There is described herein methods and devices for confining and/or manipulating molecules. At least one molecule is introduced into a fluidic chamber. The fluidic chamber is formed inside a device comprising at least one first electrode having a first surface spaced from at least one second electrode having a second surface facing the first surface. The at least one second electrode has a plurality of dielectric structures arranged to form openings along the second surface. At least one electrical signal is applied across the at least one first electrode and the at least one second electrode to generate a non-uniform electric field having electric field lines extending from the first surface of the at least one first electrode to the second surface of the at least one second electrode in the openings formed between the dielectric structures. The at least one electrical signal has a frequency level causing the at least one molecule to move inside the fluidic chamber in accordance with a predetermined movement.

The present invention provides novel microfluidic substrates and methods that are useful for performing biological, chemical and diagnostic assays. The substrates can include a plurality of electrically addressable, channel bearing fluidic modules integrally arranged such that a continuous channel is provided for flow of immiscible fluids.

A biological sorting apparatus is disclosed, which includes a light-induced dielectrophoretic chip, a supporting platform, an injecting unit and a projection module. The light-induced dielectrophoretic chip is configured to generate an internal electric field to perform sorting on a fluid including first microparticles and second micropartides. The supporting platform is utilized to support the light-induced dielectrophoretic chip thereon and has an opening. The injecting unit is configured to inject the fluid into the light-induced dielectrophoretic chip. The projection module is disposed below the supporting platform and is configured to project a light pattern onto a projection area of the light-induced dielectrophoretic chip through the opening of the supporting platform, such that the light-induced dielectrophoretic chip produces a light-induced effect to change the internal electric field, thereby sorting out the first microparticles and the second microparticles.

A method for enriching a heterogeneous population of cells includes loading one or more sample chambers containing DEP electrodes therein with a solution containing the heterogeneous population of cells, wherein the heterogeneous population of cells comprises a first subpopulation of cells having a first crossover frequency and a second subpopulation of cells having a second, higher crossover frequency. An AC electrical field is applied to the DEP electrodes, wherein the AC electrical field has an applied frequency that is between the crossover frequency of the first subpopulation of cells and the second subpopulation of cells, wherein the first subpopulation of cells are substantially killed by the applied electrical field and the second subpopulation of cells are substantially not killed by the applied electrical field.

Provided herein are systems and method for measuring cell stiffness. In particular, provided herein are microelectrode configuration and systems for measuring platelet deformation and stiffness.

A method for performing contactless ODEP for separation of CTCs is provided with the steps of obtaining patients' blood with rare cell suspected CTCs; adding at least one fluorescent antibody binding to CTCs into the blood; staining the blood; injecting the stained blood with fluorescent dye into an ODEP device and then performing fluorescent image identification; trapping the CTCs with at least one fluorescent antibody in the ODEP device by creating an image pattern and then generating an ODEP force; Separating the trapped CTCs from other non-CTCs cells; absorbing the trapped CTCs; and obtaining a high purity of CTCs. An apparatus for performing contactless ODEP for separation of CTCs is also provided.

Provided herein are systems and method for measuring cell stiffness. In particular, provided herein are microelectrode configuration and systems for measuring platelet deformation and stiffness.

Apparatuses and methods for selectively transmitting objects of interest from a first reservoir to a second reservoir are disclosed. The apparatuses include electromagnetic focusing apparatuses configured to interact with objects of interest to induce a change in a property of the objects of interest so as to increase or decrease the probability that the objects of interest pass through a throat diffusively coupling the first reservoir and the second reservoir.

Methods and apparatus for detecting, quantifying, enriching, and/or separating bacterial species in fluid sample are provided. The fluid sample is provided as input to a microfluidic passage of a microfluidic device, wherein the microfluidic device comprises at least one electrode disposed adjacent to the microfluidic passage. The at least one electrode is activated to capture bacteria in the sample using dielectrophoresis, wherein the capture efficiency of bacteria is at least 99%.

A apparatus for performing contactless ODEP for separation of CTCs comprises an ODEP device including a first conductive glass and a second conductive glass, the first conductive glass includes a transverse main channel and a longitudinal micro channel perpendicular to the main channel and joining the main channel at a cell separation zone; the first conductive glass includes a first hole and a second hole aligned with two ends of the main channel respectively, and a third hole aligned with one end of the micro channel that is distal to the cell separation zone; a sample receiving member disposed on and aligned with the first hole; an exhaust discharge member disposed on and aligned with the second hole; a target collection member disposed on and aligned with the third hole; and a controller including an optical projection device and an image fetch device.