Badke D'Andrea Carolina, Laumann Timothy O, Newbold Dillan J, Lynch Charles J, Hadji Mohammad, Nelson Steven M, Nielsen Ashley N, Chauvin Roselyne J, Krimmel Samuel R, Snyder Abraham Z, Marek Scott, Greene Deanna J, Raichle Marcus E, Dosenbach Nico U F, Gordon Evan M
Department of Radiology, Washington University School of Medicine, St. Louis, MO 63110.
Department of Psychiatry, Washington University School of Medicine, St. Louis, MO 63110.
Proc Natl Acad Sci U S A. 2025 Jul 8;122(27):e2502021122. doi: 10.1073/pnas.2502021122. Epub 2025 Jun 30.
The action-mode network (AMN) is a canonical functional brain network first identified using resting-state functional connectivity (RSFC). Based on animal and human data, we have proposed that AMN supports the brain's action mode by controlling functions required for successful goal-directed behavior. However, task fMRI averaged across groups has associated AMN regions with a variety of behaviors, contributing to uncertainty about AMN function. Here, we investigated the AMN using an inside-out approach, in which the network architecture of the AMN is first precisely mapped within individuals and then associated with behavioral functions. Individual-specific precision functional mapping with >5 h of RSFC and task functional magnetic resonance imaging (fMRI) data revealed a replicable AMN subnetwork structure. AMN subnetworks were characterized and annotated by combining a meta-analytic network association method with RSFC, intrinsic timing, and task activation profiling. We demonstrate the existence of AMN-Decision, -Action, and -Feedback subnetworks that are distributed across lobes, forming a temporally sequential within-network processing stream by which the brain adjudicates between possible goals, sets action plans, and modifies those plans in response to feedback such as pain. A subnetwork in the pars marginalis of the cingulate was distinct from the Decision, Action, and Feedback subnetworks and may be important for the construction of the bodily self.
行动模式网络(AMN)是一种典型的功能性脑网络,最初是通过静息态功能连接(RSFC)识别出来的。基于动物和人类数据,我们提出AMN通过控制成功的目标导向行为所需的功能来支持大脑的行动模式。然而,跨组平均的任务功能磁共振成像(fMRI)已将AMN区域与多种行为联系起来,这增加了AMN功能的不确定性。在这里,我们采用由内而外的方法研究AMN,即首先在个体内部精确绘制AMN的网络结构,然后将其与行为功能联系起来。使用超过5小时的RSFC和任务功能磁共振成像(fMRI)数据进行个体特异性的精确功能映射,揭示了一种可重复的AMN子网结构。通过将元分析网络关联方法与RSFC、内在时间和任务激活分析相结合,对AMN子网进行了表征和注释。我们证明了AMN决策、行动和反馈子网的存在,这些子网分布在多个脑叶中,形成了一个时间上连续的网络内处理流,大脑通过这个处理流在可能的目标之间进行裁决,制定行动计划,并根据诸如疼痛等反馈修改这些计划。扣带回边缘部的一个子网与决策、行动和反馈子网不同,可能对身体自我的构建很重要。
