Neuroscience
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Reconstruction of the Blood-Brain Barrier In Vitro to Model and Therapeutically Target Neurological Disease
Summary October 20th, 2023
The blood-brain barrier (BBB) has a crucial role in sustaining a stable and healthy brain environment. BBB dysfunction is associated with many neurological diseases. We have developed a 3D, stem-cell-derived model of the BBB to investigate cerebrovascular pathology, BBB integrity, and how the BBB is altered by genetics and disease.
Transcript
Our goal is to determine the molecular and cellular mechanisms that mediate Alzheimer's disease pathogenesis to uncover therapeutic and diagnostic opportunities. Currently, the molecular pathways and mechanisms involved in the onset and development of Alzheimer's disease are poorly understood. This is due to mouse models and other in vitro Alzheimer's disease models failing to recapitulate unique human biology that is crucial to the development of the disease.
We have developed an in vitro model of the blood-brain barrier that can be applied to study cerebrovascular pathologies associated with Alzheimer's disease, dementia, and other forms of neurodegeneration. This model has been employed to show that APOE4, the strongest risk factor for Alzheimer's disease, acts in part through a parasite-specific pathway to increase pathogenic amyloid burden Using induced pluripotent stem cells, we can construct human brain tissue in vitro that can be used to investigate disease pathology and drug screenings. Such an in vitro blood-brain barrier model enables personalized therapeutic and diagnostic approaches.
Our 3D in vitro blood-brain barrier model demonstrates physiologically relevant interactions, including vascular tube formation and localization of astrocyte endfeet with vasculature. It is also capable of modeling disease-relevant phenotypes, including amyloid pathology. Finally, the use of patient-derived induced pluripotent stem cells allows the study of any desired genetic background.
Using the in vitro blood-brain barrier model, we discovered pathways that mediate pathological cerebrovascular amyloid accumulation. This led us to explore therapeutic strategies that can reverse this pathology in aged APOE4 mice, which we are currently following up on.
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