Salcher Rolf, Schwab Burkard, Lenarz Thomas, Maier Hannes
Dept. of Otolaryngology and Inst. of Audioneurotechnology (VIANNA), Medical University Hannover, Hannover, Germany.
Dept. of Otolaryngology and Inst. of Audioneurotechnology (VIANNA), Medical University Hannover, Hannover, Germany.
Hear Res. 2014 Aug;314:1-9. doi: 10.1016/j.heares.2014.04.001. Epub 2014 Apr 13.
Mechanical stimulation of the round window (RW) of the cochlea is successfully done with the Vibrant Soundbridge (Med-El), but clinical outcomes show a substantial degree of variability. One source of variability is variation in the static force applied by the stimulator to the round window (Maier et al., 2013). In this study we investigated other sources of variability by maintaining a constant pre-load testing the effect of a coupler device and the interposition of soft tissue between the stimulator and the RW.
Experimental.
The stapes footplate displacement produced by stimulation of the round window was determined in fresh human temporal bones. The response to sound and actuator stimulation was measured with a Laser Doppler Velocimeter at the stapes footplate. The RW was stimulated by a Floating Mass Transducer (FMT) with/without (1) an additional RW coupler (supplied by the manufacturer), and (2) the interposition of TUTOPATCH between the stimulator and the RW, while maintaining a pre-load of ∼1.96 mN.
In 8 temporal bones with normal stapes footplate response to sound, we found an average 11.9 dB increase (500 Hz-2 kHz) under controlled conditions by using the coupler together with the interposition. The increase was statistically significant at 500 Hz (p < 0.01). Additionally, the coupler/interposition combination reduced the variability between experiments (FMT alone SD = 10.9 dB; FMT with TUTOPATCH & coupler: SD = 3.4 dB @ 500 Hz) and increased the repeatability.
At controlled static force an improved output level, inter-subject variability and repeatability were found by using a coupler/TUTOPATCH combination in RW stimulation with the FMT. The high variability found in clinical experience is not solely due to inter-subject variability, but to coupling conditions and can be optimized further.
使用振动声桥(美敦力公司)已成功实现对耳蜗圆窗(RW)的机械刺激,但临床结果显示存在很大程度的变异性。变异性的一个来源是刺激器施加于圆窗的静态力的变化(迈尔等人,2013年)。在本研究中,我们通过保持恒定的预负荷,测试耦合器装置的作用以及刺激器与圆窗之间软组织的插入情况,来研究变异性的其他来源。
实验性研究。
在新鲜的人类颞骨中测定刺激圆窗所产生的镫骨足板位移。使用激光多普勒测速仪在镫骨足板处测量对声音和致动器刺激的反应。通过浮动质量传感器(FMT)在有/无(1)额外的圆窗耦合器(由制造商提供)以及(2)在刺激器与圆窗之间插入TUTOPATCH的情况下刺激圆窗,同时保持约1.96 mN的预负荷。
在8块对声音有正常镫骨足板反应的颞骨中,我们发现在受控条件下,使用耦合器并插入TUTOPATCH后,平均增加了11.9 dB(500 Hz - 2 kHz)。在500 Hz时增加具有统计学意义(p < 0.01)。此外,耦合器/插入物组合减少了实验之间的变异性(单独使用FMT时标准差 = 10.9 dB;使用TUTOPATCH和耦合器的FMT:在500 Hz时标准差 = 3.4 dB)并提高了可重复性。
在受控的静态力下,在使用FMT进行圆窗刺激时,通过使用耦合器/TUTOPATCH组合可提高输出水平、降低个体间变异性并提高可重复性。临床经验中发现的高变异性并非仅由于个体间变异性,还与耦合条件有关,并且可以进一步优化。
