Abstract: A flow-through microfluidic apparatus for cell treatment is provided, including a flow chamber and a three-dimensional (3D) microelectrode array disposed in the flow chamber to produce electrical fields for cell railing, electroporation and/or sorting. The flow chamber includes a sample flow region, a first sheath flow region and a second sheath flow region. The sample flow region has an input allowing a sample flow of cells and exogenous agents to enter the sample flow region, a first output allowing damaged cells to exit from the flow chamber. Viable target cells are dielectrophoretic railed along the plurality of 3D microelectrode units; railing cells are electroporated through electrical treatment to intake/uptake of an exogenous agent; and viable treated cells loaded with exogenous agent are dielectrophoretically sorted from cells damaged during the cell treatment.

Abstract: Disclosed herein is a device for electrophoresis comprising: a separation channel in a substrate; and a plurality of capillary-well motifs cascading along the separation channel, each of the plurality of capillary-well motifs comprising a well and a plurality of non-intersecting capillaries, wherein the capillaries are downstream from the well and fluidly connected thereto, an interface between the well and the capillaries comprises a step profile. Also disclosed is a method comprising: obtaining a substrate comprising an insulator layer of an insulator material; forming a well and a plurality of trenches in the insulator layer so that only the insulator material is exposed to an interior of the well and the plurality of trenches; nonconformally depositing a film into the plurality of trenches until the film pinches off top openings of the trenches and forms a tubular void therein; transforming the tubular void into a capillary by annealing the film.

Abstract: Disclosed herein is a device for electrophoresis comprising: a separation channel in a substrate; and a plurality of capillary-well motifs cascading along the separation channel, each of the plurality of capillary-well motifs comprising a well and a plurality of non-intersecting capillaries, wherein the capillaries are downstream from the well and fluidly connected thereto, an interface between the well and the capillaries comprises a step profile. Also disclosed is a method comprising: obtaining a substrate comprising an insulator layer of an insulator material; forming a well and a plurality of trenches in the insulator layer so that only the insulator material is exposed to an interior of the well and the plurality of trenches; nonconformally depositing a film into the plurality of trenches until the film pinches off top openings of the trenches and forms a tubular void therein; transforming the tubular void into a capillary by annealing the film.

Abstract: A probe element and a method of forming a probe element are provided. The probe element includes a carrier comprising biodegradable and/or bioactive material; and at least one electrode coupled to the carrier.

Abstract: A fluid cartridge, comprising a channel layer within which at least one circumferentially sealed fluid channel is formed, the channel layer comprising a substrate and an elastic layer fixedly arranged on the substrate, wherein the substrate has a rigidity being greater than that of the elastic layer, and wherein the at least one fluid channel is defined on at least one side thereof by the elastic layer.

Abstract: A probe element and a method of forming a probe element are provided. The probe element includes a carrier comprising biodegradable and/or bioactive material; and at least one electrode coupled to the carrier.

Abstract: A measuring device includes a first substrate; and a second substrate bonded on the first substrate. The second substrate has at least two inflow ports, at least two outflow ports, and an injection port. The two inflow ports, the two outflow ports, and the injection port penetrate the second substrate. The first substrate includes partition wall portions opposing to each other, and forming a first cavity between the partition wall portions, and forming at least two second cavities close against one of the partition wall portions. Each second cavity is provided adjacent to the first cavity. Through holes are provided in the respective partition wall portions to connect the first cavity and the second cavity to each other, and the through holes are adapted to capture an object to-be-tested introduced in the first cavity.

Abstract: A measuring device includes a first substrate; and a second substrate bonded on the first substrate. The second substrate has at least two inflow ports, at least two outflow ports, and an injection port. The two inflow ports, the two outflow ports, and the injection port penetrate the second substrate. The first substrate includes partition wall portions opposing to each other, and forming a first cavity between the partition wall portions, and forming at least two second cavities close against one of the partition wall portions. Each second cavity is provided adjacent to the first cavity. Through holes are provided in the respective partition wall portions to connect the first cavity and the second cavity to each other, and the through holes are adapted to capture an object to-be-tested introduced in the first cavity.

Abstract: The present invention provides a device for analyzing the status of a biological entity. The device comprises a base substrate having a recess defined therein by two opposing lateral walls and a base wall, a filler member having at least a portion thereof occupying the recess, and a channel defined in the portion of the filler member occupying the recess, wherein the channel comprises a first aperture and a second aperture, the first aperture being arranged on a first lateral wall of the filler member, and the second aperture being arranged on a second lateral wall of the filler member, said first lateral wall of the filler member being arranged in opposing relationship with the second lateral wall of the filler member, and at least a portion of the first and the second lateral walls of the filler member being at least substantially perpendicular to the opposing lateral walls defining the recess.

Abstract: A microfluidics package (1) comprising a substrate (6) having a top surface, said top surface comprises at least one fluid channel (11, 12), at least one fluidic chip (2) having a top surface, a bottom surface, at least one side surface, and at least one passage to allow a fluid to traverse from the top surface or any side surface to the bottom surface of the chip; sides are adhesive, wherein the first adhesive side of the sheet (4) is secured to the substrate (6), and the at least one fluidic chip (2) is secured by the second adhesive side of the sheet (4), said fluidic chip (2) being arranged such that the at least one passage of the fluidic chip is in fluid communication with the at least one fluid channel (11, 12) of the substrate.

Abstract: A micro-fluidic device and a method for conducting various procedures with fluid. The device includes a substrate having a thickness direction and a substantially planar surface extending in a lengthwise direction that is substantially perpendicular to the thickness direction. A well is formed in the substrate to define a sidewall and a bottom surface. A channel having an internal surface is formed in the substrate below the substantially planar surface and extending substantially in the lengthwise direction. The channel is in communication with the well at one end thereof to define an orifice in the sidewall. Fluid in the well can be drawn into the orifice. As an example, the fluid can contain at least one cell which can be positioned against the orifice for a patch clamping procedure.