Abstract: A microfluidic device (1) comprising a hydrophilic microchannel structure (2) in which there is a functional unit that comprises a microconduit I (17) in which there is an inlet end (16), an outlet end (18), and a capillary stop function I (24) in the form of a local non-wettable surface area (44). The capillary stop function (24) defines a segment of microconduit I (17). Microconduit I (17) is within at least a part of this segment (46) divided into two or more microchannels (42). A part of the non-wettable surface area (44a,b) is associated with an inner wall of each of the microchannels (42).

Abstract: The invention is a method for determining in the amount of an analyte (An) in a sample. The method comprises competitive immunoassays and enzymatic assays in which a soluble product (immune complex and enzymatic product, respectively) is formed. The product is subsequently measured in a measuring zone of a microchannel structure of a microfluidic device.

Abstract: A centrifugal-based microfluidic device (1) that comprises a hydrophilic microchannel structure (2) in which there is a A) a separation microcavity I (4) that comprises i) a liquid inlet I (5), and ii) a liquid outlet I (6) that is at a level below the level of liquid inlet I (5) and above the level of the bottom (8) of the microcavity (4) thereby defining a lower part (4b) and an upper part (4a) of the microcavity (4), and B) a microconduit I (17) that has an inlet end I (16) directly connected to liquid outlet I (6), and an outlet end I (18) that is at a lower level than inlet end I (6). A capillary valve I (24) is associated with microconduit I (17). The flow direction through liquid outlet I (6) is directed upwards and/or liquid outlet I (6) is placed in a downwardly turned part of an inner wall of the separation microcavity (4), and/or the part of microconduit I (17) next to liquid outlet I (6) is directed upwards.

Abstract: The invention relates to a method for capturing charged molecules of interest traveling in an electrolyte flow stream through an electrically non-conductive channel, comprising at least one anode and at least one cathode individually separated from said channel, but in electrical contact with said flow stream, by a conductive ion selective semi-permeable membrane. Said membrane interferes with the normal migration of ions towards its respective electrode, generating at least two zones of different electric field. Balance between hydrodynamic and electrical forces captures certain ions into the flow stream. it also relates to a device for performing the method.

Abstract: The present invention includes a method of mixing at least two aliquots in a microchannel structure (140) provided on a rotatable substrate (130) having a rotating centre, comprising the actions of: providing a volume of X of aliquot I into a first inlet microchannel (102), providing a volume of Y of aliquot II into a second inlet microchannel (101), rotating said substrate (130) in order to overcome a first microfluidic valve (104) and to move said aliquots I and II from said first and second inlet microchannels (102, 101) into said mixing chamber (106), where said mixing chamber (106) has a volume larger than X+Y, and shaking said aliquots I and II together with a gas bubble in said mixing chamber (106).

Abstract: A rotatable microfluidic device that comprises a hydrophilic microchannel structure in which there is a) an upstream microcavity I with a liquid outlet I, b) a microconduit I connected to liquid outlet I, and c) a capillary valve I associated with microconduit I. The inlet end of the microconduit is closer to the spin axis than the outlet end of the microconduit. The difference in radial distance between the inlet end and the outlet end of microconduit I is typically ?5%, such as ?10% or ?100% or ?500%, of the difference in radial distance between the uppermost part of the upstream microcavity and liquid outlet I.

Abstract: A centrifugal based microfluidic device that comprises a microchannel structure in which there is a detection microcavity which in the upstream direction is attached to an inlet microconduit for transport of liquid (transport microconduit) to the detection microcavity and which is used for detecting the result of a reaction taking place in the detection microcavity or in a reaction microcavity positioned upstream of the detection microcavity. The detection microcavity comprises a detection microconduit having an inlet part and an outlet part and therebetween an upward or a downward meander.

Abstract: A flow path comprising a reaction cavity in which there is a solid phase to which an affinity reactant I1 has been immobilized by the use of an immobilizing pair of reactive structures that comprises a) a plurality of functional equal structures RSsp on the solid phase, and b) a structure RSari on affinity reactant I1, where RSsp and RSari are mutually reactive with each other to the formation of a link structure that immobilizes affinity reactant I1 to the solid phase. The characteristic feature is that the solid phase comprises a plurality of structures that derive from RSsp but do not immobilize affinity reactant I1 to the solid phase.

Abstract: A microfluidic device comprising a hydrophilic microchannel structure in which there is a functional unit that comprises a microconduit which a) is intended for the transportation of liquid aliquots, and b) has an inlet end and an outlet end between which there is a capillary valve I. Microconduit I comprises an upwardly directed section that extends over a part of or over the full length of microconduit I. Capillary valve I is preferably placed in this section.

Abstract: A microfluidic device (1) comprising a hydrophilic microchannel structure (2) in which there is a functional unit that comprises a microconduit I (17) in which there is an inlet end (16), an outlet end (18), and a capillary stop function I (24) in the form of a local non-wettable surface area (44). The capillary stop function (24) defines a segment of microconduit I (17). Microconduit I (17) is within at least a part of this segment (46) divided into two or more microchannels (42). A part of the non-wettable surface area (44a,b) is associated with an inner wall of each of the microchannels (42).

Abstract: A centrifugal-based microfluidic device (1) that comprises a hydrophilic microchannel structure (2) in which there is a A) a separation microcavity I (4) that comprises i) a liquid inlet I (5), and ii) a liquid outlet I (6) that is at a level below the level of liquid inlet I (5) and above the level of the bottom (8) of the microcavity (4) thereby defining a lower part (4b) and an upper part (4a) of the microcavity (4), and B) a microconduit I (17) that has an inlet end I (16) directly connected to liquid outlet I (6), and an outlet end I (18) that is at a lower level than inlet end I (6). A capillary valve I (24) is associated with microconduit I (17). The flow direction through liquid outlet I (6) is directed upwards and/or liquid outlet I (6) is placed in a downwardly turned part of an inner wall of the separation microcavity (4), and/or the part of microconduit I (17) next to liquid outlet I (6) is directed upwards.

Abstract: A microfluidic device comprising a hydrophilic microchannel structure in which there is a functional unit that comprises a microconduit which a) is intended for the transportation of liquid aliquots, and b) has an inlet end and an outlet end between which there is a capillary valve I, which preferably is based on the presence of a local non-wettable surface area. Microconduit I further comprises one or more additional capillary valves, typically one. At least one of the additional valves is upstream of capillary valve I, such as at the inlet end of the microconduit.

Abstract: The present invention relates to microfluidic systems using rotating microfluidic disc platforms comprising microchannel structures. More specifically, the present invention relates to a method and an arrangement for controlling magnetic particles in microchannel structures of a microfluidic device. The invention is based on the counterbalancing of the magnetic force and the centrifugal force on the beads when rotating the microchannel structures at different speeds close to an array of magnets.

Abstract: The invention is a method for determining in the amount of an analyte (An) in a sample. The method comprises competitive immunoassays and enzymatic assays in which a soluble product (immune complex and enzymatic product, respectively) is formed. The product is subsequently measured in a measuring zone of a microchannel structure of a microfluidic device.

Abstract: A flow through dispenser for the drop-wise dispensation of liquid which arrangement comprises: a housing (104) comprising: (i) a flow through microconduit (105) with an upstream end (106) and a downstream end (outlet) (107); and (ii) a dispenser orifice (108) between these two ends, and an inlet tube (110) which is attached to the upstream end (106) and provides an inlet (111) that can be connected to a liquid storage (112) for liquid (113) that is to be transported in flow through microconduit (105) and inlet tube (110) and/or dispensed through the orifice (108). The inner volume between the inlet and the downstream end is is ?10 ?l. An instrument set-up for drop-wise dispensation of liquid to target areas of a microdevice.

Abstract: The invention relates to a method for capturing charged molecules of interest traveling in an electrolyte flow stream through an electrically non-conductive channel, comprising at least one anode and at least one cathode individually separated from said channel, but in electrical contact with said flow stream, by a conductive ion selective semi-permeable membrane. Said membrane interferes with the normal migration of ions towards its respective electrode, generating at least two zones of different electric field. Balance between hydrodynamic and electrical forces captures certain ions into the flow stream. it also relates to a device for performing the method.

Abstract: A method for dispensing droplets of a liquid to a microsystem in the form of a disc comprising a target area (TA0I) in its surface, said disc preferably being a microfluidic disc comprising a microchannel structure with an inlet port that is a target area (TA0I).

Abstract: The present invention relates to an improved substrate for use in detection of fluorescence. More specifically the improved substrate exhibits a supported surface layer of silicon dioxide on a silicon support material, on another solid support material, or on a silicon layer supported on another solid support material. The inventive substrate allows for a significantly higher sensitivity to be obtained when used in fluorescence analysis. The invention also relates to a method of preparing the inventive substrate, which substrate in one embodiment of the invention takes the form of silicon a slide exhibiting an oxidized surface. The invention also relates to the application of the inventive substrate in microarray analysis.