The present application provides a microdroplet container and a method for manufacturing the same, a method for spreading microdroplets, a microdroplet-generating kit, a temperature-controlling device, an oil phase composition for microdroplet generating and a method for treating the same.

Disclosed herein include systems, devices, and methods for generating and directly loading droplets onto a microfluidic device with contactless delivery. Droplets can be generated and loaded onto a sealed microfluidic device through one or more connecting ports. Loaded droplets can be manipulated, such as merged.

Methods and systems for thermally controlling a chemical reaction in droplets. In an exemplary method, a first thermal zone and a second thermal zone having different temperatures from one another may be created in a reaction chamber. An emulsion including droplets encapsulated by a carrier fluid may be held in the reaction chamber. The droplets may have a density mismatch with the carrier fluid, and each droplet may include one or more reactants for the chemical reaction. An orientation of the reaction chamber may be changed to move the droplets from the first thermal zone to the second thermal zone, such that a rate of the chemical reaction changes in at least a subset of the droplets.

In one example in accordance with the present disclosure, a fluid ejection device is described. The fluid ejection device includes a vertical support and an interface movably coupled to the vertical support. The interface is to receive an ejection head. The fluid ejection device also includes a manual adjustment device associated with the interface to adjust a distance between the interface and a substrate stage.

A pipette device comprises a pipette channel filled with compressible working gas, a pipette piston movable along the pipette path, a piston drive, which drives the pipette piston, a control device, a data memory connected to the control device for signal transmission, a pressure sensor which detects the pressure of the working gas and which is connected to the control device, a position sensor which detects a position of the pipette piston and which is connected to the control device. The control device is designed to determine a quality of a dispensing sequence on the basis of a target residual quantity value, which represents the target residual quantity of dosing liquid remaining in the pipette channel, of a working gas pressure and of an end position of the pipette piston, in each case after the end of the dispensing sequence, and to output the determined quality.

Methods and systems for thermally controlling a chemical reaction in droplets. In an exemplary method, a first thermal zone and a second thermal zone having different temperatures from one another may be created in a reaction chamber. An emulsion including droplets encapsulated by a carrier fluid may be held in the reaction chamber. The droplets may have a density mismatch with the carrier fluid, and each droplet may include one or more reactants for the chemical reaction. An orientation of the reaction chamber may be changed to move the droplets from the first thermal zone to the second thermal zone, such that a rate of the chemical reaction changes in at least a subset of the droplets.

A liquid deposition system comprises a liquid delivery assembly including a dispensing probe having a sidewall including a first end having a liquid port and a second end having a tip, and a flow path opening at the tip and fluidly connected with the liquid port. The system includes a gas injection assembly with a manifold having a gas nozzle, a nozzle opening, and a gas port, the gas nozzle configured to eject a substantially laminar gas stream so that the gas stream travels through a travel path, the tip of the dispensing probe extending into the travel path. The liquid port is fluidly connectable with a liquid source and the gas port is fluidly connectable with a pressurized gas source, so that a liquid micro droplet is formed at the tip. The laminar gas stream separates the micro droplet from the tip and carries it through the travel path.

A device and method are proved for transferring a target from a first location to a second location. The target is bound to solid phase substrate to form a target bound solid phase substrate. The device includes transfer surface for receiving the target bound solid phase substrate thereon for transfer. The transfer surface movable between a first position wherein the transfer surface is aligned with the first location and spaced therefrom by a distance and a second position wherein the transfer surface is aligned with the second location. An alignment structure aligns the transfer surface with respect to the second location, with the transfer surface in the second position. A force is movable between an attraction position wherein the target bound solid phase substrate are drawn toward the transfer surface and a discharge position wherein the target bound solid phase substrate are free of the force.

A device and method are proved for transferring a target from a first location to a second location. The target is bound to solid phase substrate to form a target bound solid phase substrate. The device includes transfer surface for receiving the target bound solid phase substrate thereon for transfer. The transfer surface movable between a first position wherein the transfer surface is aligned with the first location and spaced therefrom by a distance and a second position wherein the transfer surface is aligned with the second location. An alignment structure aligns the transfer surface with respect to the second location, with the transfer surface in the second position. A force is movable between an attraction position wherein the target bound solid phase substrate are drawn toward the transfer surface and a discharge position wherein the target bound solid phase substrate are free of the force.

A device and method are proved for transferring a target from a first location to a second location. The target is bound to solid phase substrate to form a target bound solid phase substrate. The device includes transfer surface for receiving the target bound solid phase substrate thereon for transfer. The transfer surface movable between a first position wherein the transfer surface is aligned with the first location and spaced therefrom by a distance and a second position wherein the transfer surface is aligned with the second location. An alignment structure aligns the transfer surface with respect to the second location, with the transfer surface in the second position. A force is movable between an attraction position wherein the target bound solid phase substrate are drawn toward the transfer surface and a discharge position wherein the target bound solid phase substrate are free of the force.