Physiological changes throughout the ear due to age and noise - a longitudinal study

Abstract

AbstractBiological and mechanical systems, whether by their overuse or their aging, will inevitably fail. Hearing provides a poignant example of this with noise-induced and age-related hearing loss. Hearing loss is not unique to humans, however, and is experienced by all animals in the face of wild and eclectic differences in ear morphology and operation. Here we exploited the high throughput and accessible tympanal ear of the desert locust, Schistocerca gregaria (mixed sex) to rigorously quantify changes in the auditory system due to noise exposure (3 kHz pure tone at 126 dB SPL) and age. We analysed tympanal dispalcements, morphology of the auditory Müller’s organ and measured activity of the auditory nerve, the transduction current and electrophysiological properties of individual auditory receptors. We found that noise mildly and transiently changes tympanal displacements, decreases both the width of the auditory nerve and the transduction current recorded from individual auditory neurons. Whereas age – but not noise - decreases the number of auditory neurons and increases their resting potential. Multiple other properties of Müller’s organ were unaffected by either age or noise including: the number of supporting cells in Müller’s organ or the nerve, membrane resistance and capacitance of the auditory neurons. The sound-evoked activity of the auditory nerve decreased as a function of age and this decrease was exacerbated by noise, with the largest difference during the middle of their life span. This ‘middle-aged deafness’ pattern of hearing loss mirrors that found for humans exposed to noise early in their life.Key point summaryAge and noise lead to hearing loss.Tympanal displacements have a transient and delayed reduction after noise.The number of auditory neurons decreases with age. The width of the auditory nerve is reduced with noise exposure.Locusts repeatedly exposed to noise lost their hearing compared to silent controls, but their hearing became similar to old silent control locusts due to age-related hearing loss dominating.The electrophysiological properties of the auditory neurons and the transduction current remained unchanged for aged locusts but repeated noise exposure led to a cumulative decrease in the transduction current.