The present invention is related to a device (1), comprising a unit (2) for generating and emitting electric pulses, two or more electrodes or plates (2a, 2b) of a capacitor that are arranged in one electric circuit with said unit (2), and a treatment space (3) arranged between said electrodes or plates (2a, 2b) so that the treatment space (3) can be penetrated by the emitted electric pulses and an electric field resulting therefrom, characterized in that at least one adjustable resistor (9) is arranged in said electric circuit.

The present invention relates to a device (1) for treating cells for stimulating cell growth, comprising a unit (2) for generating and emitting electric pulses, and a treatment unit (3) having an inlet (3a) and an outlet (3a), a treatment space (4) being formed inside the treatment unit (3), the treatment space (4) being penetrated by the emitted electric pulses and an electric field resulting therefrom, a cell material entering into the treatment space (4) through the inlet (3a) being moved without contact through the treatment space (4) and the electric field penetrating the treatment space (4) to the outlet (3b).

The present invention is related to a treatment unit (3) having an inlet (3a) and an outlet (3b), and a treatment space (4) being formed inside the treatment unit (3) such that it can be penetrated by electric pulses, said treatment space (4) being fluidly connected with the inlet (3a) and the outlet (3b), wherein at least a portion of an inner side face of the treatment space (4) is curved. The present invention is furthermore related to a device comprising such a treatment unit and to a method to be performed with said device, and wherein the inlet (3a) is formed in a top face of the treatment unit (3), and the outlet (3b) is formed in a bottom face of the treatment unit (3).

Systems, methods, and devices for culturing a multicellular structure, such as an organoid. An exemplary system comprises a vessel, an electric/magnetic module, and a control circuit. The vessel may include a culture chamber to contain a multicellular structure. The electric/magnetic module may be configured to be located in the vessel, at a position in or adjacent the culture chamber. The control circuit may be configured to wirelessly power and/or operate the electric/magnetic module.

An object is to provide a method capable of associating position information of a cell with a cell constituent at a single-cell resolution. That is, the present technology provides an analysis method including: an imaging step of imaging a specimen in a state in which the specimen is being overlapped with a surface to which a molecule having a linker cleavable by stimulation, a barcode sequence, and a target capture portion is immobilized via the linker; an association step of associating a position of a cell with the barcode sequence of the molecule at the position by using a specimen image obtained by the imaging; a cleavage step of selectively stimulating the position of the cell to cleave the linker of the molecule at the position; and a binding step of binding the molecule released from the surface by the cleavage with a constituent of the cell via the target capture portion of the molecule.

A cell culture vessel according to an embodiment of the present invention comprises: a base substrate; at least one deposited graphene layer provided on the base substrate; and a culture substrate comprising at least one electrostimulation input terminal coupled to a working electrode and configured to transmit electrical stimuli to the deposited graphene layer.

Described herein is a bifurcated continuous field-flow fractionation (BCFFF) chip for high-yield and high-throughput nucleic acid extraction and purification. BCFFF uses a membrane ionic transistor to sustain low-ionic strength in a localized region at a junction, such that the resulting high field can selectively isolate high-charge density nucleic acids from the main flow channel and insert them into a standardized buffer in a side channel that bifurcates from the junction. The BCFFF platform can be used for isolation of both long dsDNAs and short miRNAs, without changing the device configuration or the operation protocol. BCFFF results in high-efficiency (>85%) concentration-independent DNA extraction and 40% net qRT-PCR miRNA yield from plasma, which is significantly higher than any other commercial liquid and solid extraction technologies.

A fluidic cartridge comprises a fluidic disk having a plurality of alignment openings; a fluidic chip comprising a body, one or more channels formed in the body in fluidic communications with input ports and output ports for transferring one or more fluids between the input ports and the output ports, and a plurality of protrusions formed on the body and received in the alignment openings of the fluidic disk for aligning the fluidic chip to the fluidic disk; an actuator operably engaging with the one or more channels for selectively and individually transferring the one or more fluids through the one or more channels from at least one of the input ports to at least one of the output ports at desired flow rates; and a tube member defining a cylindrical housing for accommodating the fluidic disk, the fluidic chip and the actuator therein.

Disclosed is a device for applying an electric field to a suspension of cells, comprising at least one chamber which comprises at least one internal space (40) for holding the suspension, the internal space (40) comprising at least two segments (41, 42), wherein each segment (41, 42) comprises at least one electrode (43, 44) and wherein neighboring electrodes (43, 44) are separated from each other by at least one gap (47) which is at least partially filled with an insulating material (46), and wherein the edges of the electrodes (43, 44) facing each other within the internal space (40) are rounded. Rounding the electrodes' edges facing a neighboring electrode results in a significant reduction of field gradients and thus even of the risk of arcing. Also disclosed is a method in which voltage is applied to at least one active electrode (43, 44) while the electrodes (43, 44, 45) or electrode segments next and/or opposite to the active electrode (43, 44) are set to ground potential. Setting neighboring electrodes that surround the active electrode to ground potential results in decreased scattering of the electric field within the internal space so that the electrically active area is locally limited and the field lines are focused near the active electrode and thus control of the process is enhanced.

A tool for the distribution of a sample of biological or microbiological material, the tool including an elongated body, provided with a first portion and a second portion; a distributing element, the distributing element being configured at least for distributing a sample of biological or microbiological material on a culture medium; a connector being configured for allowing the joining of the tool with a supporting element of a machine configured for carrying out a distribution of a sample of biological or microbiological material, in particular of a pipetting machine; wherein the connector is adapted and specifically configured for being removably coupled to a supporting element in alternative to another tool, in particular to a tip or pipette for the collection and/or deposit of the sample of biological or microbiological material.