{"title":"利用具有时空约束条件的正则优化技术进行脑电图动态源成像。","authors":"Mayadeh Kouti, Karim Ansari-Asl, Ehsan Namjoo","doi":"10.1007/s11517-024-03125-9","DOIUrl":null,"url":null,"abstract":"<p><p>One of the most important needs in neuroimaging is brain dynamic source imaging with high spatial and temporal resolution. EEG source imaging estimates the underlying sources from EEG recordings, which provides enhanced spatial resolution with intrinsically high temporal resolution. To ensure identifiability in the underdetermined source reconstruction problem, constraints on EEG sources are essential. This paper introduces a novel method for estimating source activities based on spatio-temporal constraints and a dynamic source imaging algorithm. The method enhances time resolution by incorporating temporal evolution of neural activity into a regularization function. Additionally, two spatial regularization constraints based on <math><msub><mi>L</mi> <mn>1</mn></msub> </math> and <math><msub><mi>L</mi> <mn>2</mn></msub> </math> norms are applied in the transformed domain to address both focal and spread neural activities, achieved through spatial gradient and Laplacian transform. Performance evaluation, conducted quantitatively using synthetic datasets, discusses the influence of parameters such as source extent, number of sources, correlation level, and SNR level on temporal and spatial metrics. Results demonstrate that the proposed method provides superior spatial and temporal reconstructions compared to state-of-the-art inverse solutions including STRAPS, sLORETA, SBL, dSPM, and MxNE. This improvement is attributed to the simultaneous integration of transformed spatial and temporal constraints. When applied to a real auditory ERP dataset, our algorithm accurately reconstructs brain source time series and locations, effectively identifying the origins of auditory evoked potentials. In conclusion, our proposed method with spatio-temporal constraints outperforms the state-of-the-art algorithms in estimating source distribution and time courses.</p>","PeriodicalId":49840,"journal":{"name":"Medical & Biological Engineering & Computing","volume":null,"pages":null},"PeriodicalIF":2.6000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"EEG dynamic source imaging using a regularized optimization with spatio-temporal constraints.\",\"authors\":\"Mayadeh Kouti, Karim Ansari-Asl, Ehsan Namjoo\",\"doi\":\"10.1007/s11517-024-03125-9\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>One of the most important needs in neuroimaging is brain dynamic source imaging with high spatial and temporal resolution. 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Performance evaluation, conducted quantitatively using synthetic datasets, discusses the influence of parameters such as source extent, number of sources, correlation level, and SNR level on temporal and spatial metrics. Results demonstrate that the proposed method provides superior spatial and temporal reconstructions compared to state-of-the-art inverse solutions including STRAPS, sLORETA, SBL, dSPM, and MxNE. This improvement is attributed to the simultaneous integration of transformed spatial and temporal constraints. When applied to a real auditory ERP dataset, our algorithm accurately reconstructs brain source time series and locations, effectively identifying the origins of auditory evoked potentials. 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引用次数: 0
摘要
神经成像最重要的需求之一是具有高空间和时间分辨率的大脑动态源成像。脑电信号源成像可从脑电图记录中估算出潜在的信号源,从而提供更高的空间分辨率和内在的高时间分辨率。为确保欠定源重建问题的可识别性,对脑电图源的约束至关重要。本文介绍了一种基于时空约束和动态声源成像算法来估计声源活动的新方法。该方法将神经活动的时间演变纳入正则化函数,从而提高了时间分辨率。此外,通过空间梯度和拉普拉斯变换,在变换域中应用了基于 L 1 和 L 2 规范的两个空间正则化约束,以解决焦点和扩散神经活动的问题。使用合成数据集对性能进行了定量评估,讨论了源范围、源数量、相关性水平和信噪比水平等参数对时间和空间指标的影响。结果表明,与 STRAPS、sLORETA、SBL、dSPM 和 MxNE 等最先进的逆解法相比,所提出的方法能提供更优越的空间和时间重建。这种改进归功于同时整合了转换的空间和时间约束。当应用于真实的听觉 ERP 数据集时,我们的算法准确地重建了脑源时间序列和位置,有效地识别了听觉诱发电位的起源。总之,我们提出的具有时空约束的方法在估计脑源分布和时间序列方面优于最先进的算法。
EEG dynamic source imaging using a regularized optimization with spatio-temporal constraints.
One of the most important needs in neuroimaging is brain dynamic source imaging with high spatial and temporal resolution. EEG source imaging estimates the underlying sources from EEG recordings, which provides enhanced spatial resolution with intrinsically high temporal resolution. To ensure identifiability in the underdetermined source reconstruction problem, constraints on EEG sources are essential. This paper introduces a novel method for estimating source activities based on spatio-temporal constraints and a dynamic source imaging algorithm. The method enhances time resolution by incorporating temporal evolution of neural activity into a regularization function. Additionally, two spatial regularization constraints based on and norms are applied in the transformed domain to address both focal and spread neural activities, achieved through spatial gradient and Laplacian transform. Performance evaluation, conducted quantitatively using synthetic datasets, discusses the influence of parameters such as source extent, number of sources, correlation level, and SNR level on temporal and spatial metrics. Results demonstrate that the proposed method provides superior spatial and temporal reconstructions compared to state-of-the-art inverse solutions including STRAPS, sLORETA, SBL, dSPM, and MxNE. This improvement is attributed to the simultaneous integration of transformed spatial and temporal constraints. When applied to a real auditory ERP dataset, our algorithm accurately reconstructs brain source time series and locations, effectively identifying the origins of auditory evoked potentials. In conclusion, our proposed method with spatio-temporal constraints outperforms the state-of-the-art algorithms in estimating source distribution and time courses.
期刊介绍:
Founded in 1963, Medical & Biological Engineering & Computing (MBEC) continues to serve the biomedical engineering community, covering the entire spectrum of biomedical and clinical engineering. The journal presents exciting and vital experimental and theoretical developments in biomedical science and technology, and reports on advances in computer-based methodologies in these multidisciplinary subjects. The journal also incorporates new and evolving technologies including cellular engineering and molecular imaging.
MBEC publishes original research articles as well as reviews and technical notes. Its Rapid Communications category focuses on material of immediate value to the readership, while the Controversies section provides a forum to exchange views on selected issues, stimulating a vigorous and informed debate in this exciting and high profile field.
MBEC is an official journal of the International Federation of Medical and Biological Engineering (IFMBE).