PROJECT SUMMARY/ABSTRACT Glaucoma affects about three million Americans and is a leading cause of blindness worldwide. Patients suffer from progressive optic neuropathy, for which intraocular pressure (IOP) induced mechanical insults at the optic nerve head (ONH) play a central role. Current treatments all aim to lower IOP. While these treatments are beneficial, many patients continue to lose vision with persistent optic nerve damage. There is a great need to identify other modifiable risk factors, based on which novel treatments may be developed to combat this public health problem. Biomechanically, the level of IOP-induced mechanical insults (i.e., stresses and strains) at the ONH are not determined by IOP alone. Computational studies have shown that peripapillary sclera (PPS) modulus and thickness are among the most influential factors. Interestingly, PPS biomechanical changes are implicated in older age, African American race, and high myopia, which have increased glaucoma risk. However, there is a knowledge gap in understanding the biomechanical interplay between ONH and PPS. For example, what PPS biomechanical properties are optimal and how PPS can be modified to mitigate IOP-induced mechanical insults at ONH remain poorly understood. We propose to use a high-resolution ultrasound elastography technique to resolve the complex mechanical responses of the ONH and PPS through full tissue thickness, and to begin to fill the knowledge gap. Using this technique, we will quantify ONH and PPS deformation in normal human donor eyes, those with PPS remodeling, and those with experimental modification of PPS properties. We will also further develop this technique for in vivo biomechanical imaging of the ONH and PPS in an animal model. Specifically, we propose the following aims: 1) test the prediction that ONH deformation is correlated with PPS deformation and different in older age and African American race, 2) test the prediction that ONH deformation is different in eyes with PPS remodeling, 3) test the prediction that ONH deformation is altered after biochemical stiffening or softening of the PPS, and 4) test the feasibility of in vivo ONH and PPS ultrasound elastography in a pig model. Successful completion of the proposed studies will establish a clear understanding of the biomechanical interplay between ONH and PPS, a key contributor to an individual eye’s mechanical susceptibility to IOP. Combined with the development of an in vivo biomechanical imaging technique, this knowledge will lay a foundation for novel diagnostic and treatment strategies to reduce glaucoma vision loss.