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: An aspect of the present invention includes a microfluidic assembly comprising: a planar substrate, a least a first surface of which has at least one open microchannel structure, a lid forming sheet material attached with a first surface to said first surface of said planar substrate, said lid forming sheet material is covering at least a portion of said at least one microchannel structure, wherein said lid forming sheet material has a first region with a first rigidity and a second region with a second rigidity. Other aspects of the present invention are reflected in the detailed description, figures and claims.

Abstract: An aspect of the present invention includes a microfluidic assembly comprising: a planar substrate, a least a first surface of which has at least one open microchannel structure, a lid-forming sheet material attached with a first surface to said first surface of said planar substrate, said lid-forming sheet material is covering at least a portion of said at least one microchannel structure, wherein said lid-forming sheet material is attached to said planar substrate with a bonding material comprising particles to control the spacing between said substrate and said lid-forming sheet material. Other aspects of the present invention are reflected in the detailed description, figures and claims.

Abstract: The present invention relates to a method for determining the identity of a microfluidic device and a home position by means of a set of home position marks on the microfluidic device, which is of the type used in a microfluidic system. Said method comprises following phases: a microfluidic device scanning phase, wherein a microfluidic device is scanned for mark identifiers; a microfluidic device identifying phase, wherein at least one a characteristic feature of the set of home marks is/are determined and used for identifying the identity of the microfluidic device; a home position determining phase, wherein the home position is determined by the use of at least a subset of the home position marks identified during said previous phases. The present invention relates to a set of home marks, a microfluidic device carrying such a set of home marks, a microfluidic system, a computer program product and a computer program on a computer usable medium.

Abstract: The present invention relates to a method, a system, a neural network and a computer program product for determining the quality of an analytical process, preferably the confidence value. The analytical process is performed in a microchannel structure of a microfluidic device, from which data information of the analytic process is acquired by scanning at least one search area of the microchannel structure for signal data. The search area comprises the result of the analytical process and the acquired data information is stored as an image, one image for each scanned search area.

Abstract: A method for determination of an analyte in an original liquid sample by performing an inhibition affinity assay in a microchannel structure of a microfluidic device.

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 that comprises several microchannel structures in which there are an inlet port, an outlet port and there between a structural unit comprising a fluidic function. The structural unit can be selected amongst units enabling a) retaining of nl-aliquots comprising constituents which has been defined by mixing of aliquots within the microfluidic device (unit A), b) mixing of aliquots of liquids (unit B), c) partition of larger aliquots of liquids into smaller aliquots of liquids and distributing the latter individually and in parallel to different microchannel structure of the same microfluidic device (unit C), d) quick penetration into a microchannel structure of an aliquot of a liquid dispensed to an inlet port of a microchannel structure (unit D), and e) volume definition integrated within a microchannel structure (unit E).

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: The invention is a method for grading a polyclonal antibody response with respect to a desired 5 binding specificity. The response is provoked by an antigenic agent in a host, preferably a vertebrate host. The characteristic feature of the method comprises the steps of: (i) providing a reaction microcavity having an inlet end and an outlet end and containing a solid phase that exposes an immobilized binding structure (BS) that are capable of affinity binding antibodies (Ab) of the response, (ii) flowing a liquid sample containing antibodies of the response in the direction from the inlet end to the outlet end through the solid phase, (iii) determining the distribution of antibodies, which are captured during step (ii), along the flow direction of the solid phase, and (iv) grading the response based on the distribution determined in step (iii).

Abstract: A microfluidic device comprising one, two, three or more enclosed microchannel structures, each of which comprises a) an inlet arrangement with an inlet opening for liquid, b) a reaction microcavity (RM1) downstream to the inlet opening, and c) an upstream section that is located between the inlet opening and the reaction microcavity (RM1) and is defined between two planar substrates made of plastic material which substrates are common for said microchannel structures. The characteristic feature is that the inner wall in said upstream section exposes a hydrophilic surface area with an underlying base layer comprising metal oxide. In one aspect the microfluidic device as such is covered.

Abstract: A microfluidic device that comprises several microchannel structures in which there are an inlet port, an outlet port and therebetween a substructure comprising a fluidic function. The device has an axis of symmetry around which the microchannel structures are arranged as two or more concentric annular zones. for an inlet port and an outlet port of the same microchannel structure the inlet port is typically closer to the axis of symmetry than the outlet port. Each microchannel structure comprises a substructure that can retain liquid while the disc is spun around the axis and/or the inlet ports are positioned separate from the paths waste liquid leaving open waste outlet ports will follow across the surface of the disc when it is spun. For the microchannel structures of an annular zones the corresponding substructures are at essentially at the same radial distance while corresponding substructures in microchannel structures of different annular zones are at different radial distances.

Abstract: A method for the determination of an analyte which is a) present in a liquid sample 1 suspected of containing the analyte, and b) at least bivalent with respect to simultaneous affinity binding of at least two binding structures BSs. The method comprises formation of an affinity complex that comprises the analyte and an affinity reactant 1 that is immobilized to a solid phase. The method comprises the steps of: (i) providing a microfluidic flow path that comprises a reaction cavity containing a solid phase to which affinity reactant 1 is immobilized, (ii) providing sample 1 upstream of the cavity and flowing it through the cavity for the formation of the affinity complex under flow conditions, (iii) measuring the amount of complex formed in the solid phase by a) incorporating an analytically detectable and soluble affinity reactant 2 that comprises a binding structure BS into the complex subsequent to step (ii), and b) measuring the amount of affinity reactant 2 incorporated.

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 method and a system for grading the confidence of a result of an experiment that comprises one or more biological and/or chemical reactions and is carried out in a microchannel structure (110a) of a microfluidic device, said confidence determination comprises the steps of: i) detecting within each of at least one liquid detector segment of said microchannel structure (110a) the presence or absence of liquid and/or gas during a period of time for which it is known if liquid and/or gas shall be present and/or absent in the segment, and ii) assigning a lowered confidence to said result if the presence and/or absence of liquid and/or gas found in step (i) is deviating from what it shall be.

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.