应用IBASPM分析孤独症儿童脑灰质结构改变

摘要
图/表
参考文献(15)
相关文章 (15)

全文: PDF (0 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要目的：运用基于统计学参数图（Statistical parametric mapping，SPM）的个体脑图谱形态分析（Individual brain atlases using Statistical Parametric Mapping，IBASPM）软件，分析孤独症儿童不同脑区灰质结构体积变化。资料与方法：采用GE HDx 1.5T磁共振扫描仪对23例经临床诊断为孤独症的患儿和28例年龄、性别匹配的健康儿童进行全脑扫描，采用3D快速扰相梯度回波（Fast spoiled gradient echo，FSPGR）序列获得高分辨力T1WI像。在SPM5平台上，运用IBASPM软件对原始数据进行处理，获得各脑区体积值。采用两独立样本t-检验进行组间比较。结果：符合实验要求的被试包括孤独症组16例，正常对照组18例。孤独症组，男性11例，女性5例，平均年龄（2.81±0.91）岁；正常对照组，男性11例，女性7例，平均年龄（2.61±0.50）岁。与正常对照组相比，孤独症组体积增大的脑区包括左侧中扣带回、左侧缘上回、双侧杏仁体、双侧尾状核；孤独症组体积减小的脑区为小脑蚓部Ⅷ区。结论：孤独症儿童脑灰质结构存在异常，这些脑区均与情绪、语言、行为控制相关，可为孤独症的临床症状的解释和诊断提供客观依据。运用IBASPM软件可自动化对不同脑区进行体积测量，从形态学角度对孤独症儿童脑灰质结构进行分析。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	陈静
	李欣
	王春祥
	刘俊刚
	赵滨

关键词 ：孤独症障碍, 磁共振成像

Abstract：Objective: To analyse the volume changes of gray matter structures in different brain regions of autistic children by using IBASPM software based on SPM. Methods: Twenty-three autistic children diagnosed by clinical features and 28 healthy children were selected in this study, whose age and sex were matched. High resolution T1 weighted images of each child’s whole brain were acquired by using 3D FSPGR sequence on GE HDx 1.5T MRI. The raw data was dealed with IBASPM software based on SPM5, to obtain the volume value of every brain region. Two independent sample t-test was used to compare the groups. Results: The data of 16 autistic children and 18 normal controls matched the experimental requirements. The autism group included 11 males and 5 females, whose mean age was 2.81±0.91 years old. The normal control group included 11 males and 7 females, whose mean age was 2.61±0.50 years old. Compared with the normal control group, the volume values of the left mid cingulum, left supramarginal gyrus, bilateral amygdaloid body and bilateral caudate nucleus were enlarged in the autism group; the volume value of vermis Ⅷ area was decreased. Conclusion: Some gray matter structures of autistic children were abnormally changed, which were related to emotion, language and behavior control, and then provided an objective basis for the interpretation and diagnosis of clinical symptoms of autism. The IBASPM software can be used to automatically measure the volumes of different brain regions, and to morphologically analyse the gray matter structures of autistic children.

Key words： Autistic disorder Magnetic resonance imaging

收稿日期: 2015-10-21

PACS:	Ｒ749.91
	Ｒ445.2

通讯作者: 陈静，天津市儿童医院影像科，300074。E-mail：bbchenjing@126.com

作者简介: 陈静（1982-），女，天津人，主治医师。E-mail：bbchenjing@126.com

引用本文:

陈静，李欣，王春祥，刘俊刚，赵滨. 应用IBASPM分析孤独症儿童脑灰质结构改变[J]. 中国临床医学影像杂志, 2016, 27(5): 309-313.
CHEN Jing, LI Xin, WANG Chun-xiang, LIU Jun-gang, ZHAO Bin. Analysis of cerebral gray matter structural changes in autistic children by IBASPM. JOURNAL OF CHINA MEDICAL IMAGING, 2016, 27(5): 309-313.

链接本文:

http://www.jccmi.com.cn/CN/ 或 http://www.jccmi.com.cn/CN/Y2016/V27/I5/309

[1]Schumann CM, Barnes CC, Lord C, et al. Amygdala enlargement in toddlers with autism related to severity of social and communication impairments[J]. Biol Psychiatry, 2009, 66(10): 942-949.
[2]Cheung C, Chua SE, Cheung V, et al. White matter fractional anisotrophy differences and correlates of diagnostic symptoms in autism[J]. J Child Psychol Psychiatry, 2009, 50(9): 1102-1112.
[3]Anagnostou E, Taylor MJ. Review of neuroimaging in autism spectrum disorders: what have we learned and where we go from here[J]. Mol Autism, 2011, 2(1): 4-12.
[4]Courchesen E, Campbell K, Solso S. Brain growth across the life span in auism: age-specific changes in anatomical pathology[J]. Brain Res, 2011, 1380(3): 138-145.
[5]Tzourio-Mazoyer N, Landeau B, Papathanassiou D, et al. Automated anatomical labeling of activations in SPM using a macroscopic anatomical parcellation of the MNI MRI single-subject brain[J]. Neuroimage, 2002, 15(1): 273-289.
[6]Libero LE, DeRamus TP, Deshpande HD, et al. Surface-based morphometry of the cortical architecture of autism spectrum disorders: volume, thickness, area, and gyrification[J]. Neuropsychologia, 2014, 62(9): 1-10.
[7]Levitt JG, Blanton RE, Smalley S, et al. Cortical sulcal maps in autism[J]. Cereb Cortex, 2003, 13(7): 728-735.
[8]White SW, Albano AM, Johnson CR, et al. Development of a cognitive-behavioral intervention program treat anxiety and social deficits in teens with high-functioning autism[J]. Clin Child Fam Psychol Rev, 2010, 13(1): 77-90.
[9]Jiao Y, Chen R, Ke X, et al. Predictive models of autism spectrum disorder based on brain regional cortical thickness[J]. Neuroimage, 2010, 50(2): 589-599.
[10]Ameis SH, Fan J, Rockel C, et al. Altered cingulum bundle microstructure in autism spectrum disorder[J]. Acta Neuropsychiatr, 2013, 25(5): 275-282.
[11]Nordahl CW, Scholz R, Yang X, et al. Increased rate of amygdala growth in children aged 2 to 4 years with autism spectrum disorders: a longitudinal study[J]. Arch Gen Psychiatry, 2012, 69(1): 53-61.
[12]Kim JE, Lyoo IK, Estes AM, et al. Laterobasal amygdalar enlargement in 6- to 7-year-old children with autism spectrum disorder[J]. Arch Gen Psychiatry, 2010, 67(11): 1187-1197.
[13]Levitt JG, Blanton R, Capetillo-Cunliffe L, at al. Cerebellar vermis lobules VIII-X in autism[J]. Prog Neuropsychopharmacol Biol Psychiatry, 1999, 23(4): 625-633.
[14]Stoodley. Distinct regions of the cerebellum show gray matter decreases in autism, ADHD, and developmental dyslexia[J]. Front Syst Neurosci, 2014, 8(5): 92-108.
[15]Sears LL, Vest C, Mohamed S, et al. An MRI study of the basal ganglia in autism[J]. Prog Neuropsychopharmcol Biol Psychiatry, 1999, 23(4): 613-624.