The present disclosure is drawn to inertial pumps. An inertial pump can include a microfluidic channel, a fluid actuator located in the microfluidic channel, and a check valve located in the microfluidic channel. The check valve can include a moveable valve element, a narrowed channel segment located upstream of the moveable valve element, and a blocking element formed in the microfluidic channel downstream of the moveable valve element. The narrowed channel segment can have a width less than a width of the moveable valve element so that the moveable valve element can block fluid flow through the check valve when the moveable valve element is positioned in the narrowed channel segment. The blocking element can be configured such that the blocking element constrains the moveable valve element within the check valve while also allowing fluid flow when the moveable valve element is positioned against the blocking element.

The invention relates to a microfluidic poration device having narrow channels slightly smaller than the width of a target cell, wherein the channels are lined with a plurality of nanospikes in a row extending down the middle of the channel, i.e. in a row parallel to the sides of the channel. In one embodiment, one channel may have 2 nanospikes (or 2 nanolancets). Thus, in particular embodiments, the invention provides microfluidic poration devices capable of simultaneously squeezing cells while piercing holes in their membranes for allowing foreign molecules into cells. The holes in porated cells spontaneously close after exiting the channels, thus entrapping the foreign molecules inside of the target cells. This porated cell population has approximately a 95% viability with greater than 50% containing at least one foreign molecule.

A 4D-perfused tumoroid-on-a-chip platform used in personalized cancer treatment. The platform includes a plate with a plurality of bottomless wells that resides atop a microfluidic channel layer, which in turn resides atop a surface acoustic wave (SAW) based sensor layer that is capable of measuring potential pH values of fluids disposed within the platform. The microfluidic channel layer includes a plurality of bioreactors, with each bioreactor including an inlet well, a culture well, and an outlet well. The inlet well, culture well, and outlet well form a closed system via fluid conduits spanning from the inlet well to the culture well, as well as from the culture well to the outlet well. Due to the fluid flow from the plate to the chip, and from the inlet well to the outlet well on the chip through the culture well, target cell (tumoroid) growth is promoted within the culture well.

Vascularizing cell aggregates or tissue segments in a microfluidic device by filling a chamber within the device with a matrix that allows for endothelial sprouting; creating at least three voids within the matrix, of which at least two outer voids are lumenally connected to separate perfusion paths within the device and at least one additional void is positioned in between the at least two outer voids; endothelializing the at least two outer voids; introducing at least one cell type, matrix material, tissue segment, or combinations thereof into the void between the two outer voids; and using vascular growth factors to induce the endothelial cells to sprout into the matrix until the at least three voids are interconnected by endothelial sprouts.

Provided herein is technology relating to processing biological samples and particularly, but not exclusively, to systems and apparatuses for dissociating biological tissues into viable cells.

Multiplanar microfluidic devices are provided that facilitate direct transverse fluid communication between a first microfluidic channel a plurality of adjacent microfluidic channels, where the adjacent microfluidic channels reside both laterally adjacent and vertically adjacent to the first microfluidic channel, thereby facilitating transverse diffusion to or from the adjacent microfluidic channels in both lateral and vertical directions. Geometrical meniscus-pinning features, such as meniscus-pinning ridge structures, are provided between adjacent microfluidic channels to restrict transverse flow between the microfluidic channels. Accordingly, a gel structure may be formed within the first microfluidic channel and one or more of the adjacent microfluidic channels can function as a perfusion channel, for example, for delivering media to cells residing withing the gel structure. Such devices may be extended and/or arrayed to include multiple channels with laterally and vertically adjacent perfusion microfluidic channels, optionally with shared lateral perfusion microfluidic channels among adjacent pairs of devices.

The present subject matter provides a microfluidic device that enables the precise and repeatable three dimensional and compartmentalized coculture of muscle cells and neuronal cells. Related apparatus, systems, techniques, and articles are also described.

Disclosed herein is a bioreactor system that allows active perfusive flow through a porous support medium enabling 3D growth of biological samples. In some embodiments, the system comprises a sample well filled with a three-dimensional (3D) cell growth medium. The system can further comprise a liquid medium reservoir fluidly connected to the sample well by a first filter material. The system can further comprises a medium collection chamber fluidly connected to the sample well by a second filter material. In some embodiments, application of negative gage pressure to the medium collection chamber or positive pressure to the liquid medium reservoir draws fluid from the liquid medium reservoir, through the first filter material, into the sample well where it permeates the three-dimensional cell growth medium, through the second filter material, and finally into the medium collection chamber.

System and method includes a body having a central microchannel separated by one or more porous membranes. The membranes are configured to divide the central microchannel into a two or more parallel central microchannels, wherein one or more first fluids are applied through the first central microchannel and one or more second fluids are applied through the second or more central microchannels. The surfaces of each porous membrane can be coated with cell adhesive molecules to support the attachment of cells and promote their organization into tissues on the upper and lower surface of the membrane. The pores may be large enough to only permit exchange of gases and small chemicals, or to permit migration and transchannel passage of large proteins and whole living cells. Fluid pressure, flow and channel geometry also may be varied to apply a desired mechanical force to one or both tissue layers.

Transfer of genetic and other materials to cells is conducted in a hands-free, automated and continuous process that includes flowing the cells between electroporation electrodes to facilitate delivery of a payload into the cells, while acoustophoretically focusing the cells. Also described is a control method for the acoustophoretic focusing of cells that includes detecting locations of cells flowing through a channel, such as with an image analytics system, and modulating a drive signal to an acoustic transducer to change the locations of the cells flowing in the channel. Finally, an electroporation driver module is described that uses a digital to analog converter for generating an electroporation waveform and an amplifier for amplifying the electroporation waveform for application to electroporation electrodes.