Criaud Marion, Longcamp Marieke, Anton Jean-Luc, Nazarian Bruno, Roth Muriel, Sescousse Guillaume, Strafella Antonio P, Ballanger Bénédicte, Boulinguez Philippe
Université de Lyon, F-69622, Lyon, France; Université Lyon 1, Villeurbanne, France; INSERM, U1028, Lyon Neuroscience Research Center, Lyon, F-69000, France; CNRS, UMR5292, Lyon Neuroscience Research Center, Lyon, F-69000, France; Centre de Neuroscience Cognitive, Bron, France; Morton and Gloria Shulman Movement Disorder Unit & E.J. Safra Parkinson Disease Program, Toronto Western Hospital, UHN, University of Toronto, Ontario, Canada; Research Imaging Centre, Campbell Family Mental Health Research Institute, Centre for Addiction and Mental Health, University of Toronto, Toronto, Ontario, Canada; Division of Brain, Imaging and Behaviour - Systems Neuroscience, Toronto Western Research Institute, UHN, University of Toronto, Ontario, Canada.
Laboratoire de Neurosciences Cognitives, CNRS UMR 7291 & Aix-Marseille Université, France.
Behav Brain Res. 2017 Aug 30;333:192-202. doi: 10.1016/j.bbr.2017.06.030. Epub 2017 Jun 21.
The neural mechanisms underlying response inhibition and related disorders are unclear and controversial for several reasons. First, it is a major challenge to assess the psychological bases of behaviour, and ultimately brain-behaviour relationships, of a function which is precisely intended to suppress overt measurable behaviours. Second, response inhibition is difficult to disentangle from other parallel processes involved in more general aspects of cognitive control. Consequently, different psychological and anatomo-functional models coexist, which often appear in conflict with each other even though they are not necessarily mutually exclusive. The standard model of response inhibition in go/no-go tasks assumes that inhibitory processes are reactively and selectively triggered by the stimulus that participants must refrain from reacting to. Recent alternative models suggest that action restraint could instead rely on reactive but non-selective mechanisms (all automatic responses are automatically inhibited in uncertain contexts) or on proactive and non-selective mechanisms (a gating function by which reaction to any stimulus is prevented in anticipation of stimulation when the situation is unpredictable). Here, we assessed the physiological plausibility of these different models by testing their respective predictions regarding event-related BOLD modulations (forward inference using fMRI). We set up a single fMRI design which allowed for us to record simultaneously the different possible forms of inhibition while limiting confounds between response inhibition and parallel cognitive processes. We found BOLD dynamics consistent with non-selective models. These results provide new theoretical and methodological lines of inquiry for the study of basic functions involved in behavioural control and related disorders.
由于多种原因,反应抑制及相关障碍背后的神经机制尚不清楚且存在争议。首先,对于一种旨在抑制明显可测量行为的功能,评估其行为的心理基础以及最终的脑-行为关系是一项重大挑战。其次,反应抑制很难与认知控制更一般方面所涉及的其他并行过程区分开来。因此,不同的心理和解剖功能模型并存,尽管它们不一定相互排斥,但常常看起来相互冲突。在“是/否”任务中反应抑制的标准模型假定,抑制过程是由参与者必须克制反应的刺激以反应性和选择性方式触发的。最近的替代模型表明,行动抑制可能反而依赖于反应性但非选择性的机制(在不确定的情况下所有自动反应都会自动被抑制)或前瞻性和非选择性的机制(一种门控功能,当情况不可预测时,在预期刺激时阻止对任何刺激的反应)。在这里,我们通过测试它们各自关于事件相关的血氧水平依赖(BOLD)调制的预测(使用功能磁共振成像的正向推理)来评估这些不同模型的生理合理性。我们建立了一个单一的功能磁共振成像设计,使我们能够同时记录不同可能形式的抑制,同时限制反应抑制和平行认知过程之间的混淆。我们发现BOLD动态与非选择性模型一致。这些结果为研究行为控制及相关障碍所涉及的基本功能提供了新的理论和方法学探究方向。
