Abstract: A pipette controller for aspirating and dispensing multiple aliquots of a fluid from a reservoir of fluid. The pipette controller can include a pipette holder adapted to operatively connect a pipette to the pipette holder; a pump having a vacuum port and a pressure port, the pump pneumatically connected to the pipette holder; an aspirate valve that controls airflow between the vacuum port and the pipette holder; a dispense valve that controls airflow between the pressure port and the pipette holder; a piston chamber; an aliquot dispense pump including a piston having a shaft that extends into the piston chamber, the shaft defining a stroke length; and an aliquot check valve that connects the pipette holder and the aliquot dispense pump; wherein the aliquot valve opens to allow airflow into the pipette holder upon engagement of the aliquot dispense valve.

Abstract: A pipette controller for aspirating and dispensing multiple aliquots of a fluid from a reservoir of fluid. The pipette controller can include a pipette holder adapted to operatively connect a pipette to the pipette holder; a pump having a vacuum port and a pressure port, the pump pneumatically connected to the pipette holder; an aspirate valve that controls airflow between the vacuum port and the pipette holder; a dispense valve that controls airflow between the pressure port and the pipette holder; a piston chamber; an aliquot dispense pump including a piston having a shaft that extends into the piston chamber, the shaft defining a stroke length; and an aliquot check valve that connects the pipette holder and the aliquot dispense pump; wherein the aliquot valve opens to allow airflow into the pipette holder upon engagement of the aliquot dispense valve.

Abstract: A method and system for optical measurement of a volume of dispensed fluid may be provided such as in connection with the calibration of pipettes. The method and system may include utilizing a fluid receptacle, an image recording device, and an image processing application to provide optical measurement of the volume of the dispensed fluid. The fluid receptacle may include a first plate and a second plate. The first and second plates may include respective opposing surfaces spaced apart from one another by a predetermined distance to define a space between the opposing surfaces. At least one of the first plate and the second plate may be substantially transparent to ensure that the dispensed fluid received in the space of the fluid receptacle is visible to the image recording device.

Abstract: A catheter for applying ablation energy to biological tissue having biological fluid flowing thereby includes a shaft having a distal-end region defining a tissue-contacting surface and a fluid-contacting surface. A plurality of band electrodes are positioned at the distal-end region of the shaft. A thermally conductive and non-electrically conductive surface covering, covers a portion of each of the band electrodes substantially coincident with the fluid-contacting surface. Each band electrode thereby has at least one masked portion substantially coincident with the fluid-contacting surface and at least one non-masked portion substantially coincident with the tissue-contacting surface. Ablation energy is transferred through the non-masked portion of the electrode. One or more thermal sensors are located in the non-masked portion of each of the band electrodes.

Abstract: A catheter for applying ablation energy to biological tissue having biological fluid flowing thereby includes a shaft having a distal-end region defining a tissue-contacting surface and a fluid-contacting surface. A plurality of band electrodes are positioned at the distal-end region of the shaft. A thermally conductive and non-electrically conductive surface covering, covers a portion of each of the band electrodes substantially coincident with the fluid-contacting surface. Each band electrode thereby has at least one masked portion substantially coincident with the fluid-contacting surface and at least one non-masked portion substantially coincident with the tissue-contacting surface. Ablation energy is transferred through the non-masked portion of the electrode. One or more thermal sensors are located in the non-masked portion of each of the band electrodes.

Abstract: A capacative probe is provided which has reduced effective stray capacitance and is thus able to accurately detect probe contact with a conducting fluid with small fluid volumes. Effective stray capacitance is reduced by dividing stray capacitance sources into two or more sources, by reducing the capacitance value of each of the divided stray capacitance sources to a value which is substantially less than the capacitance difference which occurs as a result of probe contact with the fluid and by connecting at least selected ones of the divided stray capacitance sources in series to further reduce effective stray capacitance.

Abstract: A fluid cup is provided for use with a cup support having a cup-receiving receptacle and a drain. The cup is adapted for use with a pipette probe which may introduce contaminants into the fluid, for example a dilutant fluid, in the cup. The cup has a lower cup portion and a cap, with a notch or other overflow element being provided near the top of the lower cup portion. Diluent fluid is introduced near the bottom of the lower cup portion after each probe entry, creating a fluid flow pattern which flushes any contaminant from the cup through the notch without requiring the use of a large fluid volume.