Lee Choongheon, Shokrian Mohammad, Henry Kenneth S, Carney Laurel H, Holt Joseph C, Nam Jong-Hoon
Department of Otolaryngology, University of Rochester, Rochester, NY, United States.
Department of Mechanical Engineering, University of Rochester, Rochester, NY, United States.
bioRxiv. 2024 Nov 12:2024.08.07.607009. doi: 10.1101/2024.08.07.607009.
We hypothesized that active outer hair cells drive cochlear fluid circulation. The hypothesis was tested by delivering the neurotoxin, kainic acid, to the intact round window of young gerbil cochleae while monitoring auditory responses in the cochlear nucleus. Sounds presented at a modest level significantly expedited kainic acid delivery. When outer-hair-cell motility was suppressed by salicylate, the facilitation effect was compromised. A low-frequency tone was more effective than broadband noise, especially for drug delivery to apical locations. Computational model simulations provided the physical basis for our observation, which incorporated solute diffusion, fluid advection, fluid-structure interaction, and outer-hair-cell motility. Active outer hair cells deformed the organ of Corti like a peristaltic tube to generate apically streaming flows along the tunnel of Corti and basally streaming flows along the scala tympani. Our measurements and simulations coherently suggest that active outer hair cells in the tail region of cochlear traveling waves drive cochlear fluid circulation.
我们推测,活跃的外毛细胞驱动耳蜗内的液体循环。通过将神经毒素 kainic 酸注入年轻沙鼠耳蜗完整的圆窗,同时监测耳蜗核中的听觉反应来验证这一假设。适度强度的声音显著加速了 kainic 酸的注入。当水杨酸盐抑制外毛细胞的运动时,这种促进作用就会受到影响。低频音调比宽带噪声更有效,特别是对于将药物输送到顶端位置。计算模型模拟为我们的观察提供了物理基础,该模型纳入了溶质扩散、流体平流、流固相互作用和外毛细胞运动。活跃的外毛细胞使柯蒂氏器像蠕动管一样变形,从而在柯蒂氏管中产生向顶端的流动,并在鼓阶中产生向基部的流动。我们的测量和模拟一致表明,耳蜗行波尾部区域的活跃外毛细胞驱动耳蜗内的液体循环。
