Perineuronal nets (PNNs) are a matrix of proteins that surround nerve cells and reinforce the most often used synaptic connections between neurons, essentially hard-wiring neural connections made as a child into permanent pathways that respond to specific stimuli. By dissolving these PNNs, we recreate the plasticity characteristic of a young developing brain, granting us the ability to rewire the brain with respect to any stimulus. In this study, we are looking at PNNs within the vestibular system – the sensory system that, under natural conditions, is primarily responsible for maintaining images on the fovea during movement. Hair cells within the semicircular canals of the vestibular system register head accelerations and then send reflex signals through vestibular afferent nerve endings to extra-ocular eye muscles that drive eye movements. This vestibular ocular reflex aids the maintenance of stability of images on the retina. As a therapy for vestibular loss, our lab has developed a vestibular prosthesis that electrically stimulates the afferent nerve endings of the vestibular system, thereby simulating natural vestibular response to movement. This electrical stimulation, however, spreads to untargeted as well as targeted vestibular afferents and cause inaccurate eye movements as a result. By dissolving the PNNs in the vestibular nuclei and then allowing them to regrow during a period of adaptation, we hope to suppress inappropriate eye movements in response to our prosthesis’ electrical stimulation. If our lab can prove that electrically elicited eye-movements become more accurate after the dissolving and guided re-growing of PNNs, we can show that it is possible to restore plasticity to the brain and shape its neural connections through controlled electrical stimulation to the target system. By extension, such results will ascertain if it is possible to use this method to re-wire a physiological system to accept prosthetic stimulation in place of a non-functioning system.