is critical for the application of such contrast agents to medical imaging. One such agent is a reptating polymer containing technetium-99.

Abstract: The invention relates to novel targeted magnetic resonance imaging contrast agents and methods of detecting physiological signals or substances.

Abstract: Substituted polycarboxylic ligand molecules and corresponding metal complexes of said ligands, preferably paramagnetic metals complexes for generating responses in the field of magnetic resonance imaging (MRI) The paramagnetic complexes of the polycarboxylic ligands possess advantageous tensioactive properties and are useful as MRI contrast media in formulations for investigating the blood pool.

Abstract: Delivery of metal particles to living tissue, then applying external energy that interacts with the metal particles, is found to selectively increase the energy deposition and interaction surrounding the metal particles. The method is useful to improve treatment of various conditions, since targeted cells may be selectively altered or killed. Metal particles are also loaded into cells or membrane vesicles by placing metal seed particles into the cells or vesicles, then chemically depositing additional metal on the metal seed particles. The metal particles are useful to improve imaging and therapies by their interaction with externally applied energy.

Abstract: The invention relates to super-paramagnetic single domain particles with increased R1 relaxivity and with surface-stabilizer substances. The particles are characterized in that they consist of iron hydroxide, ferric hydrate, iron oxide, iron mixed oxide or iron; are between 1 and 10 nm in size, the mean particle diameter d50 being 2-4 nm; and have increased R1 relaxivity of between 2 and 50, the ratio of the relaxivities R2/R1 being less than 5. Stabilizer substances of special carboxylic acids are bound to the particle surfaces; these prevent aggregation and sedimentation under gravity or in a magnetic field. If necessary, the particles can also contain further known stabilizer substances and other pharmacological substances. The novel particles can be used for attacking tumors, boosting immunity, for cell fusion, gene transfer, or as contrasting agents in magnetic resonance diagnostics using magnetic fields where necessary.

Abstract: The invention relates to nanoscale particles suited especially for use in tumor therapy by hyperthermia. Said particles comprise a (preferably superparamagnetic) iron oxide-containing core and at least two shells surrounding said core. The (innermost) shell adjoining the core is an envelope which comprises groups capable of forming cationic groups and is broken down by human or animal tissue at such a slow rate as to allow for association of the core surrounded by said envelope with the surface of cells and/or for absorption of said core into the inside of cells.

Abstract: Disclosed is a method for in vivo imaging tissue of a individual, by performing magnetic resonance imaging utilizing an extended cobalt complex as a contrast enhancement agent. The extended cobalt complex is comprised of cobalt atoms, a carboxylate ligand, an amine ligand, and a multidentate thiol-containing organic ligand, the cobalt atoms being linked to thiol groups and counter ions. The extended cobalt complex is characterized as stable, water soluble, non-aggregating, magnetic, and from 0.5 to 10 nm in size. This method is especially useful in imaging tumor tissue, and also tissue which is regenerating from a wound. The extended cobalt complex can be specifically targeted to a particular tissue to enable selective imaging of that tissue. This is done by linking the extended cobalt complex to a binding moiety which specifically binds a molecule selectively expressed in the tissue.

Abstract: The invention relates to a device for magnetic separation of pharmaceutical preparations, their starting or intermediate products that contain a separation space, in which a magnetic gradient field prevails and which has an inlet and an outlet, whereby the device is embodied in the form of an attachment filter for injection instruments or infusion instruments.

Abstract: The invention relates to macrocyclic perfluoroalkylamides, their production and their use in diagnosis.

Abstract: This relates to a contrast medium containing a complex of a gadolinium (Gd) type contrast agent and a polymer. More particularly, the contrast medium wherein the polymer capable of phase transit in response to environmental changes, particularly, pH, light or temperature, to develop a different water solubility, and a method for imaging by the use of this contrast medium. By binding a polymer responsive to microenvironmental changes with a Gd type MRI contrast agent, on-off switching of MRI imaging capability is enabled, wherein imaging occurs only on the target sites. Consequently, a highly specific MRI contrast medium can be obtained, whereby a highly specific MRI diagnosis is made possible, wherein only the target sites such as a tumor and a particular site are imaged and otherwise at the site where imaging is not necessary.

Abstract: This invention relates to a method of contrast agent-enhanced magnetic resonance imaging of perfusion in vasculated tissue within a human or non-human animal body in which a bolus comprising a contrast-enhancing amount of a magnetic resonance imaging contrast agent is administered into the vascular system of said body, and said body is subjected to a magnetic resonance imaging procedure whereby signals or images representative of first pass of said contrast agent bolus through tissue of interest are generated, characterised in that (i) said contrast agent is capable of exhibiting simultaneous, determinable T1 and T2* reducing effects under the imaging procedure employed and (ii) a T1-weighted imaging procedure is used (a) to visualise the first pass of said contrast agent bolus through said tissue by virtue of its signal lowering T2* effect and (b) to obtain a T1-weighted contrast agent-enhanced image of said tissue.

Abstract: The present invention provides a coating that emits magnetic resonance signals and a method for coating medical devices therewith. The coating includes a paramagnetic metal ion-containing polymer complex that facilitates diagnostic and therapeutic techniques by readily visualizing medical devices coated with the complex.

Abstract: Novel gas filled microspheres useful as magnetic resonance imaging (MRI) contrast agents are provided.

Abstract: Superparamagnetic particles consist of superparamagnetic one-domain particles and aggregates of superparamagnetic one-domain particles to whose surfaces are bound inorganic and optionally organic substances optionally having further binding sites for coupling to tissue-specific binding substances, diagnostic or pharmacologically active substances. The superparamagnetic particles consist of a mixture of small superparamagnetic one-domain particles with a particle size from 3 to 50 nm and stable, degradable aggregates of small superparamagnetic one-domain particles with a particle size from 10 to 1000 nm. They are made of iron hydroxyide, iron oxide hydrate, iron oxides, iron mixed oxides or iron to the surface of which are bound silicate group containing substances among the orthosilicic acids and their condensation products and phosphate-group containing substances among the ortho- or metaphosphoric acids and their condensation products. These substances may have further binding sites.

Abstract: The present invention pertains to an image enhancing agent having a polymeric core including an image-enhancing compound chemically bound thereto and a polymeric shell surrounding the core and compound. The agent may be used for enhancing MRI images, by introducing gadolinium or other appropriate material into the core. Generally, the core is formed from an acid monomer and an esterified monomer. Preferably, a cross-linking monomer is included in the core.

Abstract: The present invention relates generally to methods and compositions for targeting the vasculature of solid tumors using immunological- and growth factor-based reagents. In particular aspects, antibodies carrying diagnostic or therapeutic agents are targeted to the vasculature of solid tumor masses through recognition of tumor vasculature-associated antigens, such as, for example, through endoglin binding, or through the specific induction of endothelial cell surface antigens on vascular endothelial cells in solid tumors.

Abstract: In a method of contrast MR imaging, using parenterally administered contrast agents, the improvement comprising using as the contrast agent, e.g. to achieve a negative contrast effect, composite particles comprising a biotolerable, carbohydrate or carbohydrate derivative, preferably polymeric, matrix material containing magnetically responsive particles, eg. of magnetite.

Abstract: Pharmaceutical agents that contain perfluoroalkyl-containing metal complexes are useful in tumor therapy and interventional radiology.