The present disclosure is directed to a feeder-cell free methods of producing an expanded natural killer (NK) cell preparation. This method comprises providing a starting preparation of NK cells and treating the starting preparation with a natural killer cell p30-related protein (NKp30) modulating agent alone or with other expansion agents as described herein. The method further involves culturing the treated preparation under conditions effective to expand the starting preparation of NK cells to produce an expanded NK cell preparation. Other aspects of the disclosure related to therapeutic preparations of NK cells produced in accordance with the methods described herein.

The present invention relates to a method of immobilizing a cell on a support, the method comprising a) providing a compound or salt thereof comprising, preferably consisting of, one or more hydrophobic domains attached to a hydrophilic domain, wherein the one or more hydrophobic domains are covalently bound to said hydrophilic domain, and wherein the one or more hydrophobic domains each comprise a linear lipid, a steroid or a hydrophobic vitamin, and wherein the hydrophilic domain comprises a polyethylene glycol (PEG) moiety, and wherein the compound comprises a linking group; b) contacting a cell with the compound under conditions allowing the interaction of the compound with the membrane of the cell, thereby immobilizing the linking group on the surface of the cell; and c) contacting the linking group immobilized on the cell with a support capable of binding the linking group, thereby immobilizing the cell on the support.

The present invention provides the use of selected thermogelling polymers for the purpose of growing tumor spheroids. The invention provides a thermogelling platform comprising a synthetic polymer which, when seeded with cancer cells, induces the cells to grow into a natural spheroidal pattern forming a tumor spheroid. After accomplishing this in about 3-10 days, the gel washes away, leaving behind the spheroids.

Provided is a cell culture scaffold material having excellent cell adhesion. The cell culture scaffold material according to the present invention contains a peptide-conjugated polyvinyl alcohol derivative having a polyvinyl alcohol derivative portion and a peptide portion, and the peptide portion has a cyclic peptide skeleton.

The present invention relates to the manufacture of a platform for forming a neuronal spheroid and, more specifically, to the manufacture of a structure capable of simultaneously forming a test-tube three-dimensional neuronal spheroid and generating a neurite by forming a three-dimensional neuronal spheroid with a micro-platform and forming a neurite between the neuronal spheroid and the micro-platform so as to enable signal transduction, which is an essential function of a nerve cell.

The invention relates to bola-amphiphilic compounds and their uses for biomedical application. The invention particularly relates to the use of bola-amphiphilic compounds for providing low molecular weight gels (LMWG), useful, in particular, as culture media for animal or human cells, or as biocompatible material for biomedical applications.

Provided are pharmaceutical compositions that include a pharmaceutically acceptable carrier and isolated post-natal cardiac progenitor cells (CPCs) and/or progeny cells thereof that are SSEA3-positive and c-kit-negative. Also provided are methods for preparing cells capable of repairing damaged myocardium, methods for isolating populations of SSEA3-positive/c-kit-negative CPCs from cardiac tissue samples, methods for preparing an isolated cell population enriched in post-natal SSEA3-positive/c-kit-negative CPCs, therapeutic methods for using the presently disclosed cells and populations of cells to treat subjects in need thereof, and cell cultures that contain the presently disclosed cells and populations of cells.

Example bioinks that can be used for three-dimensional (3D) printing of structures are described. In one example, a bioink composition may include gelatin methacrylate and collagen methacrylate. In some examples, the bioink may also include additional components such as lithium phenyl-2,4,6-trimethylbenzoylphosphinate (LAP). The bioink may promote stem cell differentiation into cardiomyocytes to generate functional 3D structures, for example.

Novel self-assembling pentapeptides and peptides containing such self-assembling pentapeptides, self-assembled hydrogels, and methods of making and using the same are described. These pentapeptides, and peptides containing such pentapeptides, self-assemble under physiological conditions (e.g., in a physiological buffer under biologically acceptable conditions (e.g., pH≈6-11)) into long fibrils with sequence-dependent fibrillary morphologies. The hydrogels comprise one or more these pentapeptides which make up the 3-dimensional nanofibrous network of the hydrogel structure. The hydrogels are shear-thinning hydrogels that have high storage moduli and high rates of recovery after destruction. These hydrogels are useful in various applications, including but not limited to, scaffolds for tissue engineering, 2-dimensional (2-D) and 3-dimensional (3-D) cell cultures, drug delivery and encapsulation of therapeutic agents (cells, molecules, drugs, compounds), injectables (including those that gel in situ, such as hemostatic compositions), hemostatic agents, wound dressings, pharmaceutical carriers or vehicles, cell transplantation, cell storage, virus culture, and virus storage.

A method of coating a surface with nanoparticles for biological analysis of cells that includes the steps of cleaning the surface with an oxidizing acid, treating the surface with an organosilane, coating the surface with nanoparticles, and then growing cells on the surface coated with the nanoparticles. The surface may be a glass surface, a silica-based surface, a plastic-based surface or a polymer-based surface. The nanoparticles may be gold-based nanomaterials.