The present disclosure provides systems and methods for host cell improvement utilizing epistatic effects. The systems and methods described herein are host cell agnostic and therefore can be implemented across taxa. Furthermore, the disclosed systems and methods can be implemented to modulate or improve any host cell parameter of interest.

The present invention provides a stem cell manufacturing system comprising: a pre-transfer cell solution sending channel 20 through which a solution containing cells flows; an inducer solution sending mechanism 21 which sends a pluripotency inducer into the pre-transfer cell solution sending channel 20; an inducer transfer apparatus 30 which is connected to the pre-transfer cell solution sending channel 20 and transfers the pluripotency inducer into the cells to produce cells harboring the inducer; a cell cluster production apparatus 40 which cultures the cells harboring the inducer to produce a plurality of cell clusters consisting of stem cells; and a packaging apparatus 100 which sequentially packages the plurality of cell clusters.

Methods for introducing exogenous material into a cell are provided, which include exposing the cell to a transient decrease in pressure in the presence of the exogenous material. Also provided are devices for performing the method of the invention.

An object of the invention is to make it possible to provide a mechanism that applies an external stimulus and to measure structural and electromagnetic changes of a cell due to the external stimulus with high sensitivity by an NV center. There is provided an environment control mechanism configured to change a state of a sample by applying an external stimulus to the sample.

The invention provides a solution to the problem of transfecting non-adherent cells. Devices and delivery compositions containing ethanol and an isotonic salt solution are used for delivery of compounds and compositions to non-adherent cells.

A microorganism culture apparatus includes a three-layer stacked structure having a layered culture unit (1) that cultures a microorganism, a layered nutrient supply unit (2) that is arranged on a first surface (11) of the culture unit (1) and supplies a nutrient to the culture unit (1), and a layered environmental component supply unit (3) that is arranged on a second surface (12) and supplies an environmental component to the culture unit (1).

A 3D-printed in vitro model biological microenvironment in examples discussed below may have one or more of the following features: (a) a gel matrix 3D-printed scaffold, wherein the gel matrix comprises a chemical composition configured to culture a first type of live cells, (b) a target chemical disposed at one or more locations within the gel matrix, the target chemical forming a chemical depot from which a chemical gradient is created within the gel matrix, (c) a conduit disposed within the gel matrix and defining a lumen comprising a second type of live cells, wherein the conduit is configured to enable at least some of the first type of live cells to migrate through the conduit and facilitate flow of at least: some of the live cells to an outlet of the conduit, or enable introduction of at least one of other cells, Achemical mediators, or drugs into the 3D-printed microenvironment.

Methods and apparatus of bioreactors for therapeutic cells manufacturing are provided herein. In some embodiments, a bioreactor includes: an upper bioreactor reservoir configured to perform multiple cell therapy manufacturing process steps including genetic modification and expansion to a plurality of cells disposed therein, wherein the upper bioreactor reservoir includes a plurality of ports for delivering fluids into and out of the upper bioreactor reservoir; a lower bioreactor compartment configured to hold a suspension comprising a molecular species; and a membrane disposed between the lower bioreactor compartment and the upper bioreactor reservoir, wherein the membrane includes a plurality of micro-straws extending through the membrane and into the upper bioreactor reservoir to transfect the plurality of cells with the molecular species.

Disclosed herein are microinjection chips, devices, and systems for injection of unicellular or multicellular organisms. The microinjection chip and device disclosed herein include the microfluidic features, inlet port, pre-injection reservoir, injection channel and post injection channel in fluid communication with each other. The inlet port is adapted to sequentially move individual organisms into the injection channel, which is adapted to immobilize the individual organism in fluid. The injection channel features a side wall adapted to receive a microinjection pipette without a microinjection port and to reseal when the microinjection pipette is removed.

A stem cell production system provided with a preintroduction cell-feeding solution channel 20 through which a solution containing cells passes, an induction factor-feeding solution mechanism 21 for feeding a pluripotency induction factor to the preintroduction cell-feeding solution channel 20, a factor introduction device 30 connected to the preintroduction cell-feeding solution channel 20 for making cells with induction factor introduced by introducing the pluripotency induction factor into the cells, a cell mass-making device 40 for making multiple cell masses comprising stem cells by culturing the cells with induction factor introduced, and a packaging device 100 for sequentially packaging each of the multiple cell masses.