Abstract: Methods for analyzing a target nucleic acid are provided. A fluorescent label attached to a nucleic acid is incorporated into at least one strand of the target nucleic acid and the methods include monitoring change in fluorescence emission resulting from dissociation of the labeled strand of the amplification product from its complementary strand.

Abstract: Methods and kits are provided for nucleic acid analysis. In an illustrative method a target nucleic acid is amplified using a first primer and a second primer, wherein the first primer comprises a probe element specific for a locus of the target nucleic acid and a template-specific primer region, and the probe element is 5? of the template-specific primer region, subsequently allowing the probe element to hybridize to the locus to form a hairpin, generating a melting curve for the probe element by measuring fluorescence from a dsDNA binding dye as the mixture is heated, wherein the dye is not covalently bound to the first primer, and analyzing the shape of the melting curve. Kits may include one or more of the first and second primers, the dsDNA binding dye, a polymerase, and dNTPs.

Abstract: A thermal cycling method and device is disclosed. The device comprises a sample chamber whose temperature can be rapidly and accurately modulated over a range of temperatures needed to carry out a number of biological procedures, such as the DNA polymerase chain reaction. Biological samples are placed in containers each comprising a reservoir and a reaction portion, wherein the reaction portion has a small volume. The small volume reaction portion permits the rapid and accurate temperature modulation. With an optically transmissible reaction portion, DNA amplification may be monitored by fluorescence during PCR.

Abstract: The present invention is directed to devices for performing PCR and monitoring the reaction of a sample comprising a nucleic acid and a fluorescent dye. Illustrative devices comprise a heat exchange component for heating and cooling the sample, a control device for repeatedly operating the heat exchange component to subject the sample to thermal cycling, an excitation source for optically exciting the sample to cause the sample to fluoresce, a photodetector for detecting temperature-dependent fluorescence levels from the sample, and a processor configured to record and process emissions from the fluorescent dye.

Abstract: Methods are provided for nucleic acid analysis wherein a target nucleic acid that is at least partially double stranded is mixed with a dsDNA binding dye having a percent saturation of at least 50% to form a mixture. In one embodiment, the nucleic acid is amplified in the presence of the dsDNA binding dye, and in another embodiment a melting curve is generated for the target nucleic acid by measuring fluorescence from the dsDNA binding dye as the mixture is heated. Dyes for use in nucleic acid analysis and methods for making dyes are also provided.

Abstract: The present invention is directed to devices for performing PCR and monitoring the reaction of a sample comprising a nucleic acid and a fluorescent dye. Illustrative devices comprise a heat exchange component for heating and cooling the sample, a control device for repeatedly operating the heat exchange component to subject the sample to thermal cycling, an excitation source for optically exciting the sample to cause the sample to fluoresce, a photodetector for detecting temperature-dependent fluorescence levels from the sample, and a processor configured to record and process emissions from the fluorescent dye.

Abstract: The present invention is directed to devices for performing PCR and monitoring the reaction of a sample comprising a nucleic acid and a fluorescent dye. Illustrative devices comprise a heat exchange component for heating and cooling the sample, a control device for repeatedly operating the heat exchange component to subject the sample to thermal cycling, an excitation source for optically exciting the sample to cause the sample to fluoresce, a photodetector for detecting temperature-dependent fluorescence levels from the sample, and a processor configured to record and process emissions from the fluorescent dye.

Abstract: Methods are provided for nucleic acid analysis wherein a target nucleic acid that is at least partially double stranded is mixed with a dsDNA binding dye having a percent saturation of at least 50% to form a mixture. In one embodiment, the nucleic acid is amplified in the presence of the dsDNA binding dye, and in another embodiment a melting curve is generated for the target nucleic acid by measuring fluorescence from the dsDNA binding dye as the mixture is heated. Dyes for use in nucleic acid analysis and methods for making dyes are also provided.

Abstract: Methods are provided for nucleic acid analysis wherein a target nucleic acid is mixed with a dsDNA binding dye to form a mixture. Optionally, an unlabeled probe is included in the mixture. A melting curve is generated for the target nucleic acid by measuring fluorescence from the dsDNA binding dye as the mixture is heated. Dyes for use in nucleic acid analysis and methods for making dyes are also provided.

Abstract: Methods of identifying the type of a cell are provided, the methods comprising determining the Tm profile of a sample rRNA or fragment thereof from the cell using a double stranded nucleic acid-specific dye, wherein a match between the determined Tm profile and the Tm profile of a corresponding rRNA or fragment thereof of a cell from a known cell type indicates that the sample rRNA is from the known cell type.

Abstract: Methods are provided for nucleic acid analysis wherein a target nucleic acid is mixed with a dsDNA binding dye to form a mixture. Optionally, an unlabeled probe is included in the mixture. A melting curve is generated for the target nucleic acid by measuring fluorescence from the dsDNA binding dye as the mixture is heated. Dyes for use in nucleic acid analysis and methods for making dyes are also provided.

Abstract: A novel method for characterizing nucleic acids. A nucleic acid is combined with a double stranded nucleic acid-specific dye to form a detectable complex between the dye and one or more double stranded structures within the nucleic acid. The combination is then exposed to varying temperatures and the fluorescence emission of the dye is measured to determine the melting temperature(s) for the double stranded structures. In some embodiments that melting temperature profile is then compared to melting temperature profiles generated for other nucleic acid(s) to discern differences between the compared nucleic acids.

Abstract: A thermal cycling method and device is disclosed. The device comprises a sample chamber whose temperature can be rapidly and accurately modulated over a range of temperatures needed to carry out a number of biological procedures, such as the DNA polymerase chain reaction. Biological samples are placed in containers each comprising a reservoir and a reaction portion, wherein the reaction portion has a small volume. The small volume reaction portion permits the rapid and accurate temperature modulation. With an optically transmissible reaction portion, DNA amplification may be monitored by fluorescence during PCR.

Abstract: A thermal cycling method and device is disclosed. The device comprises a sample chamber whose temperature can be rapidly and accurately modulated over a range of temperatures needed to carry out a number of biological procedures, such a DNA polymerase chain reaction. Biological samples are placed in glass micro capillary tubes and then located inside the sample chamber. A programmable controller regulates the temperature of the sample inside the sample chamber. Once a heating cycle is completed, the controller opens a door to the chamber for venting hot air out and cool ambient air is moved in. Temperature versus time profiles corresponding to optimum denaturation, annealing and elongation temperatures for amplification of DNA are achieved by the present invention.

Abstract: The present invention is directed to kits for monitoring a nucleic acid during amplification. More particularly, the present invention relates to kits comprising a first oligonucleotide labeled with a first fluorophore, a second oligonucleotide labeled with a second fluorophore, and components for amplifying the locus, wherein the first and second fluorophores comprise a fluorescence resonance energy transfer pair. Hybridization of at least the first oligonucleotide to the amplified locus places the first and second fluorophores in a resonance energy transfer relationship.

Abstract: A thermal cycling method and device is disclosed. The device comprises a sample chamber whose temperature can be rapidly and accurately modulated over a range of temperatures needed to carry out a number of biological procedures, such as the DNA polymerase chain reaction. Biological samples are placed in glass micro capillary tubes and then located inside the sample chamber. A programmable controller regulates the temperature of the sample inside the sample chamber. Monitoring of the DNA amplification is monitored by fluorescence once per cycle or many times per cycle. The present invention provides that fluorescence monitoring of PCR is a powerful tool for DNA quantification.

Abstract: A thermal cycling method and device is disclosed. The device comprises a sample chamber whose temperature can be rapidly and accurately modulated over a range of temperatures needed to carry out a number of biological procedures, such a DNA polymerase chain reaction. Biological samples are placed in glass micro capillary tubes and then located inside the sample chamber. A programmable controller regulates the temperature of the sample inside the sample chamber. Once a heating cycle is completed, the controller opens a door to the chamber for venting hot air out and cool ambient air is moved in. Temperature versus time profiles corresponding to optimum denaturation, annealing and elongation temperatures for amplification of DNA are achieved by the present invention.

Abstract: A thermal cycling method and device is disclosed. The device comprises a sample chamber whose temperature can be rapidly and accurately modulated over a range of temperatures needed to carry out a number of biological procedures, such a the DNA polymerase chain reaction. Biological samples are placed in glass micro capillary tubes and then located inside the sample chamber. A programmable controller regulates the temperature of the sample inside the sample chamber. Once a heating cycle is completed, the controller opens a door to the chamber for venting hot air out and cool ambient air is moved in. Temperature versus time profiles corresponding to optimum denaturation, annealing and elongation temperatures for amplification of DNA are achieved by the present invention.

Abstract: Methods for identifying and locating alterations in a nucleic acid having a known sequence are provided. The methods involve measuring the melting temperature of probe nucleic acids hybridized to a target nucleic acid. The methods take advantage of the differential dissociation temperatures of a probe from a target resulting from mismatches at different locations along the region of the target to which the probe hybridizes.

Abstract: A method and device are described for analyzing a sample for the presence of an analyte wherein the analyte is contacted with a substrate to effect a measurable change selected from the group consisting of the quantity of the analyte, the quantity of the substrate, and the quantity of an optical or physical change to the substrate, wherein the analyte is contacted with the substrate for a predetermined time period, to generate a signal related to the measurable change. Scores are obtained from various tests performed on the signal data, and the scores are used to determine whether the substrate is present in the sample.