Abstract: The invention provides a passive fluidics circuit for directing different fluids to a common volume, such as a reaction chamber or flow cell, without intermixing or cross contamination. The direction and rate of flow through junctions, nodes and passages of the fluidics circuit are controlled by the states of upstream valves (e.g. opened or closed), differential fluid pressures at circuit inlets or upstream reservoirs, flow path resistances, and the like. Free diffusion or leakage of fluids from unselected inlets into the common outlet or other inlets at junctions or nodes is prevented by the flow of the selected inlet fluid, a portion of which sweeps by the inlets of unselected fluids and exits the fluidics circuit by waste ports, thereby creating a barrier against undesired intermixing with the outlet flow through leakage or diffusion.

Abstract: A sequencing system includes an automated sequencing instrument adapted to determine variant calls for one or more extracted polynucleotide samples with a performance of at least 98.5% raw read accuracy and a run time in a range of 5 hours to 14 hours to determine variant calls for 4 extracted polynucleotide samples using a targeted assay with one DNA pool per sample and an average amplicon size in a range of 100 to 120 bases.

Abstract: A fluidic coupler to engage a plurality of flow cells of a sensor device includes a body and a plurality of fluidics interfaces formed in the body. Each fluidic interface of the plurality of fluidics interfaces includes an opening, a first port in fluid communication with the opening, a second port, and a third port in fluidic communication with the second port.

Abstract: An apparatus includes a reaction vessels coupled to an electronic sensor for monitoring a reaction product in the reaction vessel; a fluidics system for sequentially delivering a plurality of reagents to the reaction vessel, the fluidics system including a plurality of reagent reservoirs in fluidic communication via a plurality of flow paths with a fluidics circuit and to a common passage in fluidic communication between the fluidics circuit and the reaction vessel, a solution reservoir in fluidic communication with the common passage via a branch passage connected with the common passage at a junction between the fluidics circuit and the reaction vessel; and an electrode in contact with a solution within the branch passage, the electrode being in electrical communication with the reaction vessel through fluid extending from the branch passage and through the common passage, the electronic sensor generating an output signal depending on a voltage of the electrode.

Abstract: An apparatus includes a fluidic coupler including an opening. A first port is in fluid communication with the opening and is to interface with an inlet of a flow cell of a sensor device. A second port is to interface with an outlet of the flow cell of the sensor device. A third port is in fluidic communication with the second port. The apparatus further includes a mechanical assembly moveable between a first position and a second position. The fluidic coupler is secured to the flow cell of the sensor device in the first position. The fluidic coupler is disengaged from the flow cell of the sensor device in the second position.

Abstract: The invention is directed to apparatus and methods for delivering multiple reagents to, and monitoring, a plurality of analytical reactions carried out on a large-scale array of electronic sensors under minimal noise conditions. In one aspect, the invention provides method of improving signal-to-noise ratios of output signals from the electronic sensors sensing analytes or reaction byproducts by subtracting an average of output signals measured from neighboring sensors where analyte or reaction byproducts are absent. In other aspects, the invention provides an array of electronic sensors integrated with a microwell array for confining analytes and/or particles for analytical reactions and a method for identifying microwells containing analytes and/or particles by passing a sensor-active reagent over the array and correlating sensor response times to the presence or absence of analytes or particles.

Abstract: The present invention provides novel microfluidic substrates and methods that are useful for performing biological, chemical and diagnostic assays. The substrates can include a plurality of electrically addressable, channel bearing fluidic modules integrally arranged such that a continuous channel is provided for flow of immiscible fluids.

Abstract: A sequencing system includes an automated sequencing instrument adapted to determine variant calls for one or more extracted polynucleotide samples with a performance of at least 98.5% raw read accuracy and a total instrument run time in a range of 16 hours to 22 hours to determine variant calls when sequencing 6 cfTNA extracted polynucleotide samples using a targeted assay with one nucleic acid pool per sample.

Abstract: In an example, a method for preparing a nucleotide solution includes flowing an aqueous solution from an initial solution storage of a sequencing instrument continuously through a container fluidically coupled to the sequencing instrument, the container comprising a nucleotide concentrate; and collecting the aqueous solution with nucleotide in a storage container.

Abstract: The invention provides a passive fluidics circuit for directing different fluids to a common volume, such as a reaction chamber or flow cell, without intermixing or cross contamination. The direction and rate of flow through junctions, nodes and passages of the fluidics circuit are controlled by the states of upstream valves (e.g. opened or closed), differential fluid pressures at circuit inlets or upstream reservoirs, flow path resistances, and the like. Free diffusion or leakage of fluids from unselected inlets into the common outlet or other inlets at junctions or nodes is prevented by the flow of the selected inlet fluid, a portion of which sweeps by the inlets of unselected fluids and exits the fluidics circuit by waste ports, thereby creating a barrier against undesired intermixing with the outlet flow through leakage or diffusion.

Abstract: An apparatus comprising a chemical field effect transistor array in a circuit-supporting substrate is disclosed. The transistor array has disposed on its surface an array of sample-retaining regions capable of retaining a chemical or biological sample from a sample fluid. The transistor array has a pitch of 10 ?m or less and a sample-retaining region is positioned on at least one chemical field effect transistor which is configured to generate at least one output signal related to a characteristic of a chemical or biological sample in such sample-retaining region.

Abstract: In an example, a method for preparing a nucleotide solution includes flowing an aqueous solution from an initial solution storage of a sequencing instrument continuously through a container fluidically coupled to the sequencing instrument, the container comprising a nucleotide concentrate; and collecting the aqueous solution with nucleotide in a storage container.

Abstract: The invention provides a passive fluidics circuit for directing different fluids to a common volume, such as a reaction chamber or flow cell, without intermixing or cross contamination. The direction and rate of flow through junctions, nodes and passages of the fluidics circuit are controlled by the states of upstream valves (e.g. opened or closed), differential fluid pressures at circuit inlets or upstream reservoirs, flow path resistances, and the like. Free diffusion or leakage of fluids from unselected inlets into the common outlet or other inlets at junctions or nodes is prevented by the flow of the selected inlet fluid, a portion of which sweeps by the inlets of unselected fluids and exits the fluidics circuit by waste ports, thereby creating a barrier against undesired intermixing with the outlet flow through leakage or diffusion.

Abstract: An apparatus includes a fluidic coupler including an opening. A first port is in fluid communication with the opening and is to interface with an inlet of a flow cell of a sensor device. A second port is to interface with an outlet of the flow cell of the sensor device. A third port is in fluidic communication with the second port. The apparatus further includes a mechanical assembly moveable between a first position and a second position. The fluidic coupler is secured to the flow cell of the sensor device in the first position. The fluidic coupler is disengaged from the flow cell of the sensor device in the second position.

Abstract: A sequencing system includes an automated sequencing instrument adapted to determine variant calls for one or more extracted polynucleotide samples with a performance of at least 98.5% raw read accuracy and a run time in a range of 5 hours to 14 hours to determine variant calls for 4 extracted polynucleotide samples using a targeted assay with one DNA pool per sample and an average amplicon size in a range of 100 to 120 bases.

Abstract: The present invention provides novel microfluidic substrates and methods that are useful for performing biological, chemical and diagnostic assays. The substrates can include a plurality of electrically addressable, channel bearing fluidic modules integrally arranged such that a continuous channel is provided for flow of immiscible fluids.

Abstract: The present invention provides novel microfluidic substrates and methods that are useful for performing biological, chemical and diagnostic assays. The substrates can include a plurality of electrically addressable, channel bearing fluidic modules integrally arranged such that a continuous channel is provided for flow of immiscible fluids.