A product and method for sampling cells from a bioreactor, for the purposes of determine the cell count or to remove a sample and retain sterility of the sample for quality control (OC) assessment. More specifically, a product and a method for sampling of cells during a cell expansion in a bioreactor using vacuum tubes.

The present disclosure provides systems, devices and methods for seeding cells or sets of molecules on a substrate by utilizing a seeding mesh, to obtain an essentially homogenous patterned seeding of the cells or sets of molecules on the mesh.

A transfer device designed to extract an amorphous or semi-solid structure, tissue, or construct from supporting media while maintaining the spatial integrity/organizational architecture thereof. The transfer device can include a controller, an actuator assembly, a plunger, and a needle. The controller can move the transfer device and the plunger independently.

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.

A device is provided, comprising a cell trap comprising a plurality of micro-chambers, each micro-chamber configured to hold a cell. The device can further comprise a manipulator array comprising a plurality of manipulators, each manipulator in spatial communication with a respective micro-chamber, wherein each manipulator comprises a needle, a stage, and an actuator, wherein the needle is mounted to the stage, and the actuator is operable to apply force to the stage in a direction to move the needle to penetrate a cell in the respective micro-chamber.

Disclosed is a microorganism inoculation device, which comprises a workbench, wherein support columns are provided on the upper surface of the workbench, a limiting plate is provided in the middle part of the supporting column, an injection head is provided in the middle part of the limiting plate, an air cylinder is provided in the middle part of the lower surface of the workbench, a piston rod of the air cylinder is fixedly connected with the middle part of the upper surface of a lifting plate, guide rods are provided on the upper surface of the lifting plate, the upper end of the guide rod is fixedly connected with a tray, the left and right sides of the upper surface of the tray are fixedly connected with the lower part of a fixed bracket, the middle part of the injection head is slidably connected with the limiting plate.

A system and method for printing cells in a medium. A multi-dimensional printer, stably constructed of low-mass parts, can include a computer numerically controlled system that can enable motors driving delivery systems. The motors can include encoders that can enable achieving arbitrary resolution. The motors can drive ballscrews to enable linear motion of delivery systems, and the delivery systems can enable printing of a biological material in a pre-selected pattern in a petri dish. The petri dish can accommodate a medium such as a gel, and can further accommodate a vision system that can detect actual position and deflection of the delivery system needle. The printer can accommodate multiple delivery systems and therefore multiple needles of various sizes.

A cell culture apparatus includes: an isolator in which a sterile space accommodating a cell incubator filled with a culture solution containing cells to be cultured is disposed; a sampling unit configured to sample the culture solution in the cell incubator; a delivery flow path through which an inside of the sterile space and an outside of the sterile space communicate with each other, the delivery flow path configured to limit a flow in the delivery flow path to a direction that is directed from the inside of the sterile space toward the outside of the sterile space; and a culture solution delivering section configured to deliver the sampled culture solution to the outside of the sterile space via the delivery flow path.

Disclosed is a microorganism inoculation device, which comprises a workbench, wherein support columns are provided on the upper surface of the workbench, a limiting plate is provided in the middle part of the supporting column, an injection head is provided in the middle part of the limiting plate, an air cylinder is provided in the middle part of the lower surface of the workbench, a piston rod of the air cylinder is fixedly connected with the middle part of the upper surface of a lifting plate, guide rods are provided on the upper surface of the lifting plate, the upper end of the guide rod is fixedly connected with a tray, the left and right sides of the upper surface of the tray are fixedly connected with the lower part of a fixed bracket, the middle part of the injection head is slidably connected with the limiting plate.

An automated method of T cell scale down processing. The method including: activating T cells by automatically contacting the T cells with one or more activation reagents; transducing the T cells by automatically contacting the T cells with a recombinant viral vector; automatically inoculating T cells; automatically expanding the T cells; optionally, automatically debeading the T cells; and automatically harvesting the T cells. A system for an automated method of T cell scale down processing.