The present invention provides differentiated neural cells and methods for making differentiated neural cells from pluripotent stem cells (PSC) at an industrial scale sufficient for high-throughput assays. The methods of the invention allow billions of PSCs and/or neural cells differentiated from the PSCs to be cryopreserved and expanded at multiple steps.

A composition includes porous silica particles to carry a cell fate modulating factor therein. A method for modulating cell fate includes treating various cells with the composition. The cell fate modulating factor is delivered to a stable target receptor, toxicity to subject cells for delivery may be reduced, a fate of the subject cells can be controlled through sustained release of at least 99 wt. % of the cell fate modulating factor.

Ag-Fe3O4 immunomagnetic microsphere contains poly-D-lysine modified on the surface and S100β and/or MBP antibody linked by an amide bond. The Ag-Fe3O4 immunomagnetic microsphere can specifically capturing peripheral nerve tissue-derived exosomes. When the microsphere is used to extract nerve tissue-derived exosomes, the extraction yield of exosomes per unit volume of nerve tissue is high, and the nerve specificity is strong.

According to a production method for a brain organoid, comprising a step 1 of carrying out suspension culture of human pluripotent stem cells having a mutation in at least one or more base sequences in an exon selected from the group consisting of an exon 9, an exon 10, an exon 11, an exon 12, and an exon 13 of a microtubule-associated protein tau (MAPT) gene, and having a mutation in at least one or more base sequences in an intron 10 of the MAPT gene, it is possible to produce a brain organoid having a phosphorylated 3-repeat tau protein and a phosphorylated 4-repeat tau protein.

There is provided a method of inducing differentiation of bone marrow stromal cells to neural cells or skeletal muscle cells by introduction of a Notch gene. Specifically, the invention provides a method of inducing differentiation of bone marrow stromal cells to neural cells or skeletal muscle cells in vitro, which method comprises introducing a Notch gene and/or a Notch signaling related gene into the cells, wherein the finally obtained differentiated cells are the result of cell division of the bone marrow stromal cells into which the Notch gene and/or Notch signaling related gene have been introduced. The invention also provides a method of inducing further differentiation of the differentiation-induced neural cells to dopaminergic neurons or acetylcholinergic neurons. The invention yet further provides a treatment method for neurodegenerative and skeletal muscle degenerative diseases which employs neural precursor cells, neural cells or skeletal muscle cells produced by the method of the invention.

The purpose of the present invention is to provide a novel medical application of pluripotent stem cells (muse cells) in regeneration medicine. The present invention provides a cell preparation and a pharmaceutical composition which are for amelioration and treatment of brain disorders resulting from fetal growth retardation, such as abnormal motor quality or abnormal neurological development, and which contain SSEA-3 positive pluripotent stem cells isolated from a mesenchymal tissue from a live body or cultured mesenchymal cells. It is assumed that this cell preparation is based on a mechanism where muse cells that are administered to objects having the disorders are engrafted on an impaired brain tissue, thereby ameliorating or treating the disorders.

Human striatal and midbrain organoids or spheroids are generated in vitro, which may be generated at least in part from human pluripotent stem (hPS) cells. Such spheroids model the regions of the human brain and comprise specific sets of cells that are associated with the striatum, including mature medium spiny neurons, and midbrain of a human, and that can be subsequently assembled with the cortex to form cortico-striatal-midbrain circuits in vitro.

Provided is a method for efficiently manufacturing high-purity peripheral nerve cells from undifferentiated cells. The method for manufacturing peripheral nerve cells from undifferentiated cells having an ability to differentiate into peripheral nerve cells includes the following steps (a) and (b): (a) culturing undifferentiated cells having an ability to differentiate into peripheral nerve cells to induce differentiation into neural progenitor cells without detaching a grown colony from a culture vessel; and (b) detaching the neural progenitor cells produced in the step (a) from the culture vessel, then seeding the cells at a seeding density of 2×10.sup.5 to 6×10.sup.5 cells/cm.sup.2 to a culture vessel, and culturing the cells for 14 to 42 days.

A production method for a cerebral organoid having amyloid plaques is provided, the method including a step (a) of forming, in the presence of a SMAD inhibitor, an embryoid body from a pluripotent stem cell having a mutation in an Alzheimer's disease-related gene; a step (b) of embedding the embryoid body after the step (a) in an extracellular matrix and three-dimensionally culturing the embedded embryoid body in the presence of a SMAD inhibitor and a glycogen synthase kinase 3β (GSK3β) inhibitor to form an organoid; and a step (c) of removing the organoid after the step (b) from the extracellular matrix and subjecting the removed organoid to stirring culture in a medium, where at least a part of the step (c) is carried out in the presence of leukemia inhibitory factor (LIF).

The present invention addresses a problem of providing a method for collecting extracellular vesicles derived from nervous system cells at an improved efficiency.

This problem is solved by a method for collecting extracellular vesicles derived from nervous system cells, said method comprising a step for mixing an anti-APLP1 antibody with a sample containing extracellular vesicles to form anti-APLP1 antibody-extracellular vesicle complexes and a step for collecting the anti-APLP1 antibody-extracellular vesicle complexes.