Energy Associated With Dynamic Network Changes in Patients With Multiple Sclerosis and Cognitive Impairment.

IF 7.7 1区 医学 Q1 CLINICAL NEUROLOGY
Neurology Pub Date : 2024-11-12 Epub Date: 2024-10-11 DOI:10.1212/WNL.0000000000209952
Tommy A A Broeders, Maureen van Dam, Giuseppe Pontillo, Vasco Rauh, Linda Douw, Ysbrand D van der Werf, Joep Killestein, Frederik Barkhof, Christiaan H Vinkers, Menno M Schoonheim
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引用次数: 0

Abstract

Background and objectives: Patients with multiple sclerosis (MS) often experience cognitive impairment, and this is related to structural disconnection and subsequent functional reorganization. It is unclear how specific patterns of functional reorganization might make it harder for cognitively impaired (CI) patients with MS to dynamically adapt how brain regions communicate, which is crucial for normal cognition. We aimed to identify dynamic functional network patterns that are relevant to cognitive impairment in MS and investigate whether these patterns can be explained by altered energy costs.

Methods: Resting-state functional and diffusion MRI was acquired in a cross-sectional design, as part of the Amsterdam MS cohort. Patients with clinically definitive MS (relapse-free) were classified as CI (≥2/7 domains Z < -2), mildly CI (MCI) (≥2/7 domains Z < -1.5), or cognitively preserved (CP) based on an expanded Brief Repeatable Battery of Neuropsychological Tests. Functional connectivity states were determined using k-means clustering of moment-to-moment cofluctuations (i.e., edge time series), and the resulting state sequence was used to characterize the frequency of transitions. Control energy of the state transitions was calculated using the structural network with network control theory.

Results: Imaging and cognitive data were available for 95 controls and 330 patients (disease duration: 15 years; 179 CP, 65 MCI, and 86 CI). We identified a "visual network state," "sensorimotor network state," "ventral attention network state," and "default mode network state." CI patients transitioned less frequently between connectivity states compared with CP (β = -5.78; p = 0.038). Relative to the time spent in a state, CI patients transitioned less from a "default mode network state" to a "visual network state" (β = -0.02; p = 0.004). The CI patients required more control energy to transition between states (β = 0.32; p = 0.007), particularly for the same transition (β = 0.34; p = 0.049).

Discussion: This study showed that it costs more energy for MS patients with cognitive impairment to dynamically change the functional network, possibly explaining why these transitions occur less frequently. In particular, transitions from a default mode network state to a visual network state were relevant for cognition in these patients. To further study the order of events leading to these network disturbances, future work should include longitudinal data across different disease stages.

与多发性硬化症和认知障碍患者动态网络变化相关的能量。
背景和目的:多发性硬化症(MS)患者经常会出现认知障碍,这与结构断裂和随后的功能重组有关。目前尚不清楚特定的功能重组模式会如何使认知功能受损(CI)的多发性硬化症患者更难动态调整大脑区域的交流方式,而这对正常认知至关重要。我们旨在确定与多发性硬化症认知障碍相关的动态功能网络模式,并研究这些模式是否可以用能量成本的改变来解释:方法:作为阿姆斯特丹多发性硬化症队列的一部分,我们采用横断面设计采集了静息态功能和弥散磁共振成像。临床确诊的多发性硬化症患者(无复发)被分为CI(≥2/7 domains Z <-2)、轻度CI (MCI)(≥2/7 domains Z <-1.5)或认知功能保留(CP)。功能连接状态是通过对瞬间到瞬间的共波动(即边缘时间序列)进行k-means聚类确定的,由此产生的状态序列用于描述状态转换的频率。利用网络控制理论的结构网络计算状态转换的控制能量:我们获得了 95 名对照组和 330 名患者(病程:15 年;179 名 CP、65 名 MCI 和 86 名 CI)的成像和认知数据。我们确定了 "视觉网络状态"、"感觉运动网络状态"、"腹侧注意网络状态 "和 "默认模式网络状态"。与 CP 相比,CI 患者在连接状态之间转换的频率较低(β = -5.78; p = 0.038)。相对于在一种状态下所花费的时间,CI 患者从 "默认模式网络状态 "过渡到 "视觉网络状态 "的时间较少(β = -0.02;p = 0.004)。CI患者在不同状态之间转换时需要更多的控制能量(β = 0.32; p = 0.007),尤其是在相同的转换过程中(β = 0.34; p = 0.049):本研究表明,认知障碍多发性硬化症患者动态改变功能网络需要花费更多的能量,这可能解释了为什么这些转换发生的频率较低。尤其是从默认模式网络状态到视觉网络状态的转换与这些患者的认知相关。为了进一步研究导致这些网络紊乱的事件发生顺序,未来的工作应包括不同疾病阶段的纵向数据。
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来源期刊
Neurology
Neurology 医学-临床神经学
CiteScore
12.20
自引率
4.00%
发文量
1973
审稿时长
2-3 weeks
期刊介绍: Neurology, the official journal of the American Academy of Neurology, aspires to be the premier peer-reviewed journal for clinical neurology research. Its mission is to publish exceptional peer-reviewed original research articles, editorials, and reviews to improve patient care, education, clinical research, and professionalism in neurology. As the leading clinical neurology journal worldwide, Neurology targets physicians specializing in nervous system diseases and conditions. It aims to advance the field by presenting new basic and clinical research that influences neurological practice. The journal is a leading source of cutting-edge, peer-reviewed information for the neurology community worldwide. Editorial content includes Research, Clinical/Scientific Notes, Views, Historical Neurology, NeuroImages, Humanities, Letters, and position papers from the American Academy of Neurology. The online version is considered the definitive version, encompassing all available content. Neurology is indexed in prestigious databases such as MEDLINE/PubMed, Embase, Scopus, Biological Abstracts®, PsycINFO®, Current Contents®, Web of Science®, CrossRef, and Google Scholar.
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