PURPOSE OF THE REVIEW: This article presents research findings from two invertebrate model systems with potential to advance both the understanding of noise-induced hearing loss mechanisms and the development of putative therapies to reduce human noise damage. RECENT FINDINGS: Work on sea anemone hair bundles, which resemble auditory hair cells, has revealed secretions that exhibit astonishing healing properties not only for damaged hair bundles, but also for vertebrate lateral line neuromasts. We present progress on identifying functional components of the secretions, and their mechanisms of repair. The second model, the Johnston's organ in Drosophila, is also genetically homologous to hair cells and shows noise-induced hearing loss similar to vertebrates. Drosophila offers genetic and molecular insight into noise sensitivity and pathways that can be manipulated to reduce stress and damage from noise. SUMMARY: Using the comparative approach is a productive avenue to understanding basic mechanisms, in this case cellular responses to noise trauma. Expanding study of these systems may accelerate identification of strategies to reduce or prevent noise damage in the human ear.
PURPOSE OF THE REVIEW: This article presents research findings from two invertebrate model systems with potential to advance both the understanding of noise-induced hearing loss mechanisms and the development of putative therapies to reduce human noise damage. RECENT FINDINGS: Work on sea anemone hair bundles, which resemble auditory hair cells, has revealed secretions that exhibit astonishing healing properties not only for damaged hair bundles, but also for vertebrate lateral line neuromasts. We present progress on identifying functional components of the secretions, and their mechanisms of repair. The second model, the Johnston's organ in Drosophila, is also genetically homologous to hair cells and shows noise-induced hearing loss similar to vertebrates. Drosophila offers genetic and molecular insight into noise sensitivity and pathways that can be manipulated to reduce stress and damage from noise. SUMMARY: Using the comparative approach is a productive avenue to understanding basic mechanisms, in this case cellular responses to noise trauma. Expanding study of these systems may accelerate identification of strategies to reduce or prevent noise damage in the human ear.
Authors: Yan Yu; Bing Hu; Jianxin Bao; Jessica Mulvany; Eric Bielefeld; Ryan T Harrison; Sarah A Neton; Partha Thirumala; Yingying Chen; Debin Lei; Ziyu Qiu; Qingyin Zheng; Jihao Ren; Maria Cristina Perez-Flores; Ebenezer N Yamoah; Pezhman Salehi Journal: J Assoc Res Otolaryngol Date: 2018-09-05
Authors: Ben Warren; Georgina E Fenton; Elizabeth Klenschi; James F C Windmill; Andrew S French Journal: J Neurosci Date: 2020-03-06 Impact factor: 6.167