Microfluidic probe head for processing a sequence of separate liquid volumes separated by spacers. The microfluidic probe head includes: an inlet, an outlet, a first fluid channel and a second fluid channel and a fluid bypass connecting the first fluid channel and the second fluid channel. The first fluid channel delivers the sequence of separate liquid volumes from the inlet toward a deposition area, the fluid bypass allows the spacers to be removed from the first fluid channel obtaining a free sequence of separate liquid volumes without spacers, the first fluid channel delivers the free sequence of separate liquid volumes to the deposition area, and the second fluid channel delivers the removed spacers from the fluid bypass to the outlet. The present invention also provides a microfluidic probe and method for processing a sequence of separate liquid volumes.

A method for providing a solution of a substance in a microfluidic device includes providing a dispersion of a first medium and of a lyophilizate of the substance, the lyophilizate being insoluble in the first medium, and adding a second medium to the dispersion, the lyophilizate being soluble in the second medium. The method further includes dissolving the lyophilizate in the second medium such that the solution of the substance in the second medium is obtained, and separating the solution obtained by the dissolving of the lyophilizate from the first medium.

Provided is a separating apparatus including separating unit configured to apply external force to a fluid sample containing two or more components immiscible with each other and having different specific gravities to separate the fluid sample into separation target and non-separation target, and a transfer mechanism configured to apply a pressure to the separation target separated by the separating unit to transfer he separation target.

A microfluidic device comprising one or more fluidic microchannels and one or more arrays of wireless bipolar electrodes is disclosed. The disclosed microfluidic device can be used to separate cells, especially rare cells, from its biological matrix. The disclosed device can isolate 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.

Apparatuses and methods are described herein for processing polynucleotides in a sealed path environment. The apparatuses include optical sensors to monitor operations and to track material usage for good manufacturing practice.

Methods and apparatuses for making and using therapeutics, including in particular mRNA therapeutics, that separate double-stranded RNA from single-stranded RNA as part of a continuous flow. These methods and apparatuses may include formulation of an RNA therapeutic using a permeable insert integrated into a microfluidic path device. In particular, these methods and apparatuses may include formulation of an RNA therapeutic by removing dsRNA from a solution of RNA by within a microfluidic path device including a cellulose material.

This relates to acoustic microfluidic systems that can generate emulsions/droplets or encapsulate particles of interest (including mammalian cells, bacteria cells, or other cells) into droplets upon detection of the particles of interest flowing in a stream of particles. The systems operate on the detect/decide/deflect principle wherein the deflection step, in a single operation, not only deflects particles of interest from a stream of particles but also encapsulates the particles of interest in an emulsion droplet. The microfluidic systems have an abrupt transition in the channel geometry from a shorter channel to a taller channel (i.e., in the shape of a step) to break the stream of the dispersed phase into a droplet upon acoustic actuation. When there is no acoustic wave present, no droplets/emulsions are generated and the stream of particles proceeds uninterrupted. The rapid actuation and post-actuation recovery employed by the microfluidic systems taught herein ensure that the vast majority of selected particles are properly deflected, that few or no empty droplets are produced, and that total throughput remains high.

The present invention features the use of lateral cavity acoustic transducers (LCATs) to apply mechanical stimuli on cells. LCATs utilize the generated acoustic microstreaming vortices to trap cells and apply tunable shear-induced cell deformation on them. The present invention may use such a portable, automated, and high throughput device for shear-induced cell transfection.

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 having optically transmissive properties. 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.

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 having optically transmissive properties. 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.