A method for aligning sequences of droplets in streams of an emulsion comprising target droplets and tag droplets, a tag droplet comprising first and second tags. A target droplet is split into first and second target droplets and a tag droplet is split into first and second tag droplets. Each of the first and second tag droplets comprise the first and second tags. The first target droplet and first tag droplet are in a first stream of droplets, and the second target droplet and second tag droplet are in a second stream of droplets. The method detects the first tag droplets and first target droplets in the first stream and the second tag droplets and second target droplets in the second stream, determines a first sequence of droplets in the first stream and a second sequence of droplets in the second stream, and compares these to align the sequences.

A test device is configured for diagnostic testing and includes an optical readable medium, in turn including a pattern of spots of material arranged on a surface of the device. Several patterns may be provided. The patterns accordingly formed may be human and/or machine readable. They may notably encode security information, e.g., indicating whether the device has already been used. The spots may notably be inkjet spotted. In addition, a method is provided for decoding information encoded in a pattern of such a test device. In embodiments, liquid is introduced in the device, which comprises additional spots having a substantially different solubility than spots forming the actual pattern. Thus, the additional spots get solubilized in and flushed by the liquid as the latter wets them, and an initially hidden pattern may be read, which is formed of the remaining spots (not solubilized). Encoding methods are also provided.

A microfluidic device comprising one or more fluidic microchannels and one or more arrays of cell assay units is disclosed. Each cell assay unit in turn comprises at one bipolar electrode, micropocket, reaction chamber, and leak channel. In some embodiments, the cell assay unit further comprises two or more split BPEs inside the reaction chamber. The disclosed microfluidic device can be used to separate cells, especially rare cells, from its biological matrix and then analyze the isolated cell inside the reaction chamber. The disclosed device can isolate and analyze cells in a high-throughput fashion and without any modification or labelling to the cells. Cells isolated using the disclosed devices does not lose their vitality.

A microscale method for the characterization of one or more reaction variables that influence the formation or dissociation of an affinity complex comprising a ligand and a binder, which have mutual affinity for each other. The method is characterized in comprising the steps of: (i) providing a microfluidic device comprising a microchannel structures that are under a common flow control, each microchannel structure comprising a reaction microactivity; (ii) performing essentially in parallel an experiment in each of two or more of the plurality of microchannel structures, the experiment in these two or more microchannel structures comprising either a) formation of an immobilized form of the complex and retaining under flow conditions said form within the reaction microactivity, or b) dissociating, preferably under flow condition, an immobilized form of the complex which has been included in the microfluidic device provided in step (i), at least one reaction variable varies or is uncharacterized for said two or more microchannel structures while the remaining reaction variables are kept essentially constant; (iii) measuring the presentation of the complex in said reaction microactivity in said two or more microchannel structures; and (iv) characterizing said one or more reaction variables based on the values for presentation obtained in step (iii).

Certain embodiments are directed to paper/polymer hybrid microfluidic devices integrated with nano-biosensors for pathogen detection and infectious disease diagnosis.

The combined value of integrating optical forces and electrokinetics allows for the pooled separation vectors of each to be applied, providing for separation based on combinations of features such as size, shape, refractive index, charge, charge distribution, charge mobility, permittivity, and deformability. The interplay of these separation vectors allow for the selective manipulation of analytes with a finer degree of variation. Embodiments include methods of method of separating particles in a microfluidic channel using a device comprising a microfluidic channel, a source of laser light focused by an optic into the microfluidic channel, and a source of electrical field operationally connected to the microfluidic channel via electrodes so that the laser light and the electrical field to act jointly on the particles in the microfluidic channel. Other devices and methods are disclosed.

This disclosure relates to an apparatus for simultaneously filling a plurality of sample chambers. In one aspect, the apparatus comprises a common fluid source and a plurality of independent, continuous fluidic pathways. Each independent, continuous fluidic pathway comprises a sample chamber and a pneumatic compartment. The sample chamber is connected to the common fluid source, and the pneumatic compartment is connected to the sample chamber. The sample chamber comprises, in part, an assay chamber. The assay chamber comprises a monolithic substrate and a plug. In some embodiments, the assay chamber contains a magnetic mixing element. In some embodiments, the assay chamber is a double tapered chamber. In some embodiments, a ratio of a volume of the sample chamber to a volume of the pneumatic compartment is substantially equivalent for each fluidic pathway of the plurality of fluidic pathways.

In one aspect, nanoplasmonic devices are described herein. In some embodiments, a nanoplasmonic device comprises a radiation transmissive substrate, a metal layer positioned on the substrate and at least one aperture extending through the metal layer to the radiation transmissive substrate, wherein width of the aperture decreases with increasing depth of the aperture.

One example includes a device that includes an insulator panel, a plurality of electrical inputs, and a plurality of electrodes. The plurality of electrical inputs may be disposed on the insulator panel and individually receive an actuation voltage. The plurality of electrodes may be disposed on the insulator panel and are coupled to the plurality of electrical inputs. Two or more of the plurality of electrodes may be coupled to a single one of the plurality of electrical inputs for each of the plurality of electrical inputs. The plurality of electrodes may be actuated with the actuation voltage individually received at a respective electrical input to create an electric field over associated electrodes to subject a droplet proximate to the associated electrodes actuated with the actuation voltage to an electrowetting force.

A method for testing a microfluidic device includes interfacing a microfluidic device to a fluidic parameter testing system. The microfluidic device has an internal rotary valve and internal fluidic channels. Each channel has a port with a predetermined port position that the rotary valve is to align to in order to select any one of a plurality of reagents which flow through the channels. The rotary valve is rotated via the testing system to a plurality of rotary valve position of the rotary valve. A fluidic parameter of the microfluidic device is measured at each rotary valve position. The fluidic parameter is mapped relative to the rotary valve positions. It is determined from the mapping if the rotary valve aligns with each of the predetermined port positions for a flow of the reagents through the channels.