Addressing brain metabolic connectivity in treatment-resistant schizophrenia: a novel graph theory-driven application of 18F-FDG-PET with antipsychotic dose correction.

IF 3 Q2 PSYCHIATRY
Giuseppe De Simone, Felice Iasevoli, Annarita Barone, Valeria Gaudieri, Alberto Cuocolo, Mariateresa Ciccarelli, Sabina Pappatà, Andrea de Bartolomeis
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Abstract

Few studies using Positron Emission Tomography with 18F-fluorodeoxyglucose (18F-FDG-PET) have examined the neurobiological basis of antipsychotic resistance in schizophrenia, primarily focusing on metabolic activity, with none investigating connectivity patterns. Here, we aimed to explore differential patterns of glucose metabolism between patients and controls (CTRL) through a graph theory-based approach and network comparison tests. PET scans with 18F-FDG were obtained by 70 subjects, 26 with treatment-resistant schizophrenia (TRS), 28 patients responsive to antipsychotics (nTRS), and 16 CTRL. Relative brain glucose metabolism maps were processed in the automated anatomical labeling (AAL)-Merged atlas template. Inter-subject connectivity matrices were derived using Gaussian Graphical Models and group networks were compared through permutation testing. A logistic model based on machine-learning was employed to estimate the association between the metabolic signals of brain regions and treatment resistance. To account for the potential influence of antipsychotic medication, we incorporated chlorpromazine equivalents as a covariate in the network analysis during partial correlation calculations. Additionally, the machine-learning analysis employed medication dose-stratified folds. Global reduced connectivity was detected in the nTRS (p-value = 0.008) and TRS groups (p-value = 0.001) compared to CTRL, with prominent alterations localized in the frontal lobe, Default Mode Network, and dorsal dopamine pathway. Disruptions in frontotemporal and striatal-cortical connectivity were detected in TRS but not nTRS patients. After adjusting for antipsychotic doses, alterations in the anterior cingulate, frontal and temporal gyri, hippocampus, and precuneus also emerged. The machine-learning approach demonstrated an accuracy ranging from 0.72 to 0.8 in detecting the TRS condition.

使用18F-氟脱氧葡萄糖正电子发射断层扫描(18F-FDG-PET)研究精神分裂症患者抗精神病药物耐受性的神经生物学基础的研究很少,主要集中在代谢活动方面,没有一项研究调查了连接模式。在此,我们旨在通过基于图论的方法和网络比较测试,探索患者和对照组(CTRL)之间葡萄糖代谢的差异模式。我们对70名受试者进行了18F-FDG正电子发射计算机断层扫描,其中包括26名耐药性精神分裂症患者(TRS)、28名对抗精神病药物有反应的患者(nTRS)和16名对照组患者(CTRL)。相对脑葡萄糖代谢图是在自动解剖标记(AAL)-合并图谱模板中处理的。使用高斯图形模型得出受试者间的连接矩阵,并通过置换测试对组间网络进行比较。采用基于机器学习的逻辑模型来估计脑区代谢信号与治疗耐药性之间的关联。为了考虑抗精神病药物的潜在影响,我们在部分相关性计算中将氯丙嗪当量作为网络分析的协变量。此外,机器学习分析还采用了药物剂量分层折叠。与 CTRL 组相比,nTRS 组(p 值 = 0.008)和 TRS 组(p 值 = 0.001)检测到整体连通性降低,其中额叶、默认模式网络和背侧多巴胺通路的改变最为显著。在TRS患者中发现了额颞叶和纹状体与皮层连接的中断,而在nTRS患者中没有发现。在调整抗精神病药物剂量后,前扣带回、额叶和颞叶回、海马和楔前也出现了改变。机器学习方法在检测TRS状况方面的准确率为0.72至0.8。
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