A method for obtaining a plurality of pluripotent adult olfactory stem cells (APOSCs) includes isolating the APOSCs, culturing the isolated APOSCs in a sphere culture medium, and collecting the cultured APOSCs that express Bmi-1 (B-lymphoma moloney murine leukemia virus insertion region-1), Oct-4 (Octamer-binding transcription factor 4), Sox-2 (Sex-determining region Y (SRY)-box 2), Nanog, SSEA-4 (Stage-specific embryonic antigen-4), ki67, c-Myc, KLF-4 (Kruppel Like Factor 4), K14 (Cytokeratin 14) and ICAM-1 (Intercellular Adhesion Molecule 1).

The present invention provides a system for conservation and efficient use of energy through controlling and monitoring of devices. At least one processing controller connected to a sensor and a device, the processing controller configured to receive the ambient data from the sensor and operating parameters from the device; a user module configured to IO receive input parameters from a plurality of users; a central processing module, connected to the structure, the user module, and the admin module through wired and/or wireless connection, the central processing module configured to process the data received from the processing controller adapted in the zone of the structure and generate the optimum parameters for operating the device adapted in the zone to the structure.

Ex-vivo culture systems are provided. Accordingly there is provided a culture system comprising a culture medium and a precision-cut tissue slice placed on a tissue culture insert, wherein the precision-cut tissue slice is maintained in a highly oxygenated atmosphere containing at least 50% oxygen and wherein said culture is rotationally agitated facilitating intermittent submersion of the tissue slice in the culture medium. Also provided are methods of culturing a tissue and methods of using the culture system for selecting a drug for the treatment of a disease.

Provided is a method for efficiently culturing pluripotent stem cells with higher safety. The present invention relates to a method for culturing pluripotent stem cells, the method comprising culturing an isolated pluripotent stem cells in a pseudo-microgravity environment to proliferate the pluripotent stem cells while maintaining the pluripotent stem cells in an undifferentiated state, thereby forming and growing spheroids of the pluripotent stem cells; and a method for inducing differentiation of pluripotent stem cells by using the method.

Provided is a cell culture support, which is a support for attaching and culturing cells, and which includes: a fibrous web which is made by accumulating fibers of a biodegradable polymer and on which a plurality of pores are formed; and a plurality of beads formed on the fibers to secure spaces through which the cells penetrate into the fibrous web and grow therein.

A polymerizable unit that yields an electrochemically responsive polymer (advantageously pyrrole) is anchored by polymerization within a polycaprolactone matrix to form an electroactive scaffold upon which cells can be cultured and in which the micro- and nano-topological features of the polycaprolactone matrix are preserved. A scaffold manufactured in accordance with the preferred embodiment can support Schwann cells, which produce nerve growth factor when electrically stimulated. Nerve growth factor has been demonstrated to promote the regeneration of nerve tissue. By implanting the scaffold on which Schwann cells have been cultured into damaged nerve tissue and applying a voltage across the scaffold, nerve growth factor is produced, thereby promoting repair of the damaged nerve tissue.

A engineered textile construction includes a first textile having a first average pore size forming a textile cell growth matrix in which the first textile is a woven or a knit construction, the textile cell growth matrix is configured to have a surface area sufficient to promote cell expansion and the first average pore size is preselected to prevent filling of the pores during cell expansion.

A two-layer gradient coating article is provided that is operable to cause selective adhesion and directional migration of endothelial cells. The first layer includes cell-resisting polymers that repels cells, the second layer includes one layer of peptides that has affinity to and binds specifically to endothelial cells. Furthermore, the peptides are distributed in a gradient in which attached ECs migrate towards the direction of increased concentration, thus enriching the ECs to a desired locus. The combination of a cell-repelling layer and a graded affinity peptide produces a unique result of selective adhesion, directional migration, thus local enrichment of endothelial cells. A method for using such gradient coating article and its potential use in treating cardiovascular diseases are also provided. The invention provides an inexpensive, stable and effective means for attracting ECs to desirable locations.

This application provides constructs for use as complex cell systems of a desired shape and methods of preparing thereof. The constructs comprise cells contained within a biocompatible gel matrix deposited on a scaffold material optionally cut into defined patterns and impregnated with a crosslinking agent, wherein the biocompatible gel matrix crosslinks upon contact with the crosslinking agent on the scaffold. By stacking multiple alternating layers of the scaffold material cut into defined patterns and the biocompatible gel matrix deposited on the scaffold in defined patterns, complex 3D structures with features like embedded channels are be formed. These complex cell system constructs can be used as in vitro models of biological processes.

The present invention provides a technique which enables organization of bone marrow cells by a simple method in a short period of time. A method for preparing a bone marrow cell aggregate, comprising adding a liquid containing a bone marrow cell population to a medium containing a swellable material and culturing the bone marrow cell population in the presence of the swellable material. A method for reassembling a bone marrow tissue, comprising adding a liquid containing a bone marrow cell population to a medium containing a swellable material and culturing the bone marrow cell population in the presence of the swellable material. According to common knowledge in the art, it has been considered difficult to reorganize once disintegrated bone marrow tissue without changing the cell composition (that is, without adding any adherent cell or extracellular matrix which will work as a connecting material (binder)). Indeed, it was impossible to aggregate bone marrow cells by conventional methods. As a result of its achievement, the present invention changes such conventional thought and results and provides a major breakthrough technique pertaining to 3D culture of bone marrow cells. It has also been confirmed that culture of a bone marrow-like tissue reassembled by the method of the present could be continued up to day 14 in the MC medium.