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).

Methods of expanding tumor infiltrating lymphocytes (TILs) from cryopreserved tumor tissue and methods of using the expanded TILs in the treatment of human diseases, including cancers, are disclosed. Preparing the tumor tissue for freezing includes fragmenting the tumor tissue, and incubating the fragments in a cryopreservation medium. In an embodiment, the fragments may be incubated in the cryo preservation medium at 2° C. to 8° C. for about 30 to about 80 minutes. Freezing the fragments may be done by flash freezing using the vapor phase of liquid nitrogen, e.g. using a dry cryoshipper. In some embodiments, compositions of cryopreserved tumor tissues are disclosed.

Provided herein are novel organoid culture media, organoid culture systems, and methods of culturing tumor organoids using the subject organoid culture media. Also provided herein are tumor organoids developed using such organoid culture systems, methods for assessing the clonal diversity of the tumor organoids, and methods for using such tumor organoids, for example, for tumor modelling and drug development applications. In particular embodiments, the tumor organoid culture media provided herein is substantially free of R-spondins (e.g., R-spondin1).

Embodiments of the present disclosure provide a target capturing apparatus and a manufacturing method thereof, and a target detecting method. The target capturing apparatus includes a cavity structure, the cavity structure includes: an inlet portion, an outlet portion and a capture region positioned between the inlet portion and the outlet portion, and the capture region includes a capture component, and a combination specifically combined with a to-be-captured target is included in the capture component so as to capture the target in a sample entering the cavity structure.

The present invention relates to a method for extracting nucleic acids from a biological sample, and the extraction method presents a novel method for effectively extracting nucleic acids. When nucleic acids are extracted from biological samples in the related art, various impurities present in the biological samples are not properly removed, such that the purification rate is low, but the present invention provides a method for extracting nucleic acids from a biological sample of which the bacteria, virus and nucleic acid recovery rates are enhanced, by adding a surfactant and a sodium sulfate (Na.sub.2SO.sub.4) solution in a biological sample disruption step and a purification step, thereby enabling pathogens to be detected more sensitively and accurately.

The present invention relates to methods for obtaining skeletal muscle derived cells (SMDC), and the use of SMDCs in a method of preventing and/or treating neuromyopathies and/or myopathies, wherein the neuromyopathy and/or myopathy is incontinence, in particular a urinary and/or an anal or fecal incontinence.

Provided herein is technology relating to processing biological samples and particularly, but not exclusively, to systems and apparatuses for dissociating biological tissues into viable cells.

A system that easily and stably separates various living cells from a living body-derived tissue, the system including: a mincing unit that minces the living body-derived tissue based on a parameter; a measurement unit that acquires information regarding the living body-derived tissue being minced; and an analysis unit that calculates a ratio of impurities to the living body-derived tissue being minced from the information acquired by the measurement unit. Methods for separating various living cells from a living body-derived tissue are also disclosed.

The present disclosure provides improved methods for bead beating and a bead beating system useful therefor. The present disclosure further provides methods of using the bead beating system to extract nucleic acids from cells containing the nucleic acids.

A method for processing biological material containing stringy tissue in a container having a tissue collector disposed in a tissue retention volume on one side of an internal filter includes washing biological material contained in the tissue retention volume with wash liquid to the tissue retention volume and allowing the wash liquid and rotating the tissue collector disposed in the tissue retention volume relative to the container in a first direction of rotation about an axis of rotation to sweep the teeth positioned on the tissue collector through the biological material and to collect stringy material on the tissue collector.