Abstract: A device and a method for isolating a target from a biological sample are provided. The target is bound to solid phase substrate to form target bound solid phase substrate. The device includes a lower plate with an upper surface having a plurality of regions. The biological sample is receivable on a first of the regions. An upper plate has a lower surface directed to the upper surface of the lower plate. A force is positioned adjacent the upper plate and attracts the target bound solid phase substrate toward the lower surface of the upper plate. At least one of the upper plate and the lower plate is movable from a first position wherein the target bound solid phase substrate in the biological sample are drawn to the lower surface of the upper plate and a second position wherein the target bound solid phase substrate are isolated from the biological sample.

Abstract: A device and method are provided to facilitate the handling of a volume or fluid. The device includes an elongated tube having an open first end and a second end. The tube defines a reservoir for receiving the volume or fluid. A stanchion has a first end received within the reservoir of the tube and a second end projecting from the open end of the elongated tube. In operation, the elongated tube is deposited in a first capsule having fluid therein. The first capsule is centrifuged such that the volume of fluid is received in a reservoir in the tube through the open end. The tube is removed from the first capsule and positioned in a second capsule such that the open end of the tube is spaced from a closed end of the second capsule. The second capsule is centrifuged such that the volume of fluid is expelled from the reservoir of the tube.

Abstract: A deformable well structure for a microtiter plate and method are provided. The deformable well structure includes a sample container defining a well for receiving a sample therein. The sample received in the well has a concave meniscus. A deformation tool is engageable with the sample container and is moveable between a first disengaged position wherein the deformation tool is spaced from the sample container and a second, engaged position wherein the deformation tool engages and deforms at least a portion of the sample container such that the meniscus of the sample in the well is converted from concave to convex.

Abstract: A device is provided for the administration of a compound in a body. The device includes a capsule having a reservoir therein for receiving the compound therein and a delivery instrument for positioning the capsule within the body. The delivery instrument includes a barrel having an interior adapted to receive the capsule therein and a dispersal element interacting with the barrel to selectively expel the capsule therefrom and into the body. A diffusion regulator communicates with the reservoir and controls the diffusion of the compound from the reservoir into the body. A retention structure projects from capsule and is configured to retain the capsule at a desired location within the body. Multiple devices may be used in conjunction to provide a multiplexed point source to administer multiple compounds simultaneously in vivo.

Abstract: A method and microfluidic device are provided for containing a droplet having an outer surface at a predetermined location. The microfluidic device includes a plate having an upper surface and a central region communicating with the upper surface. The central region is adapted for receiving a droplet of fluid thereon. The central region includes an outer periphery that defines a first fluid constraint configured for discouraging fluid on the central region from flowing therepast. A second fluid constraint extends about the first fluid constraint. The second fluid constraint is configured for discouraging fluid flowing therepast. A third fluid constraint extends about the second fluid constraint. The third fluid constraint configured for discouraging fluid flowing therepast.

Abstract: A non-displasive pipette is provided. The non-displasive pipette is configured for connection to a tip having a fluid therein. The tip includes an orifice to allow for the discharge of the fluid therefrom. The non-displasive pipette includes a body defining a chamber therethrough and having first and second opposite ends. The second end of the body is configured for connection to the tip. A plunger is slidably received in the chamber at the first end of the body. The plunger is moveable in the chamber between an extended position and a discharge position wherein the fluid is urged from tip through the orifice. An air discharge arrangement is configured to allow air from the chamber to escape therefrom and to maintain the fluid in the tip in response to connection of the second end of the body to the tip.

Abstract: A device and a method for isolating a target from a biological sample are provided. The target is bound to solid phase substrate to form target bound solid phase substrate. The device includes a lower plate with an upper surface having a plurality of regions. The biological sample is receivable on a first of the regions. An upper plate has a lower surface directed to the upper surface of the lower plate. A force is positioned adjacent the upper plate and attracts the target bound solid phase substrate toward the lower surface of the upper plate. At least one of the upper plate and the lower plate is movable from a first position wherein the target bound solid phase substrate in the biological sample are drawn to the lower surface of the upper plate and a second position wherein the target bound solid phase substrate are isolated from the biological sample.

Abstract: A device is provided for the administration of a compound in a body. The device includes a capsule having a reservoir therein for receiving the compound therein and a delivery instrument for positioning the capsule within the body. The delivery instrument includes a barrel having an interior adapted to receive the capsule therein and a dispersal element interacting with the barrel to selectively expel the capsule therefrom and into the body. A diffusion regulator communicates with the reservoir and controls the diffusion of the compound from the reservoir into the body. A retention structure projects from capsule and is configured to retain the capsule at a desired location within the body. Multiple devices may be used in conjunction to provide a multiplexed point source to administer multiple compounds simultaneously in vivo.

Abstract: A device and a method are provided for isolating a fraction in a biological sample. The fraction is bound to solid phase substrate to define a fraction-bound solid phase substrate. The device includes an input zone for receiving the biological sample therein and a second zone for receiving an isolation fluid therein. A force is provided that is generally perpendicular to gravity. The force is movable between a first position adjacent the input zone and a second position adjacent the isolation zone. The force captures the fraction-bound solid phase substrate and the fraction-bound solid phase substrate moves from the input zone to the isolation zone in response to the force moving from the first position to the second position.

Abstract: A device and method are proved for transferring a target from a first location to a second location. The target is bound to solid phase substrate to form a target bound solid phase substrate. The device includes transfer surface for receiving the target bound solid phase substrate thereon for transfer. The transfer surface movable between a first position wherein the transfer surface is aligned with the first location and spaced therefrom by a distance and a second position wherein the transfer surface is aligned with the second location. An alignment structure aligns the transfer surface with respect to the second location, with the transfer surface in the second position. A force is movable between an attraction position wherein the target bound solid phase substrate are drawn toward the transfer surface and a discharge position wherein the target bound solid phase substrate are free of the force.

Abstract: A device and a method are provided for isolating a fraction in a biological sample. The fraction is bound to solid phase substrate to define a fraction-bound solid phase substrate. The device includes an input zone for receiving the biological sample therein and a second zone for receiving an isolation fluid therein. A force is provided that is generally perpendicular to gravity. The force is movable between a first position adjacent the input zone and a second position adjacent the isolation zone. The force captures the fraction-bound solid phase substrate and the fraction-bound solid phase substrate moves from the input zone to the isolation zone in response to the force moving from the first position to the second position.

Abstract: A device and a method for isolating a target from a biological sample are provided. The target is bound to solid phase substrate to form target bound solid phase substrate. The device includes a lower plate with an upper surface having a plurality of regions. The biological sample is receivable on a first of the regions. An upper plate has a lower surface directed to the upper surface of the lower plate. A force is positioned adjacent the upper plate and attracts the target bound solid phase substrate toward the lower surface of the upper plate. At least one of the upper plate and the lower plate is movable from a first position wherein the target bound solid phase substrate in the biological sample are drawn to the lower surface of the upper plate and a second position wherein the target bound solid phase substrate are isolated from the biological sample.

Abstract: A device and a method are provided for isolating a fraction in a biological sample. The fraction is bound to solid phase substrate to define a fraction-bound solid phase substrate. The device includes an input zone for receiving the biological sample therein and a second zone for receiving an isolation fluid therein. A force is provided that is generally perpendicular to gravity. The force is movable between a first position adjacent the input zone and a second position adjacent the isolation zone. The force captures the fraction-bound solid phase substrate and the fraction-bound solid phase substrate moves from the input zone to the isolation zone in response to the force moving from the first position to the second position.

Abstract: A device and a method are provided for isolating a fraction in a biological sample. The fraction is bound to solid phase substrate to define a fraction-bound solid phase substrate. The device includes an input zone for receiving the biological sample therein and a second zone for receiving an isolation fluid therein. A force is provided that is generally perpendicular to gravity. The force is movable between a first position adjacent the input zone and a second position adjacent the isolation zone. The force captures the fraction-bound solid phase substrate and the fraction-bound solid phase substrate moves from the input zone to the isolation zone in response to the force moving from the first position to the second position.