A three-dimensional (3D) cell culture system comprising: a solid porous polymeric support, preferably comprising a biocompatible polymer; a first type of cells bound to the solid porous polymeric support; and a biocompatible hydrogel comprising a second type of cells, wherein biocompatible hydrogel is in physical contact with the solid porous polymeric support, is described. Methods for preparing this 3D cell culture system, as well as uses of this system for example for anticancer drug screening, are also described.

A composite material film for expanding circulating tumor cells ex vivo and a preparation method thereof, a kit and a method for expanding circulating tumor cells ex vivo, a method for detecting an effect of a drug, and a cryopreservation solution are provided. The preparation method includes: mixing one or more kinds of particles and a solvent to form a mixed liquid, in which the particles are selected from the group consisting of metal particles, metal oxide particles, silicon oxide particles and combinations thereof; placing the mixed liquid on a substrate to form a particle layer; adding a medium material to the particle layer, in which the medium material is selected from the group consisting of styrene and its derivatives, polyester monomers, silicon oxide compounds and combinations thereof; and polymerizing the medium material to form a medium layer to fix the particle layer on the substrate.

A material for culturing cells is disclosed. The material contains a bulk-modified elastomer having a Shore hardness (DIN EN ISO 868) in a range of Shore00 20 to Shore A 80 and comprising a plurality of fatty acid moieties covalently bound to the elastomer bulk, wherein the carboxylic acid groups of said moieties are available on an external surface of said material to provide said binding, and wherein the bulk-modified elastomer is obtained by forming a composition comprising a vinyl-functionalized or a hydride-functionalized elastomer or at least one precursor thereof, a free of saponified unsaturated fatty acid in a range of 0.5-5% by weight of the total weight of the a vinyl-functionalized or a hydride-functionalized elastomer or at least one precursor thereof and a cross-linking catalyst in a mold having a polar inner surface; and bulk-modifying the vinyl-functionalized or the hydride-functionalized elastomer by covalently binding the free or saponified unsaturated fatty acid to the elastomer bulk in said mold by a cross-linking reaction between a vinyl group or a hydride group of the elastomer and an unsaturated carbon-carbon bond of the unsaturated fatty acid to obtain the material. Also disclosed are a fluidic device module and fluidic device, a cell culturing method and a drug testing method.

Kits for making a spheroid-stabilizing hydrogel in a calcium-free or calcium-chelated cell culture media include (a) a gelation agent including a polygalacturonic acid (PGA) compound or an alginic acid compound, wherein the PGA compound includes at least one of: (i) pectic acid or salts thereof, or (ii) partially esterified pectic acid having a degree of esterification from about 1 to about 40 mol % or salts thereof; (b) a crosslinking agent, wherein the crosslinking agent includes a salt of a divalent ion; and (c) a proton donor, wherein the proton donor includes lactones, esters, or other compounds that hydrolyze in aqueous solutions to form acids over a period of from 10 minutes to 1 hour. Resultant spheroid-stabilizing hydrogels and methods of preparing the same.

Systems and methods for tissue engineered synthetic support structures, such as grafts and patches are provided. The systems and methods can be used to make tissue engineered planar sheathes or meshes that can be fashioned into substantially planar or non-planar 3D tissue/organ structures adaptable to structure and organs within a human or mammalian body. The systems and methods can use bioink deposited on a material having specified properties and matured under specified conditions to create the tissue engineered planar sheathes or meshes having biomechanical and biological properties tailored to a particular tissue.

The present disclosure provides an encapsulated liver tissue that can be used in vivo to improve liver functions, in vitro to determine the hepatic metabolism and/or hepatotoxicity of an agent and ex vivo to remove toxic compounds from patients' biological fluid. The encapsulated liver tissue comprises at least one liver organoid at least partially covered with a biocompatible cross-linked polymer. Processes for making the encapsulated liver tissue are also provided.

The present invention provides a tissue-engineering vascular graft (TEVG) comprising a biodegradable scaffold, and a plurality of stem cell-derived vascular smooth muscle cells (VSMCs), wherein the plurality of stem cell-derived VSMCs are seeded on the biodegradable synthetic polymer scaffold and are cultured under mechanical and biochemical stimulation.

The present disclosure provides a substrate for cell culture. Systems comprising the substrate, and methods for using and manufacturing the substrate are also disclosed herein.

The present disclosure provides methods of evaluating a therapeutic agent for cancer, and methods of cancer treatment.

Provided herein are, in various embodiments, methods and compositions for differentiating olfactory mucosa-derived mesenchymal stem cells (OM-MSC). In certain embodiments, the disclosure provides for media to differentiate OM-MSCs. In still further embodiments, the disclosure provides for methods and compositions using differentiated OM-MSCs for the treatment of nerve repair. In particular embodiments, the disclosure provides for novel treatments of peripheral nerve repair.