Disclosed herein are methods relating to manufacturing an embolizing agent precursor. Manufacture of the embolizing agent precursor may involve mixing a first component contained within a first container with a second component contained within a second container, the first component including a plurality of negatively charged gaseous components and a first stabilizer, the second component comprising a plurality of positively charged oil components, a second stabilizer, and a cationic surfactant. Further steps may include mixing the first component with the second component such that the first and second component are held together as a single agglomerated entity.

Disclosed herein are compositions and methods for an embolizing agent precursor. The embolizing agent precursor may include a gaseous component and a first stabilizer to stabilize the gaseous component, the first stabilizer may include a a polymer, and wherein a gas portion of the gaseous component is selected from the group consisting of sulphur hexafluoride and C3-6 perfluorocarbons. The embolizing agent precursor may further include an oil component which comprises a C1-7 hydrocarbon, a second stabilizer to stabilize the oil component, and a vaporous component configured to enlarge the gaseous component.

Various oil-in-water (O/W) nanoemulsions containing an oil phase or oil core, preferably selected from vitamin E or oleic acid, stabilized by a sphingolipid of the sphingomyelin type, and optionally other lipids such as phospholipids, cholesterol, octadecylamine, DOTAP (N-[1-(2,3-Dioleoyloxy) propyl]-N, N, N-trimethylammonium methyl-sulfate), and PEGylated derivatives (derivatives with polyethylene glycol), for use as a nanotech vehicle, for example for the management of cancer and metastatic disease. Said nanoemulsions can be functionalized with ligands capable of interacting or binding to receptors expressed on the cell membrane of tumor cells, and in particular capable of interacting or binding to receptors expressed on the membrane of primary and/or disseminated or metastatic tumor cells. Also, antitumor drugs or therapeutic biomolecules can be encapsulated in said nanoemulsions and, finally, contrast agents can be incorporated for their use in the in vivo diagnosis in said nanoemulsions.

The present disclosure discloses preparation and application of a novel multifunctional nanocomposite material with new photosensitizer, and belongs to the technical field of photodynamic therapy and the field of biomedicine. The photosensitizer multifunctional nanocomposite material provided by the present disclosure is prepared by self-assembly of cercosporin and an acid-sensitive copolymer multifunctional material with liver tumor cell targeting ability and traceability, wherein the acid-sensitive copolymer multifunctional material can be a copolymer of poly(N,N-dimethylaminoethyl methacrylate) and poly-3-azido-2-hydroxypropyl methacrylate covalently linked by galactose-modified rhodamine B. The photosensitizer multifunctional nanocomposite material disclosed by the present disclosure can specifically recognize liver tumor cells and be endocytosed into the cells through galactose-asialoglycoprotein receptor interaction, and can trigger the release of the photosensitizer cercosporin under acidic pH conditions to exert photodynamic therapy efficiency. The novel photosensitizer multifunctional nanocomposite material has a good application prospect in targeted photodynamic therapy of tumor cells.

The present disclosure related to a method of using high frequency sound waves directed toward an acoustically active particle. The high frequency sound waves may be configured to enlarge the acoustically active particle and oscillate the acoustically active particle, thereby facilitating extravasation of an agent to a tissue compartment of a region of interest.

A oil-in-water curcumin nanoemulsion that includes curcumin dissolved in at least one miscible solvent and encapsulated in an oil core, wherein the oil core also comprises a stabilizer, wherein the oil core forms an organic phase which is dispersed in an aqueous solvent, and wherein the oil core is selected from a pharmaceutically acceptable oil. A method of manufacturing an oil-in-water curcumin nanoemulsion includes dissolving the curcumin in at least one miscible solvent; encapsulating the curcumin in the oil core to produce an organic phase solution; adding the stabilizer to the organic phase solution; dispersing the organic phase solution in the aqueous solvent; and evaporating the mixture. A method of preventing metastatic cancer using an oil-in-water curcumin nanoemulsion by administering an amount of the nanoemulsion topically to an area of an excised primary tumor, and monitoring any reincidence of metastatic cancer in the excised primary tumor area.

The present disclosure relates to a method of imaging, involving administration of a bi-phasic formulation followed by application of high frequency sound waves to identify a region of interest. Following identification, a phase shift of the bi-phasic formulation may be activated by a second administration of high frequency sound waves such that gaseous components of the bi-phasic formulation are enlarged and localised at the region of interest.

There is described herein a nanoparticle comprising an outer shell comprising a porphyrin salt, an expanded porphyrin salt or an analog of porphyrin salt, around an inner oil core.

Disclosed are a film-forming agent composition for contrast agent, a film-forming lipid solution including the film-forming agent composition, a contrast agent including the film-forming lipid solution, and a preparation method thereof. The film-forming agent composition for contrast agent includes a lipid, an emulsifier and a surface charge modifier; relative to 100 parts by weight of the lipid, the content of the emulsifier is 20-50 parts by weight, and the content of the surface charge modifier is 10-35 parts by weight; and the lipid is a carboxylated phospholipid, and the surface charge modifier is a polyelectrolyte. Based on the composition, the nanodroplets of the resulting contrast agent have more uniform particle size, higher stability and better controllability, as well as a lower threshold value for ultrasonic gasification.

This disclosure provides compositions of fluorinated nanoemulsions and associated methods for producing cellular labels for tracking cells by magnetic resonance imaging (MRI), computed tomography (CT), positron emission tomography (PET), and related methods.