A heater for a microfluidic test card is disclosed herein. In a general example embodiment, a test card for analyzing a fluid sample includes at least one substrate layer including a microchannel extending through at least a portion of one of the substrate layers, and a printed substrate layer that is bonded to or printed on one substrate layer of the at least one substrate layer. The printed substrate layer includes a heater printed on the printed substrate layer so as to align with at least a portion of the microchannel. The heater includes two electrodes aligned on opposite sides of the microchannel, and a plurality of heater bars electrically connecting the two electrodes. The plurality of heater bars includes a central heater bar disposed between outer heater bars.

Systems, methods, and apparatuses are provided for self-contained nucleic acid preparation, amplification, and analysis.

A method for amplifying nucleic acids by a polymerase chain reaction in a reaction volume heated using electrical energy. In at least one of the passages of the amplification cycle of the polymerase chain reaction, the ratio of the electrical energy used in the denaturation step to heat the reaction volume to the size of the reaction volume is less than 20 Joule per milliliter. Further shown is a method of amplifying nucleic acids in a reaction volume by using a device that includes a reaction vessel and a heating means with at least one heating element in contact with the reaction volume where at least one heating element is conjugated to oligonucleotides. Also shown is a device for the amplification of nucleic acids in a reaction volume including a reaction vessel for receiving the reaction volume and a heating means consisting of at least one heating element contacting the reaction volume.

Disclosed herein is an apparatus for controlling assay processes performed in a microfluidic cartridge used in sample-to-answer and point-of-care diagnostic instruments. The apparatus controls reagent dispensing into a microfluidic cartridge, magnetic bead based movement of analytes within a microfluidic cartridge, as well as nucleic acid sample preparation, amplification, and detection processes.

The present invention relates to methods for amplifying nucleic acids in micro-channels. More specifically, the present invention relates to methods for performing a real-time polymerase chain reaction (PCR) in a continuous-flow microfluidic system and to methods for monitoring real-time PCR in such systems.

The present invention relates to systems and methods for monitoring the amplification of DNA molecules and the dissociation behavior of the DNA molecules. A method according to one embodiment of the invention may include the steps of: forcing a sample of a solution containing real-time PCR reagents to move though a channel; and while the sample is moving through an analysis region of the channel, performing the steps of: (a) cycling the temperature of the sample until the occurrence of a predetermined event; (b) after performing step (a), causing the sample's temperature to gradually increase from a first temperature to a second temperature; and (c) while the step of gradually increasing the sample's temperature is performed, using an image sensor to monitor emissions from the sample.

An optical instrument monitors PCR replication of DNA in a reaction apparatus having a temperature cycled block with vials of reaction ingredients including dye that fluoresces in presence of double-stranded DNA. A beam splitter passes an excitation beam to the vials to fluoresce the dye. An emission beam from the dye is passed by the beam splitter to a CCD detector from which a processor computes DNA concentration. A reference strip with a plurality of reference emitters emit reference beams of different intensity, from which the processor selects an optimum emitter for compensating for drift. Exposure time is automatically adjusted for keeping within optimum dynamic ranges of the CCD and processor. A module of the beam splitter and associated optical filters is associated with selected dye, and is replaceable for different dyes.

Temperature-controllable reagent cartridges and systems for controlling the temperature in such reagent cartridges are provided. An example such system may include a reagent cartridge having reagent reservoirs located at least in part within an interior plenum volume of a cartridge housing. In such an example system, each reagent reservoir may be defined, in part, by a sidewall, and a first reagent reservoir may be spaced apart from a second reagent reservoir to form a fluid flow passage between corresponding sidewalls thereof. A fluid inlet through the cartridge housing may be provided that fluidically connects the interior plenum volume with a fluid supply port of a temperature control system of an analysis instrument when the reagent cartridge is received by the analysis instrument; a fluid outlet through the cartridge housing that fluidically connects the interior plenum volume with a fluid return port of the temperature control system may also be provided.

The present invention relates to methods for amplifying nucleic acids in micro-channels. More specifically, the present invention relates to methods for performing a real-time polymerase chain reaction (PCR) in a continuous-flow microfluidic system and to methods for monitoring real-time PCR in such systems.

The present invention provides, among other things, the devices and methods that can rapidly change or cycle (i.e. heat and cool) a sample temperature with high speed, less heating energy, high energy efficiency, a compact and simplified apparatus (e.g. handheld), easy and fast operation, and/or low cost.