Abstract: A multilayer microfluidic device comprising: an inlet section comprising an inlet port and configured to transport and access the sample to a flat, laterally extending filtration membrane; a metering section, comprising an extraction chamber configured to receive an extracted body fluid from the filtration membrane and arranged in fluid communication with a metering channel; and an outlet section comprising a capillary means for collection of the metered volume of body fluid, wherein a roof of the extraction chamber is defined by a flat lower surface of the filtration membrane, and a floor of the extraction chamber is continuous with a floor of the metering channel and extends at an acute angle from the lower surface of the filtration membrane, and wherein the floor of the extraction chamber is inclined with respect to the floor of the metering channel to create a slope.

Abstract: Disclosed herein is a microfluidic device and a method for transporting and sampling a defined volume of plasma, providing a fluid passageway from an inlet to an outlet comprising a first region with the inlet with a first high flow resistance configured to receive and collect a whole blood sample and to separate plasma; and a second region with the outlet lower flow resistance. The second region is in fluid connection with the first region and configured to meter the separated plasma by comprising a metering channel.

Abstract: A microfluidic device is configured to sample, meter and collect a metered volume of body fluid for analysis by means of capillary transport. The device comprises: an inlet section, for receiving the body fluid sample, the inlet section comprising an inlet port; a metering section configured to receive body fluid from the inlet section and comprising a metering channel, wherein the metering section is arranged to separate a metered volume of body fluid filled in the metering channel; and an outlet section comprising a cavity between an outlet part of the metering channel and an outlet orifice of the device, a hydrophilic porous bridge element conformable to a shape of the cavity and inserted in the cavity to substantially fill the cavity and the outlet orifice, and a capillary means attached to the outlet section in contact with the hydrophilic porous bridge element.

Abstract: A microfluidic device is configured to sample, meter and collect a metered volume of body fluid for analysis by means of capillary transport. The device comprises: an inlet section, for receiving the body fluid sample, the inlet section comprising an inlet port; a metering section configured to receive body fluid from the inlet section and comprising a metering channel, wherein the metering section is arranged to separate a metered volume of body fluid filled in the metering channel; and an outlet section comprising a cavity between an outlet part of the metering channel and an outlet orifice of the device, a hydrophilic porous bridge element conformable to a shape of the cavity and inserted in the cavity to substantially fill the cavity and the outlet orifice, and a capillary means attached to the outlet section in contact with the hydrophilic porous bridge element.

Abstract: A method of manufacturing an outlet section of a microfluidic device configured to sample, meter and collect a metered volume of body fluid for analysis by means of capillary transport; the method comprising: providing a microfluidic device having an outlet section in fluid communication with a metering section comprising a metering channel configured to receive body fluid from an inlet section with an inlet port, wherein the outlet section comprises a cavity between an outlet part of the metering channel and an outlet orifice of the device; providing a hydrophilic porous bridge element arranged to conform to the shape of the cavity; inserting the bridge element into the cavity, such that the bridge element substantially fills the cavity and the outlet orifice; and attaching a capillary means to the outlet section, thereby establishing contact between the capillary means and the bridge element.

Abstract: A microfluidic device configured to sample, meter and collect a metered volume of body fluid for analysis by means of capillary transport, wherein the device comprises: an inlet section for receiving a sample of body fluid, the inlet section comprising an inlet port and a channel system; a filtration membrane configured to separate plasma from blood, wherein the inlet section and the channel system are configured to transport the sample of body fluid to, and to distribute it across the filtration membrane with a stepwise or gradually increasing capillarity from the inlet section to the filtration membrane; a metering function, configured to meter a predefined volume of the received body fluid; and at least one porous medium for receiving the transported sample of body fluid.

Abstract: A microfluidic device comprising: an inlet section, for receiving a body fluid sample, the inlet section comprising an inlet port arranged to receive a supply of body fluid; a metering function configured to receive body fluid from the inlet section and comprising a first channel; and a sequent section configured to receive the body fluid from the metering function and comprising a second channel, wherein the first channel comprises a capillary stop valve configured to interrupt or reduce flow of the body fluid therethrough, and a means for visual inspection arranged adjacent to the capillary stop valve, wherein a geometry and/or dimension of the inlet port is configured such that when the supply of body fluid to the inlet port is removed, the Laplace pressure of a body fluid meniscus at the inlet port is higher than a threshold pressure of the capillary stop valve.

Abstract: A microfluidic device comprising: an inlet section, for receiving a body fluid sample, the inlet section comprising an inlet port arranged to receive a supply of body fluid; a metering function configured to receive body fluid from the inlet section and comprising a first channel; and a sequent section configured to receive the body fluid from the metering function and comprising a second channel, wherein the first channel comprises a capillary stop valve configured to interrupt or reduce flow of the body fluid therethrough, and a means for visual inspection arranged adjacent to the capillary stop valve, wherein a geometry and/or dimension of the inlet port is configured such that when the supply of body fluid to the inlet port is removed, the Laplace pressure of a body fluid meniscus at the inlet port is higher than a threshold pressure of the capillary stop valve.

Abstract: A microfluidic device configured to sample, meter and collect a metered volume of body fluid for analysis by means of capillary transport, wherein the device comprises: an inlet section for receiving a sample of body fluid, the inlet section comprising an inlet port and a channel system; a filtration membrane configured to separate plasma from blood, wherein the inlet section and the channel system are configured to transport the sample of body fluid to, and to distribute it across the filtration membrane with a stepwise or gradually increasing capillarity from the inlet section to the filtration membrane; a metering function, configured to meter a predefined volume of the received body fluid; and at least one porous medium for receiving the transported sample of body fluid.

Abstract: A multilayer microfluidic device comprising: an inlet section comprising an inlet port and configured to transport and access the sample to a flat, laterally extending filtration membrane; a metering section, comprising an extraction chamber configured to receive an extracted body fluid from the filtration membrane and arranged in fluid communication with a metering channel; and an outlet section comprising a capillary means for collection of the metered volume of body fluid, wherein a roof of the extraction chamber is defined by a flat lower surface of the filtration membrane, and a floor of the extraction chamber is continuous with a floor of the metering channel and extends at an acute angle from the lower surface of the filtration membrane, and wherein the floor of the extraction chamber is inclined with respect to the floor of the metering channel to create a slope.

Abstract: A microfluidic device configured to sample, meter and collect a metered volume of body fluid for analysis by means of capillary transport, comprises: an inlet section, for receiving a sample of body fluid, the inlet section comprising an inlet port; a metering section configured to receive body fluid from the inlet section and comprising a metering channel, wherein the metering section is arranged to separate a metered volume of body fluid filled in the metering channel; and an outlet section configured to receive and transport the separated metered volume of body fluid for collection in a capillary means having a predetermined surface geometry. The metering channel has an outlet part with a dimensional change configured to cause a fluid front meniscus of the separated metered volume of body fluid, when transported to the outlet section, to assume a shape which substantially conforms to the surface geometry of the capillary means.

Abstract: A method of manufacturing an outlet section of a microfluidic device configured to sample, meter and collect a metered volume of body fluid for analysis by means of capillary transport; the method comprising: providing a microfluidic device having an outlet section in fluid communication with a metering section comprising a metering channel configured to receive body fluid from an inlet section with an inlet port, wherein the outlet section comprises a cavity between an outlet part of the metering channel and an outlet orifice of the device; providing a hydrophilic porous bridge element arranged to conform to the shape of the cavity; inserting the bridge element into the cavity, such that the bridge element substantially fills the cavity and the outlet orifice; and attaching a capillary means to the outlet section, thereby establishing contact between the capillary means and the bridge element.

Abstract: Disclosed herein is a microfluidic device and a method for transporting and sampling a defined volume of plasma, providing a fluid passageway from an inlet to an outlet comprising a first region with the inlet with a first high flow resistance configured to receive and collect a whole blood sample and to separate plasma; and a second region with the outlet lower flow resistance. The second region is in fluid connection with the first region and configured to meter the separated plasma by comprising a metering channel.

Abstract: A device for detecting resistant bacteria includes a microfluidic chip, a detector and an analyzer. The microfluidic chip includes fluidic structures having a fluid inlet and an interaction chamber fluidically connected to the fluid inlet, and a labeled substrate that is immobilized inside the interaction chamber and enters into a verifiable interaction with bacterial factors of bacteria, so that by introducing a culture medium containing an active substance to be analyzed and the bacteria into the interaction chamber and by detecting the result of the verifiable interaction, it can be ascertained whether the bacteria are resistant to the active substance to be analyzed. The detector detects information that is a measure of whether or not the verifiable interaction has taken place. On the basis of the detected information, the analyzer outputs a display regarding the resistance of the bacteria to the active substance to be analyzed.

Abstract: What is shown is a measuring device for simultaneously analyzing melting curves of DNA samples in DNA microarrays with the aid of a fluorescence detector array. Embodiments show monitoring of melting curves of DNA microarrays (dynamic fluorescence measurement) by means of silicon photomultipliers (SiPM) or other photodetectors such as, e.g., PIN diodes (positive intrinsic negative diodes), avalanche photodiodes (APD), or photomultiplier tubes (PMT). The DNA microarray is applied, along with a thin-film heating element, to a substrate made of plastic or glass or is integrated in a microfluidic channel.