Abstract: Embodiments of the present disclosure relate to techniques, processes, devices or systems for pump devices for providing a fixed volume of fluid, which is delivered and refilled within one pumping cycle. In one approach, a wearable drug delivery device may include a reservoir for storing a liquid drug, and a delivery pump device including a drive mechanism coupled to the reservoir. The drive mechanism may include a housing having a pump chamber fluidly connected with a channel chamber, an inlet channel operable to deliver the liquid drug from the reservoir to the channel chamber, and an outlet channel operable to expel the liquid drug from the channel chamber. The drive mechanism may further include a resilient sealing member sealing the pump chamber, and a plunger adjacent the resilient sealing member, wherein the plunger is operable to enter the pump chamber to displace the liquid drug from the pump chamber.

Abstract: A liquid injection port including a liquid input block defining a liquid input conduit; a compression block adapted to mate with the liquid input block; and a septum including a deformable material mounted in a septum retainer, the septum defining a central perforation, and forming a seal between the liquid input block and the compression block. The septum defines a conical deformation toward the liquid input conduit. A method for delivering fluid from a pipette tip includes a) introducing the fluid into the pipette tip; b) inserting the pipette tip into a pipette conduit defined by a compression block; c) inserting the pipette tip through a septum mounted in the compression block; and d) releasing the fluid in the pipette tip into a liquid input conduit defined in a liquid input block, the septum defining a conical deformation toward the liquid input conduit while maintaining a seal.

Abstract: A liquid injection port including a liquid input block defining a liquid input conduit; a compression block adapted to mate with the liquid input block; and a septum including a deformable material mounted in a septum retainer, the septum defining a central perforation, and forming a seal between the liquid input block and the compression block. The septum defines a conical deformation toward the liquid input conduit. A method for delivering fluid from a pipette tip includes a) introducing the fluid into the pipette tip; b) inserting the pipette tip into a pipette conduit defined by a compression block; c) inserting the pipette tip through a septum mounted in the compression block; and d) releasing the fluid in the pipette tip into a liquid input conduit defined in a liquid input block, the septum defining a conical deformation toward the liquid input conduit while maintaining a seal.

Abstract: An array of probes is provided wherein the probes are maintained in place in bores extending through a housing by a friction force applied to the probes. The friction force can be overcome by another force applied to the probes, thereby allowing the probes to move to a new position within the bore. In one embodiment, the probes contain an internal conduit through which liquid samples are introduced into the probes. Thereafter, the probes are moved to contact a substrate surface to move the probes to a new position, the configuration of which replicates the substrate surface configuration. The housing is then raised a predetermined distance to allow sample to be accurately deposited on the substrate surface from a desired height above the substrate surface. The probes are then returned to their original position.

Abstract: Regulator for precision control of pressure based on a means of measuring pressure differentials. More specifically, the present invention provides a pressure control that tracks a relatively high background pressure, and applies a positive or negative offset to create the small pressure differentials that can be utilized to transport fluids within a capillary network. The present invention is also directed to a method of controlling microfluidic elements (such as donut cavities) with a high degree of precision. In high performance liquid chromatography applications, this is accomplished using tracking pressure regulators to measure and respond to the difference between the liquid pump pressure and the regulated pneumatic pressure.

Abstract: Regulator for precision control of pressure based on a means of measuring pressure differentials. More specifically, the present invention provides a pressure control that tracks a relatively high background pressure, and applies a positive or negative offset to create the small pressure differentials that can be utilized to transport fluids within a capillary network. The present invention is also directed to a method of controlling microfluidic elements (such as donut cavities) with a high degree of precision. In high performance liquid chromatography applications, this is accomplished using tracking pressure regulators to measure and respond to the difference between the liquid pump pressure and the regulated pneumatic pressure.

Abstract: A fluid connector which provides a low fluid dead volume face seal capable of withstanding high pressures for coupling a fluid conduit to a microfluidic device. The fluid connector includes a housing, a clamping member, a first load support surface and a sealing member. The sealing member preferably includes first and second fluidically connected bores of different diameters so the fluid conduit may be retained within the larger diameter bore. The sealing member is positioned so that the smaller diameter bore interfaces with a port of the microfluidic device. In operation, the clamping member supplies an axial force to the first load support surface which is operatively coupled to the fluid conduit. When an axial force is transferred to the fluid conduit, the face of the fluid conduit at one end seals against the pliant portion of the sealing member while simultaneously urging the sealing member against the surface area surrounding the port of the microfluidic device to create a fluid-tight face seal.