Disclosed herein are gelatin particles that have been crosslinked without using a crosslinking agent and are easily taken up by cells themselves, and a method for producing such gelatin particles. The gelatin particles are made of self-crosslinked gelatin and have a particle diameter of 0.010 m or more but 5.0 m or less. The gelatin particles can be produced by discharging droplets of a liquid containing melted gelatin into air in a heating tube or a drying chamber and drying the droplets to form the gelatin into particles under conditions where a difference between the temperature in the heating tube or the drying chamber and the temperature of the liquid is 235 C. or less and further by crosslinking the gelatin forming the particles.

3D cine MR angiography systems and methods are disclosed for use during the steady state intravascular distribution phase of ferumoxytol. The 3D cine MRA technique enables improved delineation of cardiac anatomy in pediatric patients undergoing cardiovascular MRI.

The present disclosure relates to a process for the preparation of core-shell particles by the coacervation method encapsulating contrast agents for multimodal imaging. The process consists in: a. Providing a water in oil emulsion of a biocompatible polyelectrolyte polymer. b. Providing an aqueous solution of a biocompatible polyelectrolyte polymer having opposite charges of the polyelectrolyte of step a). c. Adding a crosslinking agent to the primary emulsion and the secondary solution. d. Adding at least a tracer independently to the primary emulsion or the secondary solution or emulsion. e. Adding the secondary aqueous solution to the primary emulsions and occurring of the complex coacervation leading to the separation of the coacervate particles. f. Optionally absorb a further tracer into the nanoparticles The disclosure also relates to the coacervates obtained by the above described process and their use as probe for multimodal imaging in the diagnostic field.

The present invention provides iron oxide magnetic particles containing iron oxide and MX.sub.n, wherein M as a transition metal containing electrons in a 5d orbital on the periodic table includes one or more selected from the group consisting of Hf, Ta, W, Re, Os, Ir, Pt, Au, and Hg, X includes one or more selected from the group consisting of F, Cl, Br, and I, and n is an integer of 1 to 6.

The disclosure pertains to conformational epitopes in A-beta, antibodies thereto and methods of making and using immunogens and antibodies specific thereto.

A biocompatible curable composition and a method of detecting a border of a tumor, a tissue of interest, or both including injecting the biocompatible curable composition and contacting the border of a tumor or a tissue, the biocompatible curable composition crosslinks to form a three-dimensional cured nanocomposite, and imaging the three-dimensional (3D) cured nanocomposite, and imaging the 3D cured nanocomposite by at least one of MRI, CT, ultrasound, and X-ray, to detect the border of the tumor or the tissue of interest or track tumor motion during radiotherapy treatment. The biocompatible curable composition comprising an organic polymer having a hydrolysable functional group, a metallic nanoparticle, and a polar or a non-polar solvent. A brachytherapy strand consisting of a biocompatible curable composition and a radio-isotope seed. The biocompatible curable composition is shaped into an elongated cylinder and forms a 3D cured nanocomposite with a radio-isotope seed embedded.

The disclosure pertains to epitopes identified in A-beta including conformational epitopes, antibodies thereto and methods of making and using immunogens and antibodies specific thereto.

The presently disclosed subject matter provides agents, compositions, and methods for augmenting ablation of a target tissue in a subject in need thereof, for example, using agents that modulate protective and/or reparative cellular processes induced in target tissue by application of ablative energy to the target tissue to sensitize the target tissue to the ablative energy. The presently disclosed subject matter further provides methods for augmenting radiofrequency ablation of cardiac tissue, for example, by applying radiofrequency energy to ablate cardiac tissue in the presence of metallic nanoparticles magnetically guided to the cardiac tissue.

The present invention relates to a magnetic resonance structure with a cavity or a reserved space that provides contrast and the additional ability to frequency-shift the spectral signature of the NMR-susceptible nuclei such as water protons by a discrete and controllable characteristic frequency shift that is unique to each MRS design. The invention also relates to nearly uniform solid magnetic resonance T.sub.2* contrast agents that have a significantly higher magnetic moment compared to similarly-sized existing MRI contrast agents.

Multifunctional nanoparticles can include two or more different populations of nanocrystals that impart a combination of properties arising from the constituent populations in a single, multifunctional nanoparticle.