Abstract: The present disclosure is directed to methods of treating Allan-Herndon-Dudley syndrome comprising administering 3,5-diiodothyropropionic acid (DITPA) to a subject in need thereof, and to administering gene therapy to the subject by introducing normal human MCT8 into the subject's cells in order to increase T3 in the subject's brain.

Abstract: The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.

Abstract: Brain microvascular endothelial cells (BMECS) can be generated from pluripotent stem cells, and possess membrane barrier functions along with capability for maturation into other developing tissues. This cell type has not been successfully frozen with loss of significant viability and/or BMEC functional properties. For example, BMECs can be used to model barrier function in blood brain barrier, by calculating the trans-endothelial resistance (TEER). However, thawed primary BMECs lose TEER resistance. By optimizing cell preparation, freezing media selection, and the controlled freezing, the Inventors have achieved complete recovery of frozen cells, achieving proper tight junction protein expression and physiologically relevant TEER. The freezing methods and compositions described herein, thereby allow for BMECs to be manufactured, frozen and distributed at scale.

Abstract: The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.

Abstract: Described here are systems and methods for deriving both spinal motor neurons and brain microvascular endothelial cells from induced pluripotent stem cells using distinct methods and combining them in a chip format. Neurons cultured alone in chip microvolume displayed increased calcium transient function and chip-specific gene expression. When seeded with endothelial cells, interaction further enhanced neural function, elicited vascular-neural interaction, niche gene expression with enhanced in vivo-like signatures arising from the chip co-cultures. Development of novel media formulations further allow for improved readout of differentiation process, by eliminating additives that otherwise confound differentiation processes and resulting phenotypes.

Abstract: The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.

Abstract: The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.

Abstract: The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.

Abstract: Brain microvascular endothelial cells (BMECS) can be generated from pluripotent stem cells, and possess membrane barrier functions along with capability for maturation into other developing tissues. This cell type has not been successfully frozen with loss of significant viability and/or BMEC functional properties. For example, BMECs can be used to model barrier function in blood brain barrier, by calculating the trans-endothelial resistance (TEER). However, thawed primary BMECs lose TEER resistance. By optimizing cell preparation, freezing media selection, and the controlled freezing, the Inventors have achieved complete recovery of frozen cells, achieving proper tight junction protein expression and physiologically relevant TEER. The freezing methods and compositions described herein, thereby allow for BMECs to be manufactured, frozen and distributed at scale.

Abstract: The invention relates to culturing brain endothelial cells, and optionally astrocytes and neurons in a fluidic device under conditions whereby the cells mimic the structure and function of the blood brain barrier. Culture of such cells in a microfluidic device, whether alone or in combination with other cells, drives maturation and/or differentiation further than existing systems.