A microfluidic device comprises a lower layer that is electrically conductive and transparent with respect to an incident optical beam, an upper layer, comprising first portions that are electrically conductive and second portions that are electrically insulating, adjacent and alternated to the first ones; a compartment seamlessly extending between the lower layer and the upper layer; the compartment contains a filler medium configured to emit an optical emission beam and markers dispersed in the filler medium, which are electrically charged and are adapted to move inside the compartment in all directions according to the intensity of the electrical signal applied to the first portions, the filler medium is configured to interact with the markers to increase or decrease the intensity of the optical emission beam according to the local concentration of the markers.

Methods for on-demand printing discrete entities including, e.g., cells, media or reagents to substrates are provided. In certain aspects, the methods include manipulating qualities of the entities or biological components thereof. In some embodiments, the methods may be used to create arrays of microenvironments and/or for two and three-dimensional printing of tissues or structures and/or for in situ printing for microsurgeries. Systems and devices for practicing the subject methods are also provided.

Disclosed herein are cartridges for transfecting cells and/or generating clonal populations of cells comprising: a) a first compartment configured for performing cell transfection, wherein the first compartment comprises a first inlet configured for introduction of a cell sample; b) a second compartment configured for performing cell selection, wherein an inlet of the second compartment is operably coupled to an outlet of the first compartment, and wherein the second compartment further comprises at least one optically-transparent wall and an outlet that is operably coupled to an intermediate cell removal port; and c) a third compartment configured for performing cell expansion, wherein an inlet of the third compartment is operably coupled to the outlet of the second compartment.

A particle arrangement transportation device includes: a base material in which is formed a flow channel from an inlet port-side opening through which a solution containing particles to be an object of arrangement and transportation is introduced to an outlet port-side opening; an electrode which is formed along the flow channel on a wall surface of the base material being exposed in the flow channel; electrodes which are formed along the flow channel in the base material on both sides of the flow channel; and a power supply which applies an AC voltage between the electrodes.

There is provided a biological substance detection chip having high detection accuracy. The present technology provides a biological substance detection chip which is composed of a plurality of pixels in which the pixel includes at least a holding surface on which a biological substance is held and a photoelectric conversion unit that is provided below the holding surface and provided on a semiconductor substrate, wherein a partition wall made of a conductor is provided between the pixels on the holding surface. In addition, the present technology provides a biological substance detection device and a biological substance detection system using the biological substance detection chip.

A microfluidic system includes a fluidic platform having a surface, a first liquid disposed onto the fluidic platform, and a droplet disposed onto the first liquid. The first liquid has a first temperature. The droplet has a second temperature higher than the first temperature so that the droplet is levitated above the first liquid by a cushion of vapor of the first liquid. In an embodiment, a device is configured to provide a magnetic field that has variable strength across the surface. A location of a magnetic droplet relative to the surface area is affected by the magnetic field. A method includes providing a fluidic platform, providing a magnetic field, introducing a first liquid onto the fluidic platform, introducing a first magnetic droplet onto the first liquid, and locally varying the magnetic field.

A microfluidic device comprises upper and lower spaced apart substrates defining a fluid chamber therebetween; an aperture for introducing fluid into the fluid chamber; and a fluid input structure disposed over the upper substrate and having a fluid well for receiving fluid from a fluid applicator inserted into the fluid well. The fluid well communicates with a fluid exit provided in a base of the fluid input structure, the fluid exit being adjacent the aperture. The fluid well comprises first, second and third portions, with the first portion of the well forming a reservoir for a filler fluid; and the second portion of the well being configured to sealingly engage against an outer surface of a fluid applicator inserted into the fluid well. The third portion of the well communicates with the fluid exit and has a diameter at the interface between the third portion and the second portion that is greater than the diameter of the second portion at the interface between the third portion and the second portion.

Disclosed herein is a system to detect and characterize individual particles and cells using at least either optic or electric detection as the particle or cell flows through a microfluidic channel. The system also provides for sorting particles and cells or isolating individual particles and cells.

A microfluidic device and a detection method for the microfluidic device are provided. The microfluidic device includes a driving substrate configured to drive a movement of a droplet; and a position detector configured to detect a position of the droplet on the driving substrate.

An electrowetting device includes a first substrate, a plurality of first electrodes formed on the first substrate, a dielectric layer formed on the plurality of first electrodes, a first water-repellent layer formed on the dielectric layer, a second substrate, a second electrode formed on the second substrate, and a second water-repellent layer formed on the second electrode. The first substrate and the second substrate are arranged with a gap between the first water-repellent layer and the second water-repellent layer. The first electrode includes an indium oxide-zinc oxide layer, the dielectric layer includes a silicon nitride layer, and the silicon nitride layer is formed directly on the indium oxide-zinc oxide layer.