An evacuated container assembly suitable for use in connection with blood collection including: (a) a container member formed of a first polymeric material and having a sidewall and one or more openings; (b) a nanocomposite barrier coating disposed on the container member having a thickness of up to about 30 microns and being derived from an aqueous dispersion including (i) a dispersed barrier matrix polymer; and (ii) a substantially exfoliated silicate filler having an aspect ratio of more than 50; and (c) one or more sealing members disposed in the opening(s) operative to hermetically seal the cavity; wherein the cavity is evacuated and maintains a pressure below atmospheric pressure and exhibits a draw volume loss lower than that of a like assembly without a nanocomposite barrier film by a factor of at least 1.5.

A disposable cartridge used in a digital microfluidics system has a bottom layer with first hydrophobic surface, a rigid cover plate with second hydrophobic surface, and a gap there-between. The bottom layer is a flexible film on an uppermost surface of a cartridge accommodation site of a system, attracted to and spread over the uppermost surface by an underpressure. A lower surface of the plate and the flexible bottom layer are sealed to each other. The assembled cartridge is removed from the cartridge accommodation site in one piece and potentially includes samples and processing fluids. The system has a base unit and a cartridge accommodation site with an electrode array of individual electrodes and a central control unit for controlling selection of individual electrodes and for providing these electrodes with individual voltage pulses for manipulating liquid droplets within the gap by electrowetting.

The present disclosure relates to a fluid analysis device which comprises a sensing device for analyzing a fluid sample, the sensing device comprising a micro-fluidic component for propagating the fluid sample and a microchip configured for sensing the fluid sample in the micro-fluidic component; a sealed fluid compartment containing a further fluid, the compartment being fluid-tight connected to the sensing device and adapted for providing the further fluid to the micro-fluidic component when the sealed fluid compartment is opened; and an inlet for providing the fluid sample to the micro-fluidic component. Further, the present disclosure relates to a method for sensing a fluid sample using the fluid analysis device.

Since a few kilovolts of an application voltage is necessary to take in a biological sample, an EWOD electrode, for example, is destroyed, and the electrode becomes non-reusable for moving a droplet. Therefore, an object of the present invention is to provide a biochemical cartridge usable for multiple times for taking in a biological sample by a capillary array, for example, and a biochemical analysis device using the biochemical cartridge. In order to solve the problem, the biochemical cartridge according to the present invention includes a passage through which a sample is transported, a plurality of electrodes disposed on the passage along a direction in which a sample is transported, the plurality of electrodes being provided to transport a sample, and an opening provided opposite to the plurality of electrodes disposed on a downstream side of the passage.

Analyte collection and testing systems and methods, and more particularly to testing systems and methods that achieve significant improvements in the detection of fluorescence signals in the reader by modulating the applied optical excitation. Also described herein are optical detection apparatuses and methods for removable photonic chips that do not require translation for calibration when coupling the photonics chip with the sensing system. Also described herein are methods and apparatuses for accurately calibrating a dilution factor when reading from a photonics chip.

Provided herein are methods for the assembly of a polynucleic acid sequence that is at least partially carried out on a microfluidic device; methods for the preparation of a library of polynucleic acid sequences; microfluidic devices; methods for designing nucleic acid sequences; methods for planning the assembly of a polynucleic acid sequence from a plurality of nucleic acid sequences; systems comprising components for carrying out these methods; computer programs which, when run on a computer, implements these methods; and computer readable medium or carrier signals encoding such a computer program.

A sample handling device includes a reservoir for holding a fluid medium. A channel system used in connection with the reservoir includes a dilution portion for a sample to be analyzed with a measurement device. The sample is arranged to be transferred from the dilution portion to the measurement device by the fluid medium. A set of capillary channels in the dilution portion is arranged to be filled by capillary action to collect an established quantity of the sample to be diluted by the fluid medium. A pump transfers the fluid medium from the reservoir to the channel system. The pump includes at least one plunger, a seal separating the reservoir and the channel system and a delivery system of potential energy including a compressible element configured to provide repeatable transfer of the fluid medium from the reservoir to the channel system.

The present invention relates to a buffy coat extraction kit including: a kit body having a cylindrical plasma part that has an internal volume for forming a plasma layer, a cylindrical buffy coat part which extends in the longitudinal direction while communicating with the lower part of the plasma part and has a diameter smaller than the diameter of the plasma part and an internal volume for forming a buffy coat layer, and a cylindrical erythrocyte part which extends in the longitudinal direction while communicating with the lower part of the buffy coat part and has a diameter larger than the diameter of the buffy coat part and an internal volume for forming an erythrocyte layer, wherein the free end part of the plasma part and the free end part of the erythrocyte part are respectively opened; a lower packing movably accommodated in the erythrocyte part while maintaining an air-tight state; and a pusher moving the lower packing.

Apparatus (2) for testing a liquid specimen, which apparatus (2) comprises: (i) a container (4) for the liquid specimen; (ii) a lid (6) for closing the container (4) after the liquid specimen has been provided in the container (4); (iii) first securing means (8) by which the lid (6) is secured to the container (4); (iv) a test capsule (10) for securing to the lid (6) when the lid (6) is on the container (4); (v) second securing means (12) by which the test capsule (10) is secured to the lid (6); and (vi) a response chart (14) which is operable in response to contact with the liquid specimen, and the apparatus (2) being such that: (vii) the lid has an openable portion (18) which when opened permits a liquid specimen in the container (4) to enter the test capsule (10); (viii) the test capsule (10) has opener means (20) for opening the openable portion on the lid (6) when the test capsule (10) is secured to the lid (6); and (ix) the response chart (14) is inside the test capsule (10) and is contacted by the liquid specimen when the liquid specimen enters the test capsule (10).

Biological sample collection kits are devised with physical features to enable a high performance collection system which delivers preprocessed biological matter via conventional shipping means to a testing laboratories. In particular, untrained and unskilled users deposit biological matter such as saliva or blood into a receiving vessel. By sealing the container, the user causes release of a premixed solution containing preservatives and optionally lysis reagents. In addition, a purification agent is arranged to bind to target molecules and facilitate their removal from solution. These time consuming processes occur while the sample is in transit to the testing facility such that when it arrives, it is in a preconditioned state immediately ready for execution of washing steps. Thus, the high performance containers taught herein are useful for collection biological samples and performing initial process steps on received matter—steps which are largely effected during the shipping stage of the transfer process.