The present application relates to an aptamer nucleic acid molecule, a complex containing the aptamer nucleic acid molecules, a method of detecting intracellular or extracellular RNA, DNA or other target molecules, and a kit containing the aptamer. The aptamer of the present application is capable of specifically binding a kind of fluorophore micromolecules, and can significantly enhance fluorescence intensity under excitation light of appropriate wavelength.

The present disclosure relates to a structure capable of simultaneously purifying and detecting a nucleic acid by directly applying a sample, and more particularly, to a structure capable of performing sample preparation, loop-mediated isothermal amplification, detection and analysis steps on a single chip by applying lab-on-paper technology, and capable of finally determining whether the disease or bacterial is infected by moving the sample in a lateral flow method.

In an amplification reaction in a microfluidic apparatus, the reaction is carried out using starting substances tagged with fluorophore and quencher. The detection of reaction products occurs according to the disclosure by a separation of fluorophore and quencher occurring in the context of the amplification reaction. For the detection reaction, at least one energy-transferring substance is added and the evaluation occurs on the basis of the fluorescence emission of the fluorophores which occurs.

In an amplification reaction in a microfluidic apparatus, the reaction is carried out using starting substances tagged with fluorophore and quencher. The detection of reaction products occurs according to the disclosure by a separation of fluorophore and quencher occurring in the context of the amplification reaction. For the detection reaction, at least one energy-transferring substance is added and the evaluation occurs on the basis of the fluorescence emission of the fluorophores which occurs.

Improved compositions and methods for using modified non-retroviral reverse transcriptase to perform 3′ extension of a nucleic acid, employ non-templated deoxynucleotide addition to a single-stranded nucleic acid and/or synthesis of complementary DNA using non-complementary nucleic acids as primer and template (RNA- or DNA-templated DNA polymerase activity.

Improved compositions and methods for using modified non-retroviral reverse transcriptase to perform 3′ extension of a nucleic acid, employ non-templated deoxynucleotide addition to a single-stranded nucleic acid and/or synthesis of complementary DNA using non-complementary nucleic acids as primer and template (RNA- or DNA-templated DNA polymerase activity.

Techniques are provided for generating an array-specific range of Tm values to be used for calling a sample in a given array positive or negative for a target nucleic acid sequence. A sample well in an array is provided with a control sample containing a control nucleic acid sequence. The control sample is amplified by thermal cycling the sample well. A Tm value for the control sample is identified and compared to an expected Tm value for the control nucleic acid sequence to calculate a relationship between the identified control Tm value and the expected control Tm value. By applying this relationship to an expected Tm value for a target nucleic acid sequence, an array-specific range of Tm values for the target nucleic acid sequence is generated and can be used for calling an experimental sample in the same array positive or negative for the target nucleic acid sequence.

Techniques are provided for generating an array-specific range of Tm values to be used for calling a sample in a given array positive or negative for a target nucleic acid sequence. A sample well in an array is provided with a control sample containing a control nucleic acid sequence. The control sample is amplified by thermal cycling the sample well. A Tm value for the control sample is identified and compared to an expected Tm value for the control nucleic acid sequence to calculate a relationship between the identified control Tm value and the expected control Tm value. By applying this relationship to an expected Tm value for a target nucleic acid sequence, an array-specific range of Tm values for the target nucleic acid sequence is generated and can be used for calling an experimental sample in the same array positive or negative for the target nucleic acid sequence.

A microfluidic reaction chamber with a reaction chamber circuit includes a microfluidic reaction chamber to contain a reaction fluid for amplification of nucleic acids, and a reaction chamber circuit disposed within the microfluidic reaction chamber. The microfluidic reaction chamber includes a base wall, a top wall parallel to the base wall and defined in part by a transparent lid, a first side wall, and a second side wall. The reaction chamber circuit is disposed within the microfluidic reaction chamber, and includes a top surface, a bottom surface, a first side wall, and a second side wall. The reaction chamber circuit is in fluidic contact with the reaction fluid and includes a photodetector to detect a fluorescence signal from a labeled fluorescent tag in the reaction fluid.

A microfluidic reaction chamber with a reaction chamber circuit includes a microfluidic reaction chamber to contain a reaction fluid for amplification of nucleic acids, and a reaction chamber circuit disposed within the microfluidic reaction chamber. The microfluidic reaction chamber includes a base wall, a top wall parallel to the base wall and defined in part by a transparent lid, a first side wall, and a second side wall. The reaction chamber circuit is disposed within the microfluidic reaction chamber, and includes a top surface, a bottom surface, a first side wall, and a second side wall. The reaction chamber circuit is in fluidic contact with the reaction fluid and includes a photodetector to detect a fluorescence signal from a labeled fluorescent tag in the reaction fluid.