PROJECT SUMMARY/ABSTRACT Alzheimer’s disease (AD) is a devastating, progressive, neurodegenerative disease that affects millions of Americans, yet there is no cure, and there are very limited treatment options. Failure of otherwise promising drugs for AD may be due, in part, to poor penetration into the brain and/or large systemic dose requirements to achieve therapeutic brain concentrations, resulting in off-target effects. To address blood brain barrier (BBB) impenetrability, ultrasound-targeted microbubble cavitation (UTMC) is being explored as a new treatment strategy for AD. In this approach, low intensity ultrasound is applied to intravenously injected ultrasound contrast agents (microbubbles) as they traverse the microcirculation of the brain. UTMC causes transient endothelial barrier hyperpermeability, allowing for site-specific delivery of therapeutics across the BBB. While UTMC shows promise as a technique to increase BBB permeability, its underlying mechanisms are incompletely understood, ultimately constraining clinical translation. My overarching goal is that UTMC directed to the brain offers an approach to enhance drug delivery across the BBB for treatment of AD. To facilitate clinical translation of this platform, my proposal will determine mechanisms mediating UTMC-induced BBB hyperpermeability and utilize UTMC for delivering therapeutics directed at Ab plaques in vivo in the following Aims: (1) To identify mechanisms by which UTMC causes transient BBB hyperpermeability. UTMC applied to umbilical vein endothelial cells in vitro has been shown to change cytoskeletal dynamics, leading to inter-endothelial cell gaps, which can increase paracellular permeability, and was associated with Ca2+ influx into cells in contact with, and remote from, cavitating microbubbles. Extending these findings to the BBB, I hypothesize that UTMC-mediated Ca2+ influx disrupts tight and adherens junctions between brain microvascular endothelial cells, and may also lead to Ca2+-mediated changes in adjacent astrocytes. A contact co-culture in vitro transwell model of the BBB will be used to study changes in function and structure (confocal microscopy) of endothelial cells and astrocytes after UTMC. (2) To determine whether UTMC-mediated BBB opening, in combination with drug therapy, will lower Ab plaque burden and improve the therapeutic window. I hypothesize that UTMC-mediated BBB opening will decrease the dose required for a specific drug designed to lower Ab plaque deposition, thereby minimizing off-target effects. The drug will be administered, and UTMC will be applied to the brain in a mouse model of AD. Brain Ab plaques will be quantified by serial brain PET imaging. I have assembled an exceptional multidisciplinary team of mentors and collaborators, along with specific coursework and seminars, to acquire the necessary content expertise in AD biology, ultrasound theranostics, imaging, and murine AD models. Through meetings with my mentors and conducti...