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.

This invention relates to compositions of matter, methods, modules and instruments for automated mammalian cell growth and mammalian cell transduction followed by nucleic acid-guided nuclease editing in live mammalian cells. The present compositions and methods entail viral delivery of an editing cassette to live mammalian cells such that the editing cassettes edit the cells and the edited cells continue to grow, preferably using a fully-automated end-to-end instrument to process the cells without human intervention to enhance cell processing uniformity and to maintain the integrity of the cell culture.

A microfluidic device (100) comprises an emulsification section (101) comprising one or more emulsification units (170); and a container section (102) comprising one or more groups of containers comprising one group of containers for each emulsification unit; each emulsification unit (170) comprising a fluid conduit network (135) comprising: a plurality of supply conduits comprising a primary supply conduit (103) and a secondary supply conduit (106); a transfer conduit (112); and a first fluid junction (120) providing fluid communication between the primary supply conduit (103), the secondary supply conduit (106), and the transfer conduit (112); each group of containers (103) comprising a plurality of containers comprising an intermediate chamber (174), a collection container (134), and one or more supply containers (131) comprising a secondary supply container, the secondary supply container (131) defining a secondary supply cavity, the secondary supply container (131) comprising a secondary orifice (177) extending from the secondary supply cavity and a primary orifice (176) extending from the secondary supply cavity, the collection container (134) being in fluid communication with the transfer conduit (112) of the corresponding emulsification unit (170) via a collection orifice of the collection container (134), the secondary supply container (131) being in fluid communication with the secondary supply conduit (106) of the corresponding emulsification unit (170) via the secondary orifice (177), the secondary supply container (131) being in fluid communication with the intermediate chamber (174) of the same group of containers (103) via the primary orifice (176), the intermediate chamber (174) being in fluid communication with the first fluid junction (120) of the corresponding emulsification unit (170) via the primary supply conduit (103) of the corresponding emulsification unit (170). Furthermore a method of manufacturing said device and a method for providing emulsion droplets using such a microfluidic device.

A device may include a substrate, a first fluid processing chip, a second fluid processing chip, a tapered channel, and a fluid actuator. The first fluid processing chip may be disposed on the substrate and may process a micro-volume of fluid. The second fluid processing chip may be disposed on the substrate and co-planar with the first fluid processing chip. The second fluid processing chip may process at least a portion of the micro-volume of fluid. The tapered channel may be disposed between the first and second fluid processing chips to transport the at least the portion of the micro-volume of fluid from the first fluid processing chip to the second fluid processing chip. The fluid actuator may be disposed proximate to the tapered channel and may control movement of the at least the portion of the micro-volume of fluid within the tapered channel.

A method of replacing liquids including introducing a second liquid into a fluidic device which includes a substrate having wells formed on a surface thereof, the wells including openings which accommodate a first liquid including a surfactant and are sealed with a first sealing solution applied on the surface of the substrate, where the introducing includes supplying the second liquid to the surface such that the first sealing solution is replaced with the second liquid, and that the second liquid is introduced into the wells.

Embodiments disclosed herein may relate to a testing apparatus. The testing apparatus may include a sealed, chemically-resistant testing apparatus body defining a testing void; a first fluid port and a second fluid port; and a first geomaterial and a second geomaterial. The first and second geomaterials may be positioned between the first fluid port and the second fluid port and relative to one another such that a flow channel may be provided between the first and second geomaterials. The first and second geomaterials may be coupled to a testing void interior surface so as to restrict flow to the flow channel between an upflow region and a downflow region of the testing void. The first and second geomaterials may be comprised of a natural formation material.

The present invention relates to a bioreactor. The bioreactor includes a fluidic channel layer including a set of channels configured to generate a suction caused by a negative pressure or a retrieval force caused by a positive pressure; an elastic conductive layer configured with a pair of electrodes, configured on the fluidic channel layer, driven by the suction or the retrieval force to have a deformation toward a deformation direction, and receiving a voltage difference by the pair of the electrodes to form an electrical field along an electrical field direction; and a culture layer configured on the elastic conductive layer and providing for a biological tissue to culture in vitro on the elastic conductive layer.

A fluid handling device according to an embodiment of the present invention is a fluid handling device that includes a substrate and a film bonded to the substrate and that is configured to process a fluid, the fluid handling device including: a channel; a well connected to the channel; a rotary membrane valve disposed between the channel and the well; and a rotary membrane pump connected to the channel. For example, in the fluid handling device according to the embodiment of the present invention, a filter is disposed in the well or between the well and the rotary membrane valve for separating a blood cell component.

A mixing system that employs a pump with a highly sensitive means of adding and controlling volumes of single or multiple reagents to a controllable volume of a sample, mixing said samples and reagents, providing the means of employing a specific measurement tool on some portion of the mixed sample, and finally reporting the results to a final control element automatically under industrial conditions and often essentially in situ to fluid flows such as fluid moving through a pipeline or industrial process.

The present disclosure relates to a method for separating an aqueous liquid comprising biological material into at least two cavities, the use of a polysiloxane having at least one hydroxy group in such a method, as well as a system for separating an aqueous liquid into at least two cavities.