A computational model to simulate spectral modulation and speech perception experiments of cochlear implant users.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-03-09 eCollection Date: 2023-01-01 DOI:10.3389/fninf.2023.934472
Franklin Alvarez, Daniel Kipping, Waldo Nogueira
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Abstract

Speech understanding in cochlear implant (CI) users presents large intersubject variability that may be related to different aspects of the peripheral auditory system, such as the electrode-nerve interface and neural health conditions. This variability makes it more challenging to proof differences in performance between different CI sound coding strategies in regular clinical studies, nevertheless, computational models can be helpful to assess the speech performance of CI users in an environment where all these physiological aspects can be controlled. In this study, differences in performance between three variants of the HiRes Fidelity 120 (F120) sound coding strategy are studied with a computational model. The computational model consists of (i) a processing stage with the sound coding strategy, (ii) a three-dimensional electrode-nerve interface that accounts for auditory nerve fiber (ANF) degeneration, (iii) a population of phenomenological ANF models, and (iv) a feature extractor algorithm to obtain the internal representation (IR) of the neural activity. As the back-end, the simulation framework for auditory discrimination experiments (FADE) was chosen. Two experiments relevant to speech understanding were performed: one related to spectral modulation threshold (SMT), and the other one related to speech reception threshold (SRT). These experiments included three different neural health conditions (healthy ANFs, and moderate and severe ANF degeneration). The F120 was configured to use sequential stimulation (F120-S), and simultaneous stimulation with two (F120-P) and three (F120-T) simultaneously active channels. Simultaneous stimulation causes electric interaction that smears the spectrotemporal information transmitted to the ANFs, and it has been hypothesized to lead to even worse information transmission in poor neural health conditions. In general, worse neural health conditions led to worse predicted performance; nevertheless, the detriment was small compared to clinical data. Results in SRT experiments indicated that performance with simultaneous stimulation, especially F120-T, were more affected by neural degeneration than with sequential stimulation. Results in SMT experiments showed no significant difference in performance. Although the proposed model in its current state is able to perform SMT and SRT experiments, it is not reliable to predict real CI users' performance yet. Nevertheless, improvements related to the ANF model, feature extraction, and predictor algorithm are discussed.

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模拟人工耳蜗用户频谱调制和语音感知实验的计算模型。
人工耳蜗 (CI) 用户的语音理解能力存在很大的受试者间差异,这可能与外周听觉系统的不同方面有关,如电极-神经接口和神经健康状况。这种变异性使得在常规临床研究中证明不同 CI 声音编码策略之间的性能差异更具挑战性,然而,在所有这些生理方面都可以控制的环境中,计算模型有助于评估 CI 用户的语音性能。本研究利用计算模型研究了高保真 120(F120)声音编码策略的三种变体之间的性能差异。计算模型包括:(i) 采用声音编码策略的处理阶段;(ii) 考虑到听觉神经纤维(ANF)退化的三维电极-神经接口;(iii) 一组现象学 ANF 模型;(iv) 用于获取神经活动内部表征(IR)的特征提取算法。作为后端,选择了听觉辨别实验模拟框架(FADE)。进行了两项与语音理解相关的实验:一项与频谱调制阈值(SMT)相关,另一项与语音接收阈值(SRT)相关。这些实验包括三种不同的神经健康状况(健康 ANF、中度和重度 ANF 退化)。F120 被配置为使用顺序刺激(F120-S),以及使用两个(F120-P)和三个(F120-T)同时激活的通道进行同步刺激。同时刺激会导致电相互作用,从而使传输到 ANF 的频谱时相信息模糊不清,据推测,在神经健康状况较差的情况下,这种情况会导致信息传输更加糟糕。一般来说,神经健康状况较差会导致预测性能较差;不过,与临床数据相比,这种不利影响很小。SRT 实验结果表明,同时刺激(尤其是 F120-T)比顺序刺激更容易受到神经退化的影响。SMT 实验结果表明,两者的性能没有明显差异。虽然目前提出的模型能够进行 SMT 和 SRT 实验,但还不能可靠地预测真实 CI 用户的表现。尽管如此,我们还是讨论了与 ANF 模型、特征提取和预测算法相关的改进措施。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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