Department of Otolaryngology/Head and Neck Surgery, Oregon Hearing Research Center, Oregon Health and Science University, Portland, Oregon, United States of America.
PLoS One. 2011 Apr 28;6(4):e19130. doi: 10.1371/journal.pone.0019130.
Exposure to intense sound or high doses of aminoglycoside antibiotics can increase hearing thresholds, induce cochlear dysfunction, disrupt hair cell morphology and promote hair cell death, leading to permanent hearing loss. When the two insults are combined, synergistic ototoxicity occurs, exacerbating cochlear vulnerability to sound exposure. The underlying mechanism of this synergism remains unknown. In this study, we tested the hypothesis that sound exposure enhances the intra-cochlear trafficking of aminoglycosides, such as gentamicin, leading to increased hair cell uptake of aminoglycosides and subsequent ototoxicity.
Juvenile C57Bl/6 mice were exposed to moderate or intense sound levels, while fluorescently-conjugated or native gentamicin was administered concurrently or following sound exposure. Drug uptake was then examined in cochlear tissues by confocal microscopy.
Prolonged sound exposure that induced temporary threshold shifts increased gentamicin uptake by cochlear hair cells, and increased gentamicin permeation across the strial blood-labyrinth barrier. Enhanced intra-cochlear trafficking and hair cell uptake of gentamicin also occurred when prolonged sound, and subsequent aminoglycoside exposure were temporally separated, confirming previous observations. Acute, concurrent sound exposure did not increase cochlear uptake of aminoglycosides.
Prolonged, moderate sound exposures enhanced intra-cochlear aminoglycoside trafficking into the stria vascularis and hair cells. Changes in strial and/or hair cell physiology and integrity due to acoustic overstimulation could increase hair cell uptake of gentamicin, and may represent one mechanism of synergistic ototoxicity.
暴露于高强度声音或高剂量氨基糖苷类抗生素会增加听力阈值,导致耳蜗功能障碍、破坏毛细胞形态并促进毛细胞死亡,从而导致永久性听力损失。当这两种刺激同时存在时,会产生协同性耳毒性,加剧耳蜗对声音暴露的敏感性。这种协同作用的潜在机制尚不清楚。在这项研究中,我们检验了以下假设,即声音暴露会增强氨基糖苷类药物(如庆大霉素)在耳蜗内的转运,导致毛细胞摄取更多的氨基糖苷类药物,从而引发耳毒性。
幼年 C57Bl/6 小鼠暴露于中等或高强度声音水平下,同时给予荧光标记或未标记的庆大霉素,或在声音暴露后给予。然后通过共聚焦显微镜检查耳蜗组织中的药物摄取情况。
导致暂时性听阈移位的长时间声音暴露增加了耳蜗毛细胞对庆大霉素的摄取,并增加了庆大霉素穿过螺旋血迷路屏障的通透性。当长时间声音暴露和随后的氨基糖苷类暴露在时间上分离时,也会发生增强的庆大霉素在耳蜗内的转运和毛细胞摄取,证实了之前的观察结果。急性、同时的声音暴露不会增加氨基糖苷类在耳蜗中的摄取。
长时间、中等强度的声音暴露增强了氨基糖苷类在螺旋血管纹和毛细胞内的转运。由于声过载引起的耳蜗血管纹和/或毛细胞生理学和完整性的改变可能会增加毛细胞对庆大霉素的摄取,这可能是协同性耳毒性的一种机制。
