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Predictors of Recovery from Traumatic Brain Injury-Induced Prolonged Consciousness Disorder PDF

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Hindawi Neural Plasticity Volume 2017, Article ID 9358092, 11 pages https://doi.org/10.1155/2017/9358092 Research Article Predictors of Recovery from Traumatic Brain Injury-Induced Prolonged Consciousness Disorder HiroakiAbe,1,2KeigoShimoji,3YoshihideNagamine,4 SatoruFujiwara,5andShin-IchiIzumi2,6 1DepartmentofRehabilitationMedicine,KohnanHospital,TohokuRyogoCenter,Sendai,Japan 2DepartmentofPhysicalMedicineandRehabilitation,GraduateSchoolofMedicine, TohokuUniversity,Sendai,Japan 3DepartmentofDiagnosticRadiology,TokyoMetropolitanGeriatricHospital,Tokyo,Japan 4DepartmentofNeurosurgery,KohnanHospital,TohokuRyogoCenter,Sendai,Japan 5DepartmentofNeurosurgery,KohnanHospital,Sendai,Japan 6GraduateSchoolofBiomedicalEngineering,TohokuUniversity,Sendai,Japan CorrespondenceshouldbeaddressedtoHiroakiAbe;[email protected] Received28October2016;Revised19January2017;Accepted22January2017;Published23February2017 AcademicEditor:Cheng-ShengChen Copyright©2017HiroakiAbeetal.ThisisanopenaccessarticledistributedundertheCreativeCommonsAttributionLicense, whichpermitsunrestricteduse,distribution,andreproductioninanymedium,providedtheoriginalworkisproperlycited. Weinvestigatedtheclinicalpredictorsofthedegreeofrecoveryinpatientswithprolongeddisordersofconsciousness(PDC)caused bytraumaticbraininjury.FourteenpatientswithPDCunderwenttwodiffusiontensorimaging(DTI)studies;thefirstandsecond scanswereperformedat345.6±192.6and689.1±272.2daysaftertheinjury,respectively.Inadditiontothetemporalchangesin eachofthesediffusionparameters,fractionalanisotropy(FA),meandiffusivity,axialdiffusivity(AD),andradialdiffusivitywere assessedovera1-yearperiod.RelationshipofclinicalandDTIparameterswithrecoveryfromPDC(RPDC)wasevaluatedusing Spearman’srank-correlationandstepwisemultiplelinearregressionanalysis.ThemeanFAandnumberofvoxelswithFAvalues> 0.4(VsFA0.4)weresignificantlydecreasedatthesecondscan.Asignificantpositivecorrelationwasobservedbetweenthedegree ofRPDCandmeanFA(𝑟=0.60)andVsFA0.4(𝑟=0.68)aswellasbetweenthedifferenceinVsFA0.4(𝑟=0.63)andAD(𝑟=0.54) betweenthefirstandsecondscans.Onmultiplelinearregressionanalysis,initialseverityofPDCandthedifferenceinADremained significantlyassociatedwiththedegreeofRPDC.Themicrostructuralwhitematterchangesobservedinthisstudyindicatetheir potentialrelationwiththedegreeofRPDCoverthelongerterm. 1.Introduction patientswhoremainedinavegetativestateafterTBIuntilthe timeoftheirdeath[3,4].Thus,severeTBIcommonlyinvolves Diffuseaxonalinjury(DAI)isacommonformoftraumatic multiplediffuselesionsinbothwhiteandgraymatter. brain injury (TBI) sustained in motor vehicle collisions. Diffusion tensor imaging (DTI) has been useful in The injury involves rotational forces and is characterized describing the microstructure changes in the chronic stage by extensive white matter damage [1]. The neuropathology of DAI [5]. Several studies have documented posttraumatic of disorders of consciousness (coma, vegetative state, and findingsofaxotomyanddemyelination,monthstoyearsafter minimallyconsciousstate)hasbeenextensivelydescribedat injury. These include findings of increased water diffusion postmortem [2–4]. Diffuse disruption of subcortical white as measured by mean diffusivity (MD) and a reduction matteris the most commonpostmortemfindingin victims in the directionality of diffusion as measured by fractional of TBI associated with impaired consciousness [2]. DAI anisotropy (FA) on DTI [5]. These findings, in conjunction and thalamic damage were the most common postmortem with the apparent loss of subcortical white matter volume, structural abnormalities reported in a case series of 35 suggest that acute edema may be a potential early marker 2 NeuralPlasticity ofposttraumaticdeteriorationthatultimatelyimpairsaxonal daysaftertheinitialinjury);thesecondscanwasperformed integrity in the chronic state [5]. Few longitudinal studies approximately1yearafteradmission(689.0±272.2daysafter have examined temporal evolution of white matter damage theinitialinjury). after DAI in humans [6–9]. However, the acute scans were Furthermore, we prospectively recruited 8 healthy nor- collected,onaverage,withintwomonthsafterinjury;smaller malvolunteers(2malesand6females)forcomparison.The time windows are necessary to obtain a more thorough agerangeofthehealthyparticipantswas32–60(45.5±9.1) understandingoftheevolutionofwhitematterdamage.Fur- years(Table2). ther, several studies have documented correlation between decreased FA in several brain regions and unfavorable out- 2.2. Standard Protocol Approvals, Registrations, and Patient comesinpatientswithsevereTBI[8,10,11].Arecentwhole Consent. This study was conducted in compliance with the brain WM analysis of DTI parameters revealed an increase ethicalprinciplesforbiomedicalresearchonhumansubjects in axial diffusivity (AD) and radial diffusivity (RD) in the enshrined in the Declaration of Helsinki and informed acute phase and a positive correlation of RD with severity consent regulations. Approval from the institutional ethics ofinjury[5].LongitudinalanalysisshowedreductioninFA committee was obtained prior to the initiation of the and AD, but not in RD [5]. This study [5] examined the study. evolution of white matter integrity from acute to chronic stages of DAI due to TBI. Data from this study suggest 2.3. PDC Assessment. PDC was assessed using the Kohnan complicatedmild-to-severeTAIresultsinsignificantedema score,whichmeasurestheseverityofconsciousnessdisorder thateventuallyresolvesleavingbehindacompromisedwhite fromasevere,persistentvegetativestate(Appendix[12]).The matter microstructure. The data [5] also suggest that white Kohnanscorewasdevelopedatourinstitutiontoresolvethis matter compromise after DAI is a process involving white issue.Theunidimensionalityandhigherintra-andinterrater matterdemyelinationaswellasaxonaldamagethatmaybe reliability of this score have previously been reported [12]. present not only in the early stage but also in the chronic The score is based on seven parameters, each of which is stage[5].However,themechanismthatexplainsthisfinding subdivided into 5 grades: extreme (10 points), severe (9 is still unclear. DTI still appears to be capable of detecting points),moderate(7or8points),mild(5points),andslight(0 microstructuralchangesafterDAI. points).Weadditionallyassessedgeneralfunctionalrecovery Patients with severe PDC, such as those in a vegetative usingtheExtendedGlasgowOutcomeScale(GOSE)(range state,typicallyhaveunfavorableoutcomesalthoughgradual, 1–8; higher scores indicate superior functional outcomes). subtle,andminorclinicalchangesareonrecord.Inthelast These assessments were performed at admission and at 2 2 years, our institution provided inpatient care to patients yearsafteradmission. with prolonged disorders of consciousness (PDC) due to TBI. The therapeutic modalities include standard nursing 2.4. Image Acquisition. MRI was performed using a 3.0T care, physical therapy, and occupational therapy, as well as Signa Excite HD scanner (General Electric, Milwaukee, otheralternativetreatmentmodalitiessuchasmusictherapy, WI, USA). The parameters for DTI were as follows: echo aroma massage, and exposure to natural environment (i.e., ∘ time, 59ms; repetition time, 9,000ms; flip angle, 90 ; slice feelingthesunlight,blowingwind,andexposuretoseasonal thickness, 3mm with no gap; field of view, 28.8 × 28.8cm; temperature changes). Indeed, a few patients have shown acquisitionmatrix,96×96;imagematrix,256×256witha slight positive reactions during inpatient residency at our voxel size of 1.125 × 1.125 × 3.0mm; number of excitations, institution. 1;andbandwidth,250kHz.Imageswereobtainedusing15- In this study, we sought to identify potential predictors of the degree of recovery from PDC over a period of 2 directionaldiffusionencoding(𝑏value,1,000s/mm2ineach years,usingDTIparametersinwholebrain.Weexaminedthe direction)andonesetofimageswith𝑏=0s/mm2. longitudinal alterations in anatomical connections of white Atotalof46axialsectionscoveringtheentirecerebrum matter in these patients and explored potential association wereobtained.ThemostinferiorDTIsliceswerepositioned ofmicrostructuralimagingbiomarkersinwholebrainwhite atthemedullaoblongataduringacquisition. and gray matter with clinical markers of potential clinical relevance. 2.5.ImagePreprocessing. AllDTIdatawereprocessedusing theFSLsoftwarepackage(theOxfordCentreforFunctional 2.Methods MagneticResonanceImagingoftheBrainSoftwareLibrary [13]). DTI images were skull-stripped using the Brain 2.1.Patients. Weretrospectivelyrecruited14patientsatour ExtractionTool(BET)intheFSL.Theimageswerecorrected institution that had chronic severe PDC resulting from usingtheEddyCorrectprogramoftheFSLpackagetoadjust traffic accident-related brain injury. All patients with PDC fortheeffectsofheadmovementandeddycurrents.FA,MD, underwent3TMRIstudiesatadmissionandaftercompletion AD, and RD maps were generated using dtifit program in of1yearoftreatmentatourinstitution.Meanage(±SD)of theFSL.Lastly,wecalculatedthemeanFA,MD,AD,andRD patientswas58.6±19.3years;themeanduration(±SD)from andcountedthenumberofvoxelsinwhichFAvalueswere admissiontostudyrecruitmentwas339.8±191.7days.The >0.4 in the whole brain (VsFA0.4) using fslstats program clinicalcharacteristicsofpatientsarepresentedinTable1.The implementedintheFSL.Weassumedthatusingwholebrain first DTI scan was performed at admission (345.6 ± 192.6 methodaffectednotonlywhitematterchangesbutalsogray NeuralPlasticity 3 Degreeofimprove-mentfromprolongedconscious-ness∗disorders2 29 −1 7 2 421 29 1 3 10 1 2 21 rmn Kohnancoreafteyearfrodmissio 63 5 68 56 62 6434 0 62 64 52 64 65 34 s1a n Kohnanscoreatdmissio 65 34 67 63 64 6855 29 63 67 62 65 67 55 a ermn ftoo ury. GCSEa1yearfradmissi 2 3 2 2 2 23 3 2 2 2 2 2 3 nj ni aton ai Esi br CSmis 2 3 2 2 2 22 3 2 2 2 2 2 2 eto Gad u disordersd Daysuntilthesecondscanfrominjury 768 548 636 416 885 591396 286 580 1173 779 849 1200 540 s nsciousnes Daysuntilthefirstscanfrominjury 415 266 311 135 629 158232 149 228 490 360 400 807 258 o prolongedc Daysuntiladmissionfollowinginjury 407 264 296 126 629 155230 147 226 482 350 391 798 256 Table1:Clinicalprofilesofpatientswith Diagnosis Rightacutesubduralhematoma,cerebralcontusionTraumaticsubarachnoidhemorrhage,pneumocephalus,diffuseaxonalinjuryTraumaticsubarachnoidhemorrhage,diffuseaxonalinjury,brainstemcontusionCerebralcontusion,traumaticsubarachnoidhemorrhage,diffuseaxonalinjury,brainstemcontusionLeftsubduralhematoma,traumaticsubarachnoidhemorrhage,intracerebralhemorrhageTraumaticsubarachnoidhemorrhageTraumaticsubarachnoidhemorrhage,diffuseaxonalinjuryTraumaticsubarachnoidhemorrhage,leftintracerebralhemorrhageTraumaticsubarachnoidhemorrhage,cerebralcontusion,leftintracerebralhemorrhageLeftintraventricularhemorrhage,leftintracerebralhemorrhage,diffuseaxonalinjuryCerebralcontusion,intraventricularhemorrhage,brainstemcontusionTraumaticsubarachnoidhemorrhage,diffuseaxonalinjury,cerebralcontusionRightacutesubduralhematoma,traumaticsubarachnoidhemorrhage,cerebralcontusion,diffuseaxonalinjuryTraumaticsubarachnoidhemorrhage,cerebralcontusion,leftcerebralhemorrhage hnanscorefromadmissiontoafter1year. o Gender Female Male Male Female Female MaleFemale Male Female Male Male Male Female Male nceinK e Age(y) 75 60 68 68 78 8644 58 77 31 56 64 23 33 differ e h t 1 2 3 4 5 67 8 9 10 11 12 13 14 ∗is 4 NeuralPlasticity DifferenceinRD−32×[10mm/s]fromthefirsttothesecondscan −0.120.06−0.05−0.05−0.05−0.10−0.04−0.040.01−0.070.05−0.07−0.020.30 2m/s]ond RD−3×[10matthesecscan 1.491.251.301.271.441.331.051.231.491.391.141.341.361.28 diffusivity. 2m/s]scan adial RD−3mefirst 1.371.311.261.221.391.231.011.191.491.331.181.281.341.58 RD:r etobraininjury. DifferenceinAD−32×[10mm/s]×[10fromthefirstatthtothesecondscan −0.170.11−0.03−0.05−0.07−0.060.020.140.01−0.090.18−0.060.040.41 AD:axialdiffusivity; ssdisordersdu AD−32×[10mm/s]atthesecondscan 2.001.711.771.711.971.891.461.672.001.831.621.801.821.86 meandiffusivity; onsciousne AD−320mm/s]hefirstscan 1.831.821.741.661.901.841.481.812.021.741.801.741.862.27 brain;MD: dc ×[1att ole e h withprolong DifferenceinMD−32×[10mm/s]fromthefirsttothesecondscan −0.140.08−0.04−0.05−0.06−0.09−0.020.020.01−0.070.09−0.070.000.34 an0.4inthew s h arameterofpatient MD−32×2[10mm/s]m/s]atthesecondscanscan 1.661.401.461.411.621.521.181.381.661.541.301.501.511.47 otropyvaluegreatert 2:Eachdiffusionp DifferenceinMDVsFA0.4−3×fromthe[10mfirsttotheatthefirstsecondscan−15191.5281921.4849831.4235771.369651.56219771.431.178618444801.39−19871.671.476167322121.3935801.4385241.5297381.81 withafractionalanis Table VsFA0.4atthesecondscan 2341439756307502669030802555012909439949260242184440235338541771046882 ofvoxels VsFA0.4atthefirstscan 2189547948357333026731767774783771284429240372801172447374342623456620 4:number DifferenceinFAfromthefirsttothesecondscan 0.000.010.010.010.000.040.020.070.000.000.050.010.030.00 py;VsFA0. o FAatthesec-ondscan 0.210.220.210.210.220.250.220.210.210.190.240.210.200.25 nisotr a FAatthefirstscan 0.210.240.220.220.220.290.240.280.210.190.290.220.220.26 onal ber acti m r f Nu 1234567891011121314 FA: NeuralPlasticity 5 matter and ventricles. To eliminate these effects, we chose No significant correlations were observed between the themethodofVsFA0.4thatselectsonlythevoxelwithhigh degree of recovery from PDC and age. Kohnan score was FAvalues. stronglyassociated(𝑟=−0.76,𝑃=0.002)withthedegreeof recoveryfromPDC.AmongtheDTIparameters,significant 2.6. Statistical Analysis. Statistical analyses were performed correlations were observed between the degree of recovery using the Statistical Package for the Social Sciences (SPSS) from PDC and FA (𝑟 = 0.60, 𝑃 < 0.05) and VsFA0.4 at 24.0 for Mac (IBM SPSS, Chicago, IL, USA). Comparisons thefirstscan(𝑟 = 0.68,𝑃 = 0.008);however,nosignificant over time for group Kohnan scores, GOSE, FA, VsFA0.4, correlationwasobservedbetweentheMD,AD,andLDatthe MD, AD, and RD were conducted using the paired 𝑡-test first scan (Table 6). In the longitudinal DTI parameters, no or Wilcoxon rank-sum test according to the results of the significantcorrelationswereobservedbetweenthedegreeof Shapiro–Wilk test. The Spearman rank-correlation coeffi- recoveryfromPDCanddifferenceinFA,MD,andRDover cientwasusedtoevaluatetherelationshipsbetweenage,time time(Table6).However,asignificantpositivecorrelationwas ofadmissionfrominjury,degreeofrecoveryfromPDC(as observedbetweenthedegreeofrecoveryfromPDCandtime- determinedbychangeintheKohnanscoreduringthe2-year dependentchangesinAD(𝑟=0.544,𝑃<0.05)andVsFA0.4 periodafteradmission),andthediffusiontensorparameters. (𝑟 = 0.624, 𝑃 < 0.05) between the first and second scans These diffusion tensor parameters used for comparisons (Table6). were FA, VsFA0.4 MD, AD, and RD in the first scan and Variablesshowingasignificantassociation(Pvalue<0.1) the differences in the same parameters between the first were included in the Spearman correlation analysis. Thus, and the second scan. All univariate potential factors with day of institution admission from injury, Kohnan score at a 𝑃 value < 0.1 were entered into the multivariate linear thefirstassessment,FAatthefirstscan,VsFA0.4atthefirst regression model. In addition, variance inflation factors scan,differenceinVsFA0.4,andMDandADfromthefirstto werecomputedtoexaminethepossiblecollinearityproblem thesecondscanwereincludedinthemultivariateregression amongthepredictors.Stepwisemultipleregressionanalyses analysis. Stepwise multiple regression analysis revealed that wereperformedtoidentifythevariablesassociatedwiththe theKohnanscoreatthefirstscan(standardized𝛽 = −0.723, degreeofrecoveryfromPDC.Thealphalevelwassetto0.05 95% CI: 32.7–63.0, 𝑃 < 0.0001) and difference in AD over for all statistical tests and adjusted for multiple tests (e.g., time (standardized 𝛽 = 0.337, 95% CI: 4610.7–46541.3, 𝑃 < 𝑛 = 5,𝑃 > 0.01,comparisonofthemeanFA,MD,AD,and 0.05)accuratelypredictedthedegreeofrecoveryfromPDC RD)withBonferronicorrection. [adjusted𝑅2=0.841]. 3.Results 4.Discussion In this study, 12 patients had a GOSE score of 2 (vegetative We explored potential clinical predictors of the degree of state),and2patientshadGOSEscoreof3(severedisorder) recovery from PDC after 2 years of admission, with a atadmission.However,Kohnanscoresatadmissionshowed particularfocusontheDTIparameters.Ourresultsshowed morevariability(range:29–68).Theserangedfromminimum significantly decreased FA values and number of voxels consciousness disorder (<39) to complete vegetative state in which FA values were >0.4 (VsFA0.4) in whole brain, (>65).After2years,therewasnosignificantchangeinGOSE but MD, AD, and RD showed no significant change. In scores(𝑃 = 0.16,Wilcoxonrank-sumtest):10patientshad contrast, healthy participants did not exhibit such changes. aGOSEscoreof2,while4patientshadaGOSEscoreof3. Oncorrelationanalysis,KohnanscoreandFAandVsFA0.4, In contrast, a subset of PDC patients showed a significant thedifferenceofVsFA0.4,andADweresignificantlycorre- recoverybasedontheKohnanscore(58.9±12.3versus48.7± lated in monovariable analysis. Multiple regression analysis 22.7,𝑃<0.01;Wilcoxonrank-sumtest)(Table3).Themean revealed that each Kohan score in the first assessment and differenceinKohnanscoresatadmissionandatcompletion the difference in AD over time have statistically significant of2yearswas10.14±11.10. contributiontothedegreeofrecoveryfromPDC.Currently, In patients with PDC, FA, VsFA0.4, MD, AD, and RD tothebestofourknowledge,therearenoknownpredictors valuesinthefirstscanwere0.24±0.03,43715.14±20913.54, of long-term positive clinical response in patients with 1.47 ± 0.15 [×10−3mm2/s], 1.82 ± 0.18 [×10−3mm2/s], and PDC. Several clinicians were forced to provide long-term 1.30±0.14[×10−3mm2/s],respectively,whereasthoseinthe care without established specific clinical goals for patients second scan were 0.22 ± 0.02, 33036.07 ± 10413.59, 1.47 ± with PDC. Therefore, it is critical to develop predictors of 0.01 [×10−3mm2/s], 1.79 ± 0.15 [×10−3mm2/s], and 1.31 ± long-term changes elicited through long-term therapeutic 0.13[×10−3mm2/s],respectively(Table3).PatientswithPDC interventioninthesepatients.Ourresultsdemonstratethat showedsignificantchangesinFA(𝑃 = 0.006,paired𝑡-test) microstructural white matter changes occurred in patients and VsFA0.4 (𝑃 = 0.003, Wilcoxon rank-sum test) over with PDC, which suggests that the assessment of white time.However, therewere no significantdifferences in MD matter changes may help identify valid long-term outcome (𝑃 = 0.993,paired𝑡-test),AD(𝑃 = 0.506,paired𝑡-test),and predictorsinthesepatients. RD (𝑃 = 0.650, paired 𝑡-test) values between the first and DTI is based upon the diffusivity of water molecules, second scans (Table 4). In contrast, any significant change which varies in different tissues [14]. In white matter, it is of DTI parameters was not shown in the 8 normal healthy morelimitedinthedirectionsofdiffusion.Inhealthytracts, participants(Table5). theanisotropy(limiteddirectionalityofdiffusion)ishigher 6 NeuralPlasticity DifferenceinRD−32×mm/s][10fromthefirsttothesecondscan 0.880.920.890.880.830.850.920.86 2m/s]ond RD−3×m[10atthesecscan 1.251.311.261.281.221.231.311.26 usivity. ff RD−32×mm/s][10atthefirstscan 1.001.051.011.010.960.981.050.99 RD:radialdi DifferenceinAD−32×mm/s][10fromthefirsttothesecondscan 96457111993123996122068150473118282111993144917 xialdiffusivity; ants. AD−32×mm/s][10atthesecondscan 0.260.260.260.270.270.260.260.28 ffusivity;AD:a yparticip AD−32mm/s]0hefirstscan 0.890.910.880.880.860.860.750.86 D:meandi nnormalhealth DifferenceinMD−32×mm/s][10×[1fromthefirstatttothesecondscan 1.271.301.271.281.261.251.141.26 ewholebrain;M i h parameter MD−32×mm/s]10atthesecondscan 1.021.041.011.010.990.990.880.99 than0.4int Eachdiffusion MD[−32×[10mm/s]atthefirstscan 97531115720125776125151149240122442135897145240 pyvaluegreater Table3: DifferenceinVsFA0.4fromthefirsttothesecondscan 0.260.260.260.270.280.270.290.27 alanisotro VsFA0.4atthesecondscan 0.880.920.890.880.830.850.920.86 fraction a VsFA0.4atthefirstscan 1.251.311.261.281.221.231.311.26 elswith x DifferenceinFAfromthefirsttothesecondscan 1.001.051.011.010.960.981.050.99 berofvo m FAatthesecondscan 96457111993123996122068150473118282111993144917 0.4:nu FAatthefirstscan 0.260.260.260.270.270.260.260.28 y;VsFA p Gender FemaleFemaleFemaleFemaleFemaleFemaleMaleMale nisotro a Agember(years) 6049444354463236 fractional Nu 12345678 FA: NeuralPlasticity 7 Table4:Comparisonofdiffusiontensorparametersandconsciousnessdisorders. Firstscan Secondscan Diffusionparameters Standard Standard 𝑃values Mean Mean deviation deviation Kohnanscore∗ 58.86 12.30 48.71 22.69 0.001 GSCE∗ 2.14 0.36 2.29 0.47 0.157 Fractionalanisotropy 0.24 0.03 0.22 0.02 0.006 Numberofvoxelswithafractionalanisotropyvaluegreater ∗ 43715.14 20913.55 33036.07 10413.59 0.003 than0.4inthewholebrain Meandiffusivity(MD)[×10−3mm2/s] 1.47 0.15 1.47 0.01 0.993 Axialdiffusivity(AD)[×10−3mm2/s] 1.82 0.18 1.79 0.15 0.506 Radialdiffusivity(RD)[×10−3mm2/s] 1.30 0.14 1.31 0.13 0.65 ∗ Wilcoxonranktest. Table5:Comparisonofdiffusiontensorparametersinnormalhealthyparticipants. Firstscan Secondscan Diffusionparameters Standard Standard 𝑃values Mean Mean deviation deviation Fractionalanisotropy 0.26 0.07 0.27 0.01 0.13 Numberofvoxelswithafractionalanisotropyvaluegreaterthan0.4 122522.38 17745.24 127124.63 16594.75 0.15 inthewholebrain Meandiffusivity(MD)[×10−3mm2/s]∗ 1.01 0.03 0.99 0.05 0.40 Axialdiffusivity(AD)[×10−3mm2/s]∗ 1.26 0.03 1.25 0.05 0.23 Radialdiffusivity(RD)[×10−3mm2/s]∗ 0.88 0.03 0.09 0.05 0.57 ∗ Wilcoxonranktest. Table6:Correlationbetweenthedegreeofrecoveryfromprolongedconsciousnessdisorderandeachvalue. DegreeofrecoveryfromPCD Variable 𝑟 𝑃values (Spearmancorrelationcoefficient) Atthefirstscanorassessment Age −0.24 0.41 Dayofinstitutionadmissionfrominjury −0.48 0.086 Kohnanscore −0.76 0.002 Fractionalanisotropy 0.60 0.023 Numbersofvoxelswithafractionalanisotropyvaluegreaterthan0.4 0.68 0.008 Meandiffusivity −0.22 0.459 Axialdiffusivity −0.01 0.976 Radialdiffusivity −0.34 0.241 Thedifferencebetweenthefirstandthesecondscan Fractionalanisotropy 0.38 0.177 Numbersofvoxelswithafractionalanisotropyvaluegreaterthan0.4 0.62 0.017 Meandiffusivity 0.48 0.086 Axialdiffusivity 0.54 0.044 Radialdiffusivity 0.40 0.162 than that in the gray matter. This difference allows for the havedemonstratedthepotentialutilityofDTIforproviding calculationoffractionalanisotropy(FA)valuesfortissueand quantitative assessments of microstructural damage in TBI, thegenerationofwhitematterfibermaps.FArangesfrom0 inwhichDAIiscommon[1–11,14–16].Althoughthespecifics to1,where0representsisotropicdiffusion(orlackofdirec- arestillnotwellunderstood,FAisbelievedtobeinfluenced tional organization) and 1 represents anisotropic diffusion by many factors, including the degree of myelination and (ororganizedtissuesuchaswhitemattertracts)[15].Studies axonaldensityand/orintegrity[9,17–19]. 8 NeuralPlasticity Slight(0)(1)Capableofmovementwithintention(2)Capableofunassistedposturechange(partialchangeinclusive)(3)Movingwheelchairunassisted,evenifawkwardly Ingestingonownusingspoonawkwardly Exceptduringthenight,preevacuationandpreurinationcommunicationispossible (1)Capableofreadingeasywords(2)Capableofunderstandingsimplenumbers(3)WhenwatchingTV,responseandlaughterareapparent Mild(5)(1)Occasionalmovementtomeetanobject(2)Capableofraisingthearmsupwardormovingthemintheintendeddirection,thatis,faceorhead,imitatingapostureofthetester(1)Capableofunassistedingestionbyswallowing;masticationcouldbeawkward(2)Capableofingestingallthericegruelservedorchoppedfoodwithassistance(3)Attemptingtoreachmouthwithapassedspoonorputthefoodintomouthawkwardly(1)Forcedregularevacuatingandurinatingleadtothepreventionoffecalandurinaryincontinence(2)Communicatingthefactinacertainwayafterincontinence (1)Discriminatingcloserelativesfollowedbyafacialexpression(2)Favoritepicture,amongotherthings,inducesafacialexpression able7 GradeModerate(8/7) (1)Occasionalall/partialextremitymovementwithnointention(2)Extremitycouldbeparetic(3)Brushingawayreactionforpain (1)Capableofmasticating;evenifnot,almostcapableofassistedauroralingestionbyswallowing,thoughsometimeschoking(2)Insufficientperoralingestionrequirestubenutrition Afterincontinence,adispleasedlookorsomesignalisobserved,thatis,frequentsomaticmovement (1)Lookingstraighttowardthedirectionofthecall(2)FollowingamovingobjectorstaringataTV,althoughunderstandingisimpossible T Severe(9)(1)Almostabsentbutpartsoftheextremitiesmoveminutely(2)Partoftheextremityflexedandpartparalyzed(3)Painreflexornopainreflexwithclearlyfrowningface (1)Almostontubenutrition(2)Salivaswallowingormasticationisfound(3)Capableofattemptingslightperusalingestion,thatis,fruitjuice,custardpudding,andsoforth Slightsomaticmovementwhenevacuating/urinating (1)Eyesopened,blinkreflex(2)Nofollowingocularmovementandnofocusingeyesonanobject Extreme(10) (1)Absent(2)Acrocontracture(3)Painreflexbutslighttremblingandroughbreathing Totallyincapableofmasticatingandswallowing;ontubenutrition(gastric/nasalfeeding) Noobservedsomaticmovementwhenevacuating/urinating (1)Eyesnotopened(2)Eyesopened,noblinkreflex ms y hy Clinicalsympto Voluntarymovement Voluntaryingestion Fecalandurinarincontinence Ophthalmograpandvisualrecognition NeuralPlasticity 9 Slight(0) (1)Capableofvocalizingasimplewordresponse(2)Lipmovementcorrespondstowhatisasked Changeofexpression,suchascryingandsmiling,exactlymatchesanexpectedresponsetotheambientstimulation Mild(5) (1)Occasionalvocalizingofameaningfulword(2)Vocalresponsetocalls(3)Imitatingtalkingbythetesterundertracheostomy Changeofexpression,suchassmiling,crying,andanger,closelymatchesanexpectedresponsetotheambientstimulation 7:Continued. GradeModerate(8/7)(1)Ashortutterancethoughnotunderstandable(2)Occasionalinarticulatevocalresponsetocalls(3)Undertracheostomy,responsetocallsisthroughlipmovement Changeofexpressionisoccasionallyfoundinresponsetoambientstimulations e l b Ta Severe(9) (1)Groaning,amongothers,withoutmeaningfulutterances(2)Lipmovementobservedundertracheostomy Changeofexpression,suchassmiling,crying,andanger,isnotduetoambientstimulations er Vgs Extreme(10) (1)NovocalizingNolipmovementundtracheostomy oresponsetoambientndstimulationsandTnds,amongotherthin 2) Nouou ( ss s m o pt nd m a sy nges ofon Clinical Vocaliziutteranc Changeexpressi 10 NeuralPlasticity FAhasbeenshowntodecreaseinpatientswithmildand asaprognostictoolneedsfurtherinvestigationinstudieswith moderate/severebraininjury[1,4,5,11,14–16,19–28].Perez alargernumberofsubjects. etal.[5]reportedsignificantlylowerFAinthechronicphase In conclusion, on stepwise multiple linear regression of TBI as compared to that in healthy controls; in contrast, analysis, Kohnan score and the difference in AD showed AD, MD, and RD in chronic patients were significantly a significant association with the degree of recovery from higher than in healthy controls. Additionally, chronic FA PDC.Inotherwords,wedemonstrateevidenceoftemporal showed a positive correlation with processing speed [28]. microstructuralwhitematterchangesinpatientswithPDC; In this study, patients with chronic PDC had significantly DTI parameters are useful indices for assessment of white lower FA and VsFA0.4 at 2 years as compared to those at matteralterationsinthesepatients.Asanoninvasivemodal- admission. Our first scan data were collected 345.6 ± 192.6 ity, DTI provides in vivo quantitative pathophysiological daysafterinjury,whichcorrespondstothechronicstageof information.Trackingwhitemattermicrostructuralchanges whitematterdamage.Thus,ourresultssuggestoccurrenceof over time has the potential to measure neuroplasticity and microstructuralchangeoverthelongerterm.Onunivariate repair after TBI and may eventually be utilized to monitor correlationanalysis,FAandVsFA0.4atthefirstscansignifi- therapeuticresponses.Furtherresearchisrequiredtoinves- cantlycorrelatedwiththedegreeofrecoveryofPDC,whichis tigatetheleadsidentifiedinthisstudy. consistentwithpreviousstudies[5–8,10,11,14,20–29]where patients with higher FA showed good recovery. Temporal Appendix changeinVsFA0.4andADsignificantlycorrelatedwiththe degree of recovery from PDC. This probably indicates that SeeTable7. minor microstructural changes correlate with the degree of recovery from PDC. Several previous studies [6, 8, 10, 11, CompetingInterests 20, 25–29] have reported a positive association of FA with higher cognitive function and outcomes. However, in this Theauthorsdeclarethattheyhavenocompetinginterests. study,higherdifferenceofVsFA0.4,MD,andADpositively correlated with the degree of recovery from PDC. In other Acknowledgments words, a time-dependent decrease in VsFA0.4, MD, and AD may be related to a better outcome in PDC. In this This study was supported by a medical research grant on respect,ourresultsarenotinconsistentwiththoseofseveral traffic accidents from the General Insurance Association of previous reports [6, 8, 10, 11, 20, 25–29], which indicated Japan. This work was also supported by JSPS KAKENHI that a time-dependent decrease in FA was associated with Grantno.JP16H06280,Grant-in-AidforScientificResearch pooroutcomesasassessedbycognitivefunctionandGOSE. on Innovative Areas-Resource and Technical Support Plat- These contradictory findings may reflect the difference in forms for PromotingResearch “Advanced Bioimaging Sup- PDC severity between studies; most of our patients had GOSE scores of ≤3 and showed subtle and minor clinical port.” The authors would like to thank the patients and normalhealthyvolunteerswhoparticipatedinthisstudy.The changes.Althoughsignificantrecoverieswereobservedbased authorswouldalsoliketothanktheimagingstaff,particularly on Kohnan scores, the changes were not significant when TomohiroChiba,fortheirskilledMRIacquisition.Theyalso based on GOSE scores, which suggests that improvement thankEnagofortheEnglishlanguagereview. in our patients was lower than that reported in previous studies [6, 8, 10, 11, 20, 25–29]. Our subjects generally had more severe outcomes; all our patients had GOSE scores ≤ References 3, which indicates more severe disability than that among patientsinthepreviousstudies[6,8,10,11,20,25–29].Thus, [1] M. A. Warner, C. M. De La Plata, J. Spence et al., “Assessing spatial relationships between axonal integrity, regional brain interstudy differences in results may reflect DAI severity. volumes, and neuropsychological outcomes after traumatic Differences with respect to time elapsed since injury may axonalinjury,”JournalofNeurotrauma,vol.27,no.12,pp.2121– alsohavecontributedtothedivergentfindings;weincluded 2130,2010. patientswithPDCintheextendedchronicphase. [2] H. C. Kinney and M. A. Samuels, “Neuropathology of the In patients with PDC, the degree of recovery was very persistentvegetativestate.Areview,”JournalofNeuropathology small, as shown by the lack of change in GOSE scores. In andExperimentalNeurology,vol.53,no.6,pp.548–558,1994. our participants, induction of a severe inactive state due [3] J.H.Adams,B.Jennett,D.R.McLellan,L.S.Murray,andD.I. to brain injury might lead to secondary neurodegeneration Graham,“Theneuropathologyofthevegetativestateafterhead that might be detected by DTI. However, the underlying injury,”JournalofClinicalPathology,vol.52,no.11,pp.804–806, mechanism behind longitudinal alterations in white matter 1999. remains unclear. In addition, this study had some limi- [4] D. Ferna´ndez-Espejo, T. Bekinschtein, M. M. Monti et al., tations. The number of subjects was small, and they had “Diffusionweightedimagingdistinguishesthevegetativestate variouspathologicalstates,suchascontusion,subarachnoid fromtheminimallyconsciousstate,”NeuroImage,vol.54,no.1, hemorrhage, and intracranial hemorrhage. Thus, further pp.103–112,2011. longitudinal studies are warranted that combine DTI with [5] A. M. Perez, J. Adler, N. Kulkarni et al., “Longitudinal white volumetricmeasurementsandotherdetailedanalyses,such matterchangesaftertraumaticaxonalinjury,”JournalofNeu- asfunctionalconnectivityanalysis.ThepotentialofDTIuse rotrauma,vol.31,no.17,pp.1478–1485,2014.

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We investigated the clinical predictors of the degree of recovery in patients with prolonged disorders of with prolonged disorders of consciousness (PDC) due to have demonstrated the potential utility of DTI for providing . b ers. (3). W hen w atchin g. T. V. , resp onse an d lau gh ter are ap p
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