Ikeda Ryoukichi, Hamanishi Shinji, Kikuchi Toshiaki, Oshima Hidetoshi, Kawamura Yoshinobu, Kusano Yusuke, Kawase Tetsuaki, Katori Yukio, Wada Hiroshi, Kobayashi Toshimitsu
Sen-En Rifu Otological Surgery Center, Miyagi, Japan; Department of Otolaryngology-Head and Neck Surgery, Tohoku University School of Medicine, 1-1 Seiryo-machi, Aoba-ku, Sendai 980-8574, Japan.
Department of Mechanical Engineering and Intelligent Systems, Tohoku Gakuin University, Sendai, Japan.
Auris Nasus Larynx. 2021 Aug;48(4):738-744. doi: 10.1016/j.anl.2020.12.001. Epub 2020 Dec 29.
A system enabling the objective assessment of the transmission of voice sounds to the external auditory canal (EAC) during phonation has recently been revised. Our aim was to evaluate the effectiveness of this new system in the diagnosis of patulous Eustachian tube (PET) patients by comparing the results obtained using this method with those obtained from conventional objective tests to diagnose PET.
A prospective survey of medical records was included with definite PET, possible PET, and sensorineural hearing loss as control. The measurement system consists of a personal computer, an AD/DA converter (NI 6361, National Instruments), a probe microphone system for recording voice sound (ER-10C, Etymotic Research) and two microphones for measuring noise sound in the EAC (ER-10B+, Etymotic Research). Pronouncing the "Ni" sound for 5 s were recorded with these three microphones. The ratio of the maximum sound pressure of voice sound and noise sound in EAC (EAC/Voice) was simultaneously calculated, and results were displayed on a personal computer for diagnosing.
Thirty-one patients of 42 ears with definite PET, 26 patients of 38 ears with possible PET, and 12 patients of 24 ears with sensorineural hearing loss as control were included. The EAC/Voice were 8.63 ± 5.43, 25.41 ± 32.63, and 25.87 ± 24.93 in the control, definite PET, and possible PET group respectively. The control group was significantly different from the definite PET (p < 0.05) and possible PET group (p < 0.05). ROC curve analysis confirmed 14.7 as the best diagnostic cut-off value of EAC/Voice (area under the curve=0.782, 95% CI 0.671-0.894). By adopting this cut-off point, 25 (56.8%) and 22 (61.1%) ears were determined as positive findings in the definite PET and possible PET group, respectively. There was no significant correlation between the positive findings judged by the current method and that of sonotubometry in the control (r = -0.63, p = 0.769), definite PET (r = 0.12, p = 0.451), and possible PET group (r = 0.12, p = 0.451).
The current system is more useful in the objective assessment of autophony during phonation by calculating the ratio of voice sound and elicited noise sound transmitted in the EAC (EAC/Voice). This method seems promising because it is able to detect cases eluding conventionally used test methods such as sonotubometry performed without phonation, thereby increasing the accuracy of PET diagnoses.
最近对一种能够客观评估发声时声音传入外耳道(EAC)情况的系统进行了修订。我们的目的是通过比较使用该方法获得的结果与传统客观测试诊断咽鼓管异常开放(PET)患者所获得的结果,来评估这个新系统在PET诊断中的有效性。
对确诊为PET、可能为PET以及作为对照的感音神经性听力损失患者的病历进行前瞻性调查。测量系统由一台个人计算机、一个AD/DA转换器(NI 6361,美国国家仪器公司)、一个用于记录声音的探头麦克风系统(ER-10C,伊顿研究公司)以及两个用于测量外耳道噪声的麦克风(ER-10B+,伊顿研究公司)组成。用这三个麦克风记录发“尼”音5秒的声音。同时计算外耳道中声音和噪声的最大声压之比(EAC/Voice),并将结果显示在个人计算机上用于诊断。
纳入了42耳确诊为PET的31例患者、38耳可能为PET的26例患者以及作为对照的24耳感音神经性听力损失的12例患者。对照组、确诊PET组和可能PET组的EAC/Voice分别为8.63±5.43、25.41±32.63和25.87±24.93。对照组与确诊PET组(p<0.05)和可能PET组(p<0.05)有显著差异。ROC曲线分析确定EAC/Voice的最佳诊断临界值为14.7(曲线下面积=0.782,95%CI 0.671 - 0.894)。采用这个临界值,确诊PET组和可能PET组分别有25耳(56.8%)和22耳(61.1%)被判定为阳性结果。当前方法判定的阳性结果与对照组(r = -0.63,p = 0.769)、确诊PET组(r = 0.12,p = 0.451)和可能PET组(r = 0.12,p = 0.451)的声导抗测听结果之间均无显著相关性。
当前系统通过计算传入外耳道的声音与诱发噪声之比(EAC/Voice),在客观评估发声时的自听过响方面更有用。这种方法似乎很有前景,因为它能够检测出常规测试方法(如无声发声时的声导抗测听)遗漏的病例,从而提高PET诊断的准确性。
