机器学习在自闭症儿童早期识别和诊断领域的应用

doi:10.3724/SP.J.1042.2022.02321

摘要/Abstract

摘要：

早发现、早诊断、早干预是开展自闭症儿童教育康复工作的共识, 但传统识别和诊断方法局限及专业人员缺乏常导致自闭症儿童错失最佳干预期。为改善现状, 近年来机器学习凭借其客观准确、简便灵活等方面的优势, 逐渐被应用到自闭症的早期预测、筛查、诊断和评估过程管理中, 积累了较为丰富的成果。但是机器学习也在研究对象选取、分类数据采集和理论模型应用等方面存在局限性。未来研究应推动构建孕产期和新生儿病理生理信息追踪数据库和标准化模型分类指标体系, 同时继续优化算法, 加快智能化自闭症识别和诊断理论成果向实践转化。

关键词: 机器学习, 自闭症, 早期识别与诊断, 系统综述

Abstract:

In recent years, autism spectrum disorder has gradually become a major global public health problem due to complex etiology and large group, and its prevalence rate has been rising all over the world. A series of explorations and discussions, which focused on effective intervention, have been conducted in this field. Early detection, early diagnosis and early intervention have been determined as the consensus of autistic children education and rehabilitation. However, both the limitations of traditional identification and diagnosis methods and the lack of professionals mostly caused the miss of the well-timed intervention in autistic children. However, traditional identification and diagnosis methods often have some limitations (e.g., strong subjectivity, time-consuming) and face the situation that lack of professionals and higher requirements for professional clinical ability, which seriously affect the early intervention of autistic children and even make them miss the best opportunity of education and rehabilitation; Furthermore, which brings huge psychological and economic burden to autistic children and their families. In order to improve this situation, machine learning has made great achievement in recent years. With its advantages of objectivity, accuracy, simplicity and flexibility, machine learning has been gradually applied in the early prediction, screening, diagnosis and evaluation of autism. Previous studies were mostly conducted on the basis of traditional machine learning algorithms (e.g., support vector machines, naive bayes and random forest) or deep learning algorithms (e.g.,, convolutional neural network, artificial neural network and multilayer perceptions), and the analysis of EEG signals, behavioral data and genetic data could support for establishing predictive or classification models which contribute to predict, identify and diagnose autistic children. Compared with the traditional classification, this method could not only improve the efficiency and reduce the pressure of professionals, but also automatically extract and sort out subtle and potentially critical information from a large amount of data. Moreover, it could gain insight into the inherent laws of complex problems, build a multimodal classification model, complement each other's advantages, and improve the classification accuracy. However, machine learning has limitations in the selection of research objects, the extraction and collection of classified data, and the application of theoretical models. To solve the above problems, first of all, future research should clarify the pathology, etiology and course factors of autism in the early stage of development, and promote the construction of a tracking database of pathophysiological information of pregnant women and newborn. The data collection of the health information of pregnant women and their family could know about related genetic and environmental teratogenic factors and try to transfer "passive waiting" to "active defense" and avoid obstacles as soon as possible. Secondly, it is very important to sort out the criteria and basis for selecting classification indicators and improve the fineness of indicators. For example, the appropriate classification indicators, which adapt to autistic children come from different age groups and different disability degree groups, should be determined. Following studies should gradually detectestable, widely adaptable and higher accurate indicators. The build of a more scientific and stable standardized classification index system could promote the internal order of classification indexes. Finally, the actual needs and worries of different audiences should be carefully investigated. The problems such as sample representativeness, model applicability, algorithm accuracy and stability should be solved as well. The extension of propaganda about theoretical research achievements is needed; Meanwhile, more efforts should be taken to accelerate the transformation from theoretical achievements of intelligent autism identification and diagnosis to practice.

Key words: machine learning, autism, early identification and diagnosis, systematic review

中图分类号:

R395

侯婷婷, 陈潇, 孔德彭, 邵秀筠, 林丰勋, 李开云. (2022). 机器学习在自闭症儿童早期识别和诊断领域的应用. 心理科学进展 , 30(10), 2321-2337.

HOU Tingting, CHEN Xiao, KONG Depeng, SHAO Xiujun, LIN Fengxun, LI Kaiyun. (2022). Application of machine learning in early identification and diagnosis of autistic children. Advances in Psychological Science, 30(10), 2321-2337.

图/表 5

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序号	中文名称	英文名称(简称)
1	自闭症脑成像数据交换数据库	Autism Brain Imaging Data Exchange (ABIDE)
2	自闭症遗传资源交换数据库	Autism Genetic Resource Exchange (AGRE)
3	波士顿自闭症协会	Boston autism consortium (AC)
4	自闭症治疗网络	Autism Treatment Network (ATN)
5	SSC数据库	Simons Simplex Collection (SSC)
6	Simons VIP数据库	Simons Variation in Individuals Project (Simons VIP)
7	加州大学欧文分校知识库	University of California Irvine Repository (UCI)

序号	中文名称	英文名称(简称)
1	自闭症脑成像数据交换数据库	Autism Brain Imaging Data Exchange (ABIDE)
2	自闭症遗传资源交换数据库	Autism Genetic Resource Exchange (AGRE)
3	波士顿自闭症协会	Boston autism consortium (AC)
4	自闭症治疗网络	Autism Treatment Network (ATN)
5	SSC数据库	Simons Simplex Collection (SSC)
6	Simons VIP数据库	Simons Variation in Individuals Project (Simons VIP)
7	加州大学欧文分校知识库	University of California Irvine Repository (UCI)

一级维度	具体指标
影像	功能性磁共振成像(functional Magnetic Resonance Imaging, fMRI), 结构性磁共振成像(structural Magnetic Resonance Imaging, sMRI), 脑电图(electroencephalogram, EEG), 超声波(ultrasonic, UT)
量表/问卷	自闭症诊断观察量表(Autism Diagnostic Observation Schedule, ADOS), 自闭症诊断访谈量表-修订版(Autism Diagnostic Interview—Revised, ADI-R), 精神疾病诊断与统计手册(DSM-IV/ DSM-V), 国际疾病分类(ICD-10), 婴幼儿自闭症观察量表(Autism Observational Scale for Infants, AOSI), 修订版婴幼儿自闭症检核表(Modified Checklist for Autism in Toddlers, M-CHAT), 穆林早期学习量表(Mullen Scales of Early Learning, MSEL), 文兰适应行为量表(Vineland Adaptive Behavior Scales, VABS), 社会反应量表(Social Responsiveness Scale, SRS), 自闭症谱系量表(Autism-spectrum Quotient-10, AQ-10), 儿童行为检核表(Child Behavior Checklist, CBCL), 社交沟通问卷(Social Communication Questionnaire, SCQ), 家长问卷²(²作者注：在传统的诊断过程中, ADOS、ADI-R、DSM-V、ICD-10等主要用于自闭症临床诊断, 但是在本研究参考文献中, 研究者也会将其用作筛查指标参数, 因此正文未做明确划分。)
典型行为	眼动行为, 社会行为, 刻板行为, 姿势控制, 上肢运动等
个人特征	父母的病史信息, 儿童的个人信息(年龄、性别、惯用手、智商、种族、病史、饮食、睡眠等)
其他	DNA, RNA, 代谢物, 语音

一级维度	具体指标
影像	功能性磁共振成像(functional Magnetic Resonance Imaging, fMRI), 结构性磁共振成像(structural Magnetic Resonance Imaging, sMRI), 脑电图(electroencephalogram, EEG), 超声波(ultrasonic, UT)
量表/问卷	自闭症诊断观察量表(Autism Diagnostic Observation Schedule, ADOS), 自闭症诊断访谈量表-修订版(Autism Diagnostic Interview—Revised, ADI-R), 精神疾病诊断与统计手册(DSM-IV/ DSM-V), 国际疾病分类(ICD-10), 婴幼儿自闭症观察量表(Autism Observational Scale for Infants, AOSI), 修订版婴幼儿自闭症检核表(Modified Checklist for Autism in Toddlers, M-CHAT), 穆林早期学习量表(Mullen Scales of Early Learning, MSEL), 文兰适应行为量表(Vineland Adaptive Behavior Scales, VABS), 社会反应量表(Social Responsiveness Scale, SRS), 自闭症谱系量表(Autism-spectrum Quotient-10, AQ-10), 儿童行为检核表(Child Behavior Checklist, CBCL), 社交沟通问卷(Social Communication Questionnaire, SCQ), 家长问卷²(²作者注：在传统的诊断过程中, ADOS、ADI-R、DSM-V、ICD-10等主要用于自闭症临床诊断, 但是在本研究参考文献中, 研究者也会将其用作筛查指标参数, 因此正文未做明确划分。)
典型行为	眼动行为, 社会行为, 刻板行为, 姿势控制, 上肢运动等
个人特征	父母的病史信息, 儿童的个人信息(年龄、性别、惯用手、智商、种族、病史、饮食、睡眠等)
其他	DNA, RNA, 代谢物, 语音

		预测
		ASD	Non-ASD
真实	ASD	真阳性 (True Positive, TP)	假阴性 (False Negative, FN)
真实	Non-ASD	假阳性 (False Positive, FP)	真阴性 (True Negative, TN)