It is intended to provide a kit or a device for the detection of colorectal cancer and a method for detecting colorectal cancer. The present invention provides a kit or a device for the detection of colorectal cancer, comprising a nucleic acid capable of specifically binding to a miRNA in a sample from a subject, and a method for detecting colorectal cancer, comprising measuring the miRNA in vitro.

It is intended to provide a kit or a device for the detection of colorectal cancer and a method for detecting colorectal cancer. The present invention provides a kit or a device for the detection of colorectal cancer, comprising a nucleic acid capable of specifically binding to a miRNA in a sample from a subject, and a method for detecting colorectal cancer, comprising measuring the miRNA in vitro.

It is intended to provide a kit or a device for the detection of breast cancer and a method for detecting breast cancer. The present invention provides a kit or a device for the detection of breast cancer, comprising nucleic acid(s) capable of specifically binding to a miRNA in a sample of a subject, and a method for detecting breast cancer, comprising measuring the miRNA in vitro.

A method of separating a target double-stranded nucleic acid molecule from a sample including the target double-stranded nucleic acid molecule and a non-target double-stranded nucleic acid molecule, including (1) mixing the sample, a pyrrole-imidazole-containing polyamide (first PI polyamide) modified with a first linker molecule and capable of specifically binding to a sequence of the target double-stranded nucleic acid molecule, and a carrier a modified with a first ligand capable of specifically binding and/or adsorbing to the first linker molecule such that a mixed solution is produced, (2) forming a complex A by binding the carrier a to the first PI polyamide with which the target double-stranded nucleic acid molecule is bound in the mixed solution, and (3) separating the complex A from the mixed solution.

A method of separating a target double-stranded nucleic acid molecule from a sample including the target double-stranded nucleic acid molecule and a non-target double-stranded nucleic acid molecule, including (1) mixing the sample, a pyrrole-imidazole-containing polyamide (first PI polyamide) modified with a first linker molecule and capable of specifically binding to a sequence of the target double-stranded nucleic acid molecule, and a carrier a modified with a first ligand capable of specifically binding and/or adsorbing to the first linker molecule such that a mixed solution is produced, (2) forming a complex A by binding the carrier a to the first PI polyamide with which the target double-stranded nucleic acid molecule is bound in the mixed solution, and (3) separating the complex A from the mixed solution.

The present invention provides an antisense oligonucleotide for inhibiting biosynthesis of chondroitin sulfate. The antisense oligonucleotide comprises at least one modified nucleotide, wherein the antisense oligonucleotide suppresses expression of one or both of the chondroitin sulfate N-acetylgalactosaminyltransferase-1 (CSGalNAcT1) gene and the chondroitin sulfate N-acetylgalactosaminyltransferase-2 (CSGalNAcT2) gene.

The purpose of the present invention is to provide a method for accurately measuring and controlling intracellular potential by a simple method that is less invasive to the cell and does not require a skilled technique. The present invention makes it possible to provide an intracellular recording electrode inside the cytoplasm by introducing conductive nanoparticles into a cell cultured on a conductive plate electrode, attracting the conductive nanoparticles inside the cell to the side of the cell adhered to the conductive plate electrode, and causing the conductive nanoparticles to pass through the cell membrane. Measuring the current or voltage between the intracellular recording electrode and an extracellular electrode in extracellular solution makes it possible to measure the intracellular potential. In addition, applying a current from one of the electrodes or applying a voltage makes it possible to control the intracellular potential and to measure the activity of the ion channels using a membrane potential fixation method. Similarly, using a magnetic electrode adhered to the cell surface of a target cell into which conductive nanoparticles have been introduced beforehand to attract the conductive nanoparticles in the cell to the side of the cell adhered to the electrode and cause the conductive nanoparticles to pass through the cell membrane to make contact with the magnetic electrode, makes it possible to provide an intracellular recording electrode inside the cytoplasm. Alternatively, adhering conductive nanoparticles adsorbed to the surface of a magnetic electrode to the upper side of the target cell and causing the conductive nanoparticles to pass through the cell membrane by attracting the conductive particles to an iron plate provided on the lower side of the cell thereby forms an intracellular recording electrode.

Immunogenic compositions containing a human immunodeficiency virus (HIV) gp140 protein, sorbitol, polysorbate 20, and histidine buffer are described. The described immunogenic compositions are advantageous in that they are stable at refrigerated temperature for extended periods of time, and are compatible with an adjuvant. Also described are methods for storing the immunogenic compositions.

Immunogenic compositions containing a human immunodeficiency virus (HIV) gp140 protein, sorbitol, polysorbate 20, and histidine buffer are described. The described immunogenic compositions are advantageous in that they are stable at refrigerated temperature for extended periods of time, and are compatible with an adjuvant. Also described are methods for storing the immunogenic compositions.

The present invention aims to provide a method for simply and highly accurately detecting castration-resistant prostate cancer (CRPC), and a reagent that can be used for this method. By measuring the level of GDF15 propeptide present in a sample as a novel detection marker for CRPC, acquisition of castration resistance in a prostate cancer patient during or after endocrine therapy is detected. An antibody that specifically recognizes GDF15 propeptide is included in the CRPC detection reagent.