Abstract: The present invention provides novel methods and devices that employ microfluidic technology to generate molecular melt curves. In particular, the devices and methods in accordance with the invention are useful in providing for the analysis of PCR amplification products.

Abstract: The invention provides methods of performing a sizing analysis. In the methods, a sizing ladder used in performing the sizing analysis is corrected. In one method, the sizing ladder is corrected for batch-to-batch variations in a sieving gel. In another method, the sizing ladder is corrected for a sample concentration that is different from the archival sizing ladder concentration. Methods are also provided in which the sizing ladder is corrected using a standard marker in a sample and/or using a real-time standard sizing ladder. The methods may be used individually or in combination.

Abstract: The invention provides devices, systems, and methods for extracting target objects from a sample. In the method, a stream of sample containing a plurality of target and non-target objects is directed by first and second streams of buffer through a sample inlet channel into a fluid junction and through the fluid junction into a sample waste channel. In response to detecting a target object within the stream of sample, an actuator is energized to close a normally open valve, resulting in a transient burst of cross-flow into the fluid junction that briefly diverts the flow of sample within the fluid junction and results in an aliquot of sample being directed into an aliquot delivery channel. The combination of the valve and the actuator acts as a self-limiting pulse generator.

Abstract: The invention provides devices and methods for isolating one or more sample components of a sample material following separation of the sample material into a plurality of sample components. A device includes a separation channel having a sample loading well. A low-conductivity buffer is disposed in the loading well, the buffer having a conductivity<0.2 mS/cm. In a method, a buffer is loaded into a loading well in fluid communication with a separation channel of a device. A sample material having a conductivity higher than that of the buffer is then loaded into the loading well such that the sample material is disposed beneath the buffer, the buffer disposed over and covering the sample material. The sample material is separated into a plurality of separated components in the separation channel, and a separated component is collected from a collection well disposed in a collection leg of the device.

Abstract: The invention provides a method and apparatus for isolating individual target cells. The apparatus includes a body structure comprising a main channel, a collection channel, and a waste channel fluidly coupled at a first fluid junction. A plurality of trapping channels intersect the collection channel, each trapping channel having a diameter at a location adjacent to the intersection of the trapping channel with the collection channel that is less than a diameter of an individual target cell. The apparatus also includes an imaging system configured to image individual target and non-target cells within the main channel, thereby producing imaging data; a processor configured to perform real-time, multivariate analyses of the imaging data; and a directing system configured to direct the individual target cells. A pressure source is in fluid communication with one or more of the collection channel, the waste channel, the first side channel, and the second side channel.

Abstract: Methods are provided for detecting low copy nucleic acids of interest in a sample. In one method, a sample comprising a nucleic acid of interest is aliquotted into a plurality of reaction mixtures, at least two of which are single-copy reaction mixtures. The reaction mixtures are subjected to one or more amplification reactions while flowing through a channel of a microfluidic device. At least one of the reaction mixtures is formulated in an aqueous phase of an emulsion comprising aqueous droplets suspended in an immiscible liquid. The nucleic acid of interest is present as a single copy in at least one aqueous droplet of the aqueous phase prior to performing the amplification reaction(s). Amplification is performed on the reaction mixture when it is formulated in the emulsion. The nucleic acid is continuously flowed during a plurality of steps of the method.

Abstract: Dopamine reuptake inhibitors, and their analogs, are disclosed for treating and delaying the progression of autoimmune diseases.

Abstract: The invention provides microfluidic devices, systems, and methods for manipulating an object within a channel of a microfluidic device using an external electrode. The device has a channel disposed within the device, the channel having no included electrodes. The channel has a wall, at least a portion of which is penetrable by an electric field generated external to the device, the wall being penetrable such that the electric field extends through the wall portion and into a region within the channel. The system includes the microfluidic device and an electrode external to and not bonded to the device. In the method, the external electrode is placed adjacent to the device and energized to generate an electric field that extends through the wall of the device and into the channel, thereby manipulating an object within the channel.

Abstract: Methods are provided for detecting low copy nucleic acids of interest in a sample. In one method, a sample comprising a nucleic acid of interest is aliquotted into a plurality of reaction mixtures, at least two of which are single-copy reaction mixtures. The reaction mixtures are subjected to one or more amplification reactions while flowing through a channel of a microfluidic device. At least one of the reaction mixtures is formulated in an aqueous phase of an emulsion comprising aqueous droplets suspended in an immiscible liquid. The nucleic acid of interest is present as a single copy in at least one aqueous droplet of the aqueous phase prior to performing the amplification reaction(s). Amplification is performed on the reaction mixture when it is formulated in the emulsion. The nucleic acid is continuously flowed during a plurality of steps of the method.

Abstract: Dopamine reuptake inhibitors, and their analogs, are disclosed for treating and delaying the progression of autoimmune diseases.

Abstract: Techniques and systems for displaying chromatographic data using a graphical user interface are provided. Chromatographic separation data that represent multiple series of measurements for multiple samples can be displayed on a display device of a computer system as a series of bands, the bands being arranged to resemble output from an electrophoresis gel. The bands may be aligned using a marker included in each sample.

Abstract: The present invention is an automated microfluidic chip processing apparatus that includes a deck for holding at least one microfluidic chip and capable of being accessed by a liquid handling system, a fluid control system, and a detection system, wherein a chip handling device transports the chip from the deck to the fluid control system and the detection system. The present invention also includes a chip for use with an automated microfluidic chip processing apparatus, and a method for processing a microfluidic chip using such an apparatus.

Abstract: A mixture of components is flowed through a binding channel region comprising a component-binding moiety, thereby binding at least a portion of a component of interest. The mixture is then flowed through a separation channel region that includes a buffer comprising a detergent, resulting in separated components. Diluent is mixed with the separated components, diluting the detergent, and the separated components are detected. The component of interest is released from the component-binding moiety and flowed through the separation channel region. Diluent is mixed with the released component of interest, diluting the detergent, and the released component of interest is detected.

Abstract: The invention provides fluidic devices having incorporated electrodes. One device comprises a card and first and second caddy segments. The first caddy segment comprises first and second electrodes. The second caddy segment comprises first and second reservoirs disposed on a first surface of the second segment, a channel disposed on a second surface of the second segment, and first and second vias extending between the first and second surfaces. The first caddy segment is attached to the first surface of the second caddy segment. The card is attached to the second surface of the second caddy segment such that the card provides a closed surface for the device.

Abstract: The present invention is an automated microfluidic chip processing apparatus that includes a deck for holding at least one microfluidic chip and capable of being accessed by a liquid handling system, a fluid control system, and a detection system, wherein a chip handling device transports the chip from the deck to the fluid control system and the detection system. The present invention also includes a chip for use with an automated microfluidic chip processing apparatus, and a method for processing a microfluidic chip using such an apparatus.

Abstract: A method of modifying the concentration of reactants and carrying out a chemical reaction on a microfluidic device in which first and second reactants are delivered into a reaction channel combined, the second reactant different from the first reactant and capable of reacting with the first reactant. The first reactant is subjected to a stacking process, thereby producing a first stacked reactant. The second reactant is subjected to the stacking process, thereby producing a second stacked reactant. The first stacked reactant is exposed to the second stacked reactant so that the first stacked reactant and the second stacked reactant undergo a chemical reaction.

Abstract: The invention provides systems and methods for processing samples. In a method, a reaction card is provided that has a channel network, a valve, and a micropump, all disposed within the card. The reaction card also has a collection well disposed on a surface of the card and a tubular member extending out from the card. A reaction vessel is provided and affixed to the reaction card such that the tubular member is inserted into the reaction vessel. Amplification reaction reagents and a sample are delivered into the reaction vessel, and an amplification reaction is initiated within the reaction vessel, resulting in an amplification product being disposed within the reaction vessel. The valve is opened to atmosphere, and the first micropump is activated to pump an aliquot of reaction product from the reaction vessel into the tubular member, through the channel network, and into the collection well.

Abstract: The invention provides fluidic devices having incorporated electrodes. One device comprises a card and a caddy. The card includes a channel disposed within the card, first and second vias in fluid communication with the channel through an upper surface of the card, and first and second electrodes disposed on the upper surface of the card. The first via and first electrode are positioned adjacent to a first end of the channel, and the second via and second electrode are positioned adjacent to a second end of the channel. The caddy comprises first and second reservoirs. The caddy is attached to the card such that the first reservoir is positioned over the first via and a portion of the first electrode, and the second reservoir is positioned over the second via and a portion of the second electrode. A portion of each of the electrodes is accessible for dry electrical contact.

Abstract: Techniques and systems for displaying chromatographic data using a graphical user interface are provided. Chromatographic separation data that represent multiple series of measurements for multiple samples can be displayed on a display device of a computer system as a series of bands, the bands being arranged to resemble output from an electrophoresis gel. The bands may be aligned using a marker included in each sample.

Abstract: An integrated microtomography and optical imaging system includes a rotating table that supports an imaging object, an optical stage, and separate optical and microtomography imaging systems. The table rotates the imaging object about a vertical axis running therethrough to a plurality of different rotational positions during a combined microtomography and optical imaging process. The optical stage can be a trans-illumination, epi-illumination or bioluminescent stage. The optical imaging system includes a camera positioned vertically above the imaging object. The microtomography system includes an x-ray source positioned horizontally with respect to the imaging object. Optical and x-ray images are both obtained while the imaging object remains in place on the rotating table. The stage and table are included within an imaging chamber, and all components are included within a portable cabinet.