["The Journal of Physiology, EarlyView. ", "\nAbstract figure legend Sounds of different frequencies elicit spatially distinct patterns of neural activity within the inferior colliculus aligned to the tonotopic organization of afferent projections. Sound‐evoked neural responses can be visualized in awake mice that express fluorescent Ca2+ sensors. We find that neural activity patterns produced in response to pure tones are not fixed but evolve during the stimulus, with discrete groups of neurons activated during onset (ON) and offset (tdOFF) periods. Sound‐evoked lateral inhibition appears to shape tdOFF responses, as tdOFF neurons were suppressed by sound and spatially clustered in sideband regions at sound offset. Loud noise‐induced hearing loss reshaped the spatiotemporal characteristics of sound processing, abolishing both sideband suppression and tdOFF responses, but preserving ON response patterns and amplitudes. This prioritization of ON responses helps preserve sound processing in hearing loss but may contribute to worsened acuity and related hearing disorders, such as hyperacusis and tinnitus.\n\n\n\n\nAbstract\nThe parsing of sensory information into discrete topographic domains is a fundamental principle of sensory processing. In the auditory cortex, these domains evolve during a stimulus, with the onset and offset of tones evoking distinct spatial patterns of neural activity. However, it is not known where in the auditory system this spatial segregation occurs or how these dynamics are affected by hearing loss. Using widefield single photon neuronal Ca2+ imaging in the inferior colliculus (IC) of awake mice, we found that pure tone stimuli elicited both spatially constrained neural activity within isofrequency bands and simultaneous sideband suppression. At cessation of the stimulus, offset responses emerged within the region of sideband suppression, demonstrating that simple stimuli elicit spatiotemporally distinct neural activity patterns to represent the presence of sound and sound termination. Because sound frequency is spatially encoded in the IC, this spatial shift creates a tonotopically distinct offset (tdOFF) response relative to sound onset. High‐resolution two‐photon Ca2+ imaging confirmed that tdOFF neuron activity in the sideband region was suppressed during sound and elevated above baseline after stimulus termination, raising the possibility that rebound excitation could contribute to this post‐stimulus activation. Loud noise exposure – a common model of hearing loss – abolished both sideband suppression and tdOFF responses. These results show that hearing loss profoundly reshapes the spatiotemporal pattern of sound processing by altering sideband activity. This preferential loss of sideband suppression and tdOFF activation after sound‐induced injury in the auditory midbrain may contribute to hyperacusis and tinnitus by promoting neuronal hyperactivity.\n\n\n\n\n\n\n\n\n\nKey points\n\nSensory systems encode different features of stimuli by activating distinct neural networks.\nSound onsets and offsets elicit distinct neural patterns in the auditory cortex, although it is unclear where this separation originates or how it may change with hearing loss.\nUsing in vivo widefield Ca2+ imaging in awake mice, we find that pure tone stimuli evoke spatiotemporally distinct on and off patterns of neural activity in the auditory midbrain.\nNeurons active during stimulus offset were suppressed by sound in sideband regions, raising the possibility that rebound excitation may contribute to this post‐stimulus activation.\nBoth sideband suppression and off responses were preferentially abolished following noise‐induced hearing loss, raising the possibility that these changes may contribute to hearing loss‐related syndromes such as tinnitus and hyperacusis.\n\n\n"]