Devices and methods for the efficient disaggregation of tissue samples, separating the tissue into individual intact cells or small aggregates of cells for analysis. A device may include a chamber to receive fluid and a tissue specimen containing more than one cell to be disaggregated. The chamber may include an opening and an agitator in fluid contact with the fluid and the tissue specimen. The agitator may include a micromotor which provides rotational motion to a shaft and an impeller fixed to the shaft such that the impeller and the shaft rotate together upon provision of the rotational motion by the micromotor. The device may include an electrical energy source electrically coupled to the micromotor to rotate the impeller sufficient to disaggregate the one or more individual cells from the tissue specimen and in a manner which does not lyse the one or more individual cells.

A cell extruder of the present invention comprises: a pressure vessel in which a sample is dispensed; a regulator for adjusting a set pressure of nitrogen gas injected into the pressure vessel and then maintaining a constant pressure; an input valve for opening and closing the injection of nitrogen gas into the pressure vessel; an exhaust valve for removing the internal pressure of the pressure vessel; a filter holder which is provided with a membrane filter soaked with a reagent, so that the sample in the pressure vessel is fed through by the nitrogen gas and crushed into extracellular vesicles; and a collection container in which the extruded sample is stored. According to the present invention, pressure can be freely adjusted by the regulator. That is, the flow rate of the membrane according to pressure can be controlled, thus allowing the validation of a biopharmaceutical production method using an extracellular vesicle extruder. In addition, during cell extrusion, a sintered disc can be removed and cells can be extruded by using only a membrane. Vesicles can be produced within a fine pressure adjustment range (at a fine low pressure at which the membrane is not torn) in which no sintered disc is required.

A deagglomerator for use in resizing masses of cells is disclosed. The deagglomerator may include a plurality of apertures defined by a plurality of front and back edges. The masses of cells may be passed through the plurality of apertures from the front to the back, and from the back to the front, repeatedly. The deagglomerator may also include a plurality of blades that may aid in the deagglomeration of the cell masses. The deagglomerator may be configured between two syringes so that the tissue may be passed back and forth from the first syringe through the device to the second syringe, and then back again from the second syringe through the device and to the first syringe. In this way, the masses of cells may be properly deagglomerated.

A disaggregation system includes a console, the console including a housing, a pod holder plate, a motive applicator mounted in the housing and configured to move the pod holder plate. The system further includes a sample pod configured for holding tissue to be disaggregated, where the sample pod includes a collector component configured for mounting to the pod holder plate; a tissue holder sleeve configured for holding tissue to be disaggregated; and a disaggregation screen. Tissue can be disposed in the sample pod, the sample pod configured to be mounted on the pod holder plate of the console, and when the motive applicator moves the pod holder plate with the pod thereon, tissue in the sample pod configured to be disaggregated into cells.

An improved dry grind system and method for producing a sugar stream from grains or similar carbohydrate sources and/or residues, such as for biofuel production. In particular, a sugar/carbohydrate stream, which includes a desired Dextrose Equivalent (DE) where DE describes the degree of conversion of starch to dextrose (aka glucose) and/or has had removed therefrom an undesirable amount of unfermentable components, can be produced after saccharification and prior to fermentation (or other sugar conversion process), with such sugar stream being available for biofuel production, e.g., alcohol production, or other processes. In addition, the systems and methods also can involve the removal of certain grain components, e.g., corn kernel components, including protein, oil and/or fiber, prior to fermentation or other conversion systems. In other words, sugar stream production and/or grain component separation occurs on the front end of the system and method.

Non-enzymatic method and milling device for preparing therapeutic cells from adipose tissue comprising: continuously feeding the adipose tissue to the milling device (2); mechanically separating the cells or cell aggregates from adipose tissue moving through the milling device (2) by means of a multiplicity of blades (19) of a rotor (10), wherein the blades (19) are arranged in a spaced arrangement with respect to the overall direction of flow and the blades (19) are moving about an axis of rotation (18), wherein the axis of rotation (18) is provided essentially parallel to said overall direction of flow; continuously withdrawing the processed tissue comprising the separated cells from the milling device (2).

Harvested adipose tissue is processed in a single-use portable processing container to prepare a centrifuges pellet phase of stromal vascular fraction concentrate, which is selectively removed and disposed in a syringe dispersed in a dispersion medium to prepare an osteoarthritis treatment product.

The present disclosure generally relates to a pretreatment arrangement (100) for pretreatment of lignocellulosic biomass. The pretreatment arrangement (100) comprises a reactor vessel (101) having an upstream inlet (102) for receiving biomass and a downstream outlet for discharging biomass (103). The pretreatment arrangement (104) further comprises a sluice vessel (104). The present disclosure also relates to a method (200) for pretreating lig- nocellulosic biomass.

The present invention relates to a method for mechanically separating tissue and cells, and more specifically, to a method for mechanically separating tissue and cells, the method comprising the steps of: preparing adipose tissue; diluting the adipose tissue with a diluent to prepare an adipose tissue mixed solution; micronizing the adipose tissue, and various tissue and cells constituting the adipose tissue, in the adipose tissue mixed solution; and separating the adipose tissue and the various tissue and cells constituting the adipose tissue, in the adipose tissue mixed solution.

Provided herein are filter cake-based systems and methods for cultivating cells and cell biomass therefrom. Provided herein is a system for cultivating cells and cell biomass comprising a filter chamber comprising at least one inlet and at least one outlet, at least one filter support located within the filter chamber, and a filter cake located on the filter support, wherein the filter cake comprises at least one filter aid and a plurality of cells. Provided herein is a method for optimizing the cultivation of cells and cell biomass, comprising providing a filter support, adding at least one filter aid to the filter support, adding a plurality of cells to the filter aid, wherein the cells and the filter aid together comprise a filter cake, growing the cells into a cell biomass in the filter cake, wherein the filter cake is at least partially compressible.