The subject invention pertains to a microfluidic apparatus and methods for screening and isolating a target cell from a population of cells. The apparatus comprises a first microfluidic layer comprising microfluidic channels; a second microfluidic layer comprising microfluidic channels; and a microfluidic cell analysis layer comprising a top hanging blocking structure located directly below each location where the first layer microfluidic channels overlap with the second layer microfluidic channels and a cell trap juxtaposed to each of the top hanging blocking structures. The top hanging blocking structures can close or open the juxtaposed cell trap when either or both the first or second layer microfluidic channels located directly above the top hanging blocking structure are sufficiently pressurized and/or sufficiently depressurized. The methods for screening and isolating a target cell from a population of cells comprise screening the population of cells using the apparatus and isolating the target cell interest therefrom.

The invention relates to a system, comprising: a) a sample processing unit, comprising an input port and an output port coupled to a rotating container having at least one sample chamber, the sample processing unit configured provide a first processing step to a sample or to rotate the container so as to apply a centrifugal force to a sample deposited in the chamber and separate at least a first component and a second component of the deposited sample; and b) a sample separation unit coupled to the output port of the sample processing unit, the cell separation unit comprising separation column holder (42), a pump (64) and a plurality of valves (1-11) configured to at least partially control fluid flow through a fluid circuitry and a separation column (40) positioned in the holder, the separation column configured to separate labeled and unlabeled components of sample flowed through the column.

A microfluidic system for cell retention for a perfusion bioreactor is provided. The system comprises at least one inlet configured to receive a bioreaction mixture to be processed. At least one curvilinear microchannel is in fluid flow connection with the at least one inlet, the at least one curvilinear microchannel being adapted to isolate cells in the bioreaction mixture, based on cell size, along at least one portion of a cross-section of the at least one curvilinear microchannel. At least two outlets are in fluid flow connection with the at least one curvilinear microchannel. At least one outlet of the at least two outlets is configured to flow the isolated cells to be recycled to the perfusion bioreactor.

Disclosed herein are systems, devices and methods for processing tissue, such as autologous tissue. Implementations of a Stromal Vascular Fraction (SVF) system are described that can isolate and wash harvested cells contained within various tissues, such as isolate and wash stem cells from fat tissue. The SVF system can minimize the handling and transferring of tissue and fluids, including minimizing the number of human interventions and manipulations required throughout processing. The SVF system can ensure sterility of processed tissue and harvested cells, as well as significantly reduce cost and time associated with the processing.

The invention is an automated advanced tissue engineering system that comprises a housing in which one or more tissue engineering modules are accommodated together with a central microprocessor that controls functioning of the tissue engineering modules. In one embodiment, the tissue engineering module comprises a housing supporting one or more bioreactor chamber assemblies and a fluid reservoir operationally engageable with the housing. The bioreactor chamber assemblies may be selected depending on the end product option desired and may include, for example, a cell therapy bioreactor chamber, a single implant bioreactor chamber and a multiple (mosaic) implant bioreactor chamber.

The invention discloses a method for selecting cells depending on their level of displaying and preferably secreting a protein of interest from a population of heterogeneously expressing cells, comprising: (a) contacting said cells with magnetic beads coated with an affinity group to the said cells, (b) mixing the said magnetic beads with the cells to capture the cells displaying/secreting the protein of interest, (c) performing at least one washing step to remove the non-captured cells, and (d) recovering the cells to which that magnetic beads have bound.

Provided is a cell trapping method for selectively trapping a specific cell included in a cell-containing solution at a filter surface by filtering a liquid, and the method includes a step of draining a liquid for n (n is a natural number) times, in which from the first step of draining the liquid to the n-th step of draining the liquid, a liquid surface of the liquid in the introduction region on the filter is maintained at a predetermined liquid surface height, and when the n-th step of draining the liquid is completed, the discharging of the liquid from the cell trapping device is stopped in a state where the liquid surface is at a predetermined height in the filter.

The present invention is directed to devices, methods and kits for cell-specific sorting of cells from a mixed population, e.g., from a tumor sample. Aspects of the invention combine aligned, electrospun microfibers with drug-or protein-releasing nanospheres to isolate cancer cells from tumor biopsies.

The present application provides a method for lysis or electroporation of cells in a biological sample including the following steps: passing cells of the sample, suspended in a fluid, through a flow path with a preset flow speed, wherein the flow path runs through a detection apparatus for detecting individual cells and wherein the flow path includes at least two electrodes for generating an electric field, which electrodes are located downstream of the detection apparatus and which electrodes are coated with a dielectric material with a relative permittivity greater than 3.9, wherein the coaling at least covers the surface of the electrodes that faces the flow path, and when the presence of a specific cell is detected in the detection apparatus, then an electric field is generated between the electrodes when the detected cell passes between the electrodes in dependence of the flow speed, wherein the electric field causes electroporation or lysis of the cell.

Cell separation systems and methods of separating cells are disclosed. In an embodiment, a cell separation system is described that comprises a non-transitory storage device that executes a centrifugation program to separate cell volume from biologic material volume; a heating mechanism; a containment mechanism; and an assembly comprised of a single-walled centrifugation bowl. In an embodiment, methods of separating cells are disclosed whereby cells are separated by agitating a volume of biologic material and a volume digestion media to form a digested volume of biologic material; centrifuging the digested volume of biologic material; removing a portion of a resulting waste via at least one fluid outlet; isolating a different portion of the waste, and removing the concentrated cell volumes from the reservoir.