Boys Town National Research Hospital, Department of Research, Omaha, Nebraska, USA.
The University of Texas at Austin, Department of Communication Sciences and Disorders, Austin, Texas, USA.
Ear Hear. 2020 Sep/Oct;41(5):1111-1124. doi: 10.1097/AUD.0000000000000831.
The objective of this study was to determine if absent air conduction stimuli vestibular evoked myogenic potential (VEMP) responses found in ears after cochlear implantation can be the result of alterations in peripheral auditory mechanics rather than vestibular loss. Peripheral mechanical changes were investigated by comparing the response rates of air and bone conduction VEMPs as well as by measuring and evaluating wideband acoustic immittance (WAI) responses in ears with cochlear implants and normal-hearing control ears. The hypothesis was that the presence of a cochlear implant can lead to an air-bone gap, causing absent air conduction stimuli VEMP responses, but present bone conduction vibration VEMP responses (indicating normal vestibular function), with changes in WAI as compared with ears with normal hearing. Further hypotheses were that subsets of ears with cochlear implants would (a) have present VEMP responses to both stimuli, indicating normal vestibular function and either normal or near-normal WAI, or (b) have absent VEMP responses to both stimuli, regardless of WAI, due to true vestibular loss.
Twenty-seven ears with cochlear implants (age range 7 to 31) and 10 ears with normal hearing (age range 7 to 31) were included in the study. All ears completed otoscopy, audiometric testing, 226 Hz tympanometry, WAI measures (absorbance), air conduction stimuli cervical and ocular VEMP testing through insert earphones, and bone conduction vibration cervical and ocular VEMP testing with a mini-shaker. Comparisons of VEMP responses to air and bone conduction stimuli, as well as absorbance responses between ears with normal hearing and ears with cochlear implants, were completed.
All ears with normal hearing demonstrated 100% present VEMP response rates for both stimuli. Ears with cochlear implants had higher response rates to bone conduction vibration compared with air conduction stimuli for both cervical and ocular VEMPs; however, this was only significant for ocular VEMPs. Ears with cochlear implants demonstrated reduced low-frequency absorbance (500 to 1200 Hz) as compared with ears with normal hearing. To further analyze absorbance, ears with cochlear implants were placed into subgroups based on their cervical and ocular VEMP response patterns. These groups were (1) present air conduction stimuli response, present bone conduction vibration response, (2) absent air conduction stimuli response, present bone conduction vibration response, and (3) absent air conduction stimuli response, absent bone conduction vibration response. For both cervical and ocular VEMPs, the group with absent air conduction stimuli responses and present bone conduction vibration responses demonstrated the largest decrease in low-frequency absorbance as compared with the ears with normal hearing.
Bone conduction VEMP response rates were increased compared with air-conduction VEMP response rates in ears with cochlear implants. Ears with cochlear implants also demonstrate changes in low-frequency absorbance consistent with a stiffer system. This effect was largest for ears that had absent air conduction but present bone conduction VEMPs. These findings suggest that this group, in particular, has a mechanical change that could lead to an air-bone gap, thus, abolishing the air conduction VEMP response due to an alteration in mechanics and not a true vestibular loss. Clinical considerations include using bone conduction vibration VEMPs and WAI for preoperative and postoperative testing in patients undergoing cochlear implantation.
本研究旨在确定在植入人工耳蜗后发现的无气导刺激前庭诱发肌源性电位(VEMP)反应是否可能是外周听觉力学改变而不是前庭丧失的结果。通过比较气导和骨导 VEMP 的反应率以及测量和评估植入人工耳蜗和正常听力对照耳的宽带声导抗(WAI)反应,研究了外周机械变化。假设是人工耳蜗的存在会导致气骨间隙,导致无气导刺激 VEMP 反应,但存在骨导振动 VEMP 反应(表明正常前庭功能),与正常听力相比,WAI 会发生变化。进一步的假设是,一部分植入人工耳蜗的耳朵会出现:(a)两种刺激的 VEMP 反应均存在,表明正常前庭功能和正常或接近正常的 WAI,或(b)两种刺激的 VEMP 反应均缺失,无论 WAI 如何,均归因于真正的前庭丧失。
本研究纳入了 27 只植入人工耳蜗的耳朵(年龄范围 7 至 31 岁)和 10 只正常听力的耳朵(年龄范围 7 至 31 岁)。所有耳朵均进行了耳镜检查、听力测试、226Hz 鼓室图、WAI 测量(吸光度)、通过插入式耳机进行气导刺激颈和眼 VEMP 测试,以及使用微型振动器进行骨导振动颈和眼 VEMP 测试。比较了正常听力和植入人工耳蜗的耳朵对气导和骨导刺激的 VEMP 反应,以及吸光度反应。
所有正常听力的耳朵对两种刺激的 VEMP 反应率均为 100%。植入人工耳蜗的耳朵对颈和眼 VEMP 的骨导振动刺激的反应率高于气导刺激;然而,这仅对眼 VEMP 有显著影响。与正常听力的耳朵相比,植入人工耳蜗的耳朵低频吸光度(500 至 1200Hz)降低。为了进一步分析吸光度,根据颈和眼 VEMP 反应模式将植入人工耳蜗的耳朵分为亚组。这些组为:(1)气导刺激反应存在,骨导振动刺激反应存在;(2)气导刺激反应缺失,骨导振动刺激反应存在;(3)气导刺激反应缺失,骨导振动刺激反应缺失。对于颈和眼 VEMP,与正常听力相比,气导刺激反应缺失而骨导振动刺激反应存在的组的低频吸光度下降最大。
与气导 VEMP 反应率相比,植入人工耳蜗的耳朵的骨导 VEMP 反应率增加。植入人工耳蜗的耳朵也表现出低频吸光度的变化,这与系统的僵硬有关。在气导刺激但存在骨导振动 VEMP 的耳朵中,这种影响最大。这些发现表明,特别是这些组的耳朵存在机械变化,可能导致气骨间隙,从而由于力学改变而消除气导 VEMP 反应,而不是真正的前庭丧失。临床考虑包括在接受人工耳蜗植入的患者中进行术前和术后使用骨导振动 VEMP 和 WAI 进行测试。
