Social Brain Functional Maturation in Newborn Infants With and Without a Family History of Autism Spectrum Disorder.
Attention Deficit Disorder with Hyperactivity
/ genetics
Autism Spectrum Disorder
/ genetics
Brain
/ anatomy & histology
Cohort Studies
Environment
Female
Functional Neuroimaging
Humans
Infant
Infant, Newborn
London
/ epidemiology
Magnetic Resonance Imaging
/ methods
Male
Meta-Analysis as Topic
Neural Pathways
/ physiopathology
Neurodevelopmental Disorders
/ epidemiology
Journal
JAMA network open
ISSN: 2574-3805
Titre abrégé: JAMA Netw Open
Pays: United States
ID NLM: 101729235
Informations de publication
Date de publication:
05 04 2019
05 04 2019
Historique:
entrez:
6
4
2019
pubmed:
6
4
2019
medline:
23
2
2020
Statut:
epublish
Résumé
What is inherited or acquired in neurodevelopmental conditions such as autism spectrum disorder (ASD) is not a fixed outcome, but instead is a vulnerability to a spectrum of traits, especially social difficulties. Identifying the biological mechanisms associated with vulnerability requires looking as early in life as possible, before the brain is shaped by postnatal mechanisms and/or the experiences of living with these traits. Animal studies suggest that susceptibility to neurodevelopmental disorders arises when genetic and/or environmental risks for these conditions alter patterns of synchronous brain activity in the perinatal period, but this has never been examined in human neonates. To assess whether alternation of functional maturation of social brain circuits is associated with a family history of ASD in newborns. In this cohort study of 36 neonates with and without a family history of ASD, neonates underwent magnetic resonance imaging at St Thomas Hospital in London, England, using a dedicated neonatal brain imaging system between June 23, 2015, and August 1, 2018. Neonates with a first-degree relative with ASD (R+) and therefore vulnerable to autistic traits and neonates without a family history (R-) were recruited for the study. Synchronous neural activity in brain regions linked to social function was compared. Regions responsible for social function were selected with reference to a published meta-analysis and the level of synchronous activity within each region was used as a measure of local functional connectivity in a regional homogeneity analysis. Group differences, controlling for sex, age at birth, age at scan, and group × age interactions, were examined. The final data set consisted of 18 R+ infants (13 male; median [range] postmenstrual age at scan, 42.93 [40.00-44.86] weeks) and 18 R- infants (13 male; median [range] postmenstrual age at scan, 42.50 [39.29-44.58] weeks). Neonates who were R+ had significantly higher levels of synchronous activity in the right posterior fusiform (t = 2.48; P = .04) and left parietal cortices (t = 3.96; P = .04). In addition, there was a significant group × age interaction within the anterior segment of the left insula (t = 3.03; P = .04) and cingulate cortices (right anterior: t = 3.00; P = .03; left anterior: t = 2.81; P = .03; right posterior: t = 2.77; P = .03; left posterior: t = 2.55; P = .03). In R+ infants, levels of synchronous activity decreased over 39 to 45 weeks' postmenstrual age, whereas synchronous activity levels increased in R- infants over the same period. Synchronous activity is required during maturation of functionally connected networks. This study found that in newborn humans, having a first-degree relative with ASD was associated with higher levels of local functional connectivity and dysmaturation of interconnected regions responsible for processing higher-order social information.
Identifiants
pubmed: 30951164
pii: 2729809
doi: 10.1001/jamanetworkopen.2019.1868
pmc: PMC6450332
doi:
Types de publication
Comparative Study
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
e191868Subventions
Organisme : Medical Research Council
ID : MR/N026063/1
Pays : United Kingdom
Organisme : Medical Research Council
ID : MR/P008712/1
Pays : United Kingdom
Références
Soc Cogn Affect Neurosci. 2013 Feb;8(2):123-33
pubmed: 23051902
Eur J Neurosci. 2018 Mar;47(6):497-514
pubmed: 28922520
J Cogn Neurosci. 2006 Jun;18(6):911-22
pubmed: 16839299
Dev Cogn Neurosci. 2017 Jun;25:5-11
pubmed: 28233663
Proc Natl Acad Sci U S A. 2007 Apr 10;104(15):6430-5
pubmed: 17404215
Brain Res Rev. 2010 Sep;64(1):160-76
pubmed: 20381527
Dev Sci. 2018 Jan;21(1):
pubmed: 27748031
Nat Neurosci. 2006 Oct;9(10):1218-20
pubmed: 17001340
Neuropsychologia. 2017 Jul 28;102:116-123
pubmed: 28619530
Dev Cogn Neurosci. 2018 Jan;29:151-167
pubmed: 28545994
Invest Ophthalmol Vis Sci. 1978 Apr;17(4):361-5
pubmed: 640783
J Am Acad Child Adolesc Psychiatry. 2012 Nov;51(11):1150-9
pubmed: 23101741
Eur Child Adolesc Psychiatry. 2013 Feb;22 Suppl 1:S37-42
pubmed: 23300017
Mech Dev. 2013 Jun-Aug;130(6-8):412-23
pubmed: 23032193
Dev Psychopathol. 2005 Summer;17(3):599-619
pubmed: 16262984
Nat Neurosci. 2016 May;19(5):716-724
pubmed: 26928064
Cortex. 2015 Nov;72:140-155
pubmed: 26143305
Neuroimage Clin. 2015 May 01;8:356-66
pubmed: 26106561
Neuroimage. 2004 May;22(1):394-400
pubmed: 15110032
Brain Dev. 1982;4(1):51-5
pubmed: 7065377
Soc Cogn Affect Neurosci. 2016 Mar;11(3):433-44
pubmed: 26454817
Neuron. 2016 Jan 20;89(2):248-68
pubmed: 26796689
Dev Neuropsychol. 2005;27(3):403-24
pubmed: 15843104
Neurophysiol Clin. 2010 May;40(2):59-124
pubmed: 20510792
Neuroimage. 2014 May 15;92:381-97
pubmed: 24530839
Cereb Cortex. 2018 Jul 1;28(7):2207-2232
pubmed: 28521007
Proc Natl Acad Sci U S A. 2017 Apr 18;114(16):E3305-E3314
pubmed: 28289200
Proc Natl Acad Sci U S A. 2010 Nov 16;107(46):20015-20
pubmed: 21041625
Brain. 1997 Dec;120 ( Pt 12):2229-42
pubmed: 9448578
Neuroimage. 2003 Oct;20(2):870-88
pubmed: 14568458
Sci Rep. 2016 May 20;6:26395
pubmed: 27198160
J Neurosci. 2008 Nov 26;28(48):12851-63
pubmed: 19036979
PLoS One. 2013;8(4):e59990
pubmed: 23565180
J Child Psychol Psychiatry. 2017 Dec;58(12):1330-1340
pubmed: 28393350
Neuroscience. 2009 Aug 4;162(1):208-21
pubmed: 19406211
Brain Connect. 2013;3(5):523-35
pubmed: 23980912
Neurosci Lett. 2010 May 26;476(1):46-51
pubmed: 20381584
PLoS One. 2011;6(12):e29361
pubmed: 22216259
J Neurosci. 1997 Jun 1;17(11):4302-11
pubmed: 9151747
Science. 2007 Sep 7;317(5843):1360-6
pubmed: 17823346
J Child Psychol Psychiatry. 2012 May;53(5):490-509
pubmed: 22486486
Nat Neurosci. 2013 Jul;16(7):903-9
pubmed: 23727819
Neurosci Biobehav Rev. 2017 Sep;80:729-742
pubmed: 28642070
Front Neurosci. 2017 Oct 05;11:546
pubmed: 29051724
Mol Autism. 2015 Oct 27;6:59
pubmed: 26512314
Autism. 2014 Jul;18(5):583-97
pubmed: 23787411
Neuroimage. 2012 Feb 1;59(3):2255-65
pubmed: 21985910
J Child Fam Stud. 2018 Jun;27(6):1705-1720
pubmed: 29731598
Nat Med. 2016 Nov;22(11):1229-1238
pubmed: 27783067
Hum Brain Mapp. 2015 Jul;36(7):2483-94
pubmed: 25787931
Neuropsychologia. 2016 Mar;83:29-36
pubmed: 26277460
Neuroimage. 2013 Jan 1;64:240-56
pubmed: 22926292
JAMA Psychiatry. 2014 Aug;71(8):936-42
pubmed: 25100167
J Vis. 2014 Nov 18;14(13):16
pubmed: 25406161
J Cogn Neurosci. 2007 Aug;19(8):1323-37
pubmed: 17651006
Cereb Cortex. 2015 May;25(5):1176-87
pubmed: 24248433
Magn Reson Med. 2017 Aug;78(2):794-804
pubmed: 27643791
Neuroimage. 2012 Mar;60(1):623-32
pubmed: 22233733
Front Hum Neurosci. 2013 Apr 09;7:89
pubmed: 23576966
Neuroimage. 2014 Jul 15;95:232-47
pubmed: 24657355
Neuroimage. 2012 Feb 1;59(3):2142-54
pubmed: 22019881
Neuroimage. 2014 Apr 15;90:449-68
pubmed: 24389422
Neuroimage. 2012 Sep;62(3):1499-509
pubmed: 22713673
Brain Res. 2006 Mar 24;1079(1):98-105
pubmed: 16513097