Cochlear synaptic vulnerability scales with pathological noise intensity in a noise-induced hearing loss model

Background: Noise-induced hearing loss (NIHL) has been traditionally attributed to outer hair cell (OHC) damage, but synaptic injury at inner hair cell (IHC)–spiral ganglion neuron (SGN) junctions may better explain persistent functional deficits. Objective: To test whether IHC ribbon loss and functional synapse loss scale with pathological noise intensity and to define their longitudinal relationship to hearing function. Methods: A rodent NIHL model was exposed to 100 dB SPL for 2 h or 110 dB SPL for 4 h. Cochleae were immunolabeled for CtBP2 (presynaptic ribbons) and GluA2 (postsynaptic AMPA receptor puncta). Putative functional synapses were quantified as closely apposed CtBP2/GluA2 pairs. Hearing function was assessed longitudinally and correlated with synaptic measures. Results: Both exposure conditions produced graded reductions in IHC ribbon counts and CtBP2/GluA2 pairs, with greater losses after 110 dB/4 h. The number of CtBP2/GluA2 apposed pairs closely tracked preserved hearing function, providing a stronger association with functional outcome than ribbon counts alone. Ribbon loss remained largely stable across post-exposure intervals, whereas functional synapse loss was disproportionately larger at early time points, consistent with transient pre–post misalignment. Over time, CtBP2/GluA2 pairing partially recovered toward levels predicted by surviving ribbons, suggesting re-alignment or reconnection of a subset of remaining synaptic elements. Conclusion: Pathological noise intensity drives exposure-dependent IHC synaptopathy in addition to OHC injury. Functional synapse counts (CtBP2/GluA2 pairs) sensitively reflect stored hearing function and indicate a potential post-exposure window for synaptic re-establishment.