Abstract: An apparatus and method is described for obtaining a preparative-scale, free-fluid electrophoretic separator with high resolution as well as an analytical capability commensurate with capillary zone electrophoresis. The electrophoretic focusing apparatus and method of the present invention features a separation chamber bounded by planar precision-pore, insulated screens, a plurality of purge chambers, a plurality of electrode chambers, and a plurality of pump means. The separation device of the invention is capable of high speed of separation and short residency of sample through the use of high voltage gradients which are produced by relatively low voltages applied across the narrow chamber dimensions. The present apparatus and method thus achieves high resolution of separation in an analytical or a preparative mode through a practically unlimited scale-up potential, and controls the adverse effects of Joule heating and electrohydrodynamics on the electrophoretic separation procedure.

Abstract: An electrophoretic focusing apparatus and method is provided for obtaining a preparative-scale, free-fluid electrophoretic separator with high resolution and an analytical capability commensurate with capillary zone electrophoresis. The present invention combines features of electrophoresis and isoelectric focusing to accomplish large scale purifications and fractionations not previously possible, and features a separation chamber bounded by precision-pore insulated screens, a plurality of purge chambers, a plurality of electrode chambers, and a plurality of pump means. The device of the invention is capable of high speed of separation through the use of high voltage gradients produced by low voltages applied across the narrow chamber.

Abstract: An apparatus and method is provided for obtaining a preparative-scale, free-fluid electrophoretic separator with high resolution as well as an analytical capability commensurate with capillary zone electrophoresis. The electrophoretic focusing apparatus and method of the present invention combines features of electrophoresis and isoelectric focusing to accomplish large scale purifications and fractionations that have not previously been possible, and features a separation chamber bounded by precision-pore, insulated screens, a plurality of purge chambers, a plurality of electrode chambers, and a plurality of pump means. The separation device of the invention is capable of high speed of separation and short residency of sample through the use of high voltage gradients which are produced by relatively low voltages applied across the narrow chamber dimensions.

Abstract: An apparatus and method is described for obtaining a preparative-scale, free-fluid electrophoretic separator with high resolution as well as an analytical capability commensurate with capillary zone electrophoresis. The electrophoretic focusing apparatus and method of the present invention features a separation chamber bounded by planar precision-pore, insulated screens, a plurality of purge chambers, a plurality of electrode chambers, and a plurality of pump means. The separation device of the invention is capable of high speed of separation and short residency of sample through the use of high voltage gradients which are produced by relatively low voltages applied across the narrow chamber dimensions. The present invention is also highly flexible, with operation in a constant electric field, continuous flow mode which permits scanning of the sample fraction content and display in a conventional histogram format.

Abstract: An apparatus and method is provided for obtaining a preparative-scale, free-fluid electrophoretic separator with high resolution as well as an analytical capability commensurate with capillary zone electrophoresis. The electrophoretic focusing apparatus and method of the present invention combines features of electrophoresis and isoelectric focusing to accomplish large scale purifications and fractionations that have not previously been possible, and features a separation chamber bounded by precision-pore insulated screens, a plurality of purge chambers, a plurality of electrode chambers, and a plurality of pump means. The separation device of the invention is capable of high speed of separation and short residency of sample through the use of high voltage gradients which are produced by relatively low voltages applied across the narrow chamber dimensions.

Abstract: An apparatus and method is provided for obtaining a preparative-scale, free-fluid electrophoretic separator with high resolution as well as an analytical capability commensurate with capillary zone electrophoresis. The electrophoretic focusing apparatus and method of the present invention combines features of electrophoresis and isoelectric focusing to accomplish large scale purifications and fractionations that have not previously been possible, and features a separation chamber bounded by glass-coated porous metal screens, a plurality of purge chambers, a plurality of electrode chambers, and a plurality of pump means. The separation device of the invention is capable of high speed of separation and short residency of sample through the use of high voltage gradients which are produced by relatively low voltages applied across the narrow chamber dimensions.

Abstract: An apparatus and method is provided for obtaining a preparative-scale, free-fluid electrophoretic separator with high resolution as well as an analytical capability commensurate with capillary zone electrophoresis. The electrophoretic focusing apparatus and method of the present invention combines features of electrophoresis and isoelectric focusing to accomplish large scale purifications and fractionations that have not previously been possible, and features a separation chamber bounded by planar porous insulated screens, a plurality of purge chambers, a plurality of electrode chambers, and a plurality of pump means. The separation device of the invention is capable of high speed of separation and short residency of sample through the use of high voltage gradients which are produced by relatively low voltages applied across the narrow chamber dimensions.

Abstract: A novel free-fluid electrophoresis system applicable to both "analytical" and "preparative" separations combines the advantages of electrophoresis with those of automated liquid chromatography. The system attains plug flow of sample molecules within a separation column that has a sufficiently small diameter to avoid uncorrected convective dispersions and a sufficiently large diameter to ensure adequate preparative throughput. Sample molecules are introduced by liquid chromatographic-type injection mechanisms and moved to the separation column by means of a highly accurate, low-pressure pumping system. A novel pressure detector monitors pressure across the column during the electrophoretic separation. When the pressure across the column is zero, electroosmotic flow within the column exactly balances pump-induced flow so that there is no lateral dispersion of the separating sample molecules (i.e., plug flow is achieved).

Abstract: A clinostat for simulating microgravity on cell systems carried in a fiber fixedly mounted in a rotatable culture vessel. The clinostat is rotated horizontally along its longitudinal axis to simulate microgravity or vertically as a control response. Cells are injected into the fiber and the ends of the fiber are sealed and secured to spaced end pieces of a fiber holder assembly which consists of the end pieces, a hollow fiber, a culture vessel and a tension spring with three alignment pins. The tension spring is positioned around the culture vessel with its ends abutting the end pieces and the alignment pins extend between the end pieces for alignment of the spring. After the fiber is secured, the spring is decompressed to maintain tension on the fiber while it is being rotated. This assures that the fiber remains aligned along the axis of rotation. The fiber assembly is placed in the culture vessel and culture medium is added.

Abstract: This invention relates to a crystal growth apparatus (10) generally used for growing protein crystals wherein a vapor diffusion method is used for growing the crystals. In this apparatus, a precipitating solution and a solution containing dissolved crystalline material are stored in separate vials (12, 14), each having a resilient diaphragm (28) across one end and an opening (24) with a puncturable septum (26) thereacross at an opposite end. The vials are placed in receptacles (30) having a manifold (41) with a manifold diaphragm (42) in contact with the vial diaphragm at one end of the receptacle and a hollow needle (36) for puncturing the septum at the other end of the manifold.

Abstract: A moving wall, continuous flow electrophoresis apparatus (10) having a frame (18) with an electrophoresis chamber (12) mounted between a pair of synchronously driven belt walls (14, 16). The frame (18), and thus the chamber (12), is supported between the belt walls (14, 16) and is angularly positionable with respect to the direction of belt travel. The belts are stored on supply reels (98, 156) at one end of the device and are taken up on driven reels (94, 132) at the other end, thus constantly exposing new belt material within the chamber.

Abstract: Apparatus is disclosed for carrying out a moving wall type electrophoresis process for separation of cellular particles. The Apparatus includes a water-tight housing (10) containing an electrolytic buffer solution. A separation chamber (12) in the housing is defined by spaced opposed moving walls (14 and 16) and spaced opposed side walls (18 and 20). Substrate assemblies (26 and 32), which support the moving wall include vacuum ports (60) for positively sealing the moving walls against the substrate walls. A plurality of suction conduits (62) communicate with the suction ports and are arranged in the form of valleys in a grid plate (64). Raised land portion of the grid plate support the substrate walls against deformation inwardly under suction. Cooling chamber (70) carried on the back side of plate (64).

Abstract: An electrophoresis device is disclosed for separating cellular particles of a sample substance into fractionated streams of different cellular species wherein the device includes a casing 10 having a distribution chamber A, separation chamber B, and collection chamber C. The electrode chambers 34 are separated from the separation chamber interior 16 by means of passages 50 and 48 such that flow variations and membrane variations around the slotted portion 34a of the electrode chamber do not enduce flow perturbations into the laminar buffer curtain flowing in the separation chamber.The cellular particles of the sample are separated under the influence of the electrical field and the separation chamber 16 and separated into streams of different cellular species. The streams of separated cells enter a partition array 52 in the collection chamber C and are fractionated and collected therein.