基于低速率阈值停用刺激部位可改善人工耳蜗使用者的频谱纹波和言语接受阈值。
Deactivating stimulation sites based on low-rate thresholds improves spectral ripple and speech reception thresholds in cochlear implant users.
作者信息
Zhou Ning
机构信息
Department of Communication Sciences and Disorders, East Carolina University, Greenville, North Carolina 27834, USA
出版信息
J Acoust Soc Am. 2017 Mar;141(3):EL243. doi: 10.1121/1.4977235.
Abstract
The study examined whether the benefit of deactivating stimulation sites estimated to have broad neural excitation was attributed to improved spectral resolution in cochlear implant users. The subjects' spatial neural excitation pattern was estimated by measuring low-rate detection thresholds across the array [see Zhou (2016). PLoS One 11, e0165476]. Spectral resolution, as assessed by spectral-ripple discrimination thresholds, significantly improved after deactivation of five high-threshold sites. The magnitude of improvement in spectral-ripple discrimination thresholds predicted the magnitude of improvement in speech reception thresholds after deactivation. Results suggested that a smaller number of relatively independent channels provide a better outcome than using all channels that might interact.
摘要
该研究考察了停用估计具有广泛神经兴奋作用的刺激部位所带来的益处,是否归因于人工耳蜗使用者频谱分辨率的提高。通过测量阵列上的低速率检测阈值来估计受试者的空间神经兴奋模式[见Zhou(2016年)。《公共科学图书馆·综合》11卷,e0165476]。通过频谱纹波辨别阈值评估的频谱分辨率,在停用五个高阈值部位后显著提高。频谱纹波辨别阈值的改善幅度预测了停用后言语接受阈值的改善幅度。结果表明,较少数量的相对独立通道比使用所有可能相互作用的通道能带来更好的效果。
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