A method of producing a cell mass by three-dimensional culture of primary cancer cells having proliferative ability and properties of handleability, versatility, and high-throughput performance, in which a tumor tissue is used as a starting material, proliferation of cells such as fibroblasts other than cancer cells is inhibited, and the cell mass includes primary cancer cells as a main component. The object is achieved by providing a method of producing a cell mass by three-dimensional culture of primary cancer cells using a tumor tissue, including: a three-dimensional culture step of culturing cells obtained from the tumor tissue in a medium containing a 5% v/v or less extracellular matrix on a substantially low-adhesive cell culture substrate.

Disclosed are compositions, in particular, organoid compositions, derived from more than one donor cell. Further disclosed are methods of making compositions, for example, organoid compositions, that comprise a differentiated cell population derived from more than one donor cell. Donor cells may include, for example, a precursor cell such as an embryonic stem cell or other precursor cell. The disclosed methods use synchronization conditions to produce a synchronized pooled-precursor cell population, which may then be differentiated into an organoid composition. Methods of using the compositions are also disclosed.

The present invention provides a nerve cell device in which early observation of nerve activity (spikes, bursts, and the like) is made possible and the measured electric strength is increased by cultivating neurons upon a cell scaffold. By using this nerve cell device, imaging of intracellular signaling is also possible.

The present disclosure relates to an advanced in vivo reprogramming system and a cell conversion method using same. The reprogramming system of the present disclosure comprises a start cell marker promoter, a pluripotency-maintaining gene protein, an amino acid isolation peptide, Cre recombinase, a target cell marker promoter, LoxP, and a gene encoding a fluorescent protein, does not require cell fixation in order to confirm cell conversion, enables real-time monitoring in a living cell state, and may be used both in vitro and in vivo. Therefore, the present disclosure is expected to be widely used in the biological and medical fields.

Provided is a three-dimensional tissue, including: a first cellular region including cells of a first type; and a second cellular region including cells of a second type different from the first type, wherein the cells of the first type are cells that emit light by chemiluminescence, bioluminescence, or fluorescence in response to an external stimulus.

The present invention relates to a method for measuring the immune-mediated effect of one or more immunotherapeutic agents on patient derived tumour cultures, using 3-dimensional visualisation of the tumour cell cultures. It also relates to the tumour cell cultures, and to a kit of parts comprising cell cultures and apparatus.

Disclosed is a spheroid liver organoid comprising hepatic lineage cells such as human hepatocytes, hepatic stellate cells, and liver sinusoidal endothelial cells. Also provided are methods of using spheroid liver organoids for applications related to drug screening and toxicity screening. In particular, spheroid liver organoids are useful for high-throughput screens to identify compounds having efficacy for treating liver disease.

Described in certain example embodiments herein are systems, methods, and uses thereof for high-throughput in vitro evaluating multiple test compounds in parallel for biological or pharmacological functions. In certain embodiments, the system allows the selection of a subset of test compounds from a group of test compounds to form an optimized pool, and methods are provided to use such optimized pool of test compounds to identify and validate therapeutic agents for treating diseases and driving guided differentiation of stem cells into desired types of cells. The systems described herein can provide, for example, a cost-effective and high-quality high-throughput approach for drug screening.

Provided is a 3D human liver organ model constructing method, comprising: preparing human primary liver cells, or mixed cells of same and liver non-parenchymal cells, or human liver cancer cell lines into a single cell suspension, and mixing the single cell suspension with a matrix material to obtain a mixed cell suspension; inoculating the mixed cell suspension into cultivation micropores of a 3D organ-on-a-chip, and carrying out cultivation at 37° C. to obtain a gelled 3D organ-on-a-chip; adding a culture medium into liquid storage holes of the organ-on-a-chip, and carrying out cultivation to obtain a 3D human liver organ model. Compared with other 2D human liver organ models, the constructed 3D human liver organ model has significantly enhanced response sensitivity to hepatotoxic drugs, and shows stronger hepatotoxic damage effect for reported hepatotoxic drugs. Compared with an animal model, the 3D human liver organ model can effectively eliminate the screening difference caused by species difference.

Compositions, devices, and systems comprising a corneal tissue carrier, wherein the corneal tissue carrier comprises a corneal tissue sample and a fluid; wherein the fluid comprises resazurin. Additionally, methods including measuring cell viability.