Abstract: The machine is configured to perform an automated rapid plasma reagent (RPR) agglutination test or other agglutination test. The machine includes a sample rack with multiple sample locations thereon and a reagent rack for storing of reagent. A shaker assembly supports at least one microtiter plate or other well supporting structure thereon with a plurality of wells in the plate. An automated pipette accesses samples and reagent and deposits them within wells of the microtiter plate. The shaker assembly shakes multiple samples within the wells of the microtiter plate. Finally, a camera photographs the wells of the plate, preferably from above with a light source below and the plate at least partially transparent. The image is then analyzed in an automated fashion to determine whether a ring of contrast material has remained smooth indicative of a non-reactive sample or has agglutinated/clumped together indicative of a reactive sample.

Abstract: The machine is configured to perform an automated rapid plasma reagent (RPR) agglutination test or other agglutination test. The machine includes a sample rack with multiple sample locations thereon and a reagent rack for storing of reagent. A shaker assembly supports at least one microtiter plate or other well supporting structure thereon with a plurality of wells in the plate. An automated pipette accesses samples and reagent and deposits them within wells of the microtiter plate. The shaker assembly shakes multiple samples within the wells of the microtiter plate. Finally, a camera photographs the wells of the plate, preferably from above with a light source below and the plate at least partially transparent. The image is then analyzed in an automated fashion to determine whether a ring of contrast material has remained smooth indicative of a non-reactive sample or has agglutinated/clumped together indicative of a reactive sample.

Abstract: Light emitting diodes (LEDs) are mounted in an array to an upper structure overlying a lower structure with a plurality of light detectors thereon. Each LED is configured to overlie a separate detector. Each LED emits light at a frequency relevant for measuring optical density of a specimen. LEDs having different frequencies are included within the LED array. A corresponding array of detectors is also provided, mounted to the lower structure. Spacing between adjacent LEDs and between adjacent detectors match a spacing between wells in a microtiter plate. Spacing between the lower structure and the upper structure supporting the LEDs is sufficient for the microtiter plate to fit between. Circuitry sequentially fires individual LEDs and gathers optical density data through the detectors for specimens in the wells of the microtiter plate. The structures are then moved to a next adjacent well position on the microtiter plate and the process repeated.

Abstract: The machine is configured to perform an automated rapid plasma reagent (RPR) agglutination test or other agglutination test. The machine includes a sample rack with multiple sample locations thereon and a reagent rack for storing of reagent. A shaker assembly supports at least one microtiter plate or other well supporting structure thereon with a plurality of wells in the plate. An automated syringe or other aspirator and dispenser accesses samples and reagent and deposits them within wells of the microtiter plate. The shaker assembly shakes multiple samples within the wells of the microtiter plate according to the RPR or other agglutination test. Finally, a camera photographs the wells of the plate, preferably from above with a light source below and the plate at least partially transparent, to evaluate whether the specimen is reactive or non-reactive. Test results and photographic evidence of the test results are preferably archived within a database.

Abstract: The automated reader operates within an enclosure also containing a sample rack and reagent rack, as well as a microtiter plate with multiple wells therein. The machine automatically loads sample and reagent into a well of the microtiter plate according to a testing protocol. The specimen can then be moved along with the microtiter plate into a slot of the reader and aligned with either a light source and detector for an optical density read or aligned with a photon counter for a chemiluminescence read. The reader includes a shroud assembly which can be raised and lowered by a lift assembly to occlude a read point from photons other than those emanating from the sample.

Abstract: Light emitting diodes (LEDs) are mounted in an array to an upper structure overlying a lower structure with a plurality of light detectors thereon. Each LED is configured to overlie a separate detector. Each LED emits light at a frequency relevant for measuring optical density of a specimen. LEDs having different frequencies are included within the LED array. A corresponding array of detectors is also provided, mounted to the lower structure. Spacing between adjacent LEDs and between adjacent detectors match a spacing between wells in a microtiter plate. Spacing between the lower structure and the upper structure supporting the LEDs is sufficient for the microtiter plate to fit between. Circuitry sequentially fires individual LEDs and gathers optical density data through the detectors for specimens in the wells of the microtiter plate. The structures are then moved to a next adjacent well position on the microtiter plate and the process repeated.

Abstract: An intelligent rack automatically detects the position of a specimen tube within a multiple specimen tube containing rack such as that utilized within automatic specimen processing apparatuses. The rack has a plurality of positions with a moving element located adjacent each position. The moving element, such as a spring, is positioned so that it moves when a specimen tube is placed within an adjacent position. A magnet or other sensor on the moving element interacts with a detector to sense when a particular position has received a specimen tube. A computer controlling the apparatus receives specimen information for each specimen tube and has an identifier for the specimen tube, such as a bar code, scanned into the computer before placement of the specimen tube into a rack position. Removal of the specimen tube from a position on the rack causes correlating removal of specimen tube position information from the computer.

Abstract: A device is disclosed, being an analysis device for the study of biological or chemical samples by means of a reagent liquid supplied via a pipette. The device has an instrument housing with a base plate, a working plate arranged on the base plate horizontally to receive the samples in a sample holder having several wells, a robot manipulator arranged above the working plate, which carries a horizontal support arm with a slide. A needle system is fastened to the slide and can move in the Z direction, carrying 3 needles and being brought into vertical positions by a first vertical drive. The needle tips can be placed in an upper position above and in a lower position below a well. The middle needle can move vertically relative to the other two needles, which can be raised and lowered by a second vertical drive. The horizontal spacing of the three needles is so small that all three needles can be positioned with their tips inside the same wells.

Abstract: A device is disclosed, being an analysis device for the study of biological or chemical samples by means of a reagent liquid supplied via a pipette. The device has an instrument housing with a base plate, a working plate arranged on the base plate horizontally to receive the samples in a sample holder having several wells, a robot manipulator arranged above the working plate, which carries a horizontal support arm with a slide. A needle system is fastened to the slide and can move in the Z direction, carrying 3 needles and being brought into vertical positions by a first vertical drive. The needle tips can be placed in an upper position above and in a lower position below a well. The middle needle can move vertically relative to the other two needles, which can be raised and lowered by a second vertical drive. The horizontal spacing of the three needles is so small that all three needles can be positioned with their tips inside the same wells.

Abstract: A method and system for accurate aspiration and dispensing of fluids and comprising in combination a volumetric pump, a motor, a motor driver, an encoder (device used to measure angular displacements) and a computing unit.

Abstract: An incubator is provided wherein the individual wells of a Micro Titer Plate are heated by means of a continuous temperature regulated flow of warm air (typically 37.degree. C.) blowing through a series of holes from a plate underneath onto the bottom of the wells. A typical Micro Titer Plate can have 96 wells and is used, for example, in medical laboratories. The volume of a well is typically 0.35 milliliter. Both the end temperature and the way the end temperature is reached is the same for all individual wells and is not dependent on either the location of the well on the Micro Titer Plate or its surrounding by other wells.