MEG Centre, Moscow State University of Psychology and Education Moscow, Russia ; MedTech West, Sahlgrenska Academy Gothenburg, Sweden.
MEG Centre, Moscow State University of Psychology and Education Moscow, Russia.
Front Hum Neurosci. 2014 Feb 6;8:34. doi: 10.3389/fnhum.2014.00034. eCollection 2014.
The extended phenotype of autism spectrum disorders (ASD) includes a combination of arousal regulation problems, sensory modulation difficulties, and attention re-orienting deficit. A slow and inefficient re-orienting to stimuli that appear outside of the attended sensory stream is thought to be especially detrimental for social functioning. Event-related potentials (ERPs) and magnetic fields (ERFs) may help to reveal which processing stages underlying brain response to unattended but salient sensory event are affected in individuals with ASD. Previous research focusing on two sequential stages of the brain response-automatic detection of physical changes in auditory stream, indexed by mismatch negativity (MMN), and evaluation of stimulus novelty, indexed by P3a component,-found in individuals with ASD either increased, decreased, or normal processing of deviance and novelty. The review examines these apparently conflicting results, notes gaps in previous findings, and suggests a potentially unifying hypothesis relating the dampened responses to unattended sensory events to the deficit in rapid arousal process. Specifically, "sensory gating" studies focused on pre-attentive arousal consistently demonstrated that brain response to unattended and temporally novel sound in ASD is already affected at around 100 ms after stimulus onset. We hypothesize that abnormalities in nicotinic cholinergic arousal pathways, previously reported in individuals with ASD, may contribute to these ERP/ERF aberrations and result in attention re-orienting deficit. Such cholinergic dysfunction may be present in individuals with ASD early in life and can influence both sensory processing and attention re-orienting behavior. Identification of early neurophysiological biomarkers for cholinergic deficit would help to detect infants "at risk" who can potentially benefit from particular types of therapies or interventions.
自闭症谱系障碍(ASD)的扩展表型包括觉醒调节问题、感觉调节困难和注意力重新定向缺陷的组合。人们认为,对外界感官刺激缓慢而低效的重新定向,对社交功能尤其不利。事件相关电位(ERPs)和磁场(ERFs)可能有助于揭示大脑对未注意到但明显感官事件的反应背后的哪些加工阶段受到 ASD 个体的影响。以前的研究集中在大脑反应的两个连续阶段——听觉流中物理变化的自动检测,由失匹配负波(MMN)表示,以及刺激新颖性的评估,由 P3a 成分表示——发现 ASD 个体对偏差和新颖性的处理要么增加,要么减少,要么正常。综述检查了这些看似矛盾的结果,注意到以前发现的差距,并提出了一个潜在的统一假设,将对未注意到的感官事件的反应迟钝与快速觉醒过程的缺陷联系起来。具体来说,“感觉门控”研究集中在非注意性觉醒上,一致表明,ASD 中对未注意到和时间新颖的声音的大脑反应在刺激开始后约 100 毫秒就已经受到影响。我们假设,先前在 ASD 个体中报告的烟碱型乙酰胆碱觉醒途径异常可能导致这些 ERP/ERF 异常,并导致注意力重新定向缺陷。这种胆碱能功能障碍可能在 ASD 个体生命早期就存在,并可能影响感觉处理和注意力重新定向行为。识别胆碱能缺陷的早期神经生理生物标志物将有助于检测到“有风险”的婴儿,他们可能受益于特定类型的治疗或干预。
