A method is directed to determining a thrombosis function and includes flowing a fluid sample over a surface having a fixed endothelial cell monolayer. The method further includes stimulating the fixed endothelial cell monolayer to induce formation of a clot, the clot being formed via interaction between the fixed endothelial cell monolayer and the fluid sample. In response to the clot formation, the method further includes determining a thrombosis function associated with the fluid sample and the fixed endothelial cell monolayer.

An in vitro microfluidic intestine on-chip is described herein that mimics the structure and at least one function of specific areas of the gastrointestinal system in vivo. In particular, a multicellular, layered, microfluidic intestinal cell culture, which is some embodiments is derived from patient's enteroids-derived cells, is described comprising L cells, allowing for interactions between L cells and gastrointestinal epithelial cells, endothelial cells and immune cells. This in vitro microfluidic system can be used for modeling inflammatory gastrointestinal autoimmune tissue, e.g., diabetes, obesity, intestinal insufficiency and other inflammatory gastrointestinal disorders. These multicellular-layered microfluidic intestine on-chips further allow for comparisons between types of gastrointestinal tissues, e.g., small intestinal duodenum, small intestinal jejunum, small intestinal ileum, large intestinal colon, etc., and between disease states of gastrointestinal tissue, i.e. healthy, pre-disease and diseased areas. Additionally, these microfluidic gut-on-chips allow identification of cells and cellular derived factors driving disease states and drug testing for reducing inflammation.

The present invention provides methods for the identification, isolation and/or enrichment of human corneal endothelial cells (HCECs). In some embodiments, the method comprises a positive selection process in which a cell population containing human corneal cells is contacted with a positive affinity reagent that selectively binds to HCECs relative to cells other than HCECs (e.g., corneal keratocytes, etc.) in the population and/or a negative selection process in which a cell population containing HCECs is contacted with a negative affinity reagent that selectively binds to cells other than HCECs in the population relative to HCECs. The present invention also provides reagents and kits for the identification, isolation and/or enrichment of HCECs as well as compositions that are enriched in HCECs.

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 microfluidic fluidic devices, methods and systems as microfluidic kidney on-chips, e.g. human Proximal Tubule-Chip.

Methods for the detection, enumeration and analysis of circulating tumor cells expressing insulin-like growth factor-1 receptors (IGF-1R) are disclosed. These methods are useful for cancer screening and staging, development of treatment regimens, and for monitoring for treatment responses, cancer recurrence or the like. Test kits that facilitate the detection, enumeration and analysis of such circulating tumor cells are also provided.

A method for testing an anticancer effect including culturing a cell structure including cancer cells and stromal cells in a presence of an anticancer drug and immune cells, and measuring the number of living cancer cells in the cell structure after the culturing, as an indicator of an anticancer effect of the anticancer drug or the immune cells.

Methods of screening rinse-off personal care compositions can include the use of explant skin in combination with measurements for moisture and/or cell proliferation.

The present invention provides methods for the identification, isolation and/or enrichment of human corneal endothelial cells (HCECs). In some embodiments, the method comprises a positive selection process in which a cell population containing human corneal cells is contacted with a positive affinity reagent that selectively binds to HCECs relative to cells other than HCECs (e.g., corneal keratocytes, etc.) in the population and/or a negative selection process in which a cell population containing HCECs is contacted with a negative affinity reagent that selectively binds to cells other than HCECs in the population relative to HCECs. The present invention also provides reagents and kits for the identification, isolation and/or enrichment of HCECs as well as compositions that are enriched in HCECs.

Disclosed herein are embodiments of a device that can be used to mimic the biochemical and physiological actions of a lung organ. Also disclosed herein are embodiments of components that are included in the device as well as methods of making and using the device. Further disclosed are platform device embodiments and various components used therein that can be used in combination with the lung organ devices disclosed herein. In some embodiments, the disclosed devices can be used to determine drug toxicity and also can be used with one or more disease models to determine methods of treating disease.