The invention, provides a method, apparatus and system for separating blood and other types of cellular components, and can be combined with holographic optical trapping manipulation or other forms of optical tweezing. One of the exemplary methods includes providing a first flow having a plurality of blood components; providing a second flow; contacting the first flow with the second flow to provide a first separation region; and differentially sedimenting a first blood cellular component of the plurality of blood components into the second flow while concurrently maintaining a second blood cellular component of the plurality of blood components in the first flow. The second flow having the first blood cellular component is then differentially removed from the first flow having the second blood cellular component. Holographic optical traps may also be utilized in conjunction with the various flows to move selected components from one flow to another, as part of or in addition to a separation stage.

A particle manipulation device includes a substrate and a microchannel included in the substrate and configured to receive a fluid including particles therein. A biasing structure is formed on the substrate adjacent to, but outside the microchannel. The biasing structure is configured to dispense radiation at a frequency to bias movement of the particles within the microchannel from outside the microchannel.

Embodiments of the present disclosure provide a device for manipulating a substance, the device comprising at least three series of interdigitated electrode pairs, wherein each electrode of each pair is connected to an electrode in an adjacent pair in the respective series by an electrical path, and a dielectric layer disposed on the at least three series of interdigitated electrode pairs, the dielectric layer comprising one or more sub layers. The at least three series of interdigitated electrode pairs are selectively and independently energisable to produce an electric field at a top surface of the dielectric layer so that a substance on the top surface may be manipulated by the electric field. The device further comprises one or more groups of the interdigitated electrode pairs, each group having a longitudinal axis, wherein in each group the respective interdigitated electrode pairs are arranged along the respective longitudinal axis such that along the respective longitudinal axis no two adjacent pairs are from a single one of the at least three series, and no pair is adjacent to two other pairs from a single one of the at least three series.

Methods and systems for purifying one or more microbial cells and/or viruses from a biological sample are provided. The biological sample is added to a well disposed in a medium. A potential is applied across the medium to cause the contaminants to enter one or more walls of the well, and retain the microbial cells and/or viruses in the well. The microbial cells and/or viruses can be removed from the well, and optionally adhered or fixed to a surface, or detected. In one embodiment, the microbial cells and/or viruses are retained in the well by embedding in the medium. The medium including the embedded microbial cells and/or viruses may be excised or otherwise removed and transferred to a glass slide or other solid surface. In some examples, a biological sample containing contaminants and one or more microbial cells is introduced to a well disposed in a porous filter medium, wherein the porous filter medium includes pores smaller than the one or more microbial cells, thereby preventing the one or more microbial cells from entering the porous filter medium.

An exemplary method and system is disclosed that facilitate the integration of multiplexed single-cell impedance cytometry in a high throughput format, which can be deployed upstream from microfluidic sample preparation and/or downstream to microfluidic cell separation. In exemplary method and system may employ impedance-based quantification of cell electrophysiology on the same microfluidic chip (i.e., “on-chip”) to provide distinguishing phenotypic information on the sample, without the need for additional sample handling, preparation or dilution steps as would be needed for other flow cytometry techniques.

A novel Self-Locking Optoelectronic Tweezers (SLOT) for single microparticle manipulation across a large area is provided. DEP forces generated from ring-shape lateral phototransistors are utilized for locking single microparticles or cells in the dark state. The locked microparticles or cells can be selectively released by optically deactivating these locking sites.

The present invention provides a method for detecting an analyte with high sensitivity. In the present method, a solution is supplied onto a substrate comprising a first electrode and a second electrode. Then, an alternating voltage is applied between the first electrode and the second electrode to aggregate, onto the surface between the first electrode and the second electrode by dielectrophoresis, bioparticles and dielectric particles contained in the solution. The aggregated bioparticles are broken to release the analyte contained in the bioparticles. The released analyte is bound to a first antibody and a second antibody to cause the dielectric particles to be immobilized onto the substrate through formation of a sandwich structure composed of the first antibody, the analyte, and the second antibody. Finally, the analyte is detected through the fluorescent substance contained in the immobilized dielectric particles.

Systems, methods, and devices are described herein for identifying, monitoring, isolating, or selecting a cell having a predefined characteristic in a mixed population of cells utilizing a combination of any one or more of iDEP, a region of localized field enhancement, a variable frequency electric field, a wide bandwidth amplifier, and/or an imaging apparatus.

A device for sorting bio-particles by image-manipulated electric force includes a first substrate, a second substrate, a fluidic channel, one or more photosensitive layers and an inlet hole. The first substrate has a first conductive electrode, and the second substrate has a second conductive electrode. The second conductive electrode is disposed opposite the first conductive electrode. The fluidic channel is disposed between the first conductive electrode and the second conductive electrode. The photosensitive layer is conformally disposed on at least one of the surfaces of the first conductive electrode and the second conductive electrode. The inlet hole is disposed in the first conductive electrode and the first substrate, where the inlet hole includes a first opening close to the fluidic channel and a second opening away from the fluidic channel, and the surface area of the first opening is greater than the surface area of the second opening.

A method for assembling multi-component nano-structures that includes dispersing a plurality of nano-structures in a fluid medium, and applying an electric field having an alternating current (AC) component and a direct current (DC) component to the fluid medium containing the plurality of nano-structures. The electric field causes a first nano-structure from the plurality of nano-structures to move to a predetermined position and orientation relative to a second nano-structure of the plurality of nano-structures such that the first and second nano-structures assemble into a multi-component nano-structure.