The present invention discloses an extracellular matrix comprising a modified polysaccharide consisting of repeating disaccharide units whereby in at least 11% of the disaccharide units one primary alcohol group is oxidized into a carboxylic acid.

Current kidney organoids model development and diseases of the nephron but not the con-tiguous epithelial network of the kidney's collecting duct (CD) system. Here, we report the generation of an expandable, 3D branching ureteric bud (UB) organoid culture model that can be derived from primary UB progenitors from mouse and human fetal kidneys, or gen-erated de novo from human pluripotent stem cells. In chemically-defined culture conditions, UB organoids generate CD organoids, with differentiated principal and intercalated cells adopting spatial assemblies reflective of adult kidney's collecting system. Aggregating 3D-cultured nephron progenitor cells with UB organoids results in a reiterative process of branching morphogenesis and nephron induction, similar to kidney development. Applying a gene editing strategy to remove RET activity, we demonstrate genetically modified UB organoids can model congenital anomalies of kidney and urinary tract (CAKUT). These platforms facilitate an understanding of development, regeneration and diseases of the mammalian collecting system.

The present invention discloses an extracellular matrix comprising a modified polysaccharide consisting of repeating disaccharide units whereby in at least 11% of the disaccharide units one primary alcohol group is oxidized into a carboxylic acid.

Provided herein are stem cells and methods for producing a culture of stem cells from urine. The stem cells may be differentiated into an osteogenic, chondrogenic, adipogenic, endothelial, neurogenic or myogenic lineage. Methods of use of the cells are provided, including methods of treating a subject in need of a cell based therapy.

Disclosed are renal tissues and arrays thereof that include a layer of renal interstitial tissue, the renal interstitial tissue comprising renal fibroblasts and endothelial cells; and a layer of renal epithelial tissue, the renal epithelial tissue comprising renal tubular epithelial cells, the renal epithelial tissue in contact with the layer of renal interstitial tissue to form a three-dimensional, engineered, biological renal tissue. Also disclosed are methods of fabricating and using the same.

The present invention relates to microfluidic fluidic devices, methods and systems as microfluidic kidney on-chips, e.g. human Proximal Tubule-Kidney-Chip, Glomerulus (Kidney)-Chip, Collecting Duct (Kidney)-Chip. Devices, methods and systems are described for drug testing including drug transport and renal clearance. Further, such devices, methods and systems are used for determining drug-drug interactions and their effect upon renal transporter functions. Importantly, they may be used for pre-clinical and clinical drug development for treating kidney diseases and for personalized medicine.

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.

Provided herein are compositions, systems, kits, and methods for generating human podocyte cells by contacting human nephron progenitor cells with an FGFR pathway inhibitor, a BMP pathway inhibitor, and a WNT pathway inhibitor. In certain embodiments, the nephron progenitor cells are further contacted with at least one factor selected from: BMP4, BMP7, lysophosphatidic acid, and gamma-secretase inhibitor XX. In certain embodiments, the contacting the nephron progenitor cells is performed under serum-free conditions.

A process of preparing buccal epithelial cell suspension and cystoscopically implanting the cell suspension in the defect site of the adult human urethra.

The present disclosure relates to novel multi-organ-chips establishing the differentiation of induced pluripotent stem cell (iPSC)-derived cells into organ equivalents on microfluidic devices and corresponding methods of generating organ equivalents. The present disclosure also relates to novel bioengineered tissue constructs mimicking organ barriers generated with iPSC-derived endothelial cells and/or organoids bioprinted in, and/or seeded on, a hydrogel. The present disclosure further relates to methods of bio-engineering organ constructs comprising co-culturing iPSC-derived organ precursor cells and iPSC-derived fibroblasts and endothelial cells. The present disclosure specifically provides a microfluidic device comprising: (i) iPSC-derived hepatocyte precursor cells; (ii) iPSC-derived intestinal precursor cells; (iii) iPSC-derived renal tubular precursor cells; and (iv) iPSC-derived neuronal precursor cells; wherein the iPSC-derived precursor cells according to (i), (ii), (iii) and (iv) are differentiated from a single donor iPSC reprogrammed from a single type of somatic cell.