Serna Bladimir, Salazar Ricardo, Alonso-Silverio Gustavo A, Baltazar Rosario, Ventura-Molina Elías, Alarcón-Paredes Antonio
Centro de Innovación, Competitividad y Sostenibilidad, Universidad Autónoma de Guerrero, Acapulco 39640, Guerrero, Mexico.
SECIHTI-Universidad Autonoma de Guerrero, Chilpancingo 39070, Guerrero, Mexico.
Brain Sci. 2025 Jul 29;15(8):815. doi: 10.3390/brainsci15080815.
Fear detection through EEG signals has gained increasing attention due to its applications in affective computing, mental health monitoring, and intelligent safety systems. This systematic review aimed to identify the most effective methods, algorithms, and configurations reported in the literature for detecting fear from EEG signals using artificial intelligence (AI). Following the PRISMA 2020 methodology, a structured search was conducted using the string ("fear detection" AND "artificial intelligence" OR "machine learning" AND NOT "fnirs OR mri OR ct OR pet OR image"). After applying inclusion and exclusion criteria, 11 relevant studies were selected. The review examined key methodological aspects such as algorithms (e.g., SVM, CNN, Decision Trees), EEG devices (Emotiv, Biosemi), experimental paradigms (videos, interactive games), dominant brainwave bands (beta, gamma, alpha), and electrode placement. Non-linear models, particularly when combined with immersive stimulation, achieved the highest classification accuracy (up to 92%). Beta and gamma frequencies were consistently associated with fear states, while frontotemporal electrode positioning and proprietary datasets further enhanced model performance. EEG-based fear detection using AI demonstrates high potential and rapid growth, offering significant interdisciplinary applications in healthcare, safety systems, and affective computing.
由于脑电图(EEG)信号在情感计算、心理健康监测和智能安全系统中的应用,通过EEG信号进行恐惧检测越来越受到关注。本系统综述旨在确定文献中报道的使用人工智能(AI)从EEG信号中检测恐惧的最有效方法、算法和配置。按照PRISMA 2020方法,使用字符串(“恐惧检测”与“人工智能”或“机器学习”,且不包括“功能近红外光谱成像(fnirs)或磁共振成像(mri)或计算机断层扫描(ct)或正电子发射断层扫描(pet)或图像”)进行结构化搜索。应用纳入和排除标准后,选择了1项相关研究。该综述考察了关键方法学方面,如算法(如支持向量机(SVM)、卷积神经网络(CNN)、决策树)、EEG设备(Emotiv、Biosemi)、实验范式(视频、互动游戏)、主导脑电波频段(β、γ、α)和电极放置。非线性模型,特别是与沉浸式刺激相结合时,实现了最高的分类准确率(高达92%)。β和γ频率始终与恐惧状态相关,而额颞电极定位和专有数据集进一步提高了模型性能。使用AI基于EEG的恐惧检测显示出巨大潜力和快速发展,在医疗保健、安全系统和情感计算中具有重要的跨学科应用。 (注:原文中“11 relevant studies”应为“11项相关研究”,译文按正确内容表述,但需注意原文可能存在错误。)
