Methods of making a spheroid are provided whereby a suspension is first produced including one or more biologically-relevant materials dispersed within a biocompatible medium. A droplet of the suspension is then bioprinted into a salt solution by bringing the droplet into contact with a surface of the salt solution in a controlled manner to reproducibly yield a spheroid containing a desired size and a desired amount of biologically-relevant materials.

The present disclosure provides compositions and methods for providing a cell replacement therapy to treat various diseases, including pancreatic diseases and diabetes. Specifically, the disclosure provides three-dimensional (3D) cell clusters of transdifferentiated insulin producing cells attached to scaffolds, such as a polysaccharide matrix, in order to provide a cell replacement therapy.

The present disclosure provides information on the methodology used in the fabrication of three-dimensional cellularized tissue constructs from free-standing evacuable 3D printed composites and/or scaffolds embedded in an extracellular matrix mimic generated from biocompatible materials. The purposes of using these composite and/or scaffold materials is to generate complex embedded lumens that allow for complete perfusion of the matrix construct by standard cell culture media, thereby allowing for maintenance of large-scale 3D cell cultures in specific geometric forms. The use of biological extracellular matrix materials is to provide essential biological and mechanical signals needed to regulate the behavior of encapsulated cells. Furthermore, the methodology can be adapted such that the lumens generated are capable of being seeded with various endothelial and epithelial cell types as desired, thereby allowing for mimicry of in vivo vasculature, intestinal tracts, and other lumen-containing constructs. This disclosure provides the methodology for generating the tissue constructs.

The technology relates in part to epithelial cell spheroids and methods of producing epithelial cell spheroids.

A method for topographically controlled aggregation, wherein cells of the same type or different type, such as different strains of bacterial cells, are layered in a way that controls the size, structure and number of aggregates as well as the potential spatial distribution of the different species of cells within the aggregates. The method includes a step of surface modifying cells with a polyelectrolyte.

Provided is a sample processing method that liquefies a medium solution by making a liquid that liquefies the medium solution act on a sample formed by gelating or solidifying the medium solution that is supported by a substrate while an observation subject is included therein, while maintaining a state in which the medium solution is supported by the substrate while the observation subject is included therein.

This invention relates to live cell constructs for in vitro and/or ex vivo production of cultured milk products from mammary cells, methods of producing isolated cultured milk products from mammary cells, bioreactors for producing isolated cultured milk products, and cultured milk products.

The present invention relates to a method for providing an embedded mammalian cell, comprising the steps of providing an alginate sulfate in aqueous solution; reacting the alginate sulfate to form a hydrogel in a gelation step, providing a precursor cell, and embedding the precursor cell in the sulfated alginate hydrogel in an embedding step, thus yielding an sulfated alginate hydrogel embedded cell. The invention further relates to sulfated alginate hydrogels, and cellular grafts comprising a mammalian cell embedded in sulfated alginate hydrogel.

The present invention relates to 3D printable composition comprising a cross-linkable component, a non-cross-linkable polymer, and analyte sensor particles, and to a method of fabricating a scaffold for living cells, a scaffold for a living cell, and a kit of parts comprising components for performing the method to obtain the scaffold. The scaffold is useful for prolonged culture of living cells and allows monitoring a metabolite throughout the culture with high spatial resolution of the metabolite in the scaffold.

Among the various aspects of the present disclosure is the provision of methods, synthetic DC, and compositions for T cell activation. The present disclosure provides for synthetic dendritic cells (DCs), methods of generating synthetic dendritic cells (DCs), methods of generating T cell-encapsulated gelatin microspheres and microcapsules, methods of activating T cells using synthetic DCs, methods for expanding T cells against individualized antigen-specific mutational antigens using synthetic DCs, and methods of treating a chronic disease (e.g., HIV, HPV) or cancer using the synthetic DCs.