The key health significance of this proposal involves the ultrasound-mediated, image-guided, localized treatment of ischemia reperfusion injury (IRI) in neuronal and cardiac models using echogenic argon microbubbles (ArMBs). There exist no clinically approved methods for treating damaged tissue after experiencing hypoxic ischemic and reperfusion injuries such as stroke or cardiac arrest. Noble gases like argon (Ar) and xenon (Xe) are highly promising cytoprotective agents that have been shown to successfully treat acute IRI in vitro and in animal models. Whereas Xe has been researched in greater detail including in early clinical trials, it can be prohibitively expensive and difficult to obtain. Ar is a hundred times cheaper and widely available, while exhibiting excellent organoprotective efficiency. Furthermore, the mechanism of Xe action depends on its interaction with glutamate receptors on cell membranes, whereas Ar is reported to work by stimulating various endogenous cellular protecting signaling pathways, making it a more versatile antiapoptotic agent. Current Ar therapy is long and systemic, via inhalation, making it non-specific to the injury site, likely diminishing therapeutic effect. As a solution, we propose the development of MBs (MBs) for localized delivery of the therapeutic gas. MBs are inherently echogenic due to their non-linear oscillations induced by clinical ultrasound. Therapeutic gases such as Ar, however, are difficult to stabilize inside bubbles due to the former's high aqueous solubility. The team has recently succeeded in small-scale production of stable, echogenic, noble gas MBs through optimization of the MB shell composition, leading to a productive, ongoing collaboration with clinicians at the Children's Hospital of Philadelphia (CHOP). The proposed research will be conducted through the implementation of three specific aims. (1) 1-10 µm ArMBs will be formulated at a high yield of >1010 MBs per mL. Ultrasound signal of optimized ArMBs will be investigated in flow phantoms and in a mouse model by measuring the magnitude, perfusion, and persistence of contrast. (2) The therapeutic effect of ultrasound mediated Ar release from bubbles in treating IRI will be estimated in in vitro cell culture-based simulations of neuronal and cardiac injuries induced by oxygen glucose deprivation. The validity of ArMBs will be proved by enhanced cell viability, decrease in caspase activation, and upregulation in the phosphatidylinositol 3 kinase (PI3K-AKT) pathway. (3) Further incentive to use ArMBs will be recognized by comparing their IRI treatment results to that of bulk Ar exposure to cells and exposure to XeMBs. ArMB activity even with the deactivation of glutamate receptors will be shown to cement the feasibility of ArMBs for a variety of cytoprotective treatments. The PI team will leverage their expertise in colloidal design, cellular dynamics, and ultrasound imaging to precisely engineer the ArMB shell and to rigorously estab...