Described herein are digital microfluidic (DMF) devices and corresponding methods for managing reagent solution evaporation during a reaction. Reactions on the DMF devices described here are performed in an air or gas matrix. The DMF devices include a means for performing reactions at different temperatures. To address the issue of evaporation of the reaction droplet especially when the reaction is performed at higher temperatures, a means for introducing a replenishing droplet has been incorporated into the DMF device. A replenishing droplet is introduced every time when it has been determined that the reaction droplet has fallen below a threshold volume. Detection and monitoring of the reaction droplet may be through visual, optical, fluorescence, colorimetric, and/or electrical means.

A system for nucleic acid amplification of a sample comprises partitioning the sample into partitioned sections and performing PCR on the partitioned sections of the sample. Another embodiment of the invention provides a system for nucleic acid amplification and detection of a sample comprising partitioning the sample into partitioned sections, performing PCR on the partitioned sections of the sample, and detecting and analyzing the partitioned sections of the sample.

According to one embodiment, a test kit includes a dropping device is configured to drop a droplet and a test device. The test device includes a reaction tank having an opening into which the droplet is dropped, the reaction tank being configured to house the droplet. The reaction detector is arranged below the opening inside the reaction tank and comprising a surface with a substance to be bound to a detection target substance. The reaction tank has an internal volume substantially equal to twice an amount of the droplet, or smaller than or equal to twice the amount.

Methods and apparatuses for mechanically controlling microfluidic movement using a force applicator and an elastically deformable sheet are described herein. These apparatuses may include a mechanical microfluidics actuator devices and a cartridge. A microfluidic droplet may be moved or displaced within an air gap of the cartridge by applying a compressive force locally and selectively reduce the gap width of the air gap near the microfluidic droplet causing the microfluidic droplet to move toward the reduced gap. Compressive forces may also be used to divide, join, mix or perform other operations on the microfluidic droplets.

Methods for detecting target analytes utilizing an array of wells are advantageous for detection of low concentrations of target analytes. Use of an array of wells requires sealing of the wells. The methods provided herein utilize digital microfluidics to seal wells of an array with a fluid that is immiscible with the aqueous liquid present in the wells to prevent evaporation and contamination of the aqueous fluid during analysis of signals from the wells. The disclosed method include generating a biphasic droplet composed of the immiscible fluid and an aqueous fluid. The immiscible fluid present in the biphasic droplet is moved over the array of wells to seal the wells by electrically actuating the aqueous fluid present in the biphasic droplet which in turn pulls the immiscible fluid.

A microfluidic valve may include a first portion of a liquid conduit to contain a gas, a second portion of a liquid conduit to contain a liquid, and a constriction between the first portion and the second portion and across which a capillary meniscus is to form between the gas and the liquid. The microfluidic valve may further include a drop jetting device within the second portion to open the valve by breaking the capillary meniscus across the constriction.

Disclosed are an array substrate and a preparation method thereof, and a digital microfluidic chip. The preparation method includes: forming a plurality of photoelectric detection devices on a silicon-based substrate; transferring the photoelectric detection devices to a base substrate by adopting a micro transfer printing process; and forming a plurality of transparent driving electrodes on the base substrate, wherein the transparent driving electrodes are insulated from the photoelectric detection devices.

A digital microfluidic (DMF) system, DMF cartridge, and method including integrated refractive index (RI) sensing is disclosed. The digital microfluidic DMF system and DMF cartridge may include, for example, a RI sensor (or sensor surface) directly in the droplet operations gap of a DMF cartridge. The digital microfluidic DMF system may include, for example, the DMF cartridge, one or more illumination sources, one or more optical measurement devices, and a controller. Additionally, a method of using the DMF system and DMF cartridge that includes integrated RI sensing is provided.

The present disclosure generally relates to systems and methods for detecting viruses, e.g., using microfluidic devices. Certain embodiments are generally directed to systems and methods that are able to detect pathogens such as viruses or bacteria by encapsulating a sample in droplets, and applying amplification reagents to the droplets able to amplify nucleic acids therein, e.g., using loop mediated isothermal amplification (LAMP) or other amplification techniques. In addition, some aspects are generally directed to identifying a species in a sample, e.g., at very low concentrations. In some cases, the sample may be broken into droplets, arid the droplets determined to determine the species.

Provided is a method including encapsulating a biological material in a droplet having a volume of 500 nl or less, depositing the droplet to an addressable location of a substrate, and performing mass spectroscopy on the droplet. The method can further include conducting omic analysis on the droplet, such as sequencing DNA or analyzing mRNA, after the mass spectroscopy. In some cases, the method can be used to screen thousands of genetically different cells to identify correlations between genetics and the production of a metabolite, wherein the metabolite is detected by mass spectroscopy. Also provided is a system for performing the method.