Restricted accessResearch articleFirst published online 2021-09
Magnetic Resonance Imaging Findings Are Associated with Long-Term Global Neurological Function or Death after Traumatic Brain Injury in Critically Ill Children
The identification of children with traumatic brain injury (TBI) who are at risk of death or poor global neurological functional outcome remains a challenge. Magnetic resonance imaging (MRI) can detect several brain pathologies that are a result of TBI; however, the types and locations of pathology that are the most predictive remain to be determined. Forty-two critically ill children with TBI were recruited prospectively from pediatric intensive care units at five Canadian children's hospitals. Pathologies detected on subacute phase MRIs included cerebral hematoma, herniation, cerebral laceration, cerebral edema, midline shift, and the presence and location of cerebral contusion or diffuse axonal injury (DAI) in 28 regions of interest were assessed. Global functional outcome or death more than 12 months post-injury was assessed using the Pediatric Cerebral Performance Category score. Linear modeling was employed to evaluate the utility of an MRI composite score for predicting long-term global neurological function or death after injury, and nonlinear Random Forest modeling was used to identify which MRI features have the most predictive utility. A linear predictive model of favorable versus unfavorable long-term outcomes was significantly improved when an MRI composite score was added to clinical variables. Nonlinear Random Forest modeling identified five MRI variables as stable predictors of poor outcomes: presence of herniation, DAI in the parietal lobe, DAI in the subcortical white matter, DAI in the posterior corpus callosum, and cerebral contusion in the anterior temporal lobe. Clinical MRI has prognostic value to identify children with TBI at risk of long-term unfavorable outcomes.
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References
1.
ShiJ., XiangH., WheelerK., SmithG.A., StallonesL., GronerJ., and WangZ. (2009). Costs, mortality likelihood and outcomes of hospitalized US children with traumatic brain injuries. Brain Inj. 23, 602–611.
2.
FaulM., WaldM.M., XuL., and CoronadoV.G. Traumatic brain injury in the United States; emergency department visits, hospitalizations, and deaths, 2002-2006. National Center for Injury Prevention and Control (U.S.), ed. Available at: www.stacks.cdc.gov/view/cdc/5571. Last accessed April22, 2021.
3.
BabikianT., and AsarnowR. (2009). Neurocognitive outcomes and recovery after pediatric TBI: meta-analytic review of the literature. Neuropsychology, 23, 283–296.
4.
BabikianT., MerkleyT., SavageR.C., GizaC.C., and LevinH. (2015). Chronic aspects of pediatric traumatic brain injury: review of the literature. J. Neurotrauma, 32, 1849–1860.
5.
PolinderS., HaagsmaJ.A., van KlaverenD., SteyerbergE.W., and van BeeckE.F. (2015). Health-related quality of life after TBI: a systematic review of study design, instruments, measurement properties, and outcome. Popul. Health Metr. 13, 4.
6.
LiL., and LiuJ. (2013). The effect of pediatric traumatic brain injury on behavioral outcomes: a systematic review. Dev. Med. Child Neurol. 55, 37–45.
7.
BiglerE.D., AbildskovT.J., PetrieJ.A., FarrerT.J., DennisM., SimicN., TaylorH.G., RubinK.H., VannattaK., GerhardtC.A., StancinT., and YeatesK.O. (2013). Heterogeneity of brain lesions in pediatric traumatic brain injury. Neuropsychology, 27, 438–451.
8.
SigmundG.A., TongK.A., NickersonJ.P., WallC.J., OyoyoU., and AshwalS. (2007). Multimodality comparison of neuroimaging in pediatric traumatic brain injury. Pediatr Neurol. 36, 217–226.
9.
HaghbayanH., BoutinA., LaflammeM., LauzierF., ShemiltM., MooreL., ZarychanskiR., DouvilleV., FergussonD., and TurgeonA.F. (2017). The prognostic value of MRI in moderate and severe traumatic brain injury. Crit. Care Med. 45, e1280–e1288.
10.
LevinH.S., MendelsohnD., LilyM.A., YeakleyJ., SongJ., ScheibelR.S., HarwardH., FletcherJ.M., KuferaJ.A., DavidsonK.C., and BruceD. (1997). Magnetic resonance imaging in relation to functional outcome of pediatric closed head injury: a test of the Ommaya-Gennarelli model. Neurosurgery, 40, 432–440.
11.
YuhE.L., MukherjeeP., Lingsma. H.F., YueJ.K., FergusonA.R., GordonW.A., ValadkaA.B., SchnyderD.M., OkonkwoD.O., MaasA.I., and ManleyG.T. and TRACK-TBIInvestigaros.. (2013). Magnetic resonance imaging improves 3-month outcome prediction in mild traumatic brain injury. Ann. Neurol. 73, 224–235.
12.
KönigsM., PouwelsP.J., Ernest van HeurnL., BakxR., VermeulenR.J., GoslingsJ.C., Poll-TheB.T., van der WeesM., Catsma-BerrevoetsC.E., and OosterlaanJ. (2018). Relevance of neuroimaging for neurocognitive and behavioral outcome after pediatric traumatic brain injury. Brain Imaging Behav. 12, 29–43.
13.
RobertsR.M., MathiasJ.L., and RoseS.E. (2014). Diffusion tensor imaging (DTI) findings following pediatric non-penetrating TBI: a meta-analysis. Dev. Neuropsychol. 39, 600–637.
14.
RobertsR.M., MathiasJ.L., and RoseS.E. (2016). Relationship between diffusion tensor imaging (DTI) findings and cognition following pediatric TBI: a meta-analytic review. Dev. Neuropsychol. 41, 176–200.
15.
NiogiS.N., MukherjeeP. (2010). Diffusion tensor imaging of mild traumatic brain injury. J. Head Trauma Rehabil. 25, 241–255.
16.
DennisM., SpieglerB.J., JuranekJ.J., BiglerE.D., SneadO.C., and FletcherJ.M. (2013). Age, plasticity, and homeostasis in childhood brain disorders. Neurosci. Biobehav. Rev. 37, 2760–2773.
17.
DeoniS.C., DeanD.C., O'MuircheartaighJ., DirksH., and JerskeyB.A. (2012). Investigating white matter development in infancy and early childhood using myelin water faction and relaxation time mapping. Neuroimage. 63, 1038–1053.
18.
RyanN.P., CatroppaC., CooperJ.M., BeareR., DitchfieldM., ColemanL., SilkT., CrossleyL., RogersK., BeachampM.H., YeatesK.O., and AndersonV.A. (2015). Relationships between acute imaging biomarkers and theory of mind impairment in post-acute pediatric traumatic brain injury: a prospective analysis using susceptibility weighted imaging (SWI). Neuropsychologia, 66, 32–38.
19.
DennisE.L., BabikianT., GizaC.C., ThompsonP.M,. and AsarnowR.F. (2017). Diffusion MRI in pediatric brain injury. Childs Nerv. Syst. 33, 1683–1692.
20.
BeauchampM.H., DitchfieldM., BablF.E., KeanM., CatroppaC., YeatesK.O., and AndersonV. (2011). Detecting traumatic brain lesions in children: CT versus MRI versus susceptibility weighted imaging (SWI). J. Neurotrauma, 28, 915–927.
21.
BeauchampM.H., BeareR., DitchfieldM., ColemanL, BablF.E., KeanM., CrossleyL, CatroppaC, YeatesK.O., and AndersonV. (2013). Susceptibility weighted imaging and its relationship to outcome after pediatric traumatic brain injury. Cortex. 49, 591–598.
22.
OmmayaA.K., GennarelliT.A. (1974). Cerebral Concussion and Traumatic Unconsciousness: Correlation of Experimental and Clinical Observations on Blunt Head Injuries. Vol 97. www.brain.oxfordjournals.org. Last accessed April29, 2020.
23.
BlackmanJ.A., RiceS.A., MatsumotoJ.A., ConawayM.R., ElginK.M., PatrickP.D., FarrellW.J., AllaireJ.H., and WillsonD.F. (2003). Brain imaging as a predictor of early functional outcome following traumatic brain injury in children, adolescents, and young adults. J. Head Trauma Rehabil. 18, 493–503.
24.
BreimanL. (2001). Random forests. Mach. Learn. 45, 5–32.
25.
WilkinsonA.A., SimicN., FrndovaH., TaylorM.J., ChoongK., FraserD., CampbellC., DhananiS., KuehnS., BeauchampM.H., FarrellC., AndersonV., GuerguerianA.M., DennisM., SchacharR., HutchisonJ.S., and Attention and Traumatic Brain Injury (ATBI) Investigators.. (2016). Serum biomarkers help predict attention problems in critically ill children with traumatic brain injury. Pediatr. Crit. Care Med. 17, 638–648.
26.
WilkinsonA.A., DennisM., SimicN., TaylorM.J., MorganB.R., FrndovaH., CampbellC., FraserD., AndersonV., GuerguerianA.M., SchacharR., HutchisonJ., and the Canadian Critical Care Trials Group (CCCTG), and Canadian Critical Care Translational Biology Group (CCCTBG). (2017). Brain biomarkers and pre-injury cognition are associated with long-term cognitive outcome in children with traumatic brain injury. BMC Pediatr. 17, 173.
27.
WilkinsonA.A., DennisM., TaylorM.J., GuerguerianA.M., BoutisK., ChoongK., CampbellC., FraserD., HutchisonJ., SchacharR., and the Canadian Critial Care Trials Group (CCCTG). . (2017). Performance monitoring in children following traumatic brain injury compared to typically developing children. Child Neurol. Open 4, 2329048X17732713.
28.
NowickiM., PearlmanL., CampbellC., HicksR., FraserD.D., and HutchisonJ. (2019). Agitated behavior scale in pediatric traumatic brain injury. Brain Inj. 33, 916–921.
29.
FiserDH. (1992). Assessing the outcome of pediatric intensive care. J. Pediatr. 121, 68–74.
30.
OyefiadeA., ErdmanL., GoldenbergA., MalkinC., BouffetE., TaylorM.D., RamaswamyV., ScantleburyN., LawN., and MabbottD.J. (2019). PPAR and GST polymorphisms may predict changes in intellectual functioning in medulloblastoma survivors. J. Neurooncol. 142, 39–48.
31.
IshwaranH., KogalurU.B., BlackstoneE.H., and LauerM.S. (2008). Random survival forests. Ann. Appl. Stat. 2, 841–860.
32.
FirschingR., WoischneckD., KleinS., ReißbergS., DöhringW., and PetersB. (2001). Classification of severe head injury based on magnetic resonance imaging. Acta Neurochir. (Wien) 143, 263–271.
33.
GentryL.R. (1994). Imaging of closed head injury. Radiology, 191, 1–17.
34.
MoenK.G., BrezovaV., SkandsenT., HåbergA.K., FolvikM., and VikA. (2014). Traumatic axonal injury: the prognostic value of lesion load in corpus callosum, brain stem, and thalamus in different magnetic resonance imaging sequences. J. Neurotrauma, 31, 1486–1496.
35.
SmithermanE., HernandezA., StavinohaP.L., HuangR., KernieS.G., Diaz-ArrastiaR., and MilesD.K. (2016). Predicting outcome after pediatric traumatic brain injury by early magnetic resonance imaging lesion location and volume. J. Neurotrauma, 33, 35–48.
36.
HudakA.M., PengL., Marquez de la PlataC., ThottakaraJ., MooreC., HarperC., McCollR., BabcockE., and Diaz-ArrastiaR. (2014). Cytotoxic and vasogenic cerebral oedema in traumatic brain injury: assessment with FLAIR and DWI imaging. Brain Inj. 28, 1602–1609.
37.
StojanovskiS., NazeriA., LepageC., AmeisS., VoineskosA.N., and WheelerA.L. (2019). Microstructural abnormalities in deep and superficial white matter in youths with mild traumatic brain injury. NeuroImage Clin. 24, 102102.
38.
van EijckM.M., SchoonmanG.G., van der NaaltJ., deVries. J., and RoksG. (2018). Diffuse axonal injury after traumatic brain injury is a prognostic factor for functional outcome: a systematic review and meta-analysis. Brain Inj. 32, 395–402.
39.
AshwalS., BabikianT., Gardner-NicholsJ., FreierM.C., TongK.A., and HolshouserB.A. (2006). Susceptibility-weighted imaging and proton magnetic resonance spectroscopy in assessment of outcome after pediatric traumatic brain injury. Arch. Phys. Med. Rehabil. 87, Suppl. 2, S50–S58.
40.
YueJ.K., WinklerE.A., PufferR.C., DengH., PhelpsR.R., WagleS. M, orrisseyM.R., RiveraE.J., RunyonS.J., VassarM.J., TaylorS.R., CnossenM.C., LingsmaH.F., YuhE.L., MukherjeePS, chynerD.M., PuccioA.M., Valadla. A.B., OkonkwoD.O., ManleyG.T., and theTRACK-TBI tnvestigarors. (2018). Temporal lobe contusions on computed tomography are associated with impaired 6-month functional recovery after mild traumatic brain injury: a TRACK-TBI study. Neurol Res. 40, 972–981.
41.
NenadovicV., HutchisonJ.S., DominguezL.G., OtsuboH., GrayM.P., SharmaR., BelkasJ., and VelazquezJ.L. (2008). Fluctuations in cortical synchronization in pediatric traumatic brain injury. J. Neurotrauma, 25, 615–627.
42.
GüizaF., DepreitereB., PiperI., CiterioG., ChambersL., JoesP.A., LoT.Y., EnbladP., NillsonP., FeyenB., JorensP., MaasA., SchuhmannM.U., DonaldR., MossL., Van den BergheG., and MeyfroidtG. (2015). Visualizing the pressure and time burden of intracranial hypertension in adult and paediatric traumatic brain injury. Intensive Care Med. 41, 1067–1076.
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