A microphysiological platform described herein includes a fluidic synthesizer with a first fluid input selectively coupleable to a source of a first input fluid solution and a second fluid input selectively coupleable to a source of a second input fluid solution. The fluidic synthesizer further includes a fluid output. The microphysiological platform further includes a fluid addressing system with a fluid input fluidically coupled to the fluidic synthesizer fluid output. The fluid addressing system further includes a first fluid output and a second fluid output. The microphysiological platform further includes a first microphysiological device with a fluid input fluidically coupled to the first fluid output of the fluid addressing system and a second microphysiological device with a fluid input fluidically coupled to the second fluid output of the fluid addressing system.

The present disclosure provides a microfluidic device and system for measuring a composite electropharyngeogram (EPG) signal from a pool of multiple nematodes, wherein the composite EPG signal is measured from the pool of nematodes present in a single recording channel connected to two or more integrated electrodes. The microfluidic device includes an inlet port and outlet port directly connected to a single recording channel and two or more electrodes directly connected to the recording channel. The recording channel is configured to hold 10 to 10,000 nematodes.

A bioreactor device includes a solid substrate having a first face and a second face. The solid substrate at least partially defines a perfusion channel, a plurality of chambers, a fluidic inlet, and a fluidic outlet. A first sheet disposed over the first face and a second sheet disposed over the second face. Characteristically, the combination of the solid substrate, the first sheet and the second sheet define the perfusion channel and each chamber of the plurality of chambers. The plurality of chambers are arranged in rows of chambers in which adjacent chambers are positioned at opposite side of the perfusion channel. The perfusion channel extends from the fluidic inlet and the fluidic outlet having a serpentine path along each row of chambers with each chamber being in fluid communication with the perfusion channel.

Provided are bacterial strains, methods of culturing bacterial cells using synthetic quorum-regulated lysis, and uses thereof.

Fluidic devices are provided and/or configured to form and support, extractable in-situ-formed hydrogels or hydrogel membranes that reside in a hydrogel chamber formed above, and in direct fluid communication with, an underlying fluidic channel, in the absence of an intervening membrane. In some example embodiments, the integrated fluidic device may include a geometrical hydrogel retention structure that provides a restoring force to the hydrogel when fluidic pressure is applied to the hydrogel from the underlying fluidic channel, or a geometrical meniscus-pinning feature that resists flow of a hydrogel precursor solution out of the hydrogel chamber, facilitating the formation of a hydrogel membrane extending over the integrated fluidic channel. The hydrogel or hydrogel membrane may be seeded with cells by delivering a cell-containing liquid to the fluidic channel, optionally while contacting the hydrogel with media provided in a media reservoir residing above the hydrogel layer.

A microfluidic system for causing perturbations in a cell membrane, the system including a microfluidic channel defining a lumen and being configured such that a cell suspended in a buffer can pass therethrough, wherein the microfluidic channel includes a cell-deforming constriction, wherein a diameter of the constriction is a function of the diameter of the cell.

A method of alignment and fusion of cells with an electrical field includes firing a first fluid dispenser of an electrofusion device until a first impedance sensor in a first microfluidic channel of the electrofusion device detects a presence of a first cell. The method includes firing a second fluid dispenser of the electrofusion device until a second impedance sensor in a second microfluidic channel of the electrofusion device detects a presence of a second cell. The method includes moving the first cell and the second cell into a merging chamber of the electrofusion device by firing a third fluid dispenser of the electrofusion device, in response to alignment of the first cell in the first microfluidic channel with the second cell in the second microfluidic channel. The method further includes fusing the first cell and the second cell in the merging chamber by creating an electrical field in the merging chamber.

A three-dimensional (3D) microelectrode array device for in vitro electrophysiological applications includes a substrate and micro vias extending from the bottom face to the top face of the substrate. A microneedle at each micro via extends from the bottom face upward beyond the top face and forms a hypodermic microneedle array on the top face. Metallic traces on the bottom face interconnect the hypodermic microneedles to form the 3D microelectrode array. A microheater is positioned on the bottom face of the substrate. Microfluidic ports may be formed at the substrate. Interdigitated electrodes may be formed at the substrate.

Described herein are methods inducing the uptake of an agent by a cell. Aspects of the invention relate to physically compressing the cell to induce perturbations (e.g., holes) in the cell membrane or wall. An agent is taken up by the cell through induced perturbations.

The devices, methods and systems are described for providing controlled amounts of gas, gas pressure and vacuum to microfluidic devices the culturing of cells under flow conditions. The devices, methods, and systems contemplated here may also be used to control the environment surrounding the microfluidic devices; offer user control over experiments comprising microfluidic devices, such as the ability to directly or remotely control experiment conditions; and comprise information aggregation and transmission, such that experimental data may be collected, stored, aggregated and transmitted to users.