《中国康复理论与实践》 ›› 2024, Vol. 30 ›› Issue (4): 404-415.doi: 10.3969/j.issn.1006-9771.2024.04.005
收稿日期:
2023-10-31
修回日期:
2024-03-11
出版日期:
2024-04-25
发布日期:
2024-05-08
通讯作者:
张杨(1983-),女,辽宁铁岭市人,博士,副教授,主要研究方向:特殊教育管理、融合教育。E-mail: 作者简介:
王振洲(1984-),男,汉族,河南周口市人,博士,讲师,硕士研究生导师,美国杜肯大学访问学者,主要研究方向:人工智能与特殊教育、残疾人高等教育招生考试政策。
基金资助:
Received:
2023-10-31
Revised:
2024-03-11
Published:
2024-04-25
Online:
2024-05-08
Contact:
ZHANG Yang, E-mail: Supported by:
摘要:
目的 了解近20年国际人工智能赋能特殊儿童临床诊断、治疗干预的研究现状、研究热点与演进路径,并预测未来的研究趋势。
方法 检索2004年至2023年Web of Science数据库核心合集中关于人工智能赋能特殊儿童诊断和干预研究的相关文献。采用CiteSpace 6.3.R1对其发文量、国家/地区、机构、作者、共现关键词、关键词聚类和时区图谱进行可视化分析。
结果 纳入314篇文献。欧美国家的高等院校主导人工智能赋能特殊儿童诊断和干预研究,Journal of Autism and Developmental Disorders是发文量最多的期刊,美国是发文量最多的国家,发文量最多的是以Acharya U Rajendra为代表的研究团队,该团队主要贡献是建立数据测试和孤独症患者的诊断模型。关键词主要为人工智能、孤独症谱系障碍、儿童、机器学习、深度学习、分类、诊断、青少年、个性化、识别等,关键词LLR聚类分析得到10个聚类集群。诊断、孤独症谱系障碍、注意力缺陷多动障碍、深度学习、机器学习的相关研究为研究热点。研究对象主要包括孤独症谱系障碍、注意力缺陷多动、学习障碍、Down综合征、视力障碍、脑瘫、智力障碍。人工智能技术主要包括深度神经网络、智能手表、面部表情识别、虚拟现实、机器人、机器学习、辅助技术、智能眼镜等。应用场景主要包括诊断与筛查、治疗、社会沟通、注意力训练、导航和物体识别、运动分析和治疗、认知治疗等。该领域的演化路径及发展趋势表现为:特殊儿童的诊断和干预服务,从最初的脑瘫和学习障碍,扩展到多种类型;从最初的分类和诊断,发展到多方面的识别和干预;从最初的传统技术,引入了新兴技术,为个性化和精准化教育提供更多的技术支持和方法创新,形成了多技术结合的干预模式。
结论 人工智能技术在特殊儿童诊断及干预的研究领域呈现显著上升趋势。研究重点逐渐从基础的分类和诊断转向更为复杂的诊断与个性化干预,尤其是在孤独症谱系障碍和注意力缺陷多动障碍领域。深度学习和机器学习等前沿技术的应用,正在推动该领域向更精准、更个性化的方向发展,多技术结合的干预模式成为该领域的未来发展趋势。
中图分类号:
王振洲, 张杨. 近20年国际人工智能赋能特殊儿童诊断及干预研究的可视化分析[J]. 《中国康复理论与实践》, 2024, 30(4): 404-415.
WANG Zhenzhou, ZHANG Yang. International researches on artificial intelligence enabled diagnosis and intervention for children with disabilities in the past two decades: a visualized analysis[J]. Chinese Journal of Rehabilitation Theory and Practice, 2024, 30(4): 404-415.
表1
来源期刊(发文量≥ 55)"
序号 | 期刊名称 | 载文量 | 年份 | 中心性 |
---|---|---|---|---|
1 | J Autism Dev Disord | 122 | 2007 | 0.13 |
2 | PLoS One | 121 | 2015 | 0.04 |
3 | Lect Notes Comput Sci | 84 | 2008 | 0.05 |
4 | IEEE Access | 75 | 2020 | 0.02 |
5 | Autism Res | 62 | 2012 | 0.08 |
6 | Sensors Basel | 61 | 2020 | 0.02 |
7 | Neuroimage Clin | 60 | 2018 | 0.03 |
8 | Sci Rep UK | 60 | 2020 | 0.01 |
9 | Arxiv | 60 | 2017 | 0.03 |
10 | Proc CVPR IEEE | 55 | 2019 | 0.01 |
表2
核心作者(发文量≥ 4)"
序号 | 姓名 | 所在机构 | 发文量/n |
---|---|---|---|
1 | Acharya U Rajendra | Kumamoto University, Research Organization for Advanced Science and Technology (IROAST) | 8 |
2 | Mahumd Mufti | Nottingham Trent University, Department of Computer Science | 7 |
3 | Wall Dennis P | Harvard University, School of Medicine, Department of Biomedical Informatics | 5 |
4 | Bronw David J | Nottingham Trent University, Computer Science Team, Interactive Systems for Social Inclusion | 5 |
5 | Atri Mohamed | Massachusetts General Hospital Psychiatry Academy | 5 |
6 | Afif Mouna | University of Monastir, Faculty of Sciences of Monastir, Laboratory of Electronics and Microelectronics (EME) | 5 |
7 | Thabtah Fadi | Manukau Institute of Technology Department of Digital Technologies | 5 |
8 | Barua Prabal Datta | Singapore University of Social Sciences, School of Science and Technology | 4 |
9 | Burton Andrew | Nottingham Trent Univ, Interact Syst Res Grp, Comp Sci Team | 4 |
10 | Shopland Nicholas | Nottingham Trent University, Interactive Systems Research Group, Computer Science Team | 4 |
11 | Washington Peter | Stanford University, Department of Biomedical Data Science | 4 |
12 | Tariq Qandeel | Manukau Institute of Technology Department of Digital Technologies | 4 |
13 | Rahman Muhammad Arifur | Nottingham Trent University, Interactive Systems Research Group, Computer Science and Informatics | 4 |
14 | Aydas Buket | Albion College, Department of Mathematics and Computer Science | 4 |
15 | Bahado-sing Ray O | Oakland University, William Beaumont School of Medicine, Department of Obstetrics and Gynecology | 4 |
16 | Wu Tung-Kuang | Changhua University of Education, Department of Information Management | 4 |
17 | Meng Ying-Ru | Hsinchu University of Education, Department of Special Education | 4 |
18 | Huang Shian-Chang | Changhua University of Education, Department of Business Administration | 4 |
表3
共现作者聚类分析"
聚类ID | 包含作者 | 共现关键词 | 高被引研究内容 |
---|---|---|---|
1 | Abdar Moloud、Acharya U Rajendra、Akhondzadeh Mohammadsadegh、Barua Prabal Datta | 人工智能技术、卷积神经网络、孤独症谱系障碍、脑图谱、脑成像数据集、功能连接模式等 | 使用卷积神经网络自动检测ASD; 基于功能连接模式对ABIDE多中心数据集的fMRI数据进行分类; 可用于更多数据测试和ASD患者预筛选的模型[ |
2 | Rahman Muhammad Arifur、Burton Andrew、Kaiser M Shamim、Shopland Nicholas、Mahmud Mufti、Bronw David J | 人工智能、孤独症谱系障碍、情绪检测、传感器数据、学习方法、游戏和任务、警报等 | 设计并实现一个基于AI的系统,用于监测和调整ASD患者的情况和学习方式; 使用传感器数据捕捉患者的情绪和面部表情,并根据这些信息选择合适的游戏和任务进行干预; 开发一个警报机制,当患者的行为出现异常时,及时通知照顾者和父母[ |
3 | Afif Mouna、Ayachi Riadh、Said Yahia、Atri Mohamed | 人工智能、室内物体检测、视觉障碍人士、深度卷积神经网络、RetinaNet等 | 探讨室内物体检测对视觉障碍人士导航辅助的重要性; 基于深度卷积神经网络框架构建一个新的室内物体检测器; 使用不同的网络结构作为RetinaNet的主干网络进行评估[ |
4 | Aydas Buket、Bahado-singh Ray O、Radhakrishna Uppala、Vishweswaraiah Sangeetha | 人工智能、DNA甲基化、脑性瘫痪、表观遗传学、神经退行性疾病、新生儿等 | 用DNA甲基化分析和AI预测新生儿脑性瘫痪; 找到影响神经功能的甲基化位点和基因; 建立高精度的预测模型; 揭示脑性瘫痪的发病机制[ |
5 | Wall Dennis P、Haber Nick、Kline Aaron、 Kalantarian Haik、Tariq Qandeel、Washington Peter、Daniels Jena | 人工智能、软件医疗器械、孤独症谱系障碍、诊断、机器学习、梯度提升决策树、情绪识别、逻辑回归分类器等 | 测试一个基于AI的软件医疗器械,用于辅助初级保健医生诊断ASD; 探讨使用Google Glass作为儿童ASD治疗工具的可行性,包括佩戴舒适度、情绪分类效果和情绪识别差异[ |
6 | Meng Ying-Ru、Wu Tung-Kuang、Huang Shian-Chang | 人工智能、人工神经网络、支持向量机、学习障碍、识别、诊断等 | 探讨使用人工神经网络和支持向量机这两种AI技术来识别和诊断学习障碍的学生的可行性和有效性; 基于学术研究的经验性发现,提出一种基于计算机的AI方法[ |
表4
核心研究机构的中心性及发文量"
序号 | 机构 | 中心性 | 年份 | 发文量/n | 占比 |
---|---|---|---|---|---|
1 | Harvard University | 0.03 | 2012 | 8 | 2.55% |
2 | Stanford University | 0.00 | 2019 | 7 | 2.23% |
3 | Egyptian Knowledge Bank | 0.08 | 2012 | 7 | 2.23% |
4 | Singapore University of Social Sciences | 0.00 | 2016 | 6 | 1.91% |
5 | Centre National de la Recherche Scientific | 0.10 | 2012 | 6 | 1.91% |
6 | Harvard Medical School | 0.00 | 2012 | 5 | 1.59% |
7 | University of Technology Sydney | 0.09 | 2020 | 5 | 1.59% |
8 | King Khalid University | 0.00 | 2015 | 5 | 1.59% |
9 | University System of Ohio | 0.00 | 2012 | 5 | 1.59% |
表5
高频及高中心性关键词(频次≥ 16)"
序号 | 关键词 | 频次 | 年份 | 中介中心性 |
---|---|---|---|---|
1 | artificial intelligence | 110 | 2004 | 0.33 |
2 | children | 88 | 2012 | 0.26 |
3 | autism spectrum disorder | 80 | 2011 | 0.19 |
4 | machine learning | 71 | 2007 | 0.08 |
5 | deep learning | 55 | 2018 | 0.06 |
6 | classification | 46 | 2006 | 0.20 |
7 | diagnosis | 34 | 2006 | 0.15 |
8 | adolescents | 19 | 2016 | 0.02 |
9 | individuals | 17 | 2021 | 0.02 |
10 | identification | 16 | 2012 | 0.04 |
表6
不同研究对象的主要支撑技术、应用场景"
研究对象 | 支撑技术 | 应用场景 |
---|---|---|
ASD | 深度神经网络、智能手表、ABIDE数据集、面部表情识别 | 诊断与筛查、治疗、社会沟通 |
ADHD | 心电图、虚拟现实、机器人 | 诊断与筛查、注意力训练、监测 |
学习障碍 | 机器学习、增强与替代性交流、虚拟现实、辅助技术 | 特殊教育、融合教育(理解能力、听说读写) |
Down综合征 | 支持向量机、特征选择 | 诊断与筛查和神经心理学研究 |
视力障碍 | 辅助技术、智能眼镜、物体检测、虚拟现实 | 导航和物体识别 |
脑瘫 | 选择、键盘仿真器、康复机器人、运动训练系统等 | 运动分析与治疗 |
智力障碍 | 社交机器人、虚拟现实、认知游戏系统 | 认知治疗、注意力训练、自我管理 |
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