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.

Systems and methods directed to an array of microstructures for biological cell sorting with each individual structure component including an integrated magnetic element.

A cell sorting system is provided to comprise: an imaging device including abeam scanner scanning abeam along a first direction to obtain a cell image data including fluorescent information or cell image information of a cell, the beam applied to the cell flowing in a channel along a second direction with an angle to the first direction; a data processing and control device in communication with the imaging device, the data processing and control device including a processor configured to process the cell image data obtained by the imaging device to determine one or more properties associated with the cell from the processed cell image data and to produce a control command based on a comparison of the determined one or more properties with a sorting criteria, and a cell sorting device in communication with the imaging device and the data processing and control device.

The present invention provides methods for designing a filtration systems for capturing viable tumor cells, such as circulating tumor cells at high efficiency and high viability. The methods involve development of a set of “key engineering design parameters” that are crucial to achieve high tumor cell viability. These important design parameters include the filter geometry design, fluid delivery method, transfilter pressure and total filtration time.

The present invention relates to the automation of incubation, processing, harvesting and analysis of samples in a multi-cell plate. In particular, a multi-cell plate including a body with a plurality of cells is presented. Furthermore, an automated crystal harvesting and processing system with a cutting unit, a fluid unit and a removing device is presented. The multi-cell plate further includes a sealing film for sealing the cells on a first side of the body and a sample film for sealing the cells on a second side of the body. The sample film is adapted for accommodating a biological material for crystallization. Furthermore, the sample film is of a thickness and composition that makes it compatible with x-rays and also with laser ablation. The design of the multi-cell plate and the automated crystal harvesting and processing system allows for several steps of incubation, processing, harvesting and analysis of the samples to be automated.

This invention relates to compositions of matter, methods, modules and instruments for automated mammalian cell growth and mammalian cell transduction followed by nucleic acid-guided nuclease editing in live mammalian cells.

In one example in accordance with the present disclosure, a cell sorting device is described. The cell sorting device includes a microfluidic channel to serially transport individual cells from a volume of cells along a flow path. A sensor disposed in the microfluidic channel distinguishes between a cell to be analyzed and waste fluid. The cell sorting device includes at least two fluid transport devices disposed within the microfluidic channel. The at least two fluid transport devices include a cell ejector to, responsive to detection of a cell to be analyzed, eject the cell to be analyzed from the cell sorting device and a waste transport device to direct the waste fluid to a waste reservoir.

A device for separating a sample of cells suspended in a bio-compatible ferrofluid is described, The device includes a microfluidic channel having a sample inlet, at least one outlet and a length between the same inlet and the at least one outlet, wherein a sample can be added to the sample inlet and flow along the microfluidic channel length to the at least one outlet. The device includes a plurality of electrodes and a power source for applying a current to the plurality of electrodes to create a magnetic field pattern along the microfluidic channel length. The present invention also includes a method of using said device for separating at least one cell type.

The present disclosure provides an automated system for processing of tissue. The system comprises a plurality of containers for storing at least one of tissue samples, buffer solutions, enzymes and other reagents, tissue processing container for processing of the tissue, and a robotic assembly coupled to the tissue processing container. The robotic assembly is configured to: carry the tissue processing container towards each of the plurality of containers, and align an inlet port of the tissue processing container with an outlet port of each of the plurality of containers for collecting the liquids, and moves the tissue processing container in multiple-planes to perform at least one of the washing processes, digestion process, phase separation process and combination thereof. The system also comprises of a control unit interfaced with the robotic assembly for controlling operations of the robotic assembly while processing the tissue.

The present disclosure provides cassettes for use in automated cell engineering systems that include cell separation filters for capturing a target cell population for automated processing. The disclosure also provides methods of separating a target cell population, as well as automated cell engineering systems using the cassettes and for carrying out the methods.