A three-dimensional (3D) microelectrode array for in vitro electrical and microfluidic interrogation of electrogenic cell constructs includes a substrate having a plurality of micro vias. A hypodermic microneedle is received within each micro via of a first subgroup of the plurality of micro vias and each has a length that exceeds the thickness of the substrate to form a hypodermic microneedle array on the top face of the substrate. Metallic traces are formed on the bottom face and interconnect the hypodermic microneedles. A culturing area is formed in the top face.

Described herein are nanostraw well insert apparatuses (e.g., devices and systems) that include nanotubes extending through and out of a membrane so that a material can pass through the membrane from a fluid reservoir depot and into a cell grown onto the nanotubes when electrical energy (e.g., electroporation energy) is applied. In particular, the device, systems and methods described herein may be adapted for cell growth viability and transfection efficiency (e.g., >70%). These apparatuses may be readily integratable into cell culturing processes for improved transfection efficiency, intracellular transport, and cell viability.

A fluid aspiration probe apparatus for automatic fluid testing equipment includes a pair of electrodes mounted on a distal probe tip. The electrodes are coupled to an impedance measurement apparatus via conductive pathways along the probe. The impedance measurements and probe tip height are monitored as the probe tip is lowered into a fluid sample. Boundaries between layers of fluid in the container are detected by recognizing sudden changes in the impedance measurements and heights of the boundaries are determined by tracking the position of probe tip when the sudden changes of impedance occur.

Fluidic devices, systems, and methods for analyzing an analyte are described. In an embodiment, the fluidic devices include a housing defining a lysis chamber shaped to receive a biological sample; a lysis buffer storage chamber disposed within the housing and carrying a lysis buffer configured to lyse cells of the biological sample; a cap configured to cooperatively couple to the housing; a compressor configured to compress the lysis buffer storage chamber and expel the lysis buffer from the lysis buffer storage chamber and into the lysis chamber when the cap is uncoupled from the housing; and a porous membrane in selective fluidic communication with the lysis chamber.

A fluidic device (10) is described. The fluidic device (10) comprises the first part (110) and the second part (120). The first part (110) comprises a first inlet (111) and a first outlet (112), mutually spaced apart. The second part (120) comprises a first chamber (121) arranged to contain a predetermined first amount A1 of a first fluid F1 therein and a first wall portion (122) arranged to contain, at least in part, the first fluid F1 in the first chamber (121). The fluidic device (10) is arrangeable in a first configuration, wherein the first part (110) is fluidically isolated from the first chamber (121). The fluidic device (10) is arrangeable in a second configuration, wherein the first inlet (111) and the first outlet (112) are fluidically coupled via the first chamber (121), whereby increasing a first pressure P1 in the first chamber (121) via the first inlet (111) urges at least a part of the predetermined first amount A1 of the first fluid F1 through the first outlet (112).

An analysis cartridge includes a first cover, a second cover, a plurality of containers, a plurality of fluid tunnels and a rotary valve. The second cover has two opposite surfaces, a plurality of first through holes and a second through hole individually penetrate through the two opposite surfaces, and the first cover is attached to the second cover. The plurality of containers are disposed between the first cover and the second cover, with each of the containers being aligned to and filled in the first through holes. The plurality of the fluid tunnels are disposed on the first cover, and each of which is individually connected with a first pipette. The rotary valve is rotatably disposed between the first cover and the second cover to correspond to the second through hole, and a flow channel disposed on the rotary valve is connected with the containers individually.

Broadly speaking, embodiments of the present techniques provide a modular sample processing device which allows a user to perform any number of biological processes within a single device, in the order the user requires. The device is customisable—a user may select two or more modules and connect them in series to form the device in which the biological processing takes place. Advantageously, this may enable a user to perform multiple processes within a single device and potentially outside of a laboratory (e.g. during field work) or outside of sterile/aseptic environments. Furthermore, the device is a hand-held device, which means the device is compact and easy to transport and use for field work.

An apparatus includes a fluid reservoir and a laminate fluidic circuit positioned above the fluid reservoir. The laminate fluidic circuit includes two or more layers laminated together to define a substantially planar substrate and one or more channels defined within the substrate. The laminate fluidic circuit includes a flexible conduit defined by a portion of the substrate encompassing an extent of at least one of the channels that is partially separated or separable from the remainder of the substrate. The flexible conduit is deflectable with respect to the planar substrate toward the fluid reservoir such that the flexible conduit fluidly connects the at least one channel to the fluid reservoir.

A system for processing a sample includes a unitary body. The unitary body including a snap lid, the snap lid having a capillary. The unitary body including a lysing container. The unitary body including a test element and a sliding actuator.

There is provided a connector, for introducing or extracting a material to or from at least one receptacle, comprising a housing extending between a distal end and a proximal end, the housing comprising, at least at one end, a pierceable seal; a hollow needle mounted, at least partially, within the housing between the distal end and the proximal end of the housing, a first end of the hollow needle being connected or connectable to a first corresponding receptacle, and a second end of the hollow needle facing the pierceable seal at an end of the housing; and an actuating mechanism acting on the housing or the hollow needle to enable the hollow needle to pierce the pierceable seal thereby forming a communication through the pierceable seal, such that material is able to transfer through the connector.