A method is disclosed for fabricating free-standing polymeric nanopillars or nanotubes with remarkably high aspect ratios. The nanopillars and nanotubes may be used, for example, in integrated microfluidic systems for rapid, automated, high-capacity analysis or separation of complex protein mixtures or their enzyme digest products. One embodiment, preferably fabricated entirely from polymer substrates, comprises a cell lysis unit; a solid-phase extraction unit with free-standing, polymeric nanostructures; a multi-dimensional electrophoretic separation unit with high peak capacity; a solid-phase nanoreactor for the proteolytic digestion of isolated proteins; and a chromatographic unit for the separation of peptide fragments from the digestion of proteins. The nanopillars and nanotubes may also be used to increase surface area for reaction with a solid phase, for example, with immobilized enzymes or other catalysts within a microchannel, or as a solid support for capillary electrochromatography-based separations of proteins or peptides.

A display process method, a data analysis apparatus, and a program are provided that allow a plurality of pieces of data obtained after an analysis to be readily rearranged and displayed. The display process method includes: acquiring the plurality of pieces of data from a data file; arranging and displaying a plurality of gel images in a predetermined order, the plurality of gel images corresponding to the acquired plurality of respective pieces of data; making an inquiry to a user as to whether or not to rearrange and display the plurality of gel images in order of display, the order of display being different from the predetermined order; and rearranging and displaying the plurality of gel images in the order of display.

A sample separation apparatus includes a first-dimension separation unit for separating the fluidic sample, having a first-dimension outlet for outputting the fluidic sample or fractions thereof, and a second-dimension separation unit for further separating the fluidic sample or fractions thereof. The second-dimension separation unit has a second-dimension inlet fluidically coupled to the first-dimension outlet. A modulation unit, coupled between the first-dimension outlet and the second-dimension inlet at a first coupling point, is configured for withdrawing fluid from the first coupling point and for ejecting fluid into the first coupling point. A second-dimension fluid drive is coupled to a second coupling point located between the first-dimension outlet and the second-dimension inlet and downstream from the first coupling point. The second-dimension fluid drive is configured for generating a fluid flow for driving at least part of the fluidic sample after treatment by the first-dimension separation unit through the second-dimension separation unit.

A sample separation apparatus for separating a fluidic sample includes an initial dimension sample separation device configured for separating the fluidic sample, a subsequent dimension sample separation device configured for further separating separated fluidic sample received from the initial dimension sample separation device, a purity detector configured for detecting information indicative of a purity of a portion of the fluidic sample which has been separated by the initial dimension sample separation device, and a control unit configured for controlling, depending on the detected information, whether or not further separation of the portion of the fluidic sample which has been separated by the initial dimension sample separation device is carried out by the subsequent dimension sample separation device.

A method of separating and analysing a plurality of components in a heterogeneous sample is provided. The method comprising the steps of: introducing a separation fluid into a separation channel that is elongate in a first direction; introducing the heterogeneous sample into said channel; separating, in the first direction, the components in the sample; introducing an auxiliary fluid into said channel; creating a lateral distribution of the components in a second direction substantially perpendicular to the first direction; and determining, sequentially, a property of each of the components based on the regimen by which the lateral distribution was created. An apparatus for separating and analysing a plurality of components in a heterogeneous sample is also provided.

An object trapping device enables efficiently trapping a plurality of objects in a specific combination. Each of a first electrode pair (13), a second electrode pair (14), and a third electrode pair (15) in an electrode pair group (3) is applied with an individual AC voltage and traps an object by dielectrophoresis generated in accordance with the AC voltage that is applied.

Spatially distributed optical excitation and integrated waveguides are used for ultrasensitive particle detection based on individual electrokinetic velocities of particles. In some embodiments, chip-integrated systems are used to identify individual particles (e.g., individual molecules) based on their velocity as they move through an optically interrogated channel. Molecular species may be identified and quantified in a fully integrated setting, allowing for particle analysis including molecular analysis that can operate at low copy numbers down to the level of single-cell lysates. In some embodiments, the single-particle velocimetry-based identification and/or separation techniques are applied to various diagnostic assays, including nucleic acids, metabolites, macromolecules, organelles, cell, synthetic markers, small molecules, organic polymers, hormones, peptides, antibodies, lipids, carbohydrates, inorganic and organic microparticles and nanoparticles, whole viruses, and any combination thereof.

A method of operating an electrowetting on dielectric (EWOD) device performs microfluidic diffusion separation. The method includes the steps of: inputting a sample droplet into the EWOD device, wherein the sample droplet includes a mixture of particles including first particles and second particles that are different from each other; inputting a collection droplet into the EWOD device; performing an electrowetting operation to bring the sample droplet into contact with the collection droplet; at an initial time, initiating a process of particle separation by which a portion of the sample droplet is introduced into the collection droplet, wherein the first particles move through the collection droplet at a rate different from the second particles; and after a time interval from the initial time, performing an electrowetting operation to segment a leaving droplet from the collection droplet, wherein the leaving droplet has a higher concentration of the first particles relative to the second particles as compared to a concentration of the first particles relative to the second particles in the sample droplet at the initial time. The method may be performed by an AM-EWOD control system executing program code stored on a non-transitory computer readable medium.

Microfluidic chips that can comprise thin substrates and/or a high density of vias are described herein. An apparatus comprises: a silicon device layer comprising a plurality of vias, the plurality of vias comprising greater than or equal to about 100 vias per square centimeter of a surface of the silicon device layer and less than or equal to about 100,000 vias per square centimeter of the surface of the silicon device layer, and the plurality of vias extending through the silicon device layer; and a sealing layer bonded to the silicon device layer, wherein the sealing layer has greater rigidity than the silicon device layer. In some embodiments, the silicon device layer has a thickness between about 7 micrometers and about 500 micrometers while a via of the plurality of vias has a diameter between about 5 micrometers and about 5 millimeters.

A microchip electrophoresis apparatus includes a microchip, a dispensing part, a suction part, and a control part. The control part is configured to perform a buffer solution filling step and a liquid surface aligning step. In the buffer solution filling step, a buffer solution is filled in a channel of the microchip, and also a liquid surface level of the buffer solution in a first reservoir and a liquid surface level of the buffer solution in a second reservoir provided on the other end of the channel are set to a predetermined level or more. The liquid surface aligning step is performed after the buffer solution filling step. In the liquid surface aligning step, tips of a first suction nozzle and a second suction nozzle are lowered from above the first reservoir and the second reservoir to the predetermined level while allowing the first suction nozzle and the second suction nozzle to perform suction operation, such that the buffer solution in the first reservoir and the second reservoir is sucked in order from a surface layer side, and aligning the liquid surface level of the first reservoir with the liquid surface level of the second reservoir.