Mouse Embryo Culture Chamber and Imaging System and Methods of Use

The culture of mouse embryos ex utero and continuous monitoring and imaging of embryos as they develop have applications in drug testing, genetic studies, and basic research on embryonic development. However, the embryo culture systems currently available for post-implantation embryos include rolling bottle culture systems, which do not permit imaging of the developing embryos and do not support the long-term survival and development of embryos ex utero.

Establishment of Induced Pluripotent Stem Cells (iPSC) from the Thirteen-lined Ground Squirrel

The limited choice in cell types available for in vitro studies has become an obstacle in hibernation research. 

Researchers at the National Eye Institute for the first time have successfully established iPSC line(s) from a mammalian hibernator, which can be potentially used to generate various cell types and tissue models for in-depth mechanistic studies of hibernation and coldness tolerance in vitro. 

Strategies to Protect Mammalian Neural Tissue Against Cold and Potentially Other Metabolic Stresses and Physical Damages

Researchers at the National Eye Institute (NEI) have discovered an invention describing a composition and method(s) of using such composition for preserving viability of cells, tissues, or organs at a low temperature (around 4ºC). Current cold storage solutions or methods for cells, tissues, and organs are suboptimal due to irreversible damage to cold-sensitive tissue or organ transplants that need a longer term of storage for facilitating clinical practices.

Biofabrication of Skin Tissues with Dermis and Epidermis in Multiwell Plate Format to be Utilized for Chemical and Biologic Testing as well as Transplantation and Regenerative Medicine

This technology includes methods for the biofabrication of full thickness skin tissues in 12, 24, 48 and 96-well plates, using commercially available hardware to enable the implementation of large-scale toxicity and efficacy testing of chemical and biologics.

Three-Dimensional Respiratory Epithelial Tissue Constructs With Perfusable Microvasculature

The invention provides two vascularized, multi-chip models for the alveoli and the small airway. Both models comprise a perfusable three-dimensional (3D) microvascular network consisting of human primary microvascular endothelial cells, fibroblasts, and pericytes with a differentiated lung epithelial layer exposed at the air-liquid interface (ALI) on top, built on a high-throughput, 64-chip microfluidic plate platform. The platform does not require the support of a permeable membrane and the epithelial cells are directly seeded on the perfused microvascular network.
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