The present invention relates to a method for preparing a nano diagnostic agent capable of selective staining of abnormal inflammatory tissues or tumor tissues. The method for preparing a nano diagnostic agent, according to the present invention, is characterized by comprising: a step of forming a first mixture by mixing polysorbate 80, soybean oil, and a water-insoluble staining material; a step of forming a second mixture by mixing and then heating the first mixture and a triblock copolymer; a step of forming a nano platform solid by cooling the second mixture; a step of forming a third mixture by mixing a solvent with the nano platform solid; a step of removing impurities from the third mixture; and a step of forming a nano-composite by freeze-drying the third mixture from which the impurities are removed. Thereby, the present invention can increase the search efficiency of a disease lesion by being transmitted through micropores of a tumor through direct permeation and absorption so as to precisely distinguish normal tissues from abnormal tissues.

The present invention is directed to compositions and methods targeting cells in a subject harboring conditions or at risk for conditions that would benefit from gas-based diagnostic and therapy. The present invention relates to the use of fluorochemical compositions and methods of delivery that result in retention of the fluorochemical composition and any bioactive agent, including gaseous substances, delivered in combination with the fluorochemical composition.

Described herein are hybrid nanoparticles that are exosomes loaded with one or more nanoparticle dendrimers. Also included are pharmaceutical compositions including the hybrid nanoparticles and methods of making the hybrid nanoparticles. Also described is a method of treating a human subject by administering to the human subject the above-described hybrid nanoparticles.

The present invention is directed to additive manufacturing compositions and methods for producing additive manufacturing composite blends with oxidized discrete carbon nanotubes with dispersion agents bonded to at least one sidewall of the oxidized discrete carbon nanotubes. Such compositions are especially useful when radiation cured, sintered or melt fused.

The present invention relates to a nanocomposite for detecting hydrogen sulfide; a method for preparing the same; a novel reactive fluorogenic compound to be used in the method; a kit for detecting hydrogen sulfide comprising the nanocomposite; and a method for providing information for the diagnosis of a disease, which causes abnormal secretion of hydrogen sulfide, by using the nanocomposite.

Embodiments of fluorescent contrast agent compositions and formulations are provided for non-invasive administration, including oral, sublingual and buccal administration, e.g., for optical imaging of a subject's body part or tissue.

An object is to provide a method of inspection enabling a slurry of a batch resulting in abnormal accumulation to be identified in advance, and to provide an SWCNT slurry for bioimaging that has undergone the inspection.

In order to solve the above problems, the present invention provides a method for inspecting a semiconductor single-walled carbon nanotube (SWCNT) slurry for bioimaging, the slurry comprising: semiconductor SWCNTs oxidized by being directly irradiated with ultraviolet rays in atmosphere and a dispersant composed of an amphiphilic substance that coats surfaces of the SWCNTs, the method comprising: using at least two types of methods selected from the group consisting of absorption spectroscopy, a photoluminescence method, and particle size measurement, confirming that an average particle size of the semiconductor SWCNTs is smaller than 10 nm, isolated dispersibility of the semiconductor SWCNTs is high, and/or the semiconductor SWCNTs are oxidized.

The present invention relates to an aqueous formulation for use in diagnostic detection wherein the aqueous formulation is administered prior to the administration of a fluorinated contrast agent or composition comprising a fluorinated contrast agent as well as to a method of administration. The invention further relates to the use of said aqueous formulation for the diagnostic detection of inflammatory pathological conditions using MR imaging. In addition the invention relates to a kit as well as a diagnostic kit suitable for use in diagnostic detection.

A contrast mixture with increased affinity and selectivity to neoplasms of the gastrointestinal tract, being of three components and consisting of 0.0005-0.01% by weight of low-molecular component, 0.05-6% by weight of high-molecular component and isotonic solution, wherein low-molecular component is a contrast substance, which is a colouring agent used in food industry and pharmacy and high-molecular component is a colloid modulator of velocity designed to decelerate diffusion of the contrast mixture into a tissue in such manner that the velocity of diffusion into healthy tissue of gastrointestinal tract and the velocity of diffusion into neoplasm tissue of gastrointestinal tract is different. In an embodiment, the colouring agent is the sodium and/or calcium salt of [4-(alpha-(4-diethylaminophenyl)-5-hydroxy-2,4-disulphophenylmethylidene)-2,5-cyclohexadiene-1-ylidene] diethylammonium hydroxide or 3,7-bis(Dimethylamino)-phenothia zin-5-ium chloride and the colloid modulator of velocity is a starch, pectin, agar-agar (agarose and agaropectins) and/or non-linearly branched amylopectins. A use of the contrast mixture for colour sharp distinction of the interface between healthy tissue and neoplasm tissue of gastrointestinal tract.

Disclosed are multi-compartmental nanoparticulate systems for imaging as well as the diagnosis, monitoring, and treatment of inflammation and/or disease. These multicompartmental nanoparticulate systems can be used to target specific cells or cellular structures. Furthermore, these systems are capable of simultaneous delivery of hydrophilic and lipophilic compositions. Finally, these systems also allow for temporal control of drug delivery.