Abstract: Animal cell colonies are picked up automatically by an apparatus having a picking head with a plurality of hollow pins and an integrated imager for capturing an image of adherent or non-adherent animal cell colonies held in liquid or semi-solid medium. Image processing identifies the locations of the animal cell colonies to be picked. Picking an animal cell colony is performed by aligning each of the hollow pins in turn with a target animal cell colony location, introducing the hollow pin into the medium, and aspirating the animal cell colony into the hollow pin. In the case of an adherent colony, the distal end of the pin is forced into oscillation to detach the animal cell colony prior to aspiration. The animal cell colony is dispensed into a well plate by increasing pressure in the fluid conduit.

Abstract: Animal cell colonies are picked up automatically by an apparatus having a picking head with a plurality of hollow pins and an integrated imager for capturing an image of adherent or non-adherent animal cell colonies held in liquid or semi-solid medium. Image processing identifies the locations of the animal cell colonies to be picked. Picking an animal cell colony is performed by aligning each of the hollow pins in turn with a target animal cell colony location, introducing the hollow pin into the medium, and aspirating the animal cell colony into the hollow pin. In the case of an adherent colony, the distal end of the pin is forced into oscillation to detach the animal cell colony prior to aspiration. The animal cell colony is dispensed into a well plate by increasing pressure in the fluid conduit.

Abstract: Animal cell colonies are picked up automatically by an apparatus having a picking head with a plurality of hollow pins and an integrated imager for capturing an image of adherent or non-adherent animal cell colonies held in liquid or semi-solid medium. Image processing identifies the locations of the animal cell colonies to be picked. Picking an animal cell colony is performed by aligning each of the hollow pins in turn with a target animal cell colony location, introducing the hollow pin into the medium, and aspirating the animal cell colony into the hollow pin. In the case of an adherent colony, the distal end of the pin is forced into oscillation to detach the animal cell colony prior to aspiration. The animal cell colony is dispensed into a well plate by increasing pressure in the fluid conduit.

Abstract: The invention relates to a microdispenser (1) for dispensing a liquid sample in a dispensing device, with a sample container (2) for receiving the liquid sample, and with a nozzle (7) for dispensing the sample located in the sample container (2). The microdispenser (1) with the filled sample container (2) can in this case be stored independently of and fluidically separately from the dispensing device, without the sample escaping from the sample container (2) during storage.

Abstract: After a sampling needle is moved to a position above a sample container, the sampling needle is moved down so that the tip of the sampling needle penetrates a septum, and is then preferably moved down to a position at which the tip of the sampling needle is not brought into contact with a sample contained in the sample container, and then, the sampling needle is once elevated until the sampling needle is pulled out of the septum, and is then again moved down to penetrate the septum until the tip of the sampling needle is inserted into the sample to suck the sample through a suction port of the sampling needle, and then, the sampling needle is moved to a sample injection port of an analyzer to inject the sample into the analyzer.

Abstract: A dispensing apparatus includes a probe that sucks or discharges a liquid; a pressure generating unit that generates a pressure necessary for the probe to suck or discharge the liquid; and a pressure measuring unit that measures the pressure generated by the pressure generating unit and applied to the probe. The apparatus also includes a setting unit that sets a correction coefficient used when correcting a physical amount based on characteristics of the dispensing apparatus using a result of the measuring by the pressure measuring unit; a storage unit that stores therein information including the correction coefficient set by the setting unit; and a correcting unit that corrects the physical amount using the correction coefficient stored in the storage unit.

Abstract: A second valve is opened to combine an injection-pressure generating pressure with a maintaining pressure into an injection pressure. After the injection pressure is applied to a capillary to cause discharge of an object therefrom, an output pressure of a regulator is set to the injection pressure. Then, a first valve is opened to reapply the injection pressure to the capillary. The second valve is opened to combine a maintaining-pressure generating pressure with the injection pressure into the maintaining pressure. After the maintaining pressure is applied to the capillary to terminate the discharge of the object, the output pressure of the regulator is set to the maintaining pressure. Then, the first valve is opened to reapply the maintaining pressure to the capillary.

Abstract: A device for automatically aspirating and/or dispensing liquids with precision, comprising a housing having an opening at a lower end with a fixed tip protruding out of the lower end; an interchangeable cartridge disposed inside the housing, the cartridge having a holding frame and a spool of tubing provided in the frame such that one end of the tubing is aligned with the tip; and an actuator enabled to automatically extrude part of the tubing so as to accommodate a preselected volume of liquid, aspirate and/or dispense the liquid through the extruded tubing, and disconnect the extruded tubing from the device.

Abstract: Pressure fluctuations are sampled at fixed time intervals and subjected to arithmetic processing, using as a trigger the event (or a sign temporally close to that event) of the reverse motor rotation for the backlash correction, thereby discriminating normal suction from suction of sample liquid with undesirable air bubbles.

Abstract: A pipetting device is described comprising more than one pipetting unit, wherein said pipetting units are independently movable in Y and Z direction and comprise at least one module arranged in a staggered manner compared to the adjacent pipetting unit.

Abstract: A sample dispensing apparatus and method for dispensing a sample such as blood and urine collected for inspection from one vessel to another are provided wherein the remaining quantity of a primary sample can be reduced without disturbing the primary sample. When clogging by a separating agent is detected during suction of a sample such as blood and urine collected for inspection, the sample dispensing apparatus performs raising of an aliquot head such that an opening at the free end of a nozzle tip does not come out of the sample liquid surface to dissolve clogging; sucking of the sample under the residual pressure; and additionally sucking of a fixed quantity of the sample to reduce the remaining quantity of the sample.

Abstract: A gel extraction device (10) comprises a hollow cutting member (12) having cutting edge (14) at one end and a squeeze bulb (16) at the other end. In a further embodiment, the air passage between the cutting edge and the bulb has a constriction zone (20) to prevent any extracted gel from being drawn too deeply into the extractor, in another embodiment, a blow-hole in the hollow cutting member or in the squeeze bulb provides for the passage of air displaced by gel through the extractor. The blow-hole may be covered to secure the gel in the receptacle for transfer from the matrix to a sample container.

Abstract: The invention relates to a device for generating and/or arranging sequences of a fluid sample in a carrier fluid. The invention comprises a microchannel having an inlet, an outlet and a nozzle opening therebetween leading into the microchannel. The invention further relates to a delivery unit, which pumps in the carrier fluid using a feed volume flow and suctions off the carrier fluid using a discharge volume flow. In a sample container, the nozzle opening is in contact with the fluid sample. By means of a control unit, the ratio between feed volume flow and discharge volume flow is varied. The cross-section of the nozzle opening is selected such that no carrier medium exits from the nozzle opening when the feed volume flow equals the discharge volume flow and that a fluid sample enters the nozzle opening when the discharge volume flow is greater than the feed volume flow. The invention further relates to a method for generating and/or arranging sequences of a fluid sample in a carrier fluid.

Abstract: A fluid dispenser useful in automated biological reaction systems comprising a barrel having a reservoir chamber, the barrel having an upper portion and a lower portion, a cap located on top of the upper portion of the barrel and connected to the reservoir chamber, the cap having an external surface with at least one hole therethrough, a valve comprising a biasing member and a hole sealer, the valve being located in the hole in the cap at the point where a downward force is applied against the cap, a coupler having a dispense chamber, the coupler being coaxial with the barrel and wherein the barrel lower portion moves into the dispense chamber during dispensing of fluid, and a vent located between the cap and the reservoir chamber, the vent including a vent opening and a vent material composed of oliophobic material.

Abstract: A second valve is opened to combine an injection-pressure generating pressure with a maintaining pressure into an injection pressure. After the injection pressure is applied to a capillary to cause discharge of an object therefrom, an output pressure of a regulator is set to the injection pressure. Then, a first valve is opened to reapply the injection pressure to the capillary. The second valve is opened to combine a maintaining-pressure generating pressure with the injection pressure into the maintaining pressure. After the maintaining pressure is applied to the capillary to terminate the discharge of the object, the output pressure of the regulator is set to the maintaining pressure. Then, the first valve is opened to reapply the maintaining pressure to the capillary.

Abstract: A pipette and a process for producing a pipette (10) with a capacity of from 1 to 50 ml from a thermoplastic polymer. An essentially cylindrical pipette shaft (12) with an internal diameter (di) and an essentially cylindrical cup-shaped pipette reservoir (16) with an internal diameter (Di) are produced in an injection molding process. The pipette shaft (12) has, at one end, a pipette tip (14) which narrows to a suction/exit orifice (20), and, at the other end, a conical widening (18). The pipette reservoir (16) has a suction nozzle (24) abutting coaxially from the bottom of the pipette reservoir (16). The conical widening (18) is welded or adhesive-bonded at the end and coaxially to the pipette reservoir (16). The ratio of the total pipette length (L) to the arithmetic mean of the internal diameters (di and Di) of the pipette shaft (12) and of the pipette reservoir (16) is at least 15. The pipette may have a suction nozzle (24) with a retainer, such as a radially inward jutting rib (34) for a cotton wool bud.

Abstract: A microfluidic dispensing system may include diaphragm pumps that may be used for aspirating in corresponding ingredients via a nozzle or a tip from supply sources. Tips may be placed in contact with ingredient supply sources, and through repeated actuation of the diaphragm pumps, desired volumes of ingredients are aspirated into the tips. In some cases, an air plug is aspirated into the tips before an ingredient. Once the desired volume of each ingredient is reached within each tip, the ingredients are dispensed from the tips through repeated actuation of corresponding diaphragm pumps.

Abstract: A two-part coaxial needle for a pipetting device, in particular for use in microscopy of cell probes, makes it possible both to inject a liquid into a pipetting container and to remove by suction a liquid from the pipetting container. Both the drive for lowering the coaxial needle into the pipetting container, and injection and removal by suction of the liquid take place pneumatically by way of only one pressure source. The design of the coaxial needle and of the drive systems makes possible fast and reliable pipetting with high metering accuracy and a particularly compact pipetting unit which without mutual interference can be used with a multitude of widely-used microscope types.

Abstract: A self-contained sampling probe characterized by a drive module and a syringe module removably coupled coaxially to the drive module to allow for different syringe modules to be interchangeably coupled to the drive module. The coupling is effected by quick connect and disconnect devices, and the syringe module may carry an identifier. The probe is engageable by a gripper or insertable in an interface device, both of which provide for communication of the probe with other system components.

Abstract: The invention relates to a device and a method for taking liquid or gaseous samples from containers and/or tubes that are filled with a medium, in particular from fermenters, by means of negative pressure, wherein an element which acts as a non-return valve is arranged within a sample probe as an inlet for the sample that is to be taken, and a supply line which is able to convey gas and a discharge line which is able to discharge sample are arranged on a common side of the element.

Abstract: A hand-held electronic pipettor includes menu driven software for controlling the information displayed on the user interface display, for inputting information to program the pipettor and for controlling the operation of the pipettor.

Abstract: An apparatus and method for automated picking of animal cell colonies. A picking head comprising a plurality of hollow pins is provided. The apparatus has an integrated imager for capturing an image of adherent or non-adherent animal cell colonies held in liquid or semi-solid medium. Image processing identifies the locations of the animal cell colonies to be picked. Picking an animal cell colony is performed by aligning each of the hollow pins in turn with a target animal cell colony location, introducing the hollow pin into the medium, and aspirating the animal cell colony into the hollow pin. In the case of an adherent colony, the distal end of the pin is forced into oscillation to detach the animal cell colony prior to aspiration. The animal cell colony is dispensed into a well plate by increasing pressure in the fluid conduit.

Abstract: An improved pipette tip (100) including an elongate body stretching between a proximal end (116) and a distal end (114). The body (112) is typically made from a plurality of layers (e.g. 130, 132, 134, 136, 138) configured and arranged to provide a fluid path extending from the distal end toward the proximal end. The improved pipette tip (100) includes a sensor component disposed to electrically interrogate fluid flowing along the fluid path. An operable sensor component includes an electrode (e.g. 154, 192) that is disposed in the fluid path to contact fluid therein. A pipette tip (100) may be embodied to: count particles, verify sample integrity (e.g. freedom from bubbles), monitor sample flow rate, and confirm an inspired volume, among other uses.

Abstract: An automatic extractor for volumetric pipettes includes a pair of gripping jaws. Each gripping jaw has a non-slip gripping surface juxtaposed symmetrically along a longitudinal pipette axis. The non-slip gripping surfaces are spaced apart from one another to provide ample room to place a volumetric pipette therebetween. A stationary support plate located above the pair of gripping jaws receives the nose of a hand-held pump while the stem of the attached pipette triggers an activation switch that closes the gripping jaws and removes the pipette.

Abstract: Aspirating a liquid, includes: providing an aspirating probe comprising probe tip and piston pump, wherein the probe tip and piston pump are in fluid communication; measuring an initial gas pressure in the probe prior to liquid entering the liquid being aspirated; moving the tip into the liquid; moving the piston a distance corresponding to the volume of liquid being aspirated; measuring gas pressure in the volume of gas when the piston stops moving and the liquid pulled into the tip has equilibrated; determining piston volume created by movement of the piston; and determining volume of liquid aspirated by the following formula: Vliquid aspirated=Vpiston volume?((Pinitial?Pfinal)*Volume/unit pressure), wherein Pinitial is initial gas pressure before liquid enters the tip, Pfinal is the final pressure of volume of gas after the liquid has equilibrated, and Volume/unit pressure is the change of gas volume for each change of unit pressure.

Abstract: A liquid transporting device capable of transporting a liquid, such as dispensing or distributing a liquid, to microplates in number larger than a value mountable on a table. The liquid transporting device comprises a table on an upper surface of which a storing member and a discharge receiving member are detachably mounted, sucking/discharger means, a control unit for transporting a liquid in accordance with a previously incorporate program while relatively moving the sucking/discharger means and the table, an input device, and an alarm signal notifier. The control unit has a function of determining whether ID information of the storing member and/or the discharge receiving member, which is a work target of the previously incorporate program, is identical to ID information of the storing member and/or the discharge receiving member mounted on the table.

Abstract: A device for drawing off a liquid from a container comprising a drawing-off needle having a free lower end and an upper end, a suction deliverer connected to the upper end of the needle, and a blower carried by the needle allowing drops of the liquid present on the inside wall(s) of the container in the bottom section of the container to be concentrated.

Abstract: Liquid aspirators are described that include an aspirating pipette; a drive source for descending the aspirating pipette; and a controller for controlling the drive source; the aspirating pipette being stopped from being descended by loss of synchronism of the drive source caused by upward force to be exerted on the aspirating pipette. Analyzers are also described.

Abstract: A system controls aspiration and dispensation of a liquid in a pipette. The system includes a computing device and the pipette. The computing device includes a pipetting module and a first communication interface. The pipetting module defines an operation to perform at the pipette. The first communication interface sends electronic signals to the pipette, the electronic signals defining the operation to perform at the pipette. The pipette includes a sampling tube, a piston assembly, a piston drive mechanism, a second communication interface, and a microprocessor. The piston assembly mounts to the sampling tube and includes a piston rod that fits within the sampling tube. The piston drive mechanism includes a control rod having a surface that contacts the piston assembly. The piston drive mechanism moves the piston rod of the piston assembly within the sampling tube thereby causing regulation of a liquid in the sampling tube.

Abstract: A sample acquisition device includes a capillary array configured to draw in a sample and retain the sample by capillary action. The capillary array may be coupled to an elongated member, such as a stem or a hollow tube, which defines a longitudinal axis extending in a first direction. In some embodiments, the capillary array defines a major sample acquisition surface that extends in a second direction different than the first direction. A ratio of the major sample acquisition surface area to maximum volume retained by the capillary array may be selected to minimize physical binding between the capillary array and sample. In some embodiments, the device may include a feedback mechanism to indicate the relative pressure applied to a sample source with the sample acquisition device. In addition, in some embodiments, the sample acquisition device may include a suction source to help draw the sample into the capillary array.

Abstract: The invention relates to a pipetting apparatus (1) having a pipette tip (2) for aspirating and dispensing liquid samples; a pump (4) for generating negative pressure or positive pressure in the pipette tip (2) that is connected to the pipette tip (2) by means of a pump conduit (3); a fluid chamber (5) defined by the pipette tip (2) and/or the pump conduit (3); a measurement probe (6) functionally connected to the fluid chamber (5) for measuring the physical parameters resulting in this fluid chamber (5) during pipetting; and a device control system (7) with a processor (8), in which an activated computer program product enables the control system (7) of the pipetting apparatus (1) to individually accept or reject pipetted liquid samples on the basis of the physical parameters measured.

Abstract: A microchip processing apparatus processes a microchip with at least one main separation channel. The microchip processing apparatus includes a holding part configured to hold the microchip, a container containing a sample or a reagent, and a dispensing probe having a needle formed on a tip of the dispensing probe. The dispensing probe is actuated to be inserted into the container from above the container, to draw the sample or reagent, and to inject to a prescribed position on the held microchip. A dispensing probe driving mechanism moves the dispensing probe between prescribed positions of the microchip and the container.

Abstract: Embodiments relate to a method and system for controlling a volume of liquid to be drawn and metered. One embodiment relates to a restraining divider for a syringe for controlling a volume of liquid drawn and metered by the syringe comprising a grooved side with a first groove and a second groove. Either the first groove or the second groove fits a shaft of a plunger of the syringe, wherein the length of at least one of the first groove, the second groove or the groove side provides a gap between a compressed thumb flange of said syringe and the body of the syringe.

Abstract: A handheld pipetting apparatus for metering liquids, with a handleable pipette housing, at least one accommodation for a fastening portion of a syringe cylinder of a syringe, at least one plunger accommodation in an accommodation body for a plunger fastening portion of a syringe plunger of the syringe, fastening means for detachably holding the fastening portion in the accommodation and the plunger fastening portion in the plunger accommodation, at least one displacement device with a displacement chamber and a shiftable chamber wall limiting the same, for displacing a fluid; at least one seat for detachably holding a pipette point, a channel, connecting a hole in the seat with a displacement chamber, and at least one drive device, which is connected to and/or couplable with the accommodation body and/or the chamber wall, for shifting the accommodation body with respect to the accommodation, and/or the chamber wall with respect to the displacement chamber.

Abstract: A flows cell for use in a microfluidic detection system is provided. The flow cell includes a flows cell body having a channel that is configured to convey a solution through the flows cell body. The flow cell also includes a bottom surface and a top surface. The bottom surface is configured to be removably held by the detection system and the top surface is transparent and permits light to pass therethrough. The flow cell body also includes fluidic inlet and outlet ports that are in fluid communication with the channel. A pump cavity is also provided in the flow cell body. The pump cavity fluidly communicates with, and is interposed between, an end of the channel and one of the fluidic inlet and outlet ports. An electroosmotic (EO) pump is held in the pump cavity. The EO pump induces flow of the solution through the EO pump and channel between the fluidic inlet and outlet ports.

Abstract: Highly efficient and rapid filtration-based concentration devices, systems and methods are disclosed with sample fluidic lines and a filter packaged in a disposable tip which concentrate biological particles that are suspended in liquid from a dilute feed suspension. A sample concentrate or retentate suspension is retained while eliminating the separated fluid in a separate flow stream. The concentrate is then dispensed from the disposable tip in a set volume of elution fluid. Suspended biological particles include such materials as proteins/toxins, viruses, DNA, and/or bacteria in the size range of approximately 0.001 micron to 20 microns diameter. Concentration of these particles is advantageous for detection of target particles in a dilute suspension, because concentrating them into a small volume makes them easier to detect. All conduits by which the disposable tip attaches to the instrument are combined into a single connection point on the upper end of the tip.

Abstract: A stirring device (1) capable of correctly detecting abnormality in a stirring process and preventing liquid which has not been stirred in a normal process from being used in an analyzing process, and an analyzer are provided. The stirring device (1) according to the present invention includes a nozzle (2), a syringe (14), and an abnormality detecting section (35) for determining whether or not a stirring process has been performed in a normal manner on liquid, which is a stirring subject, in a stirring container (23), on the basis of the amount of deviation between a suction pressure waveform indicating a suction pressure change measured by a pressure measuring section (6), and a suction pressure waveform pre-obtained during normal stirring.

Abstract: There is also provided an apparatus for use on an automated pipette machine for transmitting pressure changes produced by a pump on the machine to a pipette nozzle. The apparatus comprises a housing defining a chamber a first conduit and a second conduit. The first conduit extends into the chamber and has a first opening positioned in the chamber. The first conduit is fluidically connectible to the nozzle. The second conduit extends into the chamber and has a first opening positioned in the chamber. The second conduit is fluidically connectible to the pump. The first opening of the first conduit is positioned above the first opening of the second conduit. The chamber defines at least a selected volume between the height of the first opening of the first conduit and the height of the first opening of the second conduit.

Abstract: A liquid transporting device capable of transporting a liquid, such as dispensing or distributing a liquid, to microplates in number larger than a value mountable on a table. The liquid transporting device comprises a table on an upper surface of which a storing member and a discharge receiving member are detachably mounted, sucking/discharging means, a control unit for transporting a liquid in accordance with a previously incorporate program while relatively moving the sucking/discharging means and the table, input means, and alarm signal notifying means. The control unit has a function of determining whether ID information of the storing member and/or the discharge receiving member, which is a work target of the previously incorporate program, is identical to ID information of the storing member and/or the discharge receiving member mounted on the table.

Abstract: A method for quantitatively measuring error causing physical parameters in a fluid handling system, includes: measuring the pressure of air between a piston of a pump and a liquid being handled; detecting a pressure abnormality; determining the time at which the pressure abnormality begins to occur; and based on the time of the pressure abnormality determining the magnitude of the physical parameter causing the pressure abnormality. In a preferred embodiment, the error causing physical parameter is a bubble and the fluid handling is an aspirate operation in a diagnostic analyzer.

Abstract: A pipetting device including a pipetting unit (12) having an application chamber (26) and a first end (16) that is realized with a discharge opening (18), and a second, open end (20). In the vicinity of the second, open end (20) of the pipetting unit (12), a sleeve-like receptacle unit (14) is guided so that it can move axially on at least two sealing lips (22, 24) that project radially inward and are at some distance from each other, which is provided on the side facing the application chamber (26) of the pipetting unit (12) with a base element (28), and on the side facing away from the application chamber (26) has an opening (32) and which has, in the vicinity of its periphery, at least one opening (34), the axial dimensions of which are somewhat smaller than or equal to the distance between the sealing lips (22, 24).

Abstract: Apparatus (1) for withdrawing respective liquid samples from vials (2) which are closed by closure caps (4) penetratable by a pointed cannula comprises a plurality of racks (7) for accommodating the vials (2). A device (10) comprising a housing (25) is slideably carried on a gantry (9) which in turn is slideably carried on guide tracks (12) to provide two degrees of movement of the device (10) for selective alignment of the device (10) with the vials (2). An abutment member (43) which is vertically slideable in the housing (25) of the device (10) is driven by a second gearwheel (51) by a drive shaft (27) along which the housing (25) is slideably mounted through a first gearwheel (40) and a dog clutch (52). A cannula which is secured within a first gear rack (33) is driven upwardly and downwardly within the housing (25) by the first gearwheel (40) which is driven by the drive shaft (27).

Abstract: An apparatus and method for automated picking of animal cell colonies. A picking head comprising a plurality of hollow pins is provided. The apparatus has an integrated imager for capturing an image of adherent or non-adherent animal cell colonies held in liquid or semi-solid medium. Image processing identifies the locations of the animal cell colonies to be picked. Picking an animal cell colony is performed by aligning each of the hollow pins in turn with a target animal cell colony location, introducing the hollow pin into the medium, and aspirating the animal cell colony into the hollow pin. In the case of an adherent colony, the distal end of the pin is forced into oscillation to detach the animal cell colony prior to aspiration. The animal cell colony is dispensed into a well plate by increasing pressure in the fluid conduit.

Abstract: An improved pipette tip (100) including an elongate body stretching between a proximal end (116) and a distal end (114). The body (112) is typically made from a plurality of layers (e.g. 130, 132, 134, 136, 138) configured and arranged to provide a fluid path extending from the distal end toward the proximal end. The improved pipette tip (100) includes a sensor component disposed to electrically interrogate fluid flowing along the fluid path. An operable sensor component includes an electrode (e.g. 154, 192) that is disposed in the fluid path to contact fluid therein. A pipette tip (100) may be embodied to: count particles, verify sample integrity (e.g. freedom from bubbles), monitor sample flow rate, and confirm an inspired volume, among other uses.

Abstract: A microfluidic dispensing system may include diaphragm pumps that may be used for aspirating in corresponding ingredients via a nozzle or a tip from supply sources. Tips may be placed in contact with ingredient supply sources, and through repeated actuation of the diaphragm pumps, desired volumes of ingredients are aspirated into the tips. In some cases, an air plug is aspirated into the tips before an ingredient. Once the desired volume of each ingredient is reached within each tip, the ingredients are dispensed from the tips through repeated actuation of corresponding diaphragm pumps.

Abstract: The present invention relates to a ceramic tip and a random access print head for the transfer of microfluidic quantities of fluid. The print head can randomly collect and deposit fluid samples to transfer the samples from a source plate to a target. The print head can also be programmed to create a direct map of the fluid samples from the source plate on the target or to create any desired pattern or print on the target. The tip and print head can be used for a wide variety of applications such as DNA microarraying and compound reformatting. In one preferred embodiment, the tip is used as a capillary or “gravity” pin to draw or collect source fluid and “spot” or deposit the fluid onto the target via physical contact (touch-off). In another preferred embodiment, the tip is used in conjunction with an aspirate-dispense system to actively aspirate source fluid and deposit the fluid via a contact or non-contact approach. The tip provides improved, accurate and repeatable microfluidic transfer.

Abstract: A sample plate for a portable analysis apparatus for analysis of a solid precipitated from a fluid sample, which sample plate comprises a sample inlet, a precipitation zone, a filter and an analysis zone, the sample plate being adapted to allow: (i) a fluid sample to be fed through the sample inlet into the precipitation zone; (ii) a precipitant to be fed to the precipitation zone; (iii) conditions within the precipitation zone to be maintained such that precipitation occurs when the fluid sample and precipitant mix to form a suspension; (iv) separation of the solid in the suspension by the filter; (v) addition of a solvent to the filter to dissolve the solid and form a solution; and (vi) analysis of the solution in the analysis zone.

Abstract: A method and a device for providing a predeterminable concentration of at least one component in a microscopic sample liquid medium are described. The device includes a feeding device for the at least one component. Measurement data are determined, measuring a predeterminable parameter using a microscopic method. The concentration of the at least one component is adjusted or controlled via the feeding device based on the basis of measurement data.

Abstract: A method for metered dispensing of a medium from a container, a dosing pipette (P1P2) for removing an exactly predetermined amount of the medium to be inserted into the container, wherein the predetermined amount is adjusted on the dosing pipette (P1P2) prior to removal.

Abstract: The invention relates to a pipette, comprising a tip remover element which, upon moving it against a tip, disengages the tip. The remover element is operated with a mechanism, comprising a rotatable ramp member which is provided with a circle-forming ramp surface, including one or more segments within which the ramp surface has a high point and a low point, whereby the ramp surface, upon rotating through a single segment, forces the remover element first to move against the tip and then allows it to return.