Methods and apparatus for controlling flow in a microfluidic arrangement are disclosed. In one arrangement, a microfluidic arrangement comprises a first liquid held predominantly by surface tension in a shape defining a microfluidic pattern on a surface of a substrate. The microfluidic pattern comprises at least an elongate conduit and a first reservoir. A second liquid is in direct contact with the first liquid and covers the microfluidic pattern. A flow of liquid is driven through the elongate conduit into the first reservoir. The microfluidic pattern and the depth and density of the second liquid are such that the first reservoir grows in volume during the flow of liquid into the first reservoir, without either of the size and shape of an area of contact between the first reservoir and the substrate changing, until an upper portion of the first reservoir detaches from a lower portion of the first reservoir due to buoyancy and rises upwards through the second liquid, thereby allowing the first reservoir to continue to receive liquid from the flow of liquid without any change in the size and shape of the area of contact between the first reservoir and the substrate.

The invention relates to a device for sampling from bioreactors, comprising a rising line (1) connectable to a bioreactor, a tap line (2), and a withdrawal line (3), which are connected to a T-like connection. The withdrawal line (3) comprises a first shut-off valve (4), the tap line (2) is connected to a positive pressure source (5), and the withdrawal line (3) is connected to a pump (7). In the device for sampling, the positive pressure source (5), the pump (7), and the first shut-off valve (4) are controllable in an automated manner via a control unit (13). The invention furthermore relates to a method for using such a device for sampling.

It discloses a system for deep sediment flow culture simulating in-situ water pressure, comprising a flow culture apparatus, an inflow pressurizer and an outflow depressurizer, wherein the inflow pressurizer comprises a pressure tank, an air inlet pipe, a pressure regulating valve, a pressure-resistant container and a first support, wherein the pressure tank is connected with an air inlet of the pressure-resistant container through the air inlet pipe, the pressure regulating valve is arranged on the air inlet pipe, and the pressure-resistant container containing in-situ overlying water added with isotopes is placed on the first support, a water outlet of the pressure-resistant container being connected with a water inlet pipe of the flow culture apparatus; the outflow depressurizer comprises a porous medium pipe, a second support, a depressurized water outlet pipe and a water catcher.

The present disclosure provides an automatic microfluidic system for rapid personalized drug screening including a microfluidic chip. The microfluidic chip includes a fluid storage unit, a fluid driving unit, a reaction unit and a plurality of valve units. The fluid driving unit includes two mixing pumps. Each of the mixing pumps includes two pneumatic micro-pumps, a mixing chamber and a blocking structure. The blocking structure is disposed in the mixing chamber and is connected between the two pneumatic micro-pumps. When the two pneumatic micro-pumps are started alternately, the blocking structure is deflected alone with the operation of the two pneumatic micro-pumps.

Cell culture systems and methods provide improved immunotherapeutic product manufacturing with greater scalability, flexibility, and automation. Cell culture systems are configured with interchangeable cartridges, allowing versatility and scalability. Systems are configured to have multiple connected cell culture chambers, which allows parallel processing of different types of cells. Gas-impermeable cell culture chambers and methods for generating cells in closed systems prevent contamination and user error. Methods for recycling cell culture medium provide additional efficiencies.

Cell culture systems and methods provide improved immunotherapeutic product manufacturing with greater scalability, flexibility, and automation. Cell culture systems are configured with interchangeable cartridges, allowing versatility and scalability. Systems are configured to have multiple connected cell culture chambers, which allows parallel processing of different types of cells. Gas-impermeable cell culture chambers and methods for generating cells in closed systems prevent contamination and user error. Methods for recycling cell culture medium provide additional efficiencies.

Cell culture systems and methods provide improved immunotherapeutic product manufacturing with greater scalability, flexibility, and automation. Cell culture systems are configured with interchangeable cartridges, allowing versatility and scalability. Systems are configured to have multiple connected cell culture chambers, which allows parallel processing of different types of cells. Gas-impermeable cell culture chambers and methods for generating cells in closed systems prevent contamination and user error. Methods for recycling cell culture medium provide additional efficiencies.

Cell culture systems and methods provide improved immunotherapeutic product manufacturing with greater scalability, flexibility, and automation. Cell culture systems are configured with interchangeable cartridges, allowing versatility and scalability. Systems are configured to have multiple connected cell culture chambers, which allows parallel processing of different types of cells. Gas-impermeable cell culture chambers and methods for generating cells in closed systems prevent contamination and user error. Methods for recycling cell culture medium provide additional efficiencies.

Cell culture systems and methods provide improved immunotherapeutic product manufacturing with greater scalability, flexibility, and automation. Cell culture systems are configured with interchangeable cartridges, allowing versatility and scalability. Systems are configured to have multiple connected cell culture chambers, which allows parallel processing of different types of cells. Gas-impermeable cell culture chambers and methods for generating cells in closed systems prevent contamination and user error. Methods for recycling cell culture medium provide additional efficiencies.

Cell culture systems and methods provide improved immunotherapeutic product manufacturing with greater scalability, flexibility, and automation. Cell culture systems are configured with interchangeable cartridges, allowing versatility and scalability. Systems are configured to have multiple connected cell culture chambers, which allows parallel processing of different types of cells. Gas-impermeable cell culture chambers and methods for generating cells in closed systems prevent contamination and user error. Methods for recycling cell culture medium provide additional efficiencies.