FDG-PET-based brain network analysis: a brief review of metabolic connectivity.

EJNMMI reports Pub Date : 2025-01-20 DOI:10.1186/s41824-024-00232-6

Pham Minh Tuan, Mouloud Adel, Nguyen Linh Trung, Tatiana Horowitz, Ismail Burak Parlak, Eric Guedj

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Abstract

Background: Over the past decades, the analysis metabolic connectivity patterns has received significant attention in exploring the underlying mechanism of human behaviors, and the neural underpinnings of brain neurological disorders. Brain network can be considered a powerful tool and play an important role in the analysis and understanding of brain metabolic patterns. With the advantages and emergence of metabolic-based network analysis, this study aims to systematically review how brain properties, under various conditions, can be studied using Fluorodeoxyglucose Positron Emission Tomography (FDG-PET) images and graph theory, as well as applications of this approach. Additionally, this study provides a brief summary of graph metrics and their uses in studying and diagnosing different types of brain disorders using FDG-PET images.

Main body: In this study, we used several databases in Web of Science including Web of Science Core Collection, MEDLINE to search for related studies from 1980 up to the present, focusing on FDG-PET images and graph theory. From 68 articles that matched our keywords, we selected 28 for a full review in order to find out the most recent findings and trends. Our results reveal that graph theory and its applications in analyzing metabolic connectivity patterns have attracted the attention of researchers since 2015. While most of the studies are focusing on group-level based analysis, there is a growing trend in individual-based network analysis. Although metabolic connectivity can be applied to both neurological and psychiatric disorders, the majority of studies concentrate on neurological disorders, particularly Alzheimer's Disease and Parkinson's Disease. Most of the findings focus on changes in brain network topology, including brain segregation and integration.

Conclusion: This review provides an insight into how graph theory can be used to study metabolic connectivity patterns under various conditions including neurological and psychiatric disorders.

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基于fdg - pet的脑网络分析：代谢连通性的简要回顾。

背景：在过去的几十年中，代谢连接模式的分析在探索人类行为的潜在机制和脑神经系统疾病的神经基础方面受到了极大的关注。脑网络可以被认为是一个强大的工具，在分析和理解脑代谢模式中发挥重要作用。随着基于代谢的网络分析的优势和出现，本研究旨在系统地回顾如何使用氟脱氧葡萄糖正电子发射断层扫描（FDG-PET）图像和图论来研究不同条件下的大脑特性，以及该方法的应用。此外，本研究简要总结了图形指标及其在使用FDG-PET图像研究和诊断不同类型脑疾病中的应用。正文：本研究利用Web of Science核心集、MEDLINE等Web of Science数据库检索1980年至今的相关研究，重点研究FDG-PET图像和图论。从68篇与我们的关键词匹配的文章中，我们选择了28篇进行全面审查，以找出最新的发现和趋势。我们的研究结果表明，图论及其在分析代谢连通性模式中的应用自2015年以来引起了研究人员的关注。虽然大多数研究都集中在基于群体的分析上，但基于个体的网络分析也有增长的趋势。虽然代谢连通性可以应用于神经和精神疾病，但大多数研究集中在神经疾病，特别是阿尔茨海默病和帕金森病。大多数发现集中在大脑网络拓扑结构的变化，包括大脑分离和整合。结论：本文综述了如何利用图论来研究包括神经和精神疾病在内的各种情况下的代谢连接模式。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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EJNMMI reports

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