The present application relates to a method for adaptive evolution of living cells by continuous culture of said living cells.

The present disclosure provides systems and methods for intracellular delivery. The systems and methods may comprise the use of a cell processing apparatus which may comprise a plurality of compression elements such as ridges. The intracellular delivery may be caused by rapid compression of cells, which may result in a reduction of a cell volume. The compression may occur while the cells pass through gaps formed by at least a subset of the ridges. The cell processing apparatus may further comprise one or more recovery spaces which are positioned between adjacent ridges. The cells may recover at least a portion of the reduced cell volume by absorbing media and/or reagents surrounding the cells while flowing through the recovery spaces. The ridges may also divert less compressible cells into a diversion channel, thereby sorting the cells based on various cell properties and/or preventing clogging within the apparatus.

The present invention enables fabrication and mass production of a bubble-jetting chip that includes a desired number of bubble jetting portions of the same size having bubble-jetting outlets of the same size.

Mass production is enabled by fabricating a bubble-jetting chip comprising a substrate and a bubble-jetting portion formed on the substrate, the bubble-jetting portion comprising: an electrode that is formed of a conductive material; an insulating portion that is formed of an insulating photosensitive resin, is provided so as to sandwich the electrode, and includes an extended section that extends beyond the tip of the electrode; and a space that is formed between the extended section of the insulating portion and the tip of the electrode.

An assembly and method to precisely and concurrently control the concentration, release, and depletion of chemical and biochemical species in localized regions in a three-dimensional volume of material using spatially patterned light. The system includes a container for holding a material comprising photo-responsive substance; the container is mounted to a motorized rotation stage that rotates the container along the z-axis at a predetermined rate; and a projector configured to project radiations at predefined wavelengths along an r-axis into the container while the container is rotating, wherein the radiations from multiple angles intersect to form localized photoreactive regions within a volume of the material.

A device for performing micro-operations on a vesicular target, comprising an injection pipette (27); a barrel assembly (9); and an outer assembly (1). The injection pipette, barrel assembly, and outer assembly being designed and situated in relation to each other such that an axial vacuum passage is created between the injection pipette and the barrel assembly, and a radial vacuum passage is created between the barrel assembly and outer assembly, and such vacuum passages are isolated from each other and from atmospheric pressure (FIG. 8). The device also comprises a means of advancing and withdrawing the distal end of the barrel assembly in relation to the distal end of the outer assembly so as to create a holding well (31) and a means of advancing the pipette into, and withdrawing the pipette from, a vesicular object.

The invention relates to a bioreactor comprising a tank (100) capable of being operated for a working period, said tank (100) being intended to receive a culture medium comprising a cellular culture of photosynthetic microorganisms, a light source (200) arranged to emit incident light having a chosen incoming light intensity (Iin) in the direction of the tank, a temperature probe (400) for measuring the temperature of said culture medium in the tank, and a temperature regulator (500) capable of raising and lowering the temperature of said culture medium in the tank, and further comprising a control (700) of the temperature regulator arranged to adjust the temperature of the culture medium to a low setpoint value (VCB) during a first period, and to adjust the temperature of the culture medium to a high setpoint value (VCH) during a second period, the succession of said first and second periods making it possible to induce a cellular stress in at least some of said photosynthetic microorganisms during the working period.

An array device including a base having wells, a cover positioned over the base with a gap from the base such that openings of the wells are covered by the cover with the gap in between, an injection port communicating with the gap, a discharge port communicating with the gap and positioned apart from the injection port, and a waste liquid vessel which collects liquid that flows from the gap via the discharge port and is positioned at a level different from the gap forming a channel. The discharge port is placed to discharge a surplus aqueous solution outside the wells from the discharge port by an oleaginous sealing liquid to be delivered from the injection port.

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.

Provided is a cell culture method including introducing a factor into cells in a cell culture vessel, and culturing the cells into which the factor has been introduced in the same cell culture vessel. Also provided is a mononuclear cell collection method including treating blood to prepare a treated blood from which erythrocytes have been at least partially removed, diluting the treated blood, causing sedimentation of mononuclear cells contained in the diluted treated blood, removing the supernatant from the diluted treated blood, and collecting the mononuclear cells.

Provided is an erythrocyte removal device 100 including a blood container 10 that holds blood and an erythrocyte removal vessel 11 that at least partially removes erythrocytes from blood.