Abstract: The present disclosure provides a polar coordinate positioning system. The system can be used, for example, to sample a microtiter plate or sample tubes. In some embodiments, the system orients a sample with respect to a sampling tool using polar coordinates. In some embodiments, the sample is configured to rotate about an axis and move linearly in a direction transverse to the axis, and the sampling tool is configured to move linearly in a direction transverse to the linearly movement of the sample.

Abstract: The invention relates to a device for catching drops from a pipette mechanically attached to a pipetting device in the field of nucleic acid purification and amplification. Furthermore, a method for pipetting a liquid with a decreased potentiality of contamination of an analytical instrument as well as liquids or/and samples placed on said analytical instrument is provided. Moreover, an analytical instrument at least comprising a pipetting device, and a device for catching drops from a pipette mechanically attached to said pipetting device wherein the movement of the device for catching drops is coupled to the movement of said pipetting device is illustrated.

Abstract: Packaging for an ICSI pipette (50) has a base (10) and a slider (20) on which the pipette is retained by clips (29) and (36). The base (10) has a transparent rod (16) projecting above the thin end (52) of the pipette (50), acting as a lens to enable the tip of the pipette to be viewed. A grip portion (26) on the slider (20) projects above the pipette (50) and the rod (16) to enable the slider to be moved relative to the base such that the thick end (52) of the pipette projects beyond the end of the base for access and removal.

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: A clinical specimen processing apparatus that includes: a preparation device that is configured to conduct operations to perform predetermined processing of clinical specimen; a controller in communication with the preparation device, wherein the controller is configured to detect an operating condition of the preparation device which performs the predetermined processing; a central processing unit that is configured to: 1) compare a detection value detected by the controller to a first threshold value and a second threshold value; and 2) determine whether or not the preparation device is in any one of three condition stages.

Abstract: A method for the preparation of samples for an analyzer and a sampling station therefor are provided which allow automated injection of larger inert-gas volumes to be introduced into a sample container via a packing, in order to enrich the packing of the substances of a sample to be investigated.

Abstract: The invention concerns an automatic pipetting unit with a replaceable pipetting head. The pipetting head includes two head rails located on opposite sides. The pipetting unit also has two horizontal guide channels located in the interior of the pipetting unit for supporting the two head rails. Two frame-mounted, double-sided slider crank mechanisms are vertically arranged in the pipetting unit. Each double-sided slider crank mechanism includes two crank mechanisms each connected to a common articulated thrust joint by a thrust couple. The horizontal guide channels are formed in the articulated thrust joint and the crank mechanisms are connected indirectly to a head cover of the pipetting unit, so that with the opening and closing motion of the head cover the two slider crank mechanisms are moved between two end positions so that the pipetting head can be moved vertically between a lower end working position and an upper end replacement position.

Abstract: A pipette including a cylinder part having a cylinder and a tip part, which includes a tip channel connected to the cylinder and a movable piston tightly fit within the cylinder for aspirating liquid into and removing liquid from the tip container attached to the cylinder. In the pipette at least the tip part is made of an elastic material, such as rubber. The tip container can thus be easily and reliably fixed to and removed from the tip container.

Abstract: A method for automated loading of liquid sample to a liquid chromatography testing device is provided including installing a disposable tip on a probe, moving the probe with an automated liquid handler to a loading position proximate to a sample, and drawing a sample into the disposable tip. The probe is then moved to an injection position proximate an injection port, and the sample is injected from the disposable tip into the injection port. Also provided are the novel injection ports. After injection of the sample, the disposable tip is then removed from the probe. These steps may be repeated a plurality of times to sequentially load a plurality of samples. An exemplary method of the invention is directed to use with a liquid chromatography apparatus. An apparatus for assisting in the removal of the disposable tip is also provided.

Abstract: An apparatus and a method for taking out samples of a gaseous medium containing particles, the apparatus comprising a pipe having one end adapted for introduction into the gaseous medium, a tubular filter positioned coaxially with the pipe, a removable closure positioned on the down stream side of the tubular filter, means for removing filtered gas from the outside of the tubular filter and separate blow back means in communication with the outer side of the tubular filter.

Abstract: A sample carrier having a top wall, a base, and a support wall joining the top wall and the base. The top wall includes aligned, spaced-apart openings on at least one side of the support wall which are sized to receive sample tubes. Sleeves depending from the top wall and circumscribing each opening direct sample tubes into sample tube holding areas. The sample tube holding areas each include one or more retaining walls extending upward from the base opposite the support wall. Springs extending outward from the support wall bias sample tubes against the retaining walls. A drip shield comprising a cover plate, a pair of through-holes for accessing sample tubes in the sample carrier, and a depending fin which separates sample tubes on opposite sides of the support wall protects against cross-contamination between sample tubes held by the sample carrier.

Abstract: An automatic pipetting and analyzing device for the preparation and analysis of samples in the wells of a microtitration plate has a work platform on which positioning areas for auxiliary devices and a movement area for the sample plate are provided, a passive mechanical table without its own drive unit, the sample plate lying within the inner passive slide of the passive mechanical table, and an active mechanical table which is arranged above the passive mechanical table and by which a pipetting head can be moved in X-Y direction over the work platform in order to extract, transport and dispense liquids by at least one pipetting channel and in order to displace the sample plate by a coupling connection with the inner passive slide, for example, to place the sample plate in an incubator or to position it with the individual wells in an analysis device.

Abstract: Apparatus for aspirating liquid from a container, e.g., a test tube, having a puncturable stopper includes a pair of stepper motors that share a common linear actuator or drive member. One motor operates to axially advance the linear drive member (preferably a lead screw) to a position in which it serves to position a rigidly connected tube-detector/stripper member in engagement with the top of a stopper on a tube. Thereafter, the second motor operates to move along the surface of the same drive member to advance an aspiration probe through the engaged stopper and into a liquid aspirating position within the tube. Preferably, a linear guide rail, slidably-mounted on a frame that supports the liquid-aspirating apparatus, serves to guide both the movement of the aspiration probe and the linear drive member. As a result of the shared components, the apparatus is highly precise and reliable.

Abstract: A pipetting apparatus (1) comprises a fluidic space (7), to which a pressure transducer (11) with a pressure sensor (12) is attached with a gas filled space (15). The fluidic space (7) is defined by a pipette tip (2), a first tubing (5) that connects the pipette tip (2) to a pump (4), and an active part (6) of the pump (4). The pipetting apparatus (1) according to the present invention is characterized in that the pipetting apparatus (1) further comprises an impulse generating means (16, 18, 19) that is in operative contact with a column (10) of system liquid (8) inside the fluidic space (7). The impulse generating means (16, 18, 19) is designed to induce a vertical movement in this system liquid column (10), which results in a pressure variation in the gas filled space (15) that is pneumatically connected with the fluidic space (7).

Abstract: An automated sampling or dispensing device comprising a support surface for supporting a sample holder and a fluid holder, a first arm assembly for supporting a fluid probe comprising a z-axis support and a horizontal fluid probe support arm, a first drive assembly, a second arm assembly for supporting a sample probe comprising a z-axis support and a horizontal sample probe support arm, and a second drive assembly. The first arm assembly is suitable for collecting a fluid from a fluid vessel and transferring it to a sample vessel, the second arm assembly is suitable for collecting an amount of sample and fluid from the sample vessel, and the support surface further comprises a mixing assembly suitable for mixing the fluid and the sample.

Abstract: A level sensor apparatus is disclosed for detecting contact of a pipetting needle with a liquid contained in a vessel. The apparatus includes a sensor head made up of a pipetting needle, a needle holder, and an electromechanical transducer. The sensor head also has an associated mechanical resonance frequency. An electrical signal generator is used to generate a driving signal which when applied to the electromechanical transducer causes vibration of the pipetting needle at the resonance frequency. A measurement device is used to measure a parameter of a vibration signal indicative of the mechanical vibration of the pipetting needle when it is driven by the driving signal. An electronic circuit and associated computer software is provided to evaluate variation of the vibration signal with time and thus detect contact of the pipetting needle with a liquid contained in the vessel.

Abstract: This invention provides improved components (e.g. array “pins”, print head, substrate platen, print head platen, and the like) for microarray printing devices as well as microarray printing devices incorporating such components. In one embodiment, this invention provides a microarray print head comprising a plurality of glass or quartz spotting capillaries disposed in a support that maintains a fixed spacing between the spotting capillaries and that permits the spotting capillaries to move in a direction parallel to the long axis of the capillaries.

Abstract: A method and device for an automatic analyzer, in particular for blood analysis sampling consists in displacing a sampling needle (5) rotatable around an axis (X2) which forms an angle with the sampling needle. The method and device are particularly suitable for use in a small blood sampling automate.

Abstract: Apparatus and method for aspirating liquid from a container, e.g., a test tube or other vessel, includes apparatus for sensing that an aspiration probe tip is contacting the inside bottom wall of the container, whereby a maximum volume of liquid can be aspirated from the container. According to the invention, an encoder is mounted on the driven member of a motor (e.g., on a rotatably-driven drive shaft or a nut of a stepper or D.C. motor, or on a linearly-driven shaft of a linear actuator) used to rectilinearly advance the probe tip into the container. Such encoder produces a series of pulses indicating the speed and/or linear position of the probe tip. A motor controller responds to a predetermined change in pattern of pulses from the encoder indicating that movement of the probe tip has been resisted by the vessel bottom, whereby further movement of the driven member and of the probe connected thereto is arrested, and the probe tip remains in contact with the vessel bottom.

Abstract: In a system for sucking and discharging a solution from a vessel (micro-plate assembly 6) by suction nozzles 2, processes for suction, discharge, separation, etc. can be carried out with use of a simple mechanism, including suction nozzle moving means 3 for positioning the respective distal ends of the suction nozzles on the inner wall surface of the vessel, magnetic particle holding means 4 for magnetic particles 7 in a given position in the vessel, and solution discharge means 5 for sucking out and discharging the solution simultaneously from the vessel through the suction nozzles. Each or a combination of these means constitutes a drainage system.

Abstract: Device for automatically implementing the SPE method, with a two-dimensional needle arrangement which is suitable for removing substances from different two-dimensional specimen vessel arrangements and dispensing them under pressure into a two-dimensional cartridge arrangement.

Abstract: A microarraying head 51 has a base portion 57 and a plurality of needles 53. The needles 53 are arranged in parallel with one another on the base portion 57. The needles 53 place a solution on substrates 3 with the top ends of the needles 53 touching substrates 3. Then, the needles 53 retain the solution including biological samples and form spots of the solution on the substrates 3. A space 58 for supplying cleansing fluid or the like is provided in the base portion 57 so as to extend all over the plurality of needles 53. Since the plurality of needles 53 can be all cleansed with substantially uniform pressure applied thereto, all the plurality of needles 53 can cleansed surely in a short time.

Abstract: The sampling pipette comprises a body and an arm movable relative to the body to eject a cone fixed to the pipette, ejection taking place in a longitudinal direction of the pipette, the arm having both a first portion suitable for coming into contact with the cone, and a second portion. The two portions are engaged one in the other and, starting from an operating position, they enable the first portion to be separated from the body by means of an initial movement in a direction that is essentially perpendicular to the longitudinal direction.

Abstract: Rapid characterization and screening of polymer samples to determine average molecular weight, molecular weight distribution and other properties is disclosed. Rapid flow characterization systems and methods, including liquid chromatography and flow-injection analysis systems and methods are preferably employed. High throughput, automated sampling systems and methods, high-temperature characterization systems and methods, and rapid, indirect calibration compositions and methods are also disclosed. The described methods, systems, and devices have primary applications in combinatorial polymer research and in industrial process control.

Abstract: A sample processing device [700] comprises an elongated body [101] with a septum seal [109] on one end and a drip tube [731] on the second end. A small-diameter through-chamber [103] in the body provides a receiving and alignment chamber for a hypodermic needle [109] inserted into the septum. A sample processing chamber [709] provides a location for processing elements such as filters and adsorption or absorption frits [135,137]. Sample fluid injected into, or withdrawn from, the device by the hypodermic needle communicates with a bottom opening [701] of the drip tube via a drip tube nozzle [705], the sample processing chamber and the small-diameter chamber. The device is particularly useful in automated testing where the device is moved to various processing locations by the hypodermic needle.

Abstract: The present invention relates to a spotting device for fabricating microarrays of biological materials and a spotting pin inserted therein. More particularly, the present invention is directed to a spotting device, which comprises several pins and pin-guiding holder that allows the pins to move accurately and rectilinearly toward up-down direction by guiding and supporting pins at several points, and spotting pins inserted therein.

Abstract: An apparatus for analyzing liquid samples packed in tubes (6) closed with a top (7) capable of being perforated, includes a support (4) for the tubes and a unit (8) for sampling an aliquot from each tube and delivering it into a receptacle for treatment and/or analysis, the unit (8) including a hollow needle (45) connected to a suction/delivery device and vertically mobile; the support (4) has a circular tray provided with several tube-holders (5) on its periphery and capable of rotating about a vertical axis to bring a position successively and selectively the tubes (6) borne by the tube-holders (5) in line with the unit (8); each tube-holder (5) is connected to the tray (4) through a linkage (31) with two degrees of freedom.

Abstract: A cannula for use in transferring small volumes of fluid materials, such as in a parallel reaction process. The cannula comprises a long thin needle having various end (port) configurations, and an adapter for connecting the needle to a fluid line. The adapter may include the combination of a reservoir and transition, or simply a transition.

Abstract: In order to reduce carry-over of sample liquids in an automatic analyzer by a pipeting probe and resulting contamination of sample liquids by immersing the pipeting probe into sample liquids as shallow as possible, said pipeting probe is moving down to a position which is calculated and determined according to the detected height of a container temporarily stopping said probe there, and further moving down said probe to immerse said probe into the liquid in said container.

Abstract: A work station for simultaneously performing multiple assays includes a base structure, a receptacle rack assembly received within a receptacle rack well formed in the base structure, a pipette tip rack assembly received within a pipette tip rack well formed in the base structure, a multiple conduit substance transfer device, and substance transfer device positioning structure. The receptacle rack assembly holds a plurality of receptacles in which a plurality of individual assays are performed, and the pipette tip rack assembly holds a plurality of contamination limiting pipette tips. The substance transfer device is capable of simultaneously dispensing substances into two or more receptacles or simultaneously removing substances from two or more receptacles. Alternatively, the substance transfer device is capable of simultaneously dispensing substances into two or more receptacles, and, at about the same time, simultaneously removing substances from two or more receptacles.

Abstract: A work station for simultaneously performing multiple assays includes a base structure, a receptacle rack assembly received within a receptacle rack well formed in the base structure, a pipette tip rack assembly received within a pipette tip rack well formed in the base structure, a multiple conduit substance transfer device, and substance transfer device positioning structure. The receptacle rack assembly holds a plurality of receptacles in which a plurality of individual assays are performed, and the pipette tip rack assembly holds a plurality of contamination limiting pipette tips. The substance transfer device is capable of simultaneously dispensing substances into two or more receptacles or simultaneously removing substances from two or more receptacles. Alternatively, the substance transfer device is capable of simultaneously dispensing substances into two or more receptacles, and, at about the same time, simultaneously removing substances from two or more receptacles.

Abstract: A sample suction apparatus includes: first through third members; a drive source; and a suction needle provided on the third member. The drive source reduces a distance between the first member and the third member to perform: a first action of shifting the first member toward the third member to contact the first member with a portion of a specimen vessel; a second action of shifting the second member together with the third member toward the first member to contact the second member with another portion of the specimen vessel so that the specimen vessel is sandwiched between the first and second members; and a third action of shifting the third member toward the first member to bring the third member close to the second member so that the suction needle is inserted in the specimen vessel.

Abstract: A pin tool assembly is provided for transferring small amounts of liquids to a substrate. The assembly includes a base plate with an array of apertures formed therethrough. Pins are disposed in the apertures. The pins and the apertures are dimensioned to permit sliding movement along the axis of the pins but to prevent wobbling movement. A weight plate is mounted over the pins to urge the pins into a fully seated position in the apertures. A transition cover is releasably engaged over the base plate. The cover includes a plurality of upwardly opening receptacles for releasable engagement with a pipette head. The pipette head can be employed with a robotic device for moving the pin tool assembly from a well plate or other liquid source to a selected destination for the liquid. The pin tool assembly then can be separated from the pipette head and discarded or recycled.

Abstract: A liquid sample handler guide support has a support plate fixedly mounted to the liquid sample handler sample probe support head, which support head is movable between sample aspirating positions, and which support plate has a hole, and a plastic cylindrical guide having a hole is mounted in the plate hole. The sample probe is slidably disposed in the guide during the liquid sample handler operations. A rinse cup is reciprocally movable to a probe rinse position below the guide for insertion of the probe tip for rinsing.

Abstract: To sample hot liquids containing volatile materials, the liquid is cooled in a refrigerator and pumped through a syringe needle into a container until the container overflows. The needle is removed slowly and the container is automatically closed as the needle is withdrawn, wherein liquid flows upwardly continuously as the needle is withdrawn through an opening. The cap for the container includes a closure having a valve opening extending upwardly and sized to narrowly receive the syringe needle in a perpendicular valve member opening. The valve member includes a flat member on one end adapted to be gripped by a cam follower for opening and closing of the valve opening in coordination with the movement of the syringe needle.

Abstract: The invention concerns a pipette comprising a body, an arm mobile relative to the body along a longitudinal direction to eject a tip fixed to the body and a push button controlling the movement of the arm. The pipette is designed such that the push button is mobile relative to the body in a plane perpendicular to the longitudinal direction by being able to take up any one particular position in a continuous range of positions in said plane and enabling to control the movement of the arm in said any particular position.

Abstract: A method comprises positively displacing a first candidate luminescence material precursor from a dispenser to a first position of an array, displacing a second candidate luminescence material precursor from a dispenser mechanism to a second position of an array and simultaneously reacting the first and second candidates to produce a library of luminescence materials. A combinatorial high throughput screening liquid dispenser assembly comprises a battery of positive displacement driven dispensers for dispensing solutions of precursor luminescence materials, an array plate with wells to receive dispensed solution from the dispenser, a robotic positioning table supporting the array plate to position wells beneath respective dispensers and a controller to control dispensing of the solutions and positioning of the plate.

Abstract: An automatic sample analyzer includes: a pipette, a pipette driving device which moves the pipette to a sample vessel present in a predetermined position to cause the pipette to suck up a sample from the sample vessel, and then moves the pipette to an open vessel provided in another predetermined position to cause the pipette to discharge the sample into the open vessel, and an analyzing section for analyzing the discharged sample, the pipette driving device comprising a vertically movable main arm and an elongated guide arm cantilevered by the main arm and extending horizontally, the guide arm having a smaller flexural rigidity than the main arm, wherein the main arm vertically moves the pipette when the sample is to be sucked up from the sample vessel, and the guide arm guides the pipette to the open vessel and then vertically moves the pipette when the sample is to be discharged into the open vessel.

Abstract: A sample tube of a sampling valve is moved up and down by a cylinder. When the sample tube is moved downward, a sample inlet opposes a stored sample, and the sample can be extracted. When the sample tube is moved upward, the sample inlet opposes a cleaning liquid path. Thus, cleaning liquid is fed into the cleaning liquid path from a cleaning liquid supply port of a cleaning pipe. The cleaning liquid flows within the sample tube from the sample inlet, and flows out from a sample discharge port. Thus, an entire interior of the sample tube can be cleaned. In a sample extracting device using the sampling valve, a state in which no air or impurities are mixed in the sample can always be maintained, such that stable extraction can be carried out.

Abstract: Devices and methods for integrated packaging, shipping, storage and precise dispensing of extremely small volumes of liquids such as aqueous solutions and compounds dissolved in organic solvents are disclosed. Devices of the invention include a sealed reservoir with an integrated metering tap. The tap includes a metering tube, which is translatable between a fill position inside the reservoir and an expel position outside the reservoir. The metering tube includes: (1) a tube end closure in a lower portion of the tube, (2) a port above the tube end closure, and (3) a piston in an upper portion of the tube. The piston is movable between a down position that seals the side port and an up position above the port. Movement of the piston from the up position to the down position can displace from 10 nanoliters to 20 microliters, e.g., from 20 nanoliters to 2 microliters, or 50 nanoliters to 500 nanoliters.

Abstract: An airbag cover is defined by a predetermined breaking line which is introduced into a shaped flat material in a recessed manner. The recesses are achieved by removing material by means of laser radiation. According to the invention, the flat material is provided with a barrier layer. The barrier layer, by reason of its material properties, has greater resistance to removal of material by laser action than the material of the rest of the flat material. The recesses made by removing material extend along the predetermined breaking line in the flat material up to the barrier layer. The barrier layer makes it possible to produce a predetermined breaking line by means of laser machining which allows an exact residual wall thickness of the airbag cover in the area of the predetermined breaking line, so that the tearing strength can be adjusted very accurately, which is critically important for a reliable deployment of an airbag.

Abstract: An apparatus for analysing liquid samples packed in tubes (6) closed with a top (7) capable of being perforated, includes a support (4) for the tubes and a unit (8) for sampling an aliquot from each tube and delivering it into a receptacle for treatment and/or analysis, the unit (8) including a hollow needle (45) connected to a suction/delivery device and vertically mobile; the support (4) has a circular tray provided with several tube-holders (5) on its periphery and capable of rotating about a vertical axis to bring a position successively and selectively the tubes (6) borne by the tube-holders (5) in line with the unit (8); each tube-holder (5) is connected to the tray (4) through a linkage (31) with two degrees of freedom.

Abstract: Apparatus and a method for mixing a liquid within a disposable aspirating probe tip so that most of the liquid is forced to move past a transition zone between two different inside diameters to cause rotational mixing. The apparatus and method can be used to provide agglutination of blood, which in turn can be used for blood typing. The probe tip can comprise a single integral piece, or two separate portions. The transition zone can comprise a sharp demarcation between inside diameters, or a smooth one.

Abstract: Devices and methods for integrated packaging, shipping, storage and precise dispensing of extremely small volumes of liquids such as aqueous solutions and compounds dissolved in organic solvents are disclosed. Devices of the invention include a sealed reservoir with an integrated metering tap. The tap includes a metering tube, which is translatable between a fill position inside the reservoir and an expel position outside the reservoir. The metering tube includes: (1) a tube end closure in a lower portion of the tube, (2) a port above the tube end closure, and (3) a piston in an upper portion of the tube. The piston is movable between a down position that seals the side port and an up position above the port. Movement of the piston from the up position to the down position can displace from 10 nanoliters to 20 microliters, e.g., from 20 nanoliters to 2 microliters, or 50 nanoliters to 500 nanoliters.

Abstract: The drop-by-drop evaporation of a liquid or solution is controlled by monitoring the disappearance of each successive droplet and by actuating the deposition of the next droplet until the desired volume is deposited. In the case of a solution, non-volatile residue (NVR) is collected on a deposition surface plate as a relatively small mound. One of a variety of methods may be employed to measure the evaporative behavior of each droplet and to key the deposition procedure. The process is preferably carried out employing a clean deposition surface plate that is maintained at or below the boiling point of the particular liquid or solvent being deposited. The environment is preferably controlled so that inadvertent contamination is precluded from interfering, and thus the method permits the automatic, micro-processor controlled evaporation of liquids with the resultant deposition of non-volatile residues from solutions within relatively short periods of time.

Abstract: Several pin transfer assemblies are disclosed that utilize the surface tension of liquids for picking up and dispensing minute volumes of liquid from wells in a first well plate to a flat substrate surface or into wells in a second well plate. In one embodiment, a plurality of pins reciprocate through complementary arrays of holes in a base plate and an overlying spring plate biased apart by coil springs located around the periphery of the base plate. A foam layer sits on top of the spring plate and a weight plate sits on top of the foam layer. A single coil spring is positioned between a center of the weight plate and the cover to push the weight plate downwardly. The periphery of the cover guides the vertical movement of the weight plate and is connected to the periphery of the base plate. The periphery of the base plate is supported by a frame used to register the pin assembly in a receptacle of a manual or automated liquid transfer apparatus.

Abstract: A pathology distribution system 10 is provided for automated sample container 14, 15 distribution. The system 10 comprises a loading station 500 for loading samples in primary containers 14 of different types, a sample handling station 16 for receiving the containers 14 and identifying the container types and samples therein, and a container distribution station 38 for distributing the containers in areas or racks in the distribution station 38 marked for analyzing processes prescribed for the samples therein.

Abstract: A pin replicator is disclosed for dispensing minute volumes of liquid onto a substrate surface in an array in connection with drug discovery, diagnostic analysis, and other applications. The pin replicator comprises a base plate, a plurality of pins reciprocable through corresponding holes in the base plate, and a free floating weight plate resting on top of the upper ends of the pins. The weight plate biases the pins toward their fully extended lowered positions. A cover attaches to the base plate, encloses the pins and weight plate and guides the weight plate during vertical movement thereof. The pin replicator can be moved downwardly toward a first micro titer plate so that a lower end of each of the pins contacts the sample liquid in the corresponding well a sufficient amount to pick up and retain a small quantity of the sample liquid due to surface tension.

Abstract: After attaching a disposable pipette tip to an end of pipetting probe, which is held by a movable holder, humidity in the pipette tip is increased before a pipetting operation of a sample or a reagent. The pipette tip is transferred to a high humid chamber provided with a warmer, and high humid air is introduced into the pipette tip. Subsequently, the pipetting operation of the sample or the reagent is performed. Accordingly, an exact amount of the sample or the reagent can be supplied to a reaction vessel.

Abstract: A method and apparatus for dispensing precise quantities of reagents is disclosed including a positive displacement syringe pump in series with a dispenser, such as an aerosol dispenser or solenoid valve dispenser. The pump is controlled by a stepper motor or the like to provide an incremental quantity or continuous flow of reagent to the dispenser. The pump and dispenser are operated in cooperation with one another such that the quantity and/or flow rate of liquid dispensed by the dispenser can be precisely metered substantially independently of the particular operating parameters of said dispenser to attain a desired flow rate, droplet size or mist quality, droplet frequency and/or droplet velocity.