A microfluidic probe includes a probe head with a processing surface that includes a first aperture and a second aperture. The probe further includes a liquid injection channel, which leads to the first aperture, and a liquid aspiration channel, which extends from the second aperture. The probe also includes a bypass channel, arranged so as to fluidly connect the liquid injection channel to the liquid aspiration channel, as well as a control channel. The latter fluidly connects to the bypass channel, hence forming a junction therewith, so as to define two portions of the bypass channel. These portions includes: a first portion that extends from the junction to the liquid injection channel; and a second portion that extends from that same junction to the liquid aspiration channel. The invention is further directed to methods of operation of a probe as described above, to process a surface.

An analysis system may perform operations on an analyte that may be combined with multiple regents prior to being introduced into a flow cell. The instrument may include a volume into which the reagents to be combined with the analyte are aspirated one-by-one. The volume may be formed as a serpentine channel in a valve manifold associated with sippers for aspirating the reagents. The reagents may then be mixed by cycling a pump to move the reagents within the mixing volume or channel. For this, the reagents may be aspirated from a recipient into the volume or channel, ejected back into the recipient, and this process may be performed repeatedly to enhance mixing.

Methods and devices for pretreatment of a conducting sampling substrate which enable an electrostatic charge to be used to transfer analyte molecules onto a sampling substrate, where the analyte molecules are in powder or particulate form. In an embodiment of the present invention, the electrostatic charge can be used to transfer powder samples containing nitrogenous bases, nucleosides, food additives, and prescription drugs such as acetaminophen, oxycodone, and dextromethorphan. In an embodiment of the present invention, a powder sample is transferred to a pre-treated sampling substrate using an electrostatic charge. The spatial distribution of the powder on the original surface is retained on the pre-treated sampling substrate using the electrostatic charge transfer. The electrostatic charge transfer can be used to transfer powder samples present on a surface or in the chambers of 96, 384 and 1536 well plate formats to either pins or mesh and analyzed with ambient desorption ionization.

The present invention aims at providing a fluidic device that can hold a large amount of solutions in a reservoir without depending on an attitude. The reservoir includes a meandering flow path including: a plurality of first flow paths that extend linearly along a first direction and that are arranged to be spaced in a second direction crossing the first direction; and a second flow path that extends linearly along the second direction such that a connection between first end sides of the adjacent first flow paths and a connection between second end sides of the adjacent first flow paths are alternately switched along the second direction for each first flow path, wherein the meandering flow path meanders along the second direction. When the length of each of the first flow path and the second flow path is L, a surface tension is γ, the density of the solution is ρ, the acceleration which includes a gravity and which is applied to the solution is G, the wetted perimeter length of the first flow path and the second flow path is Wp, a cross-sectional area of the first flow path and the second flow path is A, a receding contact angle is α, and an advancing contact angle is β, a relationship L≤(γ×Wp×(cos α−cos β))/(ρ×A×G) is satisfied.

Systems and methods for continuous flow polymerase chain reaction (PCR) are provided. The system comprises an injector, a mixer, a coalescer, a droplet generator, a detector, a digital PCR system, and a controller. The injector takes in a sample, partitions the sample into sample aliquots with the help of an immiscible oil phase, dispenses waste, and sends the sample aliquot to the mixer. The mixer mixes the sample aliquot with a PCR master mix and diluting water, dispenses waste, and sends the sample mixture (separated by an immiscible oil) to the coalescer. The coalescer coalesces the sample mixture with primers dispensed from a cassette, dispenses waste, and sends the reaction mixture (separated by an immiscible oil) to the droplet generator. The droplet generator converts the sample mixture into an emulsion where aqueous droplets of the reaction mixture are maintained inside of an immiscible oil phase and dispenses droplets to the digital PCR system. The digital PCR system amplifies target DNAs in the droplets. The detector detects target DNAs in the droplets. The controller controls the system to run automatically and continuously.

The present invention provides devices and systems for use at the point of care. The methods devices of the invention are directed toward automatic detection of analytes in a bodily fluid. The components of the device are modular to allow for flexibility and robustness of use with the disclosed methods for a variety of medical applications.

The present invention generally relates to systems and methods for the control of fluids and, in some cases, to systems and methods for flowing a fluid into and/or out of other fluids. As examples, fluid may be injected into a droplet contained within a fluidic channel, or a fluid may be injected into a fluidic channel to create a droplet. In some embodiments, electrodes may be used to apply an electric field to one or more fluidic channels, e.g., proximate an intersection of at least two fluidic channels. For instance, a first fluid may be urged into and/or out of a second fluid, facilitated by the electric field. The electric field, in some cases, may disrupt an interface between a first fluid and at least one other fluid. Properties such as the volume, flow rate, etc. of a first fluid being urged into and/or out of a second fluid can be controlled by controlling various properties of the fluid and/or a fluidic droplet, for example curvature of the fluidic droplet, and/or controlling the applied electric field.

Systems and methods are provided for automatically tailoring treatment of samples in sample containers carried in a rack. The systems and methods may identify sample containers in the rack and/or detect various characteristics associated with the containers and/or the rack. This information may then be used to tailor their treatment, such as by aspirating and dispensing fluid from the sample containers in a way that accounts for the types of the samples/containers carrying them.

A cell picking device for sucking cells from a liquid sample in a sample container includes a sucking member to which a pipette tip is attachable, a driver that moves the sucking member and performs suction through the sucking member and the pipette tip, a work mode switcher that switches a work mode of the driver between a first mode and a second mode, and a controller that controls the driver.

Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.