Machine learning model for reproducing subjective sensations and alleviating sound-induced stress in individuals with developmental disorders.

IF 3.2 3区医学 Q2 PSYCHIATRY

Frontiers in Psychiatry Pub Date : 2025-03-14 eCollection Date: 2025-01-01 DOI:10.3389/fpsyt.2025.1412019

Itsuki Ichikawa, Yukie Nagai, Yasuo Kuniyoshi, Makoto Wada

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Abstract

Introduction: An everyday challenge frequently encountered by individuals with developmental disorders is auditory hypersensitivity, which causes distress in response to certain sounds and the overall sound environment. This study developed deep neural network (DNN) models to address this issue. One model predicts changes in subjective sound perception to quantify auditory hypersensitivity characteristics, while the other determines the modifications needed to sound stimuli to alleviate stress. These models are expected to serve as a foundation for personalized support systems for individuals with developmental disorders experiencing auditory hypersensitivity.

Methods: Experiments were conducted with participants diagnosed with autism spectrum disorder or attention deficit hyperactivity disorder who exhibited auditory hypersensitivity (the developmental disorders group, DD) and a control group without developmental disorders (the typically developing group, TD). Participants were asked to indicate either "how they perceived the sound in similar past situations" (Recollection task) or "how the sound should be modified to reduce stress" (Easing task) by applying various auditory filters to the input auditory stimulus. For both tasks, the DNN models were trained to predict the filter settings and subjective stress ratings based on the input stimulus, and the performance and accuracy of these predictions were evaluated.

Results: Three main findings were obtained. (a) Significant reductions in stress ratings were observed in the Easing task compared to the Recollection task. (b) The prediction models successfully estimated stress ratings, achieving a correlation coefficient of approximately 0.4 to 0.7 with the actual values. (c) Differences were observed in the performance of parameter predictions depending on whether data from the entire participant pool were used or whether data were analyzed separately for the DD and TD groups.

Discussion: These findings suggest that the prediction model for the Easing task can potentially be developed into a system that automatically reduces sound-induced stress through auditory filtering. Similarly, the model for the Recollection task could be used as a tool for assessing auditory stress. To establish a robust support system, further data collection, particularly from individuals with DD, is necessary.

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机器学习模型再现主观感觉和减轻声音诱发的个体发育障碍的压力。

患有发育障碍的个体经常遇到的日常挑战是听觉过敏症，这导致对某些声音和整体声音环境的反应痛苦。本研究开发了深度神经网络（DNN）模型来解决这个问题。一个模型预测主观声音感知的变化，以量化听觉超敏特征，而另一个模型确定声音刺激所需的修改，以减轻压力。这些模型有望为患有听觉超敏性发育障碍的个体提供个性化支持系统的基础。方法：将诊断为自闭症谱系障碍或注意缺陷多动障碍并表现出听觉超敏反应的参与者（发育障碍组，DD）和无发育障碍的对照组（典型发育组，TD）进行实验。参与者被要求通过对输入的听觉刺激施加不同的听觉过滤器来说明“他们在类似的过去情况下是如何感知声音的”（回忆任务）或“如何修改声音以减轻压力”（放松任务）。对于这两项任务，DNN模型都经过训练，以根据输入刺激预测过滤器设置和主观压力等级，并评估这些预测的性能和准确性。结果：主要有三点发现。(a)与回忆任务相比，在放松任务中观察到压力等级显著降低。(b)预测模型成功地估计了应力等级，与实际值的相关系数约为0.4至0.7。(c)根据是否使用来自整个参与者池的数据或是否分别分析DD和TD组的数据，在参数预测的表现方面观察到差异。讨论：这些发现表明，舒缓任务的预测模型可以发展成一个系统，通过听觉过滤自动减少声音引起的压力。同样，回忆任务的模型也可以作为评估听觉压力的工具。为了建立一个强有力的支持系统，需要进一步收集数据，特别是从DD患者那里收集数据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frontiers in Psychiatry Medicine-Psychiatry and Mental Health

CiteScore

6.20

自引率

8.50%

发文量

2813

审稿时长

14 weeks

期刊介绍： Frontiers in Psychiatry publishes rigorously peer-reviewed research across a wide spectrum of translational, basic and clinical research. Field Chief Editor Stefan Borgwardt at the University of Basel is supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide. The journal''s mission is to use translational approaches to improve therapeutic options for mental illness and consequently to improve patient treatment outcomes.