Electric field simulations of transcranial direct current stimulation in children with perinatal stroke.
MRI
cerebral palsy
current
electric field
hemiparesis
neuromodulation
pediatric
tDCS
Journal
Frontiers in human neuroscience
ISSN: 1662-5161
Titre abrégé: Front Hum Neurosci
Pays: Switzerland
ID NLM: 101477954
Informations de publication
Date de publication:
2023
2023
Historique:
received:
20
10
2022
accepted:
16
01
2023
entrez:
23
2
2023
pubmed:
24
2
2023
medline:
24
2
2023
Statut:
epublish
Résumé
Perinatal stroke (PS) is a focal vascular brain injury and the leading cause of hemiparetic cerebral palsy. Motor impairments last a lifetime but treatments are limited. Transcranial direct-current stimulation (tDCS) may enhance motor learning in adults but tDCS effects on motor learning are less studied in children. Imaging-based simulations of tDCS-induced electric fields (EF) suggest differences in the developing brain compared to adults but have not been applied to common pediatric disease states. We created estimates of tDCS-induced EF strength using five tDCS montages targeting the motor system in children with PS [arterial ischemic stroke (AIS) or periventricular infarction (PVI)] and typically developing controls (TDC) aged 6-19 years to explore associates between simulation values and underlying anatomy. Simulations were performed using SimNIBS https://simnibs.github.io/simnibs/build/html/index.html using T1, T2, and diffusion-weighted images. After tissue segmentation and tetrahedral mesh generation, tDCS-induced EF was estimated based on the finite element model (FEM). Five 1mA tDCS montages targeting motor function in the paretic (non-dominant) hand were simulated. Estimates of peak EF strength, EF angle, field focality, and mean EF in motor cortex (M1) were extracted for each montage and compared between groups. Simulations for eighty-three children were successfully completed (21 AIS, 30 PVI, 32 TDC). Conventional tDCS montages utilizing anodes over lesioned cortex had higher peak EF strength values for the AIS group compared to TDC. These montages showed lower mean EF strength within target M1 regions suggesting that peaks were not necessarily localized to motor network-related targets. EF angle was lower for TDC compared to PS groups for a subset of montages. Montages using anodes over lesioned cortex were more sensitive to variations in underlying anatomy (lesion and tissue volumes) than those using cathodes over non-lesioned cortex. Individualized patient-centered tDCS EF simulations are prudent for clinical trial planning and may provide insight into the efficacy of tDCS interventions in children with PS.
Identifiants
pubmed: 36816507
doi: 10.3389/fnhum.2023.1075741
pmc: PMC9932338
doi:
Types de publication
Journal Article
Langues
eng
Pagination
1075741Informations de copyright
Copyright © 2023 Carlson, Giuffre, Ciechanski and Kirton.
Déclaration de conflit d'intérêts
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Références
Neuroimage Clin. 2021;29:102563
pubmed: 33516935
Neuropsychologia. 2011 Apr;49(5):800-804
pubmed: 21335013
Brain Stimul. 2019 May - Jun;12(3):684-692
pubmed: 30738775
Front Cell Neurosci. 2015 May 12;9:181
pubmed: 26029052
Neuroimage. 2022 Oct 15;260:119501
pubmed: 35878726
Bioelectromagnetics. 2017 Sep;38(6):474-481
pubmed: 28431194
Front Hum Neurosci. 2013 Oct 21;7:688
pubmed: 24155708
NMR Biomed. 2002 Nov-Dec;15(7-8):435-55
pubmed: 12489094
Brain Stimul. 2018 Mar - Apr;11(2):289-298
pubmed: 29146468
Brain Stimul. 2022 May-Jun;15(3):654-663
pubmed: 35447379
Neuroimage Clin. 2018 Jun 27;20:7-15
pubmed: 29988959
Clin EEG Neurosci. 2012 Jul;43(3):176-83
pubmed: 22956646
Clin Neurophysiol. 2012 Apr;123(4):644-57
pubmed: 21978654
J Vis Exp. 2019 Jul 1;(149):
pubmed: 31305529
Neuroimage Clin. 2017 Apr 18;15:106-117
pubmed: 28516033
Brain Stimul. 2016 Sep-Oct;9(5):641-661
pubmed: 27372845
Cochrane Database Syst Rev. 2016 Mar 21;3:CD009645
pubmed: 26996760
Hum Brain Mapp. 2013 Apr;34(4):923-35
pubmed: 22109746
Neuromodulation. 2012 Jul;15(4):306-15
pubmed: 22780230
J Neural Eng. 2011 Aug;8(4):046011
pubmed: 21659696
J Mot Behav. 2022;54(4):480-489
pubmed: 34913842
JAMA Pediatr. 2017 Mar 1;171(3):230-238
pubmed: 28114647
J Cogn Neurosci. 2007 Jul;19(7):1081-8
pubmed: 17583985
Neuroimage. 2015 Apr 1;109:140-50
pubmed: 25613437
Pediatrics. 2020 Nov;146(5):
pubmed: 33115795
Front Hum Neurosci. 2014 Sep 19;8:739
pubmed: 25285077
Brain Stimul. 2011 Jul;4(3):169-74
pubmed: 21777878
J Neural Eng. 2013 Jun;10(3):036018
pubmed: 23649036
Brain. 1997 Jan;120 ( Pt 1):141-57
pubmed: 9055804
Stroke. 2019 Feb;50(2):233-239
pubmed: 30661493
BMC Pediatr. 2015 Nov 12;15:178
pubmed: 26558386
Stroke. 2012 May;43(5):1404-7
pubmed: 22282891
Stroke. 2013 Nov;44(11):3265-71
pubmed: 24105698
Neuroimage. 2013 Jul 15;75:12-19
pubmed: 23473936
Neuroscientist. 2011 Feb;17(1):37-53
pubmed: 21343407
Brain Stimul. 2022 Mar-Apr;15(2):296-305
pubmed: 35085816
Neuroimage. 2011 Oct 1;58(3):849-59
pubmed: 21749927
Brain Stimul. 2021 Mar-Apr;14(2):316-326
pubmed: 33516860
Brain Res Bull. 2018 Jun;140:43-51
pubmed: 29625151
Front Neurosci. 2018 Oct 31;12:787
pubmed: 30429768
J Physiol. 2000 Sep 15;527 Pt 3:633-9
pubmed: 10990547
Cereb Cortex. 2017 May 1;27(5):2758-2767
pubmed: 27166171
Brain Sci. 2022 Apr 20;12(5):
pubmed: 35624908
J Neural Eng. 2014 Jun;11(3):036002
pubmed: 24737098
Front Hum Neurosci. 2018 Jul 03;12:268
pubmed: 30018543
Int J Stroke. 2016 Dec;11(9):1028-1035
pubmed: 27550558
Proc Natl Acad Sci U S A. 2001 Sep 25;98(20):11697-701
pubmed: 11573005
Pediatrics. 2007 Sep;120(3):609-16
pubmed: 17766535
J Neurosci. 2011 Jul 27;31(30):10937-47
pubmed: 21795544
Neurology. 2016 May 3;86(18):1659-67
pubmed: 27029628
PLoS One. 2013 Sep 27;8(9):e76112
pubmed: 24086698
Stroke. 2012 Jun;43(6):1602-8
pubmed: 22474056
Neuropsychologia. 1971 Mar;9(1):97-113
pubmed: 5146491
Expert Rev Med Devices. 2016;13(4):391-404
pubmed: 26894636
Annu Int Conf IEEE Eng Med Biol Soc. 2012;2012:859-62
pubmed: 23366028
Elife. 2017 Feb 07;6:
pubmed: 28169833
Clin Neurophysiol. 2015 Jul;126(7):1392-9
pubmed: 25468234
IEEE Trans Biomed Eng. 2004 Sep;51(9):1586-98
pubmed: 15376507
J Med Assoc Thai. 2014 Sep;97(9):954-62
pubmed: 25536713
Ann Neurol. 2008 Apr;63(4):436-43
pubmed: 18306227
J Vis Exp. 2013 Jul 14;(77):e50309
pubmed: 23893039
Neuroimage. 2020 Mar;208:116431
pubmed: 31816421
Neuroimage. 2006 Jul 1;31(3):1116-28
pubmed: 16545965
Neural Plast. 2019 Jan 14;2019:2184398
pubmed: 30733800
Annu Int Conf IEEE Eng Med Biol Soc. 2015;2015:222-5
pubmed: 26736240
Pediatr Int. 2007 Feb;49(1):70-5
pubmed: 17250509
Trials. 2016 Aug 17;17(1):405
pubmed: 27530758
Neurology. 2017 Jan 17;88(3):259-267
pubmed: 27927938
Clin Rehabil. 2015 Dec;29(12):1212-23
pubmed: 25604912
J Hand Ther. 2013 Apr-Jun;26(2):162-70; quiz 171
pubmed: 22964028
J Neurol Neurosurg Psychiatry. 2016 Apr;87(4):345-55
pubmed: 26319437
Neuroimage. 2011 Aug 1;57(3):885-91
pubmed: 21620985
Lancet Child Adolesc Health. 2018 Sep;2(9):666-676
pubmed: 30119760
Brain Stimul. 2009 Oct;2(4):201-7, 207.e1
pubmed: 20648973