Abstract: Methods and apparatus configured and adapted to provide less carryover in an automated clinical analyzer are disclosed. The methods include aspirating a scavenger segment (e.g., a buffer- and surfactant-containing segment) into the interior of a pipette along with the specimen or reagent. The scavenger film aids in preventing adherence of the specimen or reagent to the interior of the pipette. Apparatus configured to carry out the methods are provided, as are other aspects.

Abstract: Methods and apparatus configured and adapted to provide less carryover in an automated clinical analyzer are disclosed. The methods include immersing a pipette into a neutralizing liquid vessel and aspirating a neutralizing liquid (e.g., a hypochlorite solution) into an interior of a pipette. The aspirated portion of the neutralizing liquid used to cleanse the pipette interior is then dispensed back into the neutralizing liquid vessel, rather than disposing of the used neutralizing liquid to a waste station. Apparatus and systems configured to carry out the methods are provided, as are other aspects.

Abstract: Methods and apparatus configured and adapted to provide less carryover in an automated clinical analyzer are disclosed. The methods include aspirating a scavenger segment (e.g., a buffer- and surfactant-containing segment) into the interior of a pipette along with the specimen or reagent. The scavenger film aids in preventing adherence of the specimen or reagent to the interior of the pipette. Apparatus configured to carry out the methods are provided, as are other aspects.

Abstract: Methods and apparatus configured and adapted to provide less carryover in an automated clinical analyzer are disclosed. The methods include immersing a pipette into a neutralizing liquid vessel and aspirating a neutralizing liquid (e.g., a hypochlorite solution) into an interior of a pipette. The aspirated portion of the neutralizing liquid used to cleanse the pipette interior is then dispensed back into the neutralizing liquid vessel, rather than disposing of the used neutralizing liquid to a waste station. Apparatus and systems configured to carry out the methods are provided, as are other aspects.

Abstract: A fingerprint sensor may include a plurality of electrostatic discharge (ESD) electrodes carried by a dielectric layer of a fingerprint sensing portion. The fingerprint sensing portion is for sensing a fingerprint of a user. The fingerprint sensing portion may include the dielectric layer, and, in some embodiments, may also include an array of sensing electrodes also carried by the dielectric layer. Accordingly, each ESD electrode may be interposed between adjacent sensing electrodes. The ESD electrodes attract ESD events and dissipate the energy therein to avoid damaging adjacent sensing electrodes and/or portions of the dielectric layer. The fingerprint sensor may also include an electrically conductive layer connected to the ESD electrodes, which may provide a convenient ground plane, for example, for removing ESD energy from the fingerprint sensor. The electrically conductive layer may extend beneath the sensing electrodes.

Abstract: A fingerprint sensor may include a plurality of electrostatic discharge (ESD) electrodes carried by a dielectric layer of a fingerprint sensing portion. The fingerprint sensing portion is for sensing a fingerprint of a user. The fingerprint sensing portion may include the dielectric layer, and, in some embodiments, may also include an array of sensing electrodes also carried by the dielectric layer. Accordingly, each ESD electrode may be interposed between adjacent sensing electrodes. The ESD electrodes attract ESD events and dissipate the energy therein to avoid damaging adjacent sensing electrodes and/or portions of the dielectric layer. The fingerprint sensor may also include an electrically conductive layer connected to the ESD electrodes, which may provide a convenient ground plane, for example, for removing ESD energy from the fingerprint sensor. The electrically conductive layer may extend beneath the sensing electrodes.

Abstract: The apparatus for simultaneous aspiration and dispensation of fluids is in the form of a syringe with two chambers located end to end along the length of the syringe. Each syringe chamber includes a port. A piston inside the syringe includes a median section that is movable in both of the syringe chambers, a first end section movable only in one of the syringe chambers, and a second end section movable only in the other syringe chamber. Both end sections of the piston are of either less diameter than the median section of the piston or of greater diameter than the median section of the piston. When the piston is moved in a first direction, an aspiration or suction force is developed at one of the chamber ports and a dispensation pressure force is developed at the other chamber port. Reverse movement of the piston causes the opposite effect at the respective chamber ports. A compression seal is provided at the median section of the piston and at opposite non-adjacent end portions of the syringe chambers.