Subgrouping and structural brain connectivity of Parkinson's disease – past studies and future directions

Tanmayee Samantaray , Jitender Saini , Cota Navin Gupta
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引用次数: 3

Abstract

Parkinson's disease (PD) is a heterogeneous neurodegenerative disorder associated with several motor and non-motor dysfunctions. The wide variety of clinical features often leads to divergent symptom progressions. Most PD studies have attempted subgrouping based on clinical features to help understand the disease etiology and thereby contribute toward specific treatment. However, clinical symptoms have proven to be overlapping, arbitrary, and non-reliable in several cases, often biasing the deciphered subgroups. Moreover, the prodromal phase complicates diagnosis and subgrouping as it is characterized by limited clinical symptom expression. Hence, recent studies have used data-driven machine learning and deep learning methods to data-mine the heterogeneity and obtain subgroups. Structural Magnetic Resonance Imaging (sMRI) is a non-invasive approach for visualization and analysis of anatomical tissue properties of brain. It has enabled the detection of brain abnormalities and is a potential modality for subgrouping.

This review article starts with a comprehensive discussion of clinical symptoms-based and data-driven structural neuroimaging-based subgrouping approaches in PD. Secondly, we summarize the work done in brain connectivity studies using structural MRI for PD. We give an overview of mathematical definitions, connectivity metrics, brain connectivity software, and widespread network atlases. Finally, we discuss the inherent challenges and give practical suggestions on selecting methods that could be attempted for subgrouping and connectivity analysis using structural MRI data for future Parkinson's research.

Abstract Image

帕金森病的亚群和结构脑连通性——过去的研究和未来的方向
帕金森病(PD)是一种异质性神经退行性疾病,与多种运动和非运动功能障碍相关。各种各样的临床特征往往导致不同的症状进展。大多数PD研究都试图根据临床特征进行亚分组,以帮助了解疾病的病因,从而有助于特异性治疗。然而,在一些病例中,临床症状被证明是重叠的、任意的和不可靠的,常常使已破译的亚组产生偏差。此外,前驱期复杂的诊断和亚分,因为它的特点是有限的临床症状表达。因此,最近的研究使用数据驱动的机器学习和深度学习方法来数据挖掘异质性并获得子组。结构磁共振成像(sMRI)是一种用于可视化和分析大脑解剖组织特性的非侵入性方法。它能够检测大脑异常,是一种潜在的亚分组方式。这篇综述文章首先全面讨论了PD中基于临床症状和数据驱动的结构神经影像学亚组方法。其次,我们总结了结构MRI在PD脑连接研究方面所做的工作。我们给出了数学定义,连接指标,大脑连接软件和广泛的网络地图集的概述。最后,我们讨论了固有的挑战,并给出了选择方法的实际建议,这些方法可以尝试使用结构MRI数据进行亚组和连通性分析,以用于未来的帕金森研究。
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来源期刊
Neuroscience informatics
Neuroscience informatics Surgery, Radiology and Imaging, Information Systems, Neurology, Artificial Intelligence, Computer Science Applications, Signal Processing, Critical Care and Intensive Care Medicine, Health Informatics, Clinical Neurology, Pathology and Medical Technology
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