A storage assembly for storing a plurality of specimens includes a frame, a plurality of modular storage units for perfusion and/or incubation of one or more specimens removably coupled to the frame, a sample transfer apparatus configured to retrieve a specimen holder from a chosen modular storage unit of the plurality of modular storage units, and a control unit communicatively coupled to the sample transfer apparatus. The control unit is configured to cause the sample transfer apparatus to retrieve a specimen from a modular storage unit of the plurality of modular storage units and deliver the specimen to a delivery position.

Cartridges for manufacturing a population of cells suitable for formulation as a cellular therapeutic are disclosed herein, along with systems and instruments for operating the cartridges and performing methods to generate the population of cells suitable for formulation as a cellular therapeutic. The population of cells suitable for formulation as a cellular therapeutic can be immunological cells, such as T lymphocytes, including endogenous T cells (ETCs), tumor infiltrating lymphocytes (TILs), CAR T-cells, TCR engineered T-cells, or otherwise engineered T-cells. The systems and methods can be largely automated.

Disclosed herein are platforms, systems, and methods including a cell culture system that includes a cell culture container comprising a cell culture, the cell culture receiving input cells, a cell imaging subsystem configured to acquire images of the cell culture, a computing subsystem configured to perform a cell culture process on the cell culture according to the images acquired by the cell imaging subsystem, and a cell editing subsystem configured to edit the cell culture to produce output cell products according to the cell culture process.

One or more embodiments of the present disclosure relate to a culture device, which comprises: an accommodation base, an accommodation chamber disposed on the accommodation base. The accommodation chamber includes a culture chamber for accommodating one or more cultures. The culture chamber includes a chamber bottom wall and a chamber side wall surrounding the chamber bottom wall. A culture solution channel is formed between an outer side of the chamber side wall and an inner wall of the accommodation chamber. At least part of the chamber side wall includes a membrane material, and a plane where the membrane material is located intersect with the chamber bottom wall.

A system of controllable separation between recyclable organic waste and graywater sewage is described; a respective method for controllable separating recyclable organic waste from graywater sewage is further described; the system includes: a garbage disposal unit, and a separation module; the method includes: draining both the graywater sewage and the recyclable organic waste; processing the organic waste into a semiliquid mixture or slurry of round organic matter and fluid; discharging the semiliquid mixture or slurry of ground organic matter and fluid and the graywater sewage; and releasing the semiliquid mixture or slurry of ground organic matter and fluid; releasing the graywater sewage; and separating the semiliquid mixture or slurry of ground organic matter and fluid from the graywater sewage.

The present disclosure provides methods and materials for the cultivation and/or propagation of a photosynthetic organism. Such methods may comprise the use of a lamp assembly that comprises a plurality of circuit boards, each comprising at least three edges, arranged in a substantially spherical shape defining an interior lamp assembly volume, wherein the plurality of circuit boards comprise a first planar surface in contact with the interior lamp assembly volume and an opposing second planar surface comprising light emitting diodes (LEDs); and a barrier that surrounds the plurality of circuit boards forming the substantially spherical shape.

Apparatus, systems and methods for the adaptive passage of a culture of cells and apparatus and methods for dissociating cell colonies are described. The systems may include an imaging module, a pipette module, a handling module, and/or a stage module. Coordinated operation of the modules, optionally in an automated manner, is effected by at least one processor based on one or more characteristics of the culture of cells calculated from one or more images captured at more than one time point. A first apparatus for adaptive passage of a culture cells includes an imaging module and at least one processor, which apparatus may be included in the systems or used in the methods. A second apparatus for dissociating cell colonies, may also be included in the systems or used in the methods, includes impact bumper(s) collidable with impact bracket(s) to transmit a dissociative force to a culture of cells.

Provided is a biological specimen holder for positioning multiple specimens for imaging by a light-sheet microscope. The specimen holder allows developing plant embryos, small intact animals, or organs to be imaged in the light-sheet microscope in a single setting. The specimen holders significantly improve the imaging conditions with respect to the standard glass capillary system. Also provided is a semi-automatic image processing pipeline that quantifies cell divisions of plants imaged with both the glass capillary and the novel chambers. Plants imaged using the specimen holder undergo cell divisions for a period at least 16 times longer than those imaged with a glass capillary system and allow increased sample throughput and the option of incorporating light emitting diode (LED) lights to generate a light-controlled environment are also advantages.

Provided is a cell culture system capable of mixing a medium for culturing animal or plant cells. The cell culture system includes a body, a movable plate including an accommodation space accommodating a culture bag accommodating a medium to mix the medium, and being tiltable in multiple directions by a central joint mounted at a first location of the body, a first actuator mounted between the body and a second location of the movable plate to move the movable plate, a second actuator mounted between the body and a third location of the movable plate to move the movable plate, and a controller for applying a control signal to the first and second actuators, wherein a first angle between a first reference line extending from the first location to the second location, and a second reference line extending from the first location to the third location is 120°.

A well plate comprises a plate main body and at least one cavity in an upper side of the plate main body. An upwardly open annular channel is formed in the at least one cavity, the annular channel being delimited at an inner circumference thereof by a closed circumferential wall. A horizontal outer circumference of the circumferential wall decreases from bottom to top up to an upper edge of the circumferential wall. Within the horizontal circumference of the circumferential wall, at its upper edge, at least two retaining elements connect upwardly to the upper edge of the circumferential wall. The at least two retaining elements are at a free horizontal distance to one another, and at least one of the at least two retaining elements is elastically supported at the plate main body in horizontal direction.