The present invention relates to systems and methods for reprogramming cells to generate neurons and identifying effective treatments for neurodegenerative disorders using such neurons, as well as systems and methods for treating and developing treatments for one or more neurodegenerative disorders.

The present disclosure relates to methods for generating microglial cells derived from stem cells (e.g., human stem cells), microglial cells obtained from such methods and compositions comprising thereof, and uses of said microglial cells for disease modeling and for treating microglia related disorders.

The present invention relates to three-dimensional (3D) tissue constructs and methods of using such 3D tissue constructs to screen for neurotoxic agents. In particular, provided herein are methods of producing and using complex, highly uniform human tissue models comprising physiologically relevant human cells, where the tissue models have the degree of sample uniformity and reproducibility required for use in quantitative high-throughput screening applications.

The present invention discloses, in one embodiment, a method of using human induced pluripotent stem cells to generate three-dimensional human organ tissue for therapeutic drug toxicity and discovery. In one embodiment, a high throughput microtiter plate is loaded with both wild type and Rett disease 3D spheroids and exposed to a drug library, and activity is measured and analyzed for disease rescue to wild type cell behavior.

The present disclosure generally relates to a cell culturing system, and specifically to a three-dimensional cell culturing system for neuronal cells that promotes both structural and functional characteristics that mimic those of in vivo peripheral fibers, including cell myelination. Using a dual hydrogel construct and spheroids comprising neuronal cells, the present disclosure provides methods, devices, and systems for in vitro spatially-controlled, three-dimensional models that permit intra- and extra-cellular electro-physiological measurements and recordings. The three-dimensional hydrogel constructs allow for flexibility in incorporated cell types, geometric fabrication, and electrical manipulation, providing viable systems for culture, perturbation, and testing of biomimetic neural growth with physiologically-relevant results.

Cocktails of chemical inducers of neuron-like properties (CINP) is provided, which includes cAMP agonists, neurogenic small molecules, glycogen synthase kinase inhibitors, TGF receptor inhibitors, and BET family bromodomain inhibitors and optionally, a selective inhibitor of ROCK or p38 MAPK. These cocktails are used in a method of inducing neuron-like properties in partially or completely differentiated non-neuronal cells. The method includes contacting cells of a first type (non-neuronal) with the CINPs for a sufficient period of time to result in reprogramming the cell into cells of a second type having neuron-like characteristics (CiNs). Isolated chemically induced neurons (CiNs) can be used in a number of applications, including but not limited to cell therapy.

Provided is a structure composed of a cell population comprising endothelial cells, astrocytes and pericytes, and a 3D (three dimensional) cell growth material within which the cell population is located. The structure has a TEER value of at least 450 /cm.sup.2. The cells of the structure may be derived from the brain. The cells may be human cells, and in particular may be primary derived non-immortalised cells. The structure is particularly suited for use in a model of the blood brain barrier, and the invention also provides such a model. The structure is located in a container, in which it separates a first chamber located on a first side of the structure and a second chamber located on a second side of the structure. The first and second chambers respectively contain first and second liquids in contact with first and second sides of the structure. The liquids mimic the brain extracellular fluid and the blood. The blood brain barrier model provided may be used in models of brain disease, and to investigate uptake of agents into the brain or diseased brain.

The present invention relates to substantially planar vascularized brain cancer organoid and methods of using such vascularized brain cancer organoids in anti-cancer drug discovery screen. In particular, provided herein are methods of producing and using complex, highly uniform vascularized brain cancer organoids that comprise physiologically relevant human cells and have the high degree of sample uniformity and reproducibility required for use in high-throughput screening applications.

A method of in vitro cellular assay includes measuring an electrical activity of at least two cell populations in a plurality of cell populations that are disposed to be spaced apart from each other and connected to each other via a neurite, in which at least one of the at least two cell populations for which the electrical activity is measured is a cell population including at least one kind of neural cell, and the at least two cell populations each exhibit different electrical activity properties at a point when the electrical activity is measured.

The present invention relates to the field of in vitro 3D modeling of neural tissues, particularly of the brain. There is the need of developing cell culture models of neural tissue that reflect physiological aspects of neural tissue. The present invention provides methods of producing bioengineered neuronal organoids (BENOs) which form functional neuronal networks. The present invention also relates to uses and applications of the produced BENOs, e.g., in the fields of drug screening and personalized medicine.