Functional human cortico-spinal-muscle assembled spheroids are generated by in vitro culture. Complete cortico-spinal-muscle spheroids (hCS-hSC-hSkM) are assembled from component cultured cell systems, where each cultured cell system is designed to provide specific sets of neural and/or muscle cells, and which components are functionally integrated in the assembled spheroid.

The presently disclosed subject matter provides systems and methods for producing a three-dimensional model of a human cervix. A microdevice is provided for culturing human cervical cells. The microdevice can include an upper microchannel including live ectocervical epithelial cells. The microdevice can include a lower microchannel including a first parallel lane and a second parallel lane including stromal media. The first and the second parallel lanes can be lined with live vascular endothelial cells. The lower microchannel can include a third parallel lane including uterine fibroblasts and live smooth muscle cells embedded in hydrogel. The first, second, and third lanes of the lower microchannel can be separated by protrusion structures. The third parallel lane can be positioned in the lower microchannel in between the first and the second parallel lanes. The microdevice can further include a porous membrane positioned in between the upper microchannel and the lower microchannel.

Methods are disclosed for forming tissue engineered, tubular gut-sphincter complexes from intestinal circular smooth muscle cells, sphincteric smooth muscle cells and enteric neural progenitor cells. The intestinal smooth muscle cells and neural progenitor cells can be seeded on a mold with a surface texture that induces longitudinal alignment of the intestinal smooth muscle cells and co-cultured until an innervated aligned smooth muscle sheet is obtained. The innervated smooth muscle sheet can then be wrapped around a tubular scaffold to form an intestinal tissue construct. Additionally, the sphincteric smooth muscle cells and additional enteric neural progenitor cells can be mixed in a biocompatiable gel solution, and the gel and admixed cells applied to a mold having a central post such that the sphinteric smooth muscle and neural progenitor cells can be cultured to form an innervated sphincter construct around the mold post. This innervated sphincter construct can also be transferred to the tubular scaffold such that the intestinal tissue construct and sphincter construct contact each other, and the resulting combined sphincter and intestinal tissue constructs can be further cultured about the scaffold until a unified tubular gut-sphincter complex is obtained.

The present invention relates to a 3 dimensional mimetic tissue structureAssembloid based on patient-derived multiple cell types to develop next generation organoid technology serving as a novel platform for new drug development and a disease model and a method of manufacturing the same, and more particularly, to a stem cell- or tumor cell-based 3D multicellular mimetic tissue structure manufactured by reconstituting epithelial or tumor cells with various cellular components of a microenvironment such as stromal cells, vascular cells, immune cells or muscle cells based on three-dimensional (3D) bioprinting, and a method of manufacturing the same. As the stem cell- or tumor cell-based 3D multicellular mimetic tissue structure containing the major factors of a tissue microenvironment, such as stromal cells, vascular cells, immune cells and muscle cells, designed according to the present invention is confirmed to mimic physiological and pathological characteristics of tissue in the body better than conventional organoids, normal and tumor assembloids may be used as a new platform for new drug development and a disease model. More specifically, together with 3D bioprinting technology, it is expected that in vitro bladder tissue and bladder tumor tissue are effectively used as a platform to develop precise and personalized therapeutic options for bladder related diseases including bladder cancer.

Methods are disclosed for forming tissue engineered, tubular bowel constructs from intestinal circular smooth muscle cells and enteric neural progenitor cells. The intestinal smooth muscle cells and neural progenitor cells can be seeded on a mold with a surface texture that induces longitudinal alignment of the intestinal smooth muscle cells and co-cultured until an innervated aligned smooth muscle sheet is obtained. The innervated smooth muscle sheet can then be wrapped around a tubular scaffold to form an intestinal tissue construct.

A method of screening a composition for cardiotoxicity comprising contacting the composition with cardiomyocytes that have increased fatty acid oxidation and/or diminished glucose oxidation. The cardiomyocytes are preferably prepared by overexpression of COX7A1. The cardiomyocytes are preferably provided in a micropatterned co-culture to provide a mature functional hPSC-CM cardiotoxicity model.

The invention is directed to a method for producing an edible composition, comprising incubating a three-dimensional porous scaffold and a plurality of cell types comprising: myoblasts or progenitor cells thereof, at least one type of extracellular (ECM)-secreting cell and endothelial cells or progenitor cells thereof, and inducing myoblasts differentiation into myotubes.

Co-culture of isolated human induced pluripotent stem cell (iPSC)-derived endothelial and smooth-muscle progenitor cells results in the formation of cellular spheroids having capillary-like structures (referred to herein as capillary fragments) at their core. Bioprinting of these spheroids into scaffold-free tissue constructs facilitates the development of microvasculature within the engineered tissue. Methods of using these bioprinted engineered tissues for cell therapy are also disclosed.

Differentiation and stability of neural stem cells can be enhanced by in vitro or in vivo culturing with one or more extracellular matrix (ECM) compositions, such as collagen I, IV, laminin and/or a heparan sulfate proteoglycan. In one aspect of the invention, adult mammalian enteric neuronal progenitor cells can be induced to differentiate on various substrates derived from components or combinations of neural ECM compositions. Collagen I and IV supported neuronal differentiation and extensive glial differentiation individually and in combination. Addition of laminin or heparan sulfate to collagen substrates unexpectedly improved neuronal differentiation, increasing neuron number, branching of neuronal processes, and initiation of neuronal network formation. In another aspect, neuronal subtype differentiation was affected by varying ECM compositions in hydrogels overlaid on intestinal smooth muscle sheets. The matrix compositions of the present invention can be used to tissue engineer transplantable innervated GI smooth muscle constructs to remedy aganglionic disorders.

The presently disclosed subject matter provides systems and methods for producing a three-dimensional model of a human cervix. A microdevice is provided for culturing human cervical cells. The microdevice can include an upper microchannel including live ectocervical epithelial cells. The microdevice can include a lower microchannel including a first parallel lane and a second parallel lane including stromal media. The first and the second parallel lanes can be lined with live vascular endothelial cells. The lower microchannel can include a third parallel lane including uterine fibroblasts and live smooth muscle cells embedded in hydrogel. The first, second, and third lanes of the lower microchannel can be separated by protrusion structures. The third parallel lane can be positioned in the lower microchannel in between the first and the second parallel lanes. The microdevice can further include a porous membrane positioned in between the upper microchannel and the lower microchannel.