Identifying Brain Network Structure for an fMRI Effective Connectivity Study Using the Least Absolute Shrinkage and Selection Operator (LASSO) Method.

IF 2.2 4区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Xingfeng Li, Yuan Zhang
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引用次数: 0

Abstract

Background: Studying causality relationships between different brain regions using the fMRI method has attracted great attention. To investigate causality relationships between different brain regions, we need to identify both the brain network structure and the influence magnitude. Most current methods concentrate on magnitude estimation, but not on identifying the connection or structure of the network. To address this problem, we proposed a nonlinear system identification method, in which a polynomial kernel was adopted to approximate the relation between the system inputs and outputs. However, this method has an overfitting problem for modelling the input-output relation if we apply the method to model the brain network directly. Methods: To overcome this limitation, this study applied the least absolute shrinkage and selection operator (LASSO) model selection method to identify both brain region networks and the connection strength (system coefficients). From these coefficients, the causality influence is derived from the identified structure. The method was verified based on the human visual cortex with phase-encoded designs. The functional data were pre-processed with motion correction. The visual cortex brain regions were defined based on a retinotopic mapping method. An eight-connection visual system network was adopted to validate the method. The proposed method was able to identify both the connected visual networks and associated coefficients from the LASSO model selection. Results: The result showed that this method can be applied to identify both network structures and associated causalities between different brain regions. Conclusions: System identification with LASSO model selection algorithm is a powerful approach for fMRI effective connectivity study.

使用最小绝对缩减和选择运算器 (LASSO) 方法识别 fMRI 有效连接性研究的大脑网络结构。
研究背景利用 fMRI 方法研究不同脑区之间的因果关系已引起人们的极大关注。要研究不同脑区之间的因果关系,我们需要识别脑网络结构和影响幅度。目前的大多数方法都集中在影响幅度的估计上,而不是识别网络的连接或结构。为了解决这个问题,我们提出了一种非线性系统识别方法,采用多项式核来近似系统输入和输出之间的关系。然而,如果我们将该方法直接用于大脑网络建模,则在模拟输入输出关系时会出现过拟合问题。方法:为了克服这一局限性,本研究采用最小绝对收缩和选择算子(LASSO)模型选择方法来识别脑区网络和连接强度(系统系数)。从这些系数中,可得出已识别结构的因果关系影响。该方法基于人类视觉皮层的相位编码设计进行了验证。功能数据经过运动校正预处理。根据视网膜位点映射法定义了视觉皮层脑区。采用八连接视觉系统网络来验证该方法。提出的方法能够识别连接的视觉网络和 LASSO 模型选择的相关系数。结果表明结果表明,该方法可用于识别不同脑区之间的网络结构和相关因果关系。结论利用 LASSO 模型选择算法进行系统识别是进行 fMRI 有效连接性研究的一种有效方法。
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来源期刊
Tomography
Tomography Medicine-Radiology, Nuclear Medicine and Imaging
CiteScore
2.70
自引率
10.50%
发文量
222
期刊介绍: TomographyTM publishes basic (technical and pre-clinical) and clinical scientific articles which involve the advancement of imaging technologies. Tomography encompasses studies that use single or multiple imaging modalities including for example CT, US, PET, SPECT, MR and hyperpolarization technologies, as well as optical modalities (i.e. bioluminescence, photoacoustic, endomicroscopy, fiber optic imaging and optical computed tomography) in basic sciences, engineering, preclinical and clinical medicine. Tomography also welcomes studies involving exploration and refinement of contrast mechanisms and image-derived metrics within and across modalities toward the development of novel imaging probes for image-based feedback and intervention. The use of imaging in biology and medicine provides unparalleled opportunities to noninvasively interrogate tissues to obtain real-time dynamic and quantitative information required for diagnosis and response to interventions and to follow evolving pathological conditions. As multi-modal studies and the complexities of imaging technologies themselves are ever increasing to provide advanced information to scientists and clinicians. Tomography provides a unique publication venue allowing investigators the opportunity to more precisely communicate integrated findings related to the diverse and heterogeneous features associated with underlying anatomical, physiological, functional, metabolic and molecular genetic activities of normal and diseased tissue. Thus Tomography publishes peer-reviewed articles which involve the broad use of imaging of any tissue and disease type including both preclinical and clinical investigations. In addition, hardware/software along with chemical and molecular probe advances are welcome as they are deemed to significantly contribute towards the long-term goal of improving the overall impact of imaging on scientific and clinical discovery.
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