Radiopaque monomers, polymers, and microspheres are disclosed herein. Methods of using the radiopaque monomers, polymers, and microspheres are disclosed herein. Methods of manufacturing radiopaque monomers, polymers, and microspheres are disclosed herein.

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 disclosure provides method of making a nanoparticle complex wherein the nanoparticle complex comprises a ligand and a metal cation. The disclosure also provides nanoparticle complexes, methods of treating a disease in a patient utilizing the nanoparticle complexes, methods of identifying a disease in a patient utilizing the nanoparticle complexes, and kits involving the nanoparticle complexes.

Provided are MR images of a subject gastrointestinal tract structure in which the lumen of the structure is usefully darkened on both T1-weighted and T2-weighted images when the structure is imaged following administration to the subject of an enteric contrast agent formulation with particles containing encapsulated gas or partial vacuum. The present invention provides an encapsulated gas or partial vacuum particle contrast medium of use in acquiring such MR images. 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.

Hybrid gas vesicle gene cluster (GVGC) configured for expression in a prokaryotic host are described comprising gas vesicle assembly (GVA) genes native to a GVA prokaryotic species and capable of being expressed in a functional form in the prokaryotic host, and one or more gas vesicle structural (GVS) genes native to one or more GVS prokaryotic species, at least one of the one or more GVS prokaryotic species different from the GVA prokaryotic species, and related gas vesicle reporting (GVR) genetic circuits, genetic, vectors, engineered cells, and related compositions methods and systems to produce GVs, hybrid GVGC and/or image a target site.

Compounds with magnetic properties are provided herein, which belong to the category of metal oxide nanoparticles, coated and conveniently functionalized, which are conjugated with naphthalene compounds related to agglomerates and β-amyloid plaques present in neurodegenerative diseases. These new nanoparticles (NPs) are used for the non-invasive detection of agglomerates and amyloid plaques using the Magnetic Resonance Imaging (MRI) technique. The nanoparticles described here cross the blood-brain barrier (BBB), without the use of any membrane-disrupting agent. Likewise, they bind with high affinity and specificity to the agglomerates and β-amyloid plaques, and are used as contrast agents in MRI for the early detection of Alzheimer's disease (AD).

A method of diagnosing a likelihood of onset or progression of Alzheimer's disease and related dementias (ADRD) in a subject is provided. The method requires determining vascularization changes in different regions of the brain on the basis of a quantitative cerebral blood volume (qCBV) map of the subject's brain. The qCBV is obtained from one or more quantitative ultrashort time-to-echo contrast-enhanced (QUTE-CE) MRI images of the brain. A method of treating a subject for ADRD is provided. Diagnostic markers for onset and progression of Alzheimer's disease are also provided.

The present invention relates to a nanocarrier for targeted therapy and/or diagnosis of a prostate cancer cell, the nanocarrier including a micelle including a phosphate surfactant represented by a specific Chemical Formula. The micelle including the phosphate surfactant constituting the nanocarrier for targeted therapy and/or diagnosis of the prostate cancer cell according to the present invention is cleaved by the overexpressed enzyme in the vicinity of the prostate cancer cell, so that therapeutic agent or diagnostic agent particles loaded on the micelle are capable of being selectively released to the prostate cancer cell. Therefore, it is possible to maximize the therapeutic and/or diagnostic effects while remarkably reducing the side effects of the drug in the living body compared to a conventional technology.

The invention relates to nano-particles comprising metallic ferromagnetic nanocrystals combined with either amorphous or graphitic carbon in which or on which chemical groups are present that can dissociate in aqueous solutions. According to the invention there is provided nano-particles comprising metal particles of at least one ferromagnetic metal, which metal particles are at least in part encapsulated by graphitic carbon. The nano-particles of the invention are prepared by impregnating carbon containing bodies with an aqueous solution of at least one ferromagnetic metal precursor, drying the impregnated bodies, followed by heating the impregnated bodies in an inert and substantially oxygen-free atmosphere, thereby reducing the metal compounds to the corresponding metal or metal alloy.