自闭症谱系障碍人群词义加工的脑激活模式：基于fMRI研究的元分析

doi:10.3724/SP.J.1042.2022.02448

摘要/Abstract

摘要：

本研究筛选了11项采用功能性磁共振成像技术探究言语自闭症人群词义加工的研究, 探讨了该人群与典型人群脑激活模式的差异是否具有跨研究的稳定性。结果表明, 差异的脑激活模式稳定存在, 且表现为主要涉及左额上回的典型脑区激活不足。该结果为言语ASD人群语言加工的神经机制提供了来自词义加工的跨研究激活证据, 在明确“减弱的额叶激活”这一稳定差异表现的基础上, 强调了针对不同语言加工任务开展元分析研究的必要性。

关键词: 自闭症谱系障碍, 词义, fMRI, 元分析

Abstract:

Language impairment is a salient and one of the earliest symptoms of Autism Spectrum Disorder (ASD). Over the past decades, researchers have employed various neuroimaging techniques (e.g., functional magnetic resonance imaging, fMRI) to explore the neural markers of language impairments in individuals with ASD. Individual investigations have converged on finding differences in neural responses of language processing (e.g., word, sentence, prosody) between autistic participants and typically developing (TD) controls. Results from meta-analytic studies further indicated that the differential neural activities were stable across studies. However, the meta-analysis that focused on semantic processing in the ASD group revealed somewhat different results from the meta-analysis on language processing. In addition, the results of sub-analyses that divided language processing tasks into subtypes reported that the ASD-TD differential activation patterns were moderated by task type. The previous meta-analysis of semantic processing in ASD populations included both sentence-level and word-level semantic processing studies. Considering the differentiated underlying mechanisms of word-meaning and sentence-meaning processing, it is essential to distinguish between these two levels of semantic processing. Lexical-semantic processing ability is at the forefront of language acquisition and a known area of impairment in individuals with ASD. Previous review studies have adequately summarized the behavioral performance of individuals with ASD for semantic processing at the single word level. However, a meta-analysis to investigate the cross-study brain activation patterns of individuals with ASD during lexical-semantics processing is still missing. The current study identified 11 published journal articles that used fMRI to investigate lexical-semantic processing in individuals with ASD. Activation likelihood estimation analysis was adopted to investigate whether atypical brain activation patterns in individuals with ASD were stable across studies and how the atypical performance manifested. The results revealed that the TD group activated the left inferior frontal gyrus, the left superior frontal gyrus, the left middle temporal gyrus, and the left middle frontal gyrus, which are brain regions responsible for completing lexical-semantics processing tasks. Like the TD group, the ASD group also showed activation in typical lexical-semantics processing brain regions, such as the left inferior frontal gyrus, the left middle temporal gyrus, and the left medial frontal gyrus. At the same time, differential brain activation patterns were steadily present between the ASD and TD groups. To be more specific, no brain region was found in the ASD group-TD group subtraction analysis, while the left superior frontal gyrus was present in the TD group -ASD group subtraction analysis. This finding indicated the atypical brain activation patterns of lexical-semantics processing in individuals with ASD manifested as hypoactivation in the left superior frontal gyrus. In addition, exploratory sub-analyses suggested that the atypical brain activation patterns of adults with ASD may differ from those of children and adolescents with ASD. Adults with ASD were more likely to show enhanced activation in the visual processing areas, while children and adolescents with ASD showed reduced activation in the left middle temporal gyrus. In summary, the current meta-analysis provided evidence for the atypical brain responses to lexical-semantics processing in verbal individuals with ASD from a cross-study perspective. Their atypical brain activation activities when processing meanings of words were consistent with the "decreased frontal lobe activation" hypothesis. The current study revealed novel findings which highlighted that distinguishing between different levels of language processing can help researchers identify the corresponding neural markers of certain types of language impairments in autistic populations. Due to the limited number of included studies, the current study had some limitations, such as only including fMRI studies and not considering the task, behavior and general language skills related factors. Future studies should take age, language background, general language skills, intervention experiences, and types of semantic processing into consideration.

Key words: Autism Spectrum Disorder, lexical-semantic, fMRI, meta-analysis

中图分类号:

B845

俞稼钰, 靳羽西, 梁丹丹. (2022). 自闭症谱系障碍人群词义加工的脑激活模式：基于fMRI研究的元分析. 心理科学进展 , 30(11), 2448-2460.

YU Jiayu, JIN Yuxi, LIANG Dandan. (2022). Brain activation differences in lexical-semantics processing in autistic population: A meta-analysis of fMRI studies. Advances in Psychological Science, 30(11), 2448-2460.

图/表 6

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研究	被试数量		平均年龄(岁) (年龄范围)		ASD诊断	语言
研究	ASD组	TD组	ASD组	TD组	ASD诊断	语言
1 Bednarz et al. (2017)	18	13	10.7 (8.1~13.8)	10.5 (8.1~14.1)	ADOS, ADI-R及专家临床观点	英语
2 Knaus et al. (2017)	15	19	13.57	12.64	DSM-4, ADOS-2 ADI-R或SCQ	英语
3 Shen et al. (2012)	14	14	24.1 (15~44)	24.2 (14~42)	DSM-4, ADI-R, ADOS	英语
54 Harris et al. (2006)	14	22	36 (18~52)	31 (19~50)	DSM-4, ADI-R, ADOS	英语
5 Kana et al. (2017)	15	15	21.63 (15~36)	27.25 (16~34)	ADI-R, ADOS, SRS	英语
6 Knaus et al. (2008)	12	12	15.46 (11.4~19.8)	14.94 (11.5~19.8)	DSM-4, ADI-R, ADOS; 临床专家确认ASD诊断	英语
7 Gaffrey et al. (2007)	10	10	26.1	25.3	DSM-4, ADI-R, ADOS	英语
8 Kleinhans et al. (2008)	14	14	23.79 (14~44)	22.41 (14~43)	DSM-4, ADI-R, ADOS-G	英语
9 Wong et al. (2019)	31	38	12.1	11.9	DSM-4, ICD-10, ADI-R汉语版; 采用DSM-5再确认	汉语
10 Chen et al. (2016)	37	35	13.3 (8~18)	13.3 (8~18)	DSM-4, ICD-10, ADI-R汉语版	汉语
11 Fan et al. (2021)	61	67	12.66 (8~18)	12.79 (8~18)	DSM-5, ADI-R汉语版	汉语

研究	被试数量		平均年龄(岁) (年龄范围)		ASD诊断	语言
研究	ASD组	TD组	ASD组	TD组	ASD诊断	语言
1 Bednarz et al. (2017)	18	13	10.7 (8.1~13.8)	10.5 (8.1~14.1)	ADOS, ADI-R及专家临床观点	英语
2 Knaus et al. (2017)	15	19	13.57	12.64	DSM-4, ADOS-2 ADI-R或SCQ	英语
3 Shen et al. (2012)	14	14	24.1 (15~44)	24.2 (14~42)	DSM-4, ADI-R, ADOS	英语
54 Harris et al. (2006)	14	22	36 (18~52)	31 (19~50)	DSM-4, ADI-R, ADOS	英语
5 Kana et al. (2017)	15	15	21.63 (15~36)	27.25 (16~34)	ADI-R, ADOS, SRS	英语
6 Knaus et al. (2008)	12	12	15.46 (11.4~19.8)	14.94 (11.5~19.8)	DSM-4, ADI-R, ADOS; 临床专家确认ASD诊断	英语
7 Gaffrey et al. (2007)	10	10	26.1	25.3	DSM-4, ADI-R, ADOS	英语
8 Kleinhans et al. (2008)	14	14	23.79 (14~44)	22.41 (14~43)	DSM-4, ADI-R, ADOS-G	英语
9 Wong et al. (2019)	31	38	12.1	11.9	DSM-4, ICD-10, ADI-R汉语版; 采用DSM-5再确认	汉语
10 Chen et al. (2016)	37	35	13.3 (8~18)	13.3 (8~18)	DSM-4, ICD-10, ADI-R汉语版	汉语
11 Fan et al. (2021)	61	67	12.66 (8~18)	12.79 (8~18)	DSM-5, ADI-R汉语版	汉语

研究	任务类型	行为结果	对比条件	坐标数量
研究	任务类型	行为结果	对比条件	ASD组	TD组
1 Bednarz et al. (2017)	判断第四个呈现的词是否与前三个词属于同一类别。	在整体正确率和反应时方面未发现组间差异。	词 > 注视点	5	6
2 Knaus et al. (2017)	3个动词呈三角形排列, 目标词位于顶部。指出底部两个词中哪一个在意义上与目标词最相似。	在整体正确率和反应时方面未发现组间差异。	词 > 图形	2	4
3 Shen et al. (2012)	判断词是否属于先前呈现类别。	ASD组的正确率显著低于TD组, 但反应时类似。	词 > 字母	3	6
4 Harris et al. (2006)	判断词义为积极还是消极。	在整体正确率和反应时方面未发现组间差异。	词义 > 词的位置	3	7
5 Kana et al. (2017)	判断一个形容词是用于形容自己还是他们最喜欢的老师。	未报告行为结果。	词 > 字母	4	12
6 Knaus et al. (2008)	思考某三词短语描述了一个怎样的词。随后呈现两个词, 判断哪一个与ta想的跟接近。	两组被试的准确率均达到“天花板”。	词 > 字母	8	7
7 Gaffrey et al. (2007)	判断词是否属于先前呈现类别。	ASD组的正确率显著低于TD组, 但反应时类似。	词 > 字母	13	14
8 Kleinhans et al. (2008)	尽可能多地说出属于某一类别的词。	ASD组产出的正确词显著少于TD组。	同一类别 > 自定速度重复“nothing”	3	3
9 Wong et al. (2019)	判断先后呈现的两个词在意义上是否有联系。	在整体正确率和反应时方面未发现组间差异。	真词 > 假词	9	18
10 Chen et al. (2016)	判断先后呈现的两个词在意义上是否有联系。	ASD组在准确率和反应时指标上都显著差于TD组。	真词 > 假词	6	5
11 Fan et al. (2021)	判断先后呈现的两个词在意义上是否有联系。	ASD青少年的准确率显著低于TD青少年。在反应时上无组间差异。	真词 > 假词	5	4

研究	任务类型	行为结果	对比条件	坐标数量
研究	任务类型	行为结果	对比条件	ASD组	TD组
1 Bednarz et al. (2017)	判断第四个呈现的词是否与前三个词属于同一类别。	在整体正确率和反应时方面未发现组间差异。	词 > 注视点	5	6
2 Knaus et al. (2017)	3个动词呈三角形排列, 目标词位于顶部。指出底部两个词中哪一个在意义上与目标词最相似。	在整体正确率和反应时方面未发现组间差异。	词 > 图形	2	4
3 Shen et al. (2012)	判断词是否属于先前呈现类别。	ASD组的正确率显著低于TD组, 但反应时类似。	词 > 字母	3	6
4 Harris et al. (2006)	判断词义为积极还是消极。	在整体正确率和反应时方面未发现组间差异。	词义 > 词的位置	3	7
5 Kana et al. (2017)	判断一个形容词是用于形容自己还是他们最喜欢的老师。	未报告行为结果。	词 > 字母	4	12
6 Knaus et al. (2008)	思考某三词短语描述了一个怎样的词。随后呈现两个词, 判断哪一个与ta想的跟接近。	两组被试的准确率均达到“天花板”。	词 > 字母	8	7
7 Gaffrey et al. (2007)	判断词是否属于先前呈现类别。	ASD组的正确率显著低于TD组, 但反应时类似。	词 > 字母	13	14
8 Kleinhans et al. (2008)	尽可能多地说出属于某一类别的词。	ASD组产出的正确词显著少于TD组。	同一类别 > 自定速度重复“nothing”	3	3
9 Wong et al. (2019)	判断先后呈现的两个词在意义上是否有联系。	在整体正确率和反应时方面未发现组间差异。	真词 > 假词	9	18
10 Chen et al. (2016)	判断先后呈现的两个词在意义上是否有联系。	ASD组在准确率和反应时指标上都显著差于TD组。	真词 > 假词	6	5
11 Fan et al. (2021)	判断先后呈现的两个词在意义上是否有联系。	ASD青少年的准确率显著低于TD青少年。在反应时上无组间差异。	真词 > 假词	5	4

	脑区	坐标(x, y, z)	体积(mm³)	ALE	来源研究
TD组	左额下回Left Inferior Frontal Gyrus	(-49.3, 25.7 3.7)	2624	0.02	4, 5, 6, 7, 10, 11
	左额上回Left Superior Frontal Gyrus	(-3.3, 17.2, 53.2)	2504	0.0219	2, 3, 4, 5, 6, 7, 9
	左颞中回Left Middle Temporal Gyrus	(-53.4, -46.4, -3.1)	1408	0.0167	5, 9, 10, 11
	左额中回Left Middle Frontal Gyrus	(-47.6, 18.2, 26.2)	688	0.0164	3, 8, 10
ASD组	左额下回Left Inferior Frontal Gyrus	(-47, 29.5, -2)	2904	0.0191	2, 3, 4, 6, 7, 10, 11
	左颞中回Left Middle Temporal Gyrus	(-56, -40.8, 0)	928	0.0183	4, 10, 11
	左额内回Left Medial Frontal Gyrus	(-4.6, 6.5, 60.2)	832	0.013	6, 7, 8, 11
TD组 & ASD组	左额下回Left Inferior Frontal Gyrus	(-47, 27.8, -4.9)	872	0.0154	4, 10, 11/ 4, 6, 7, 10
	左颞中回Left Middle Temporal Gyrus	(-53.2, -42.1, -2)	264	0.0138	4, 10
	左额内回Left Medial Frontal Gyrus	(-4.8, 4, 56.4)	80	0.0104	3
	左额下回Left Inferior Frontal Gyrus	(-48, 30, 10)	8	0.084	-
TD组-ASD组	左额上回Left Superior Frontal Gyrus	(-3.3, 15.9, 51.6)	1128	0.018	2, 4, 7, 9