Abstract Age-related hearing loss (ARHL), also referred to as presbycusis, is a complex degenerative disease characterized by hearing impairment. The condition is a significant public health problem, affecting 40% of individuals aged between 55 and 74. ARHL is attributed to central and peripheral auditory system degeneration. Central ARHL refers to age-associated degeneration in the auditory portion of the central nervous system, which affects the ability to localize the temporal and spatial origins of sounds and impairs speech understanding in noisy environments. However, studies so far have not fully elucidated the cellular mechanisms underlying deficits to temporal precision of sound localization and speech understanding in aging. In Aim 1, we will determine the age-dependent structural and molecular remodeling of central auditory synapses. We hypothesize that aging alters key structural and molecular parameters at the central synapses. As a result, the endbulb and calyx of Held synapses exhibit decreased activity. Studies in Aim 2 will determine the age-dependent structural and molecular remodeling of central nerve axonal fibers. We hypothesize that age-related deficits in myelin and internode distance along the auditory nerve and calyx axonal fibers will decrease conduction velocity (CV) and degrade synaptic activity. In addition, another most notable change in ARHL is an increase in neuronal excitability. The degradation of input at the auditory neural axis periphery shifts the balance of excitation and inhibition throughout the auditory hierarchy, including the cochlear nucleus (CN), superior olivary complex (SOC), and auditory cortex (ACtx). It leads to altered neuronal excitability and auditory dysfunctions, including tinnitus and hyperacusis. Although altered neuronal excitability (“hypo-” or “hyper”-excitability) has been found in several brain stations in the ascending auditory hierarchy, its presence in descending systems is less understood. We hypothesize that the mechanism of altered age-related neuronal excitability in the ACtx stems from modified CN and SOC pre- and post-synaptic properties, as well as neuronal demyelination. In Aim 3, we will identify structural changes in pyramidal tract (PT) projection pathways in the aging brain. We hypothesize that aging incurs structural plasticity in PT projection neurons' downstream targets. Studies in Aim 4 will determine sensory processing deficits in PT projection pathways in the aging brain. We hypothesize that altered excitability in the aged auditory system systematically degrades the spectrotemporal processing of sound. The overall goal in this project (P3) is to understand the age-dependent structural and molecular remodeling of central auditory synapses and central nerve axonal fibers, as well as providing novel insights into how aging influences structural plasticity throughout the auditory system and how connectivity with downstream brain areas are altered in aging.