高功能孤独症自我加工的机制与干预

doi:10.3724/SP.J.1042.2025.0212

摘要/Abstract

摘要：

孤独症谱系障碍(Autism Spectrum Disorder, ASD)是一种神经性发育障碍, 核心特征之一是社会性交流困难, 该症状背后的机制长期以来尚不清楚。理解自我是理解他人的基础, 自我是社会认知的核心, 自我加工异常可能是ASD社会性交流障碍的关键原因。鉴于此, 本研究以拥有感为切入点, 通过自我加工系列实验, 结合行为、眼动、皮肤电和脑电等多模态数据, 探索ASD行为和脑神经的自我加工机制, 试图揭示ASD儿童自我加工的特点。并以此为基础, 基于脑神经的可塑性进行ASD儿童自我加工认知神经干预训练, 分析ASD儿童自我认知训练对其社交能力的影响, 进而构建ASD儿童的自我加工对其社交能力影响的多模态模型, 提供临床诊断的理论依据, 并进一步形成干预治疗的策略范式。

关键词: 自我认知, 自我参照, 孤独症谱系障碍, 拥有感

Abstract:

Autism Spectrum Disorder (ASD) is a complex neurodevelopmental condition characterized by significant challenges in social communication and interaction. Despite the profound impact of these challenges on the lives of individuals with ASD and their families, the underlying mechanisms that contribute to these social communication deficits remain not fully understood. A key aspect of social cognition is self-awareness, which is essential for comprehending the thoughts, feelings, and perspectives of others. This self-awareness forms the basis of our social interactions and is a critical component of empathy and social competence.
Against this backdrop, our study proposes a novel perspective—that atypical self-processing, or the way individuals with ASD process information about themselves, may be a key factor contributing to the social communication difficulties that are hallmarks of the disorder. This hypothesis is grounded in the recognition that self-awareness is fundamental to social cognition, and disruptions in this process could lead to the social challenges observed in ASD.
To explore this hypothesis, we have designed and will conduct a series of self-processing experiments specifically tailored to children with ASD. These experiments will integrate a diverse array of data collection methods, including behavioral assessments, eye-tracking technology, electrodermal activity measurements, and EEG recordings. Each of these methods offers a unique window into the cognitive and neural processes underlying self-processing, allowing us to construct a comprehensive profile of how children with ASD process self-related information.
The behavioral assessments will provide insights into the overt actions and responses of children with ASD in controlled settings, shedding light on their social and communicative behaviors. Eye-tracking technology will allow us to monitor where children direct their visual attention, particularly in response to social cues, offering valuable information about how they perceive and process social information. Electrodermal activity will give us a measure of the children's physiological arousal and stress levels in response to various stimuli, which can be indicative of emotional regulation challenges often associated with ASD. Finally, EEG data will offer a direct measure of the brain's electrical activity, providing real-time insights into the cognitive processes involved in self-processing.
The objective of this multi-modal approach is to elucidate the self-processing characteristics in ASD with greater precision and depth than has been possible with single-modal studies. By understanding these characteristics, we aim to develop a cognitive-neural intervention program that leverages the brain's inherent plasticity to enhance self-processing abilities in children with ASD. This intervention program will be designed to target the specific self-processing deficits identified in our experiments, with the ultimate goal of improving social competence in children with ASD.
The intervention will involve a series of self-cognitive training sessions, carefully crafted to stimulate and reinforce the self-processing mechanisms in children with ASD. These sessions will be adapted to meet the individual needs and abilities of each participant, ensuring that the training is both effective and accessible. We will rigorously assess the impact of this training on the social competence of the children, using a variety of outcome measures to capture the full range of potential benefits.
By constructing a multi-modal framework that elucidates the relationship between self-processing and social competence, we aim to establish a robust theoretical foundation for clinical diagnosis and intervention in ASD. This framework will not only advance our understanding of the disorder but also inform the development of more effective, targeted intervention strategies. Our hope is that by improving self-processing abilities in children with ASD, we can enhance their social competence, thereby improving their quality of life and their ability to connect with others on a deeper level.
In conclusion, this study represents a significant advancement in the field of ASD research. Our innovative approach, which combines multi-modal data analysis with targeted cognitive-neural interventions and the development of a comprehensive model, has the potential to revolutionize our understanding of ASD and the way we approach interventions for children with the disorder. Through this work, we aim to not only enhance the social competence of children with ASD but also contribute to the broader understanding of the neurodevelopmental mechanisms underlying social cognition and communication.

Key words: self cognition, self reference, autism spectrum disorder, sense of ownership

中图分类号:

R395

周爱保, 袁月. (2025). 高功能孤独症自我加工的机制与干预. 心理科学进展 , 33(2), 212-222.

ZHOU Aibao, YUAN Yue. (2025). Self-processing mechanisms and interventions for children with autism spectrum disorders. Advances in Psychological Science, 33(2), 212-222.

图/表 6

图1 自我哲学争论的交叉图

图2 研究思路图

图3 自我的多层嵌套层次模型及认知神经基础(Qin et al., 2020)

图4 本研究总体框架图

图5 刺激的形成过程。本研究中使用的刺激物包括一组36个抽象几何图形注：抽象几何图形是由一系列水平排列的方块和一个垂直排列的方块组成。水平和垂直方向上的方块数量总是相同的。(A)中的36个数字代表两个系列交叉的空间和36个刺激物。(B)显示出抽象几何图形的不同之处在于下面和上面的方格数, 以及重叠方格的左边和右边。(C)为两个抽象几何图形的例子。

图6 干预流程图

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