The purpose of the present invention is to provide a nucleic acid analyzer which prevents an increase in reagent consumption caused by a branched channel structure and on which multiple kinds of substrates having different channel numbers can be mounted. The nucleic acid analyzer according to the present invention is provided with a first substrate that comprises an inlet section connected to an introduction path, a first outlet section connected to a first discharge path, a second outlet section connected to a second discharge path, a first channel guiding a reagent from the inlet section to the first outlet section, a second channel guiding the reagent from the inlet section to the second outlet section, and a branching section branching, from the inlet section, into the first and second channels, wherein the first and second channels are connected to each other exclusively at the branching portion.

A fluidic device holder configured to orient a fluidic device. The device holder includes a support structure configured to receive a fluidic device. The support structure includes a base surface that faces in a direction along the Z-axis and is configured to have the fluidic device positioned thereon. The device holder also includes a plurality of reference surfaces facing in respective directions along an XY-plane. The device holder also includes an alignment assembly having an actuator and a movable locator arm that is operatively coupled to the actuator. The locator arm has an engagement end. The actuator moves the locator arm between retracted and biased positions to move the engagement end away from and toward the reference surfaces. The locator arm is configured to hold the fluidic device against the reference surfaces when the locator arm is in the biased position.

A dispensing device which has a dispensing channel extending between a supply opening and an output opening into the course of which a pump, a selection valve and a dispensing valve are connected. The selection valve is also connected to a pressurised air source. The dispensing device allows a dispensed output of a fluid, wherein a buffer channel portion is filled by the pump in a pump dispensing phase, to which buffer channel portion pressure is applied from the pressurised air source during a pressurised air dispensing phase such that a precise fluid output is subsequently possible by clocked actuation of the dispensing valve until the target fluid amount has been reached.

The present invention is related to a biochip and production method thereof. The biochip comprises a carrier, a cell or tissue culture area deposited on the carrier, and a sensor area deposited on the carrier adjacent and fluidly communicating with the cell or tissue culture area. A containing space is contained in the cell or tissue culture area comprising a simulated vascular channel, a cell or a tissue and a culture medium. At least one sensor fixation area is contained at the sensor area for placing a sensor element. The present invention can be a model for stimulating cancer of specific patient to realtimely reflecting the cancer formation, transferring status and treatment strategies. The biochip could also carry testing drugs to observe how the drugs functioning to the cells/tissue as to provide a more accurate instruction of the drugs. The present invention can perform multiple test just within on chip which can save cost and also provide a more accurate test model for the patient.

Devices and methods for characterization of analyte mixtures are provided. Some methods described herein include performing enrichment steps on a device before expelling enriched analyte fractions from the device for subsequent analysis. Also included are devices for performing these enrichment steps.

A lysis device including a sample vessel, at least one piezo element, and a controller is disclosed. The sample vessel has a microchannel formed therein. The sample vessel has at least one port extending through a surface to the microchannel. The piezo element is attached to the surface of the sample vessel. The controller has logic to cause the controller to emit a first signal including a series of frequencies to the at least one piezo element to cause the at least one piezo element to generate ultrasonic acoustic standing waves in the sample vessel, to receive a second signal indicative of measured vibration signals from the sample vessel detected by the at least one piezo element, and to determine a resonant frequency of the sample vessel using the measured vibration signals.

Techniques regarding one or more structures that can facilitate automated, multi-stage processing of one or more nanofluidic chips are provided. For example, one or more embodiments described herein can comprise a system, which can comprise a roller positioned adjacent to a microfluidic card comprising a plurality of fluid reservoirs in fluid communication with a plurality of nanofluidic chips. An arrangement of the plurality of nanofluidic chips on the microfluidic card can defines a processing sequence driven by a translocation of the roller across the microfluidic card.

The present disclosure relates to the field of molecular biology and more specifically to microarrays and methods, including methods for modifying immobilized capture primers comprising: a) contacting a substrate comprising a plurality of immobilized capture primers with a plurality of template nucleic acids under conditions sufficient for hybridization to produce one or more immobilized template nucleic acids, and b) extending one or more immobilized capture primers to produce one or more immobilized extension products complementary to the one or more template nucleic acid.

The present invention relates to methods and systems for testing for the presence of a material such as one or more analyte types within a sample and more particularly, for improved single enzyme-linked immunosorbent assay (sELISA) testing as well as other variants of single-enzyme linked molecular analysis (SELMA).

There is provided an assembly, useable to screen sample fluids for predefined molecules, the comprising, a needle unit comprising n hollow needles, wherein n is greater than one; a flow cell unit comprising m flow cells, wherein m is greater than one, each flow cell having an input and an output, and a test surface on which ligands can be provided; a first selector valve unit which is fluidly connected between the needle unit and flow cell unit, which is operable to selectively fluidly connect any one of the n hollow needles with the m flow cells in the flow cell unit; a pumping means which is selectively operable to provide negative pressure; a second selector valve unit which is fluidly connected between the pumping means and the output of each flow cell. There are further provided methods of screening sample fluids for predefined molecule.