The present invention relates to a magnetic resonance imaging (MRI) contrast agent, particularly a metal oxide nanoparticle-based T1-T2 dual-mode MRI contrast agent that can be used not only as a T1 MRI contrast agent but also as a T2 MRI contrast agent, and a method for producing the same. The metal oxide nanoparticle-based T1-T2 dual-mode MRI contrast agent can provide more accurate and detailed information associated with disease than single MRI contrast agent by the beneficial contrast effects in both T1 imaging with high tissue resolution and T2 imaging with high feasibility on detection of a lesion.

Described herein are formulations that can include one or more enzymes that can break down one or more components of scar tissue. Also provided herein are methods of treating scar tissue by administering a formulation provided herein to a subject in need thereof.

A liposomal nanocarrier delivery system for targeting an active CD44 molecule, preparation method therefor, and uses thereof. The surface of the liposome is partially modified by a targeting ligand, wherein the targeting ligand is a ligand that can be specifically combined with the active CD44 molecule. The liposomal nanocarrier delivery system can be used for diagnosing, preventing, and treating vulnerable plaque or diseases related to vulnerable plaque.

The present invention relates to new molecular design that allows micelles to report their activation and disassembly by an enzymatic trigger. The molecular design is based on introduction of a labeling moiety selected from a fluorescent dye, a dark quencher, combinations of dyes or dyes/quenchers, and a fluorinated moiety (a .sup.19F-magenetic resonance (MR) probe for turn ON/OFF of a .sup.19F-MR signal) through covalent binding to the focal point of amphiphilic polymer-dendron hybrids with the labeling moiety. At the assembled micellar state, the dyes are closely packed and hence the probability for intermolecular interactions increases significantly, leading to alteration of the fluorescent properties (signal quench or shift) or the .sup.19F-MR signal (OFF state) of the micelles. Upon enzymatic cleavage of the hydrophobic end-groups from enzyme-responsive dendron, the polymers become hydrophilic and disassemble. This structural change is then translated into a spectral change as dye-dye interactions are halted and the dyes regain their intrinsic fluorescent properties, or alternatively by turn ON the .sup.19F-MR signal. The high modularity of the design allows the introduction of various types of dyes and thus enables rational adjustment of the spectral response. Two major types of responses are described: Turn-On/Off and spectral shift, depending on the type of labeling dye. The present invention further provides methods of use of the hybrid delivery system and to a kit comprising the same.

A composition comprises an anti-nucleolin agent conjugated to nanoparticles, and optionally containing gadolinium. Furthermore, a pharmaceutical composition for treating cancer comprises a composition including an anti-nucleolin agent conjugated to nanoparticles, and a pharmaceutically acceptable carrier. The composition enhances the effectiveness of radiation therapy, enhancing contrast in X-ray imaging techniques, and when gadolinium is present, provide cancer selective MRI contrast agents.

Pharmaceutical composition containing poly(bile) acid (PBA) polymers for oral delivery of agent(s) show enhanced uptake by the pancreas, liver, and colon. These nanoparticles show significant retention in the pancreas and colon and are therefore useful for selective delivery. The examples demonstrate efficacy of oral administration of insulin to treat diabetes, and oral induction of tolerance by administration of insulin or ovalbumin in combination with rapamycin. Diabetic animals treated with the insulin or insulin with rapamycin showed normalization of blood glucose levels.

An imaging nanoparticle comprising a plant virus particle having an interior surface and an exterior surface, an imaging agent that is linked to the interior and/or exterior surface, and a layer of biocompatible mineral such as silica coated over the exterior surface, is described. The imaging nanoparticle can be used in method of generating an image of a tissue region of a subject, by administering to the subject a diagnostically effective amount of an imaging nanoparticle and generating an image of the tissue region of the subject to which the imaging nanoparticle has been distributed.

One embodiment of the present invention relates to a nanoemulsion and a preparation method therefor, the nanoemulsion comprising an oil component, a surfactant, and an aqueous component, wherein the aqueous component comprises a water-soluble active ingredient, a polysaccharide, and hyaluronic acid.

One embodiment of the present invention relates to a nanoemulsion and a preparation method therefor, the nanoemulsion comprising an oil component, a surfactant, and an aqueous component, wherein the aqueous component comprises a water-soluble active ingredient, a polysaccharide, and hyaluronic acid.

The present invention relates to a compressed solid composition for MRI comprising a physiologically acceptable manganese (II) compound, its preparation and use for preparing an oral solution.