Disclosed herein is a more sensitive and accurate method of monitoring the pH of a solution, wherein the pH of the solution is quantified as a function of the electrochemical response of the solution in a two or three-electrode electrochemical cell, wherein the solution comprises a compound capable of undergoing a change in its oxidation state and/or structural conformation as a function of the pH of the solution. Also disclosed are highly accelerated methods and processes enabling analysis of specific polynucleotide sequences in a sample, e.g. a biological sample. The methods disclosed herein are, for example, useful for rapid screening of a large amount of samples in a point-of-care setting.

Disclosed herein is a more sensitive and accurate method of monitoring the pH of a solution, wherein the pH of the solution is quantified as a function of the electrochemical response of the solution in a two or three-electrode electrochemical cell, wherein the solution comprises a compound capable of undergoing a change in its oxidation state and/or structural conformation as a function of the pH of the solution. Also disclosed are highly accelerated methods and processes enabling analysis of specific polynucleotide sequences in a sample, e.g. a biological sample. The methods disclosed herein are, for example, useful for rapid screening of a large amount of samples in a point-of-care setting.

The present invention relates to a composition for detecting nucleic acid comprising duplex molecular beacon and graphene oxide and a colorimetric signal enhancement method of detecting nucleic acid using the same. According to the composition, kit and method for detecting nucleic acid of the present invention, a complex can be formed by adsorbing a single strand having a DNAzyme sequence dissociated from the conjugate of a duplex molecular beacon and a target nucleic acid to the graphene oxide surface, and separated, and a colorimetric signal amplified therefrom can be induced, so that a very low concentration of target nucleic acid can be detected with high efficiency and the target nucleic acid can be detected quickly and easily in seconds. Therefore, a new colorimetric target nucleic acid detection system capable of point of care testing (POCT) can be provided.

The present invention relates to a composition for detecting nucleic acid comprising duplex molecular beacon and graphene oxide and a colorimetric signal enhancement method of detecting nucleic acid using the same. According to the composition, kit and method for detecting nucleic acid of the present invention, a complex can be formed by adsorbing a single strand having a DNAzyme sequence dissociated from the conjugate of a duplex molecular beacon and a target nucleic acid to the graphene oxide surface, and separated, and a colorimetric signal amplified therefrom can be induced, so that a very low concentration of target nucleic acid can be detected with high efficiency and the target nucleic acid can be detected quickly and easily in seconds. Therefore, a new colorimetric target nucleic acid detection system capable of point of care testing (POCT) can be provided.

The present invention relates to a method of visualizing biomolecules, having the steps of: a) providing a sample of immobilized biomolecules in a matrix and carry on the electrophoresis process; b) incubating the matrix of step a) in a solution containing a cyanine-derived molecule, for a time of 5 to 60 minutes, at room temperature, in a container preventing exposure to light, shaking the container at less of 75 rpm; c) transferring the matrix from step b) to a container with a solution having: at least one tetrazolium salt and incubating for a time of 15 to 120 minutes at room temperature under light exposure; d) removing the matrix with immobilized biomolecules from the previous step and washing with distilled water; and e) visualizing directly by the naked eye the biomolecules immobilized in the matrix.

The present invention relates to a method of visualizing biomolecules, having the steps of: a) providing a sample of immobilized biomolecules in a matrix and carry on the electrophoresis process; b) incubating the matrix of step a) in a solution containing a cyanine-derived molecule, for a time of 5 to 60 minutes, at room temperature, in a container preventing exposure to light, shaking the container at less of 75 rpm; c) transferring the matrix from step b) to a container with a solution having: at least one tetrazolium salt and incubating for a time of 15 to 120 minutes at room temperature under light exposure; d) removing the matrix with immobilized biomolecules from the previous step and washing with distilled water; and e) visualizing directly by the naked eye the biomolecules immobilized in the matrix.

Methods for degrading contaminant nucleic acid. The methods use combinations of metal ions and peroxide ions to produce a variety of oxidative species that degrade nucleic acid. Methods of the invention are useful for decontaminating laboratory equipment or solutions. After the equipment or solutions have been decontaminated, the metal ion and peroxide ion solution can be deactivated by raising the temperature to dissociate the peroxide or by binding the metal ions, e.g., with a chelating agent.

Methods for degrading contaminant nucleic acid. The methods use combinations of metal ions and peroxide ions to produce a variety of oxidative species that degrade nucleic acid. Methods of the invention are useful for decontaminating laboratory equipment or solutions. After the equipment or solutions have been decontaminated, the metal ion and peroxide ion solution can be deactivated by raising the temperature to dissociate the peroxide or by binding the metal ions, e.g., with a chelating agent.

A method of immobilizing an oligonucleotide on a polypropylene surface involves oxidizing at least a portion of the polypropylene surface, and contacting an amine-terminated oligonucleotide with the oxidized polypropylene surface to immobilize the oligonucleotide to the oxidized polypropylene surface. The method of immobilizing labelled ssDNA on a polypropylene surface is useful in a hybridization assay.

A method of immobilizing an oligonucleotide on a polypropylene surface involves oxidizing at least a portion of the polypropylene surface, and contacting an amine-terminated oligonucleotide with the oxidized polypropylene surface to immobilize the oligonucleotide to the oxidized polypropylene surface. The method of immobilizing labelled ssDNA on a polypropylene surface is useful in a hybridization assay.