The invention relates to a neural tissue unit for use in implantation into the nervous system of a human or non-human mammal, wherein said neural tissue unit contains differentiated post-mitotic neuronal cells in an extracellular matrix, said unit being obtained from a cellular microcompartment comprising a hydrogel capsule surrounding the neural tissue unit, and said hydrogel capsule being at least partially removed before use of the neural tissue unit. The invention also relates to a process for preparing such a neural tissue unit.

Degradable hollow shell particles are disclosed that can encapsulate cells within the hollow inner cavity that allows for the high-throughput screening and sorting of the encapsulated cells based on their phenotypic properties. The solid-phase of the particle is porous such that solution exchange can occur between the external environment and the interior cavity. Further, the solid-phase contains degradable crosslinkers and can be degraded to release enclosed biological entities. An example embodiment consists of encapsulating a cell within the hollow shell particle, allowing the cell to accumulate biomass, selecting hollow shell particles based on accumulated biomass, and degrading the hollow shell particles to release the cells and develop hyper-producing cell lines. Exemplary cell types include microalgae, mammalian cells, bacteria, yeast, and fungi.

The present disclosure provides a process for obtaining an expanded primed mesenchymal stem cell population. In the process, the MSCs are cultured in the culture medium comprising a corneal stromal stem cell derived-conditioned medium to obtain the expanded population of the primed mesenchymal stem cell population along with the mesenchymal stem cell derived-conditioned medium. Also, provided is a method of culturing the MSCs in 3D culture using a spheroid-based method or a microcarrier-based method, in order to obtain the expanded primed mesenchymal stem cell population. Further, an exosome preparation obtained from the expanded primed mesenchymal stem cell derived-conditioned medium is also disclosed herein. The present disclosure also discloses a composition comprising an expanded population of the primed mesenchymal stem cells, or a primed mesenchymal stem cell derived-conditioned medium, or an exosome preparation, or combinations thereof.

Disclosed is a microcapsule which is used in tissue regeneration, which may be specifically directed to the damaged tissues, and which forms an extracellular matrix-like structure at a certain point and thus allows cell proliferation, and to the production method of such microcapsule.

Hydrodynamic methods for conformally coating non-uniform size cells and cell clusters for implantation, thus preventing immune rejection or inflammation or autoimmune destruction while preserving cell functionality. A method for conformally coating cells and c clusters with hydrogels that are biocompatible, mechanically and chemically stable and porous, with an appropriate pore cut-off size. The methods of the invention are advantageously reproducible and result in a relatively high yield of coated versus non-coated cell clusters, without compromising cell functionality. Conformal coating devices configured to perform the methods of the invention, methods of optimally utilizing said devices and purifying the coated islets, and coated biomaterials made by said methods.

Disclosed herein are compositions and methods for cellular reconstitution of photopolymerized, lyophilized, bioactive chondroitin sulfate glycosaminoglycan (CS-GAG)-based hydrogel matrices.

The devices, methods, and compositions disclosed herein accomplish robust cell encapsulation in polymer microparticles using a vertically oriented microfluidic device. A hydrophilic polymer precursor solution is flowed into a first inlet channel, which extends inward from an upper surface of the device housing. A hydrophobic fluid is flowed into a second inlet channel, which extends inward from a lower surface of the device housing. The two inlet channels meet at a junction, and an outlet channel extends away from the two inlet channels. When the two inwardly flowing streams meet at the junction, the polymer precursor solution disperses into the hydrophobic fluid. The dispersed precursor droplets are photopolymerized into microparticles as they travel through the outlet channel. The resulting microparticles are highly uniform, and are larger than conventionally formed microparticles. Cells of varying types can be encapsulated with high viability and spatial uniformity.

A pharmaceutical composition includes a silicified cell or fraction thereof, a cationic layer disposed on at least a portion of the surface of the silicified cell or fraction thereof, and an immunomodulatory moiety bound to at least a portion of the cationic layer. Alternatively, the pharmaceutical composition includes a silicified cell or fraction thereof, a cationic layer disposed on at least a portion of the surface of the silicified cell or fraction thereof, an anionic layer disposed on at least a portion of the cationic layer, and an immunomodulatory moiety bound to at least a portion of the anionic layer.

A composite shell particle including a composite shell layer is provided. The composite shell layer is a hollow shell, wherein the composite shell layer includes a porous biological layer and a metallic layer. The porous biological layer is composed of an organic substance including a cell wall or a cell membrane of a bacteria or algae. The metallic layer is crosslinked with the porous biological layer to form the composite shell layer. The metallic layer includes at least one metal selected from the group consisting of iron, molybdenum, tungsten, manganese, zirconium, cobalt, nickel, copper, zinc, and calcium, and/or includes at least one selected form the group consisting of metal chelates, metal oxides, metal sulfides, metal chlorides, metal selenides, metal acid salt compounds, and metal carbonate compounds. A method of manufacturing the composite shell particle, and a biological material including the composite shell particle and the applications thereof are also provided.

A broad object of a the instant invention can be to provide a method for separating X and Y sperm cells within a sample sperm cell population, the method including (i) differentiating between and (ii) separating sperm cells that have undergone a cellular process and sperm cells that have not undergone the cellular process, whereby a majority of the sperm cells that have undergone the cellular process can comprise one of X or Y sperm cells, and a majority of the sperm cells that have not undergone the cellular process can comprise the other of X or Y sperm cells. As to particular embodiments, the cellular process can be a maturational step. As to particular embodiments, the maturational step can be capacitation. As to particular embodiments, the maturational step can be the acrosome reaction. As to particular embodiments, non-viable and viable sperm cells can also be (i) differentiated between and (ii) separated.