Disclosed herein is a method for the detection of the presence of sperm DNA fragmentation in a semen sample. The method comprises a step of embedding the semen sample containing sperm cells in a gel comprising acrylamide, acrylic acid, methacrylic acid, N-isopropylacrylamide (NIPAM), alginate, or polyethylene glycol (PEG), to obtain a sperm cells-embedded gel. A kit for detecting sperm DNA fragmentation in a semen sample is also disclosed.

The present invention relates to a method for detecting a target nucleic acid, which induces any surrogate target to be amplified in the presence of the target nucleic acid and is useful for molecular diagnosis, prenatal diagnosis, early diagnosis, cancer diagnosis, genetic related diagnosis, genetic trait diagnosis, diagnosis of infectious bacteria, identification of drug-resistant bacteria, forensic medicine, species identification of organisms, and the like.

Described herein are systems and methods for multiplexed analysis of two or more targets in a test sample including a first set of particles including a first set of target-specific reagents and a first optically detectable identifier capable of emitting a first wavelength indicative of a first target, and at least one second set of particles including a second set of target-specific reagents and a second optically detectable identifier capable of emitting a second wavelength indicative of a second target; and at least one optically detectable reporter probe capable of constitutively emitting a third wavelength in response to reaction of the first set of target-specific reagents with the first target in the test sample and/or reaction of the second set of target-specific reagents with the second target in the test sample, wherein the first wavelength, the second wavelength, and the third wavelength are optically discernable from one another.

Described herein are systems and methods for multiplexed analysis of two or more targets in a test sample including a first set of particles including a first set of target-specific reagents and a first optically detectable identifier capable of emitting a first wavelength indicative of a first target, and at least one second set of particles including a second set of target-specific reagents and a second optically detectable identifier capable of emitting a second wavelength indicative of a second target; and at least one optically detectable reporter probe capable of constitutively emitting a third wavelength in response to reaction of the first set of target-specific reagents with the first target in the test sample and/or reaction of the second set of target-specific reagents with the second target in the test sample, wherein the first wavelength, the second wavelength, and the third wavelength are optically discernable from one another.

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.

In certain embodiments, this application discloses methods for detecting lung cancer. The method includes characterization of cells extracted from human sputum, which is a valuable tissue surrogate and source of upper respiratory cells that become cancerous early in 5 the process of lung cancer development. The method includes the staining of extracted cells with fluorescent reporters that produce a specific pattern in the nuclei of labeled cells, which can be made visible by light microscopy. The pattern is relevant to a type of epigenetic coding of DNA known as DNA methylation, which changes in specific cells of the lung during cancer development, in comparison to normal respiratory cells.

In certain embodiments, this application discloses methods for detecting lung cancer. The method includes characterization of cells extracted from human sputum, which is a valuable tissue surrogate and source of upper respiratory cells that become cancerous early in 5 the process of lung cancer development. The method includes the staining of extracted cells with fluorescent reporters that produce a specific pattern in the nuclei of labeled cells, which can be made visible by light microscopy. The pattern is relevant to a type of epigenetic coding of DNA known as DNA methylation, which changes in specific cells of the lung during cancer development, in comparison to normal respiratory cells.

Methods are provided here for an easy and reliable non-fluorescent approach to detecting and monitoring PCR amplification. This includes monitoring PCR amplification by using magnesium-sensitive colorimetric dye. The dye is visually detectable color dye. Compositions are described here that comprise a magnesium-sensitive colorimetric dye, a buffer, dNTPs, magnesium ion and DNA polymerase.

Methods are provided here for an easy and reliable non-fluorescent approach to detecting and monitoring PCR amplification. This includes monitoring PCR amplification by using magnesium-sensitive colorimetric dye. The dye is visually detectable color dye. Compositions are described here that comprise a magnesium-sensitive colorimetric dye, a buffer, dNTPs, magnesium ion and DNA polymerase.