Oxidized metal complexes are formed using methods which adjust the pH of solutions to obtain oxidized metal complexes having particular physicochemical properties. A method for preparing an oxidized metal complex includes providing a first solution comprising a highly oxidized metal and having a pH between 0 to 7; providing a second solution comprising one or more ligands or a ligand precursor and having a pH between 7 to 13 or greater; and combining the first solution and the second solution to form a third solution comprising the first oxidized metal complex. A method for preparing an oxidized metal complex includes providing a species solution comprising a first oxidized metal complex and having a pH of at least pH 11; and adjusting the pH of the species solution to form a second oxidized metal complex. Compositions and methods for preparing and using same are provided.

The present disclosure describes an imaging composition including porous silicon microparticles, and more particularly, to a biological tissue imaging composition including a composite in which oxidized porous silicon microparticles and silver nanoparticles are combined. Since a biological tissue imaging agent of the present invention, which includes a composite of oxidized porous silicon microparticles and silver nanoparticles, continuously provides an image signal without spreading in the body as compared to conventional imaging agents, it is possible to increase surgical stability by accurately identifying target tissues in vivo in an affected area.

The present disclosure describes an imaging composition including porous silicon microparticles, and more particularly, to a biological tissue imaging composition including a composite in which oxidized porous silicon microparticles and silver nanoparticles are combined. Since a biological tissue imaging agent of the present invention, which includes a composite of oxidized porous silicon microparticles and silver nanoparticles, continuously provides an image signal without spreading in the body as compared to conventional imaging agents, it is possible to increase surgical stability by accurately identifying target tissues in vivo in an affected area.

Provided is a method of producing semiconductor nanoparticles exhibiting band-edge emission with a short emission peak wavelength. The method of producing semiconductor nanoparticles comprises: obtaining a first mixture that contains a Ag salt, an In salt, a compound containing Ga and S, and an organic solvent; and performing a heat treatment of the first mixture at a temperature in a range of 125 C. or higher and 300 C. or lower to obtain first semiconductor nanoparticles.

Oxidized metal complexes are formed using methods which adjust the pH of solutions to obtain oxidized metal complexes having particular physicochemical properties. A method for preparing an oxidized metal complex includes providing a first solution comprising a highly oxidized metal and having a pH between 0 to 7; providing a second solution comprising one or more ligands or a ligand precursor and having a pH between 7 to 13 or greater; and combining the first solution and the second solution to form a third solution comprising the first oxidized metal complex. A method for preparing an oxidized metal complex includes providing a species solution comprising a first oxidized metal complex and having a pH of at least pH 11; and adjusting the pH of the species solution to form a second oxidized metal complex. Compositions and methods for preparing and using same are provided.

A method to synthesize a silver nanohybrid material. The method includes mixing a nitrate solution with a citrate solution to form silver nanoparticles (AgNPs). The method further includes esterifying a first mixture including octadecanoic acid, octadec-9-enoic acid, and octadeca-9,12-dienoic acid with caffeic acid in the presence of an acid catalyst and a solvent to form an unsaturated carboxylic acid mixture including first, second, and third acrylic acid derivatives. The method includes reacting the unsaturated carboxylic acid mixture with ethylene glycol to form a second mixture including first, second, and third ester derivatives. The method further includes mixing the AgNPs with the second mixture to form a third mixture. The method includes evaporating water from the third mixture to form the silver nanohybrid material. The silver nanohybrid material includes a AgNP core covered with the first, second, and third ester derivatives bonded to the AgNP core.

The invention is directed to a composition of metal particles and methods of manufacturing and using the composition in the treatment of microbial infections and cancer. The particles can be nanoparticles having coupled thereto at least one of a surfactant, an antibiotic, and a drug. The particles of the invention achieve enhanced stability, enhanced cytotoxicity, and enhanced antimicrobial activity through novel combinations of metals, surfactants, antibiotics, and drugs.

The invention is directed to a composition of metal particles and methods of manufacturing and using the composition in the treatment of microbial infections and cancer. The particles can be nanoparticles having coupled thereto at least one of a surfactant, an antibiotic, and a drug. The particles of the invention achieve enhanced stability, enhanced cytotoxicity, and enhanced antimicrobial activity through novel combinations of metals, surfactants, antibiotics, and drugs.

The present application relates to a nanocomposite preparation apparatus and a nanocomposite prepared using same, and a nanocomposite preparation apparatus of the present application can prepare a nanocomposite having excellent stability by reducing toxicity while maintaining antibacterial properties of conventional antibacterial metals.

The present application relates to a nanocomposite preparation apparatus and a nanocomposite prepared using same, and a nanocomposite preparation apparatus of the present application can prepare a nanocomposite having excellent stability by reducing toxicity while maintaining antibacterial properties of conventional antibacterial metals.