A microfluidic device and method for fabrication includes a microfluidic channel that has a closed portion, which comprises: a liquid pathway formed by a wetting area; and an anti-wetting area extending along and contiguously with the liquid pathway. The anti-wetting area is configured so as to provide a vent to evacuate gas along the anti-wetting area.

An apparatus for collecting, storing and transferring a liquid specimen includes a first cup for collecting a liquid specimen and a lid attachable to the first cup for closing an opening in the first cup. The lid defines a protruding collar, the lid and the collar define an aperture extending through the lid and a length of the collar. The apparatus further includes a transfer assembly including a tube having first and second ends, the first end defining a point, the second end configured for insertion through the aperture in the collar for transferring a liquid specimen from the first cup through the tube. The first end of the tube extends through a bottom of a second cup and into the second cup. The first end of the tube configured for insertion into an evacuated vial for transferring a liquid specimen from the first cup to the vial.

A pipette tip extension having a proximal end, a distal end, and an exterior wall extending between the proximal end and the distal end is disclosed. The exterior wall has an outer side and an inner side and encloses an inner cavity which is delimited by the inner side of the exterior wall. The exterior wall forms at the proximal end a reception aperture. The pipette tip extension further has one or more distance elements arranged at the inner side of the exterior wall and protruding into the inner cavity.

An enclosure device for a decapper for removing a cap from a laboratory sample container, a decapper and an apparatus comprising a decapper. The decapper comprises a cap gripper comprising at least two gripping jaws. At least one of the at least two gripping jaws is displaceable between a holding position and a release position in a radial direction. The enclosure device comprises an outer enclosure portion and an inner enclosure portion disposed within the outer enclosure portion. The outer enclosure portion comprises a wall portion and a reservoir portion at a bottom of the wall portion. The wall portion is configured to enclose the two gripping jaws. The inner enclosure portion is configured to receive a laboratory sample container and comprises at least two openings configured to allow the two gripping jaws to extend therethrough. The enclosure device is configured to be mounted to the cap gripper.

An automated pipetting system includes a pipettor. The pipettor includes a pipetting channel, a first plunger mechanism operable to change a pressure in the pipetting channel to aspirate or dispense a liquid, and a second plunger mechanism operable to change the pressure in the pipetting channel to aspirate or dispense the liquid.

A pipette tip extension having a proximal end, a distal end, and an exterior wall extending between the proximal end and the distal end. The exterior wall has an outer side and an inner side and encloses an inner cavity which is delimited by the inner side of the exterior wall. The exterior wall forms at the proximal end a reception aperture. The pipette tip extension further has one or more distance elements arranged at the inner side of the exterior wall and protrudes into the inner cavity.

Aspects of the present disclosure provide a novel design of a pipetting leakage detection apparatus that addresses the shortcomings of the current art for full-time leakage detection for pipetting actions using a single channel pipettor or multichannel pipettors. The pipetting apparatus employs an image capturing device combined with an image analysis process to provide a reliable and comprehensive leakage check for each channel of a multichannel pipettor.

A reagent dispensing apparatus. A dispensing module is attached to a support frame and includes a pressurized fluid delivery system. The fluid delivery system includes a reagent container, a dispensing head connected to the reagent container, a dispensing valve connected to the dispensing head, and a dispensing tip connected to the dispensing head. The reagent dispensing system also includes a motion drive system. A sensor remains focused on the area immediately underneath the dispensing tip. A computer is programmed to receive inputs from said sensor to determine drop success or failure from the dispensing tip. The computer is programmed to control the motion drive system to position a plate under the dispensing tip, and the computer is also programmed to open and close the dispensing valve to permit and stop fluid from flowing to the dispensing tip.

An automated pipetting system includes a pipettor. The pipettor includes a pipetting channel, a first plunger mechanism operable to change a pressure in the pipetting channel to aspirate or dispense a liquid, and a second plunger mechanism operable to change the pressure in the pipetting channel to aspirate or dispense the liquid.