Abstract: Methods and devices are provided for preparing and separating biological analytes. In one embodiment, one or more filtration devices or filter plate wells can be formed by clamping a filter sheet between first and second plates having at least one connecting cavity. First and second moveable core pins positioned on opposed sides of the sheet can be moved to remove portions of the sheet. A molten plastic can be injected to fill the volume between the cores and cavities and to form a liquid-impermeable sleeve wall or walls, each being separately sealed at the bottom to the perimeter of the sheet portion, each having liquid permeable regions of said removed and sealed sheet portion, and each remaining open at the top. Various exemplary configurations for filtration devices or filter plate wells are also disclosed.

Abstract: Methods and devices are provided for preparing and separating biological analytes. In one embodiment, one or more filtration devices or filter plate wells can be formed by clamping a filter sheet between first and second plates having at least one connecting cavity. First and second moveable core pins positioned on opposed sides of the sheet can be moved to remove portions of the sheet. A molten plastic can be injected to fill the volume between the cores and cavities and to form a liquid-impermeable sleeve wall or walls, each being separately sealed at the bottom to the perimeter of the sheet portion, each having liquid permeable regions of said removed and sealed sheet portion, and each remaining open at the top. Various exemplary configurations for filtration devices or filter plate wells are also disclosed.

Abstract: A clamshell fabrication process wherein an ultrafiltration (UF) vessel (or a strip or array of filter vessels) is formed using half cells joined along a central plane to form each vessel. A filter membrane covers a port of the cell, and an outer body is overmolded to form the completed vessel. Two filter membranes are crushed together skin to skin. When applied to strips of half cells, a multi-well strip or array is formed, with sample-holding reservoirs formed by the space created between two strips of half-cells for each row of filter cells. The membrane thus covers the entire wetted interior of each cell, and may extend from near the opening at the top of an open cell to a conical bottom of the cell. A number of strip assemblies can be formed together to create larger arrays of filter cells. The overmolding process creates a crush seal with edges of the filter membrane.

Abstract: An ultrafiltration device has a ported reservoir body, and a filter membrane sealed to the body along a closed contour surrounding the port(s) to provide a large area filtered outflow path. A frusto-conical end provides hydrostatic deadstopping with little or no wicking, greatly enhancing recovery time and efficiency. Methods of using the device rapidly isolate a predetermined amount of a desired retentate in the distal portion of the tube, and are also useful for quantitative transfer of smaller molecules and for multi-step processing of sample arrays Linear array strips of such chambers may be formed by bonding together mating halves with filter areas over the chamber ports. The vessel may include a rib to guide and orient filter during assembly, and/or a ledge or recess to engage and align the filter, assuring that the filter is precisely positioned and does not wander during manufacture and bonding.

Abstract: An ultrafiltration device has a filter membrane sealed inside a reservoir body, such as a tube. The tube has one or more ports and a closed portion distal to the port(s), and the filter membrane is sealed to the body along a closed contour widely surrounding the port(s) to provide a large area filtered outflow path. The method is effective to rapidly isolate a predetermined amount of a desired retentate in the distal portion of the tube. The method and device are also useful for quantitative transfer of smaller molecules and for multi-step processing of sample arrays. A frusto-conical peripheral filter provides high ratio of effective filter area, and may be configured for hydrostatic deadstopping and little or no wicking, greatly enhancing recovery time and efficiency. Linear array strips of such chambers may be formed by bonding together mating halves with filter areas over the chamber ports.

Abstract: An ultrafiltration device has a filter membrane sealed inside a reservoir body that has one or more ports and a closed portion distal to the port(s), and the filter membrane is sealed to the body along a closed contour widely surrounding the port(s) to provide a large area filtered outflow path. The method is effective to rapidly isolate a predetermined amount of a desired retentate in the distal portion and is also useful for quantitative transfer of smaller molecules and for multi-step processing of sample arrays. A frusto-conical peripheral filter provides high ratio of effective filter area, and may be configured for hydrostatic deadstopping and little or no wicking, greatly enhancing recovery time and efficiency. Novel constructions and methods of manufacture enhance filtration or separation vessels of various sizes.

Abstract: A reusable microconcentrator device may be disassembled, cleaned and reassembled before use. The microconcentrator device of the invention is typically useful in filtering and separating small samples of solutions and suspensions. The microconcentrator device of the invention includes an elongate sample sleeve, a base element which can be removable and replaceably coupled to a centrifugal portion of the sleeve, a compliant membrane compressing feature, and a disposable membrane. Preferably, the base element includes an O-ring which compresses the membrane to seal it to the centrifugal surface of an annular ledge portion of the sleeve, which also forms a deadstop. Among the advantages of the microconcentrator device of the invention is that a reliable retentate volume remains following filtration. The elements of the microcentrator device can also be permanently assembled to one another.

Abstract: A sanitary slider valve shown specifically as a rotary carousel diaphragm valve which has a thermoplastic elastomeric diaphragm integrally molded to form the multiple sealing ports of the rotor/stator interface is described. Ports or grooves molded into the face of the elastomeric diaphragm are positioned to sealably engage grooves or ports in the stator face, and to form sanitary elastomeric tubular ducts leading through the body of the rotor or of the stator, terminating as elastomeric flanges. These flanges permit direct connection to sanitary flared piping flanges within the carousel which lead to and from multiple columns or other solid phase bed segments, or to sanitary flared piping flanges connecting the stator to piping interconnecting the multiple carousel columns to each other and to external supply and collection lines.

Abstract: An integrated system and method are disclosed for filtering a fluid and for dispensing a desired volume of the fluid. The integrated system includes a feed pump sub-assembly for receiving fluid and for directing the fluid through a filter. A filtration sub-assembly is joined with the feed pump sub-assembly for receiving fluid from the feed pump sub-assembly and for housing the filter. A dispense pump sub-assembly is integrally joined with the filtration sub-assembly and defines a dispense chamber for receiving filtered fluid from the filtration sub-assembly. The dispense pump sub-assembly includes a dispensing means which is moveable from a fill position to a purge position for purging at least a portion of any gas bubbles from the dispense chamber. The gas bubbles are purged through a purge outlet disposed above a fluid inlet and a fluid outlet of the dispense chamber.

Abstract: The present invention relates to a multiwell apparatus for biological and biochemical analysis which provides for separate collection of filtrate from each well, without cross-contamination therebetween. The present invention provides a manifold plate having an array of filtering wells, each of the wells being closed at its bottom by a planar bottom member providing a filter support surface. A discharge nozzle of passageway depends from each well bottom (planar bottom member) in a direction normal thereto, with one such discharge nozzle or port being provided in fluid communication with each filtering well. Each of these filtrate nozzles or drain ports extends from the lower surface of the planar bottom member to such an extent that it will enter into the well of a conventional multiwell, e.g., microtiter, plate in alignment therewith and mate with the sidewall of the aligned well of the multiwell plate.

Abstract: A filtration apparatus and method is disclosed, the apparatus including a container tube for holding a sample to be filtered and a filtering vessel inserted therein. The filtering vessel carries a filter over its lower end and includes a chamber portion for receiving the filtrate. The method includes forcibly immersing the filtration vessel into the container tube, limiting the relative axial position therebetween, and subjecting the apparatus to centrifugation. The apparatus and method is useful for filtering dilute, concentrated and particle-laden samples.

Abstract: Disclosed is an apparatus and method for using the apparatus to centrifugally recover a maximal amount of concentrated macromolecular retentate.

Abstract: Disclosed is a centrifugal microconcentrator and methods for using the microconcentrator to concentrate macromolecules from a solution without filtering to dryness and to centrifugally recover a maximal amount of concentrated macromolecular retentate.