Abstract: A method and system for detecting chemical or biological hazards in items is provided. An incoming mail mailbox includes a sampler to sample air from a letter that is tested using a first sensor and then placed in a receptacle having an environment that is tested using a second sensor.

Abstract: The present invention relates to a method for determining at least one parameter of samples of physiological liquids, to test devices which may be used in the method, to a holder comprising a plurality of such test devices, and to a measuring apparatus adapted to accommodate the holder and to be used in the method and to a system comprising the apparatus and the holder.

Abstract: An automated analyzer device has a main conveyance line capable of conveying a sample rack holding a sample, a plurality of analysis units arranged along the main conveyance line, a rack supplying device for supplying the sample rack to the main conveyance line and a rack housing device for housing the sample rack conveyed by the main conveyance line. The automated analyzer includes a controller for confirming that there is no sample rack on the main conveyance line before the main conveyance line receives the sample rack from the rack supplying device. The controller controls operation of the main conveyance line so as to convey the sample rack received from the rack supplying device by the main conveyance line to a position corresponding to a specific one of the plurality of analysis units by which the sample rack is to be received without stopping.

Abstract: This invention relates to an automated device for loading a centrifuge where tubes are presented to the centrifuge via an automated routing system.

Abstract: This invention relates to an automated device for loading a centrifuge where tubes are presented to the centrifuge via an automated routing system.

Abstract: An automated slide stainer with fluid flow control. The fluid flow control controls the flow rate of fluid, e.g., water, applied to at least one slide by the slide stainer. In an automated slide stainer that applies reagents to slides to stain biological specimens on the slides, the flow rate controlled fluid can be used to adequately rinse the slides without damaging the biological specimens contained on the slides.

Abstract: A method for handling specific sample solutions for calibration and quality control by an automatic analytical apparatus in which a sample rack to hold calibrator bottles for required analysis items is set on a rack supply unit by an operator. Identification information of all calibrator bottles on the rack is read out, and data on corresponding calibrator samples are also stored. The operator enters analysis items to be measured, and a measuring channel to be used for calibration. Comparison is made between the planned number of requested calibrations and the number of permissible services to determine whether or not calibrator solution is sufficient. If it is determined to be insufficient, the required number of bottles are displayed according to the difference between the number of permissible services and the number of requests, thereby allowing the operator to add the required number of calibrator bottles.

Abstract: A device for detecting chemiluminescence from a sample. The device may include a stage for supporting a sample and one or more of the following elements: (1) an optics head, (2) an optical relay structure for transmitting chemiluminescence from the sample to a detector, (3) a drive mechanism, (4) a sensor for detecting proximity of the optical relay structure to the sample, (5) a mask structure for selecting an effective diameter of the optical relay structure, and (6) a baffle for blocking extraneous light from entering the optical relay structure.

Abstract: An automated system for preparing a plurality of cytological specimens from a plurality of fluid samples in vials includes an apparatus for collecting a monolayer of cells from each sample and transferring the cells to a microscope slide for fixing, staining, and inspection. The system includes a first loading station for receiving the sample vials, a second loading station for receiving consumables such as filter membranes, a slide dispenser, and an unloading area for removing completed specimen slides. To maintain one-to-one correlation between the samples and specimens produced therefrom, the system includes a subsystem for identifying each sample and permanently marking each slide with corresponding indicia prior to transferring the specimen thereto.

Abstract: An automated system for preparing a plurality of cytological specimens from a plurality of fluid samples in vials includes an apparatus for collecting a monolayer of cells from each sample and transferring the cells to a microscope slide for fixing, staining, and inspection. The system includes a first loading station for receiving the sample vials, a second loading station for receiving consumables such as filter membranes, a slide dispenser, and an unloading area for removing completed specimen slides. To maintain one-to-one correlation between the samples and specimens produced therefrom, the system includes a subsystem for identifying each sample and permanently marking each slide with corresponding indicia prior to transferring the specimen thereto.

Abstract: The embodiments disclosed relate to determination of an item of interest in a sample. One embodiment relates to a structure which comprises a process path. The process path comprises a process lane including a process step performance lane where a process step is performed, and a process step avoidance lane where the process step is avoided. A first prime mover is operatively connected with the process path for moving a container holding the sample along the process path. A first pipetting system is operatively associated with the process path for introducing the sample to the container. A second pipetting system is operatively associated with the process path for introducing a reagent to the container. A device is operatively connected with the process path and is selectively engagable with the container for mixing the sample and the reagent in the container.

Abstract: A system for preparing a profiling sample is provided. The system comprises a profiling sample, a plurality of vessels, a plate defining a plurality of receptacles corresponding to, and configured to receive, the plurality of vessels, a dispensing unit for dispensing the profiling sample, and a weighing device. The plurality of receptacles are arranged according to a coordinate system. The dispensing unit has a robotic device in communication therewith, wherein the robotic device is configured to operably engage the plate so as to dispense a portion of the profiling sample into a selected vessel. The weighing device has a robotic device in communication therewith, wherein the robotic device is capable of operably engaging the selected vessel, removing the vessel from the corresponding receptacle and into operable engagement with the weighing device to perform a tare measurement of the vessel, and then replacing the vessel in the corresponding receptacle.

Abstract: A sample archive method and system implement a plurality of sample carriers configured to support a plurality of sample nodes in a predetermined spatial relationship, sample storage devices for selectively placing the plurality of sample carriers in an archive, and sample node removal apparatus for locating and removing selected ones of the plurality of sample nodes. Alternative embodiments are disclosed wherein the sample node removal apparatus comprises a laser and a mechanical clipping tool, which may be manually operated or automated. An optical component may be operative to detect the location of selected sample carriers in the archive, selected ones of the plurality of sample nodes, or both. A positioning component may position the sample node removal apparatus responsive to signals transmitted by the optical component. Various apparatus and methods of archiving samples and preparing the same for analysis are also disclosed.

Abstract: A sample handling method, in which the information on the sample to be examined is transferred throughout the entire measuring process by transferring the sample cup. The sample cups are handled in two independently operating drums, in which case at least two different handling phases can be carried out simultaneously in the measuring device. The diagnostic measuring device comprises a cassette drum, on the circumference of which the sample cup cassettes containing sample cups have been placed. The sample cup is fed to the first handling drum, which is simultaneously an incubation drum. After that the sample cup is transferred to a second handling drum, where washing, drying, measuring and discharge of the sample cup are carried out. The drums have been placed near each other, overlapping so that the transfers of the sample cup can be performed directly from one drum to another by means of transfer plungers.

Abstract: A clinical analyzer where incoming samples are partitioned into groups in accord with the length of time required for the assay to be completed or in accord with the pattern of reagent addition(s) taken with length of time required for the assay to be completed. Medium length time assays are completed, removed from a reaction carousel and replaced by shorter length time assays during a single operational cycle in which longer length assays are also completed.

Abstract: Apparatus for handling biological sample containers comprises a conveyor assembly for conveying containers and a lid handling assembly operable to remove lids from and replace lids onto containers while the containers are in motion on the conveyor assembly. The lid handling assembly comprises a pair of ramps onto which a lid is lifted by a lifting mechanism configured to handle overhanging lids or non-overhanging lids as required. The lid handling assembly may be configured to handle lids of containers of various sizes by altering the ramp spacing. A conveyor assembly comprises a pair of converging rails which carry a pair of jaws operable to carry a container. The convergence of the rails makes the jaws clamp the container so that it is held tightly in position for micro-arraying to be carried out. The conveyor assembly may be adapted to handle different sizes of container by the provision of holders to hold various container types.

Abstract: Apparatus for handling biological sample containers comprises a conveyor assembly for conveying containers and a lid handing assembly operable to remove lids from and replace lids onto containers while the containers are in motion on the conveyor assembly. The lid handling assembly comprises a pair of ramps onto which a lid is lifted by a lifting mechanism configured to handle overhanging lids or non-overhanging lids as required. The lid handling assembly may be configured to handle lids of containers of various sizes by altering the ramp spacing. A conveyor assembly comprises a pair of converging rails which carry a pair of jaws operable to carry a container. The convergence of the rails rakes the jaws clamp the container so that it is held tightly in position for micro-arraying to be cared out. The conveyor assembly may be adapted to handle different sizes of container by the provision of holders to hold various container types.

Abstract: Array based fluid is stored in through holes that extend through a substrate. Combined capillary and hydrophyllic forces are used to retain the fluid and also transfer it to other substrates of similar type. In another embodiment vacuum and pressure forces are used to introduce the fluid and remove the fluid from the known through holes and transfer the remaining fluid to other substrates. In yet another embodiment, electrokinetic forces are used to retain and move the fluids across the substrates via the through holes. The substrates are aligned and the fluids are transferred or mixed based on the above techniques.

Abstract: A method and a device for removing an analytic consumable product, in particular a test element, from a storage container having chambers which are sealed by foils from which the consumable product is pushed out by means of a plunger (7) can be optimized in that the magnitude of the thrusting force exercised by the plunger (7) during its forward motion can be controlled in dependence on the plunger (7) position.

Abstract: One method and apparatus for analyzing clotting characteristics of a blood sample includes the use of a non-linear equation having coefficients capable of being related to the underlying clotting processes. The non-linear equation is curve fit to a waveform of a clotting sample to provide values for the coefficients of the non-linear function. Once the coefficients are obtained, an inference engine may be used to evaluate the non-linear relationship between the coefficients and factor concentrations within the blood sample. Advantageously, the waveform of the actual sample may be detrended to extract a residual oscillatory component to aid in the determination of initial coefficients for simplifying the curve fit operation. The non-linear equation may additionally be used for providing simulated clotting waveforms for testing clot analysis instruments. A residual oscillatory component may advantageously be extracted from the clotting signal.

Abstract: An automatic analyzer system including transport means for moving sample racks within the system. In order to simplify and reduce the cost of the means for transporting the sample racks the system comprises (a) a rack supply unit capable of containing sample racks, said rack supply unit including (a.1) a rack input device for introducing sample racks into the rack supply unit, (a.2) a rack output device for removing sample racks from the rack supply unit, (a.3) a buffer unit for storing unprocessed racks before they are transferred from said rack supply unit to a position corresponding to an analyzer unit, and for storing also already processed racks which contain samples having a probability of being reexamined, and (a.

Abstract: An automatic analysis system that, even if one module out of a plurality of analysis modules becomes analysis-incapable, allows the analysis to be continued without stopping the entire system. The automatic analysis system has a plurality of analysis modules 5, 6, 7, and 8, and a transferring line 3 for transferring specimens to these analysis modules. During the analysis operation by the entire system, each analysis module is controllable as a standby state, namely, as a single-body analysis module in a state of being independent and being cut off from the control of the entire system.

Abstract: An automated workstation capable of continuous, non-stop processing of specimens includes an environmentally controlled storage area that holds multiple cassettes containing specimen plates. A robotic arm for processing the specimens, e.g., by grasping the plates, moving them from the cassettes to other apparatus contained within the workstation, and placing the plates back in the cassettes. An interlock mechanism prevents the operator and robotic arm from simultaneously accessing a cassette. Novel robotic arms, robotic arm positioning mechanisms, plate handling mechanisms, effector tip/plate washing mechanisms, thin-walled pipetters, back-flushing mechanisms and fluid level detection mechanisms, as well as methods for operating the same, facilitate continuous operation of the workstation along with compactness, high throughput and high accuracy of operation. Narrow, thin-walled capillary-like pipetters serve as both means for acquiring and processing small quantity specimens with high precision.

Abstract: A method and a device for removing an analytic consumable product, in particular a test element, from a storage container having chambers which are sealed by foils from which the consumable product is pushed out by means of a plunger (7) can be optimized in that the magnitude of the thrusting force exercised by the plunger (7) during its forward motion can be controlled in dependence on the plunger (7) position.

Abstract: An apparatus for in-situ injection of one or more chemical components into a reaction chamber, comprising a reaction chamber for receiving one or more libraries including two or more samples; an injection module in fluid communication with the reaction chamber for permitting in-situ injection of one or more chemical components into the reaction chamber; and a selectively movable transport assembly supported by at least a portion of the reaction chamber for transporting the one or more libraries to the injection module.

Abstract: An analyzer for performing automated assay testing. The analyzer includes a storage and conveyor system for conveying cuvettes to an incubation or processing conveyor, a storage and selection system for test sample containers, a storage and selection system for reagent containers, sample and reagent aspirating and dispensing probes, a separation system for separating bound from unbound tracer or labeled reagent, a detection system and date collection/processing system. All of the subunits of the machine are controlled by a central processing unit to coordinate the activity of all of the subunits of the analyzer. The analyzer is specifically suited for performing heterogeneous binding assay protocols, particularly immunoassays.

Abstract: An automated fluid handling system configured to prepare fluid samples and to introduce them into an analytical instrument, such as a particle analyzer, flow cytometer or sorter flow cell, and that is capable of analyzing both accurately and quickly.

Abstract: A method for feeding containers into an analytical instrument whereby a sample handler moves and positions racks, containing sample tubes, into, within and out of the analytical instrument. The sample handler has an in-feed and out-feed that advance sample tube racks using a walking beam mechanism. The racks are seated within the in-feed and are transported onto a cross-feed. The cross-feed moves the racks to a position behind the out-feed where the walking beam mechanism moves the tube racks out of the analytical instrument.

Abstract: A highly automated, high volume multichannel pipetting system which transfers liquid from mother plates to daughter plates, or from a fill station to daughter plates. The mother plates are stacked in one set of stacker assemblies, while the empty daughter plates are stacked in another stacker assembly. A plate handling assembly which is capable of moving the plates in three orthogonal directions retrieves the plates from the stacker assemblies, carries them to the pipetting head, and returns them to other stacker assemblies. The pipetting head is removable for replacement or repair thereof, or for insertion of another head assembly having a different number of pipetting channels. The head slides into the housing on slideways, and is retained in place by manually operable, threaded knobs mounted on shafts. The stacker assemblies include a chimney which is removable from a base. The plates may be stacked in the chimney and then inserted on the base.

Abstract: Disclosed herein is a diagnostic instrument for analyzing liquid samples. The diagnostic instrument in accordance with this invention includes a sample carousel and a diagnostic carousel. The sample carousel includes at least one sample tube and in the exemplary embodiment a plurality of sample tubes, each having unique identifying indicia readable by a machine reader. The sample tube capable of storing the liquid sample to be analyzed. The diagnostic carousel including at least one pipette capable of storing liquid sample to be analyzed. There are matching number of pipettes to sample tubes and each having matching unique identifying indicia which is matched with the appropriate sample tube. The diagnostic carousel being offset from the sample carousel and lying in a different plane from the sample carousel. Each pipette including a transfer mechanism for transferring sample from the sample tube directly to the pipette.

Abstract: A method and a device for removing an analytic consumable product, in particular a test element, from a storage container having chambers which are sealed by foils from which the consumable product is pushed out by means of a plunger (7) can be optimized in that the magnitude of the thrusting force exercised by the plunger (7) during its forward motion can be controlled in dependence on the plunger (7) position.

Abstract: Substances having useful pharmacological properties are identified by candidate screeners and screening methods. The substances may be incorporated into medicaments. The substances may have modulating activity with respect to pre-defined molecular targets.

Abstract: The present invention provides for systems and methods that utilize automated and integratable workstations for identifying chemicals having useful activity. The present invention is also directed to chemical entities and information (e.g., chemical or biological activities of chemicals) generated or discovered by operation of workstations of the present invention. The present invention includes automated workstations that are programmably controlled to minimize processing times at each workstation and that can be integrated to minimize the processing time of the liquid samples from the start to finish of the process.

Abstract: A system and method for positioning a sample, or cargo, with respect to a device in a robotic system is provided. The system includes a macro positioning system for “gross” movement of the sample between stations and a micro positioning system for precisely locating the sample in a predetermined location at a station with respect to a device that will interact with the sample. The macro positioning system provides a positioning mechanism for the general movement of a sample along a pathway between various destinations or stations wherein the sample is “grossly” positioned with respect to the station. Once at the station, the micro positioning subsystem disposed between a sample carrier and the station provides a positioning mechanism for “precisely” positioning the sample in a predetermined location at the station with respect to a device that will interact with, or perform some function on, the sample.

Abstract: An analyzer comprises a conveyor which conveys sample cups and reaction cups intermixedly on a closed track, a reactor which maintains reaction cups at a predetermined temperature, a trashbin which collects used reaction cups, a nozzle unit, a reaction cup lift which carries a reaction cup between the conveyor, the reactor and the trashbin and a drive unit which drives the nozzle unit and the reaction cup lift to reciprocate, wherein the trashbin is placed on the straight track of the reaction cup lift, at least part of the closed track of the conveyor is straight and overlaps the straight track of the nozzle unit and the reaction cup lift, and the straight part of the track of the conveyor accommodates at least two cups.

Abstract: A workstation has a transfer device with a gripper which is suitable for gripping sample tubes by a gripper clamp and for moving them from a sample tube rack to a sample tube bucket, for example for centrifuging. The transfer device has a receiving device (23) which can be gripped on a cylindrical upper handling part (25) by the gripper and removed from a holder (24) in which it has been placed in a defined position. It has an intermediate part (33) with, on its lower end, four hooks (37) which are arranged at the apices of a rectangle and can engage eyes in the sample tube buckets. After use, the receiving device (23) is replaced in the holder (24).

Abstract: Embodiments of the invention are directed to microfluidic devices. In one embodiment, a microanalysis chip comprises a body having at least one transfer-separation channel with a channel bottom that has a bottom opening. The transfer-separation channel terminates in a discharge aperture.

Abstract: A method of performing a determination of an item of interest in a sample using a single structure is disclosed. A sample is provided accessible to the single structure. A first container for processing the sample is placed in a first process path on the single structure. The sample is transferred to the first container in the first process path. A reagent is added to the first container in the first process path. Contents of the first container is mixed in the first process path. The item of interest in the sample is separated from the contents of the first container in the first process path. The separated item of interest in the sample is transferred from the first container in the first process path to a second container in a second process path on the single structure. Contents of the second container is brought to a first temperature different from a temperature of the first process path in the second process path. The item of interest in the second container is detected in the second process path.

Abstract: An analyzer which comprises a conveyer which conveys sample cups and reaction cups intermixedly on a closed track, a reactor which maintains reaction cups at a predetermined temperature, a trashbin which collects used reaction cups, a nozzle unit, a reaction cup lift which carries a reaction cup between the conveyer, the reactor and the trashbin and a drive unit which drives the nozzle unit and the reaction cup lift to reciprocate, wherein the trashbin is placed on the straight track of the reaction cup lift, at least part of the closed track of the conveyer is straight and overlaps the straight track of the nozzle unit and the reaction cup lift, and the straight part of the track of the conveyer accommodates at least two cups.

Abstract: An analysis system which permits sample pretreatment which comprises: a sample rack; a sample container supply, a sample dispenser, a solvent-removing evaporator, a solvent dispenser for dispensing a second solvent, a sample-stirring means, a sample aspirating-and-transferring means, a sample recovery means, a sample container recovery means, and a control means for controlling the aforementioned various means.

Abstract: A method whereby a sample handler moves and positions racks, containing sample tubes, in an analytical instrument. The sample handler has an in-feed and out-feed that advance sample tube racks using a walking beam mechanism. The racks are seated within the in-feed and are transported onto a cross-feed. The racks and tubes contained thereon are moved past detection devices that identify the samples and measure various properties thereof. Thereafter, the cross-feed moves the racks to a position behind the out-feed where the walking beam mechanism moves the tube racks out of the analytical instrument.

Abstract: Waiting areas for allowing a plurality of sample racks to stop and wait are provided on by-pass line in each analysis unit. Sample racks introduced from ordinary sample inlet section or emergency sample inlet section, after waiting in the waiting area, are subjected to sample pipette operation by sample pipetting device. In the ordinary mode corresponding to ordinary sample processing, all of the stop positions of the waiting areas can be utilized, however, in the emergency mode corresponding to emergency sample processing, at least one or more of the stop positions of the waiting areas is prohibited to be used so as for the sample rack coming in to skip the stop position prohibited to be used.

Abstract: A method and system for picking and placing vessels are provided. The system includes a gripper assembly mounted on a positioning mechanism. The gripper assembly includes a cylinder, a plurality of flexible gripping members extending from the cylinder in a spaced-apart relationship for receiving therebetween a vessel and holding it by friction, a piston slideably inserted inside the cylinder, and a plunger connected to and movable with the piston and extending between the gripping members for engaging the vessel. The method includes the steps of positioning the gripper assembly, picking up and transferring a vessel, and placing, seating and releasing the vessel. The contents of the vessel may also be mixed simultaneously during the transferring of the vessel.

Abstract: A method whereby a sample handler moves and positions racks, containing sample tubes, in an analytical instrument. The sample handler has an in-feed and out-feed that advance sample tube racks using a walking beam mechanism. The racks are seated within the in-feed and are transported onto a cross-feed. The racks and tubes contained thereon are moved past detection devices that identify the samples and measure various properties thereof. Thereafter, the cross-feed moves the racks to a position behind the out-feed where the walking beam mechanism moves the tube racks out of the analytical instrument.

Abstract: A modular vial autosampler has a storage area for vials containing samples to be analyzed and at least one modular sampling station. A vial transfer mechanism includes an arm having a gripper that lifts a sample vial from the storage section, and the arm moves it to a station for identification and then to a sampling station, and under central control activates the sampling station for obtaining a sample for analysis. The vial transfer mechanism gripper is movable in X, Y, and Z directions to capture and move a selected vial and includes an alignment guide for the vials. Potentiometers are used for providing signals indicating arm position and the control is provided with updated information for calibration of the potentiometers and also updated position information for the arm relative to a fixed home position is obtained.

Abstract: A method for treating objects, in particular cytological or histological specimens, for example in an automatic stainer, the objects being delivered, preferably on object carriers and in object carrier magazines, by means of a transport device to various processing stations, inserted therein, and treated in accordance with a selectable treatment program, is characterized by automatic monitoring of the processing stations, in particular of the reagents, definable parameters being taken into consideration in the monitoring.

Abstract: A method for treating objects, in particular cytological or histological specimens, for example in an automatic stainer, the objects being delivered, preferably on object carriers and in object carrier magazines, by means of a transport device to various processing stations, inserted therein, and treated in accordance with a selectable or a definable or programmable treatment program, is characterized by unequivocal allocation of the object carriers or object carrier magazines, or clips or labeling fields to be attached thereon, to specific treatment programs.

Abstract: Briefly, the present invention provides a system and method for high throughput processing using sample holders. The system has a plurality of work perimeters, with a rotational robot preferably associated with each work perimeter. At least one transfer station area is provided between adjacent work perimeters to facilitate robotic transfer of sample holders from one work perimeter to another area. Each work perimeter typically includes a plurality of defined station locations, with each station location positioned to be accessible by the robot associated with that area. In addition, each station location is typically configured to receive a device, such as an automated instrument or a holding nest. Device components are arranged at selected station locations according to specific application requirements to provide a flexible, robust, reliable, and accurate high throughput processing system.

Abstract: A method of performing a determination of an item of interest in a sample using a single structure is disclosed. A sample is provided accessible to the single structure. A first container for processing the sample is placed in a first process path on the single structure. The sample is transferred to the first container in the first process path. A reagent is added to the first container in the first process path. Contents of the first container is mixed in the first process path. The item of interest in the sample is separated from the contents of the first container in the first process path. The separated item of interest in the sample is transferred from the first container in the first process path to a second container in a second process path on the single structure. Contents of the second container is brought to a first temperature different from a temperature of the first process path in the second process path. The item of interest in the second container is detected in the second process path.

Abstract: According to the present invention, there is provided an automatic chemical analyzer which is capable of conducting investigation of the influence of contamination regardless of the knowledge or technical skill of the user, and can prevent the occurrence of errors of determination by letting the user know that a problem has arisen in the function of inhibiting the generation of contamination.