Abstract: Sensory hair cells transmit auditory and vestibular information to the brain. While many forms of hearing loss result from hair cell death, increasing evidence shows that noise-induced and age-related hearing loss often stem from synaptic damage. Restoring hearing in these cases will require rebuilding synaptic connections, which depends on understanding how sensory synapses form and function in vivo. Our work combines genetics, CRISPR-based mutagenesis, and live imaging in zebrafish neuromast hair cells to define themolecular and activity-dependent mechanisms that drive synapse formation, function, and regeneration. By visualizing synapses in a live, transparent system, we aim to uncover principles that guide the restoration of hair cells and their synaptic connections after damage.