Cell based therapy comprises administration to the lung by injection into the blood system of viable, mammalian cells effective for alleviating or inhibiting pulmonary disorders. The cells may express a therapeutic transgene or the cells may be therapeutic in their own right by inducing regenerative effects.

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 invention is in the domain of delivery of molecules to brain cells across the blood-brain barrier. The invention relates to a novel polypeptide-based carrier that allows the efficient delivery of an effector peptide, to neuron cells across the blood-brain barrier, and to methods for the production and testing of such carrier, including a model for testing the capacity of such molecule to cross the blood-brain barrier and/or the toxicity of molecules on the blood brain barrier and/or the capacity of molecules that have crossed to target human brain cells (e/g. neurons, astrocytes and microglial cells).

The present disclosure relates to a simple, fast, and low cost method for 3D microvascular imaging, termed “scatter labeled imaging of microvasculature in excised tissue” (SLIME). The method can include perfusing a contrast agent through vasculature of a tissue sample with a contrast perfusing unit (22). The contrast agent can include colloids and a dispersant. After the contrast agent is perfused through the vasculature, the vasculature of the tissue sample can be treated with a cross-linking agent delivery unit (24) providing a molecule that cross links with at least a portion of the dispersant to form a sticky, non-Newtonian polymer that prevents leakage of the contrast agent out of the vasculature of the tissue sample. The tissue sample can then be immersed in a solution comprising a clearing agent with an optical clearing unit (26) and subsequently imaged.

Disclosed are a heterogeneous stem cell population, a preparation method therefor, and the use thereof. Specifically, disclosed is a heterogeneous stem cell population, characterized in that stem cells in the heterogeneous stem cell population express stemness genes MYC, KLF4, GMNN, SOX2 and NANOG, and in the heterogeneous stem cell population, the ratio of stem cells expressing CD146 is 1%-50%.

Provided is a process for creating a 3D metabolically active microtissue perfused with living microvessels which have a direct fluidic connection with neighboring microfluidic channels. The process comprises preparing a template comprising a plurality of channels, and creating a network within said channels, said network comprising microfluidic channels, metabolically active living microvessels, and microtissues. The microvessels can sprout from said microvessels and/or form within the microtissue in response to a stimulus applied from said microfluidic channels or stimulus derived from the said tissues. In another embodiment, a device is provided comprising a supportive structure, one or more microfluidic channels, one or more microtissue compartments, and one or more microvessels, whereby the microvessels connect said microfludic channels and microtissue and perfuse the microtissue to deliver fluid from the microfluidic channels to the microtissues.

The invention provides a combination of compositions comprising in a first composition 17β-estradiol as the active ingredient and, as a second composition, a suspension of cells for use in the treatment of functional defects of an epithelium, e.g. of an epithelium of a tissue, which tissue may be part of an organ.

A method of preparing a decellularized placental membrane is provided. The method comprises removing cells from a pre-decellularized placental membrane comprising an amnion layer and a chorion layer to produce a decellularized placental membrane without separating the amnion layer from the chorion layer. The pre-decellularized placental membrane is obtained from an amniotic sac, and the decellularized placental membrane comprises the amnion layer and the chorion layer. Also provided is a decellularized placental membrane and a placenta-derived graft comprising the decellularized placental membrane. Further provided are the uses of the decellularized placental membrane or the placenta-derived graft.

In one aspect, provided is a composition (biomimetic composition) that includes a biomimetic in vitro model of an arteriolar vessel comprising: at least one of 1) human smooth muscle cells and 2) human pulmonary endothelial cells; wherein the vessel recapitulates one or more of the overall tubular geometry, morphometrics, extracellular matrix constituents, cellular morphology, cellular alignment, and functional heterotypic connections between the human smooth muscle cells and/or the human endothelial cells as compared to an in vivo arteriolar vessel. A microfluidics-based model platform of the pulmonary circulation is provided. Methods of use include measuring flow in biomimetic vessels, and to determine the resistance of these biomimetic vessels in the setting of a variety of experimental conditions that recapitulate the pathobiology of pulmonary hypertension.

Provided herein are methods and systems for bio-printing of three-dimensional organs and organoids. Also provided herein are bio-printed three-dimensional organs and organoids for use in the generation and/or the assessment of immunological products and/or immune responses. Also provided herein are methods and system for bio-printing three-dimensional matrices.