A lung breathing chip and cell stretching culture platform and an operating method thereof are disclosed. The lung breathing chip and cell stretching culture platform controls the output of the motor by programming, stretches the micro-fluidic chip by the cam component, changes the size of the cam component and the frequency of the motor rotation to change the stretching frequency and the amount of stretching to simulate the breathing of the lungs in different states, uses liquid electrophoresis technology to arrange the cells in the biocompatible hydrogel and the hydrogel three-dimensionally to imitate the three-dimensional cell tissue, and injects drugs through the dynamic perfusion system to realize the drug testing platform that the cells of the chip bionic lung tissue are stretched.

The technology relates in part to methods and compositions for ex vivo proliferation and expansion of epithelial cells.

Disclosed are a biomimic system simulating lung tissue, a method for manufacturing same, and a microfluidic control method using same, wherein the biomimic system comprises lung epithelial cells and lung fibroblasts, which are isolated from human lungs, and commercially available vascular endothelial cells, and wherein a microfluid flows through the biomimic system. Each chamber inside the corresponding system can allow a fluid, which contains gas and a medium, to flow therethrough and simulate respiration-like movement, wherein all of the three types of cells can survive inside the system even when one week or more have elapsed after through-flow of the fluid. In addition, the pH and pO.sub.2 in the chamber can be monitored by using a pH sensor and a gas partial pressure sensor inside the system, and thus the three types of cells inside the system can be exposed to external environments, drugs, and the like under the same conditions as in the lungs in vivo. Therefore, a wide range of studies including modeling of lung diseases by harmful substances and testing of therapeutic drug efficacy can be conducted, and further, the utilization to in vitro disease modeling, customized medicine prescriptions, and the like can also be made.

The present invention provides a REGEND001 cell autologous deliverable preparation, and a use thereof for improving the pulmonary function of a patient suffering from idiopathic pulmonary fibrosis. The preparation is prepared by collection, in vitro isolation and culture and amplification of the patient's autologous bronchial basal cells.

The invention relates to a three-dimensional in vitro alveolar lung model comprising essentially the four cells types as follows: alveolar type II epithelial cells able to secrete (lung laying) surfactant, endothelial cells which forms the inner lining of capillaries providing a permeable barrier, dendritic-like cells, such as non-differentiated THP-1, linking innate and adaptive immunity and macrophage-like cells, able to participate to defense mechanisms by ingesting foreign materials by phagocytosis. The invention also relates to a process for preparing said model, and its use for assessing the irritation potential or toxicity of inhalable products such as particles or molecules on the alveolar barrier of lungs, and also for determining and/or predicting the sensitizing effects of inhalable products such as particles or molecules on the alveolar barrier of lungs.

Described are devices for tethering biological materials, which in applicable embodiments support the growth and differentiation thereof. In a specific embodiment, the biological materials are cells and the cells grow/differentiate into tethered three-dimensional aggregates. The devices disclosed herein may be used in various methods/assays relating to tethered biological materials, such as to tethered three-dimensional aggregates of cells.

The present invention relates to microfluidic fluidic systems and methods for the in vitro modeling diseases of the lung and small airway. In one embodiment, the invention relates to a system for testing responses of a microfluidic Small Airway-on-Chip infected with one or more infectious agents (e.g. respiratory viruses) as a model of respiratory disease exacerbation (e.g. asthma exacerbation). In one embodiment, this disease model on a microfluidic chip allows for a) the testing of anti-inflammatory and/or anti-viral compounds introduced into the system, as well as b) the monitoring of the participation, recruitment and/or movement of immune cells, including the transmigration of cells. In particular, this system provides, in one embodiment, an in-vitro platform for modeling severe asthma as “Severe Asthma-on-Chip.” In some embodiments, this invention provides a model of viral-induced asthma in humans for use in identifying potentially effective treatments.

The present disclosure provides systems for growing and, modeling lung cells in organoid cultures and methods of using same.

Provided herein are floating hydrogel droplet culture methods that enable scaling of stem cell derived alveolar epithelial cell (AEC) expansion to numbers compatible with large animal or human whole lung engineering, as well as molds for generating the droplets and methods of use thereof.

Disclosed herein is a method for cultivating primary human pulmonary alveolar epithelial cells (HPAEpiC), which includes cultivating the primary HPAEpiC in a first medium containing a basal medium, a culture supplement, and a Rho kinase inhibitor, and a second medium containing the basal medium and the culture supplement in sequence. The culture supplement includes Jagged-1 (JAG-1) peptide, human Noggin protein, transforming growth factor-β (TGF-β) type I receptor inhibitor SB431542, human fibroblast growth factor 7 (hFGF-7), hFGF-10, and glycogen synthase kinase 3 (GSK-3) inhibitor CHIR99021. Also disclosed is a method for preparing a three-dimensional cell culture of alveolar epithelium using the first medium and the second medium.