1
Usingneurocomputationalmodellingtoinvestigatemechanisms
underlyingsocio-economicstatuseffectsoncognitiveandbrain
development
MichaelS.C.Thomas1,2
1DevelopmentalNeurocognitionLab,CentreforBrainandCognitive
Development,Birkbeck,UniversityofLondon,UK2UniversityofLondonCentreforEducationalNeuroscience
Toappearin:S.Lipina,M.SoledadSegretin,M.,&E.Pakulak(Eds.)(2019).
Proceedingsofthe12thMindBrainandEducationSchool,Erice,Sicily:
Neuroscienceofpoverty.CLACSO.
Runninghead:NeurocomputationalmodellingofSESeffectsondevelopment
Addressforcorrespondence:
Prof.MichaelS.C.ThomasDevelopmentalNeurocognitionLabCentreforBrainandCognitiveDevelopmentDepartmentofPsychologicalScience,BirkbeckCollege,MaletStreet,BloomsburyLondonWC1E7HX,UKEmail:[email protected].:+44(0)2076316386Fax:+44(0)2076316312
2
Abstract
Thischapterproposestheutilityofonetoolwithincognitiveneuroscience–neurocomputationalmodelling–forunderstandingthemechanismsthatunderlietheeffectsoflowsocio-economicstatus(SES)oncognitiveandbraindevelopment.ThelargeempiricalliteratureinthisfieldmainlycomprisescorrelationaldatalinkingmetricsofSEStocognitiveoutcomes,educationaloutcomes,andmeasuresofbrainfunctionandstructure.Mechanisticmodelsarerequiredtounifythesedataandprovideafoundationforeffectiveintervention.Amulti-levelartificialneuralnetworkmodelofcognitivedevelopmentisdescribedthatsimulateseffectsofSESintermsofdifferencesincognitivestimulation,againstabackgroundofgeneticvariationincognitiveabilityacrossapopulation.Fiveempiricaleffectsaresimultaneouslycapturedbythemodel:gapsinIQacrossSESthatwidenwithdevelopment(vonStumm&Plomin,2015),increasingrestrictiveeffectsoflowSESonchildrenwithearlyhighcognitiveability(Feinstein,2003),highheritabilityofcognitiveability(Plominetal.,2016),geneticeffectsonsocialmobility(Ayorechetal.,2017),andnon-lineareffectsofSESonmeasuresofbrainstructure,suchascorticalsurfacearea(Nobleetal.,2015).Implicationsandlimitationsofthemodelarediscussed.Computationalmodelsareavaluabletooltocomplementothercognitiveneurosciencemethodsforunderstandingcausalpathwaysofpovertyoncognitiveandbraindevelopment.Keywords:socio-economicstatus;computationalmodelling;artificialneuralnetworks;cognitivedevelopment;behaviouralgenetics;brainimaging
3
Povertyisaboutpeople’slives.Inequality,oneofitsmajordrivers,isasocialissue.Cognitiveneuroscientistshavebecomeincreasinglyinterestedinhowbeingraisedinpovertyimpactschildren’sbrainandcognitivedevelopment.Buthowcanitbeusefultoreducepeopletoinstancesofindividualbrainfunction?Povertyistheresultofsocialstructuresandthereforeafocusonneurosciencewouldappeartobeadistraction(Farah,2017).
Thereareatleastthreereasonswhyacognitiveneuroscienceapproachmaybeuseful.First,asweshallsee,socioeconomicstatus(SES)–typicallymeasuredbyacombinationoffamilyincome,parentaloccupation,andparentaleducation–hasbeenfoundtocorrelatewithdifferencesinbrainstructure,brainfunction,cognitiveability,andeducationalachievement.However,manyfactorsco-occurwithlowSES(see,e.g.,Hackmanetal.,2015).Mothersmaybemorestressed,havepoorerdiets,andmoredrugexposurewhilepregnant;childrenmayberaisedinlessnurturing,morepolluted,andmoredangerousenvironments;theremaybelesssocialorneighbourhoodsupport,poorerschools,andlesssupportiveattitudestoeducation;childrenmayhavefewerresourcesandopportunitiesforcognitivestimulationandlearning.Thisarrayoffactorsmaynotallbeequallyresponsibleforproducinghealth,cognitive,andeducationaloutcomes.IfthebiologicalcausalpathwaysofSESeffectsareidentified,thiscanhelptotargetthemostefficientinterventionstoalleviatethedownstreameffectsofpoverty.Suchinterventionsoffershort-termmeasures,whilethelonger-termsocialgoalofreducingpovertycanbepursued.
Second,thereisastraightforwardsenseinwhichevidencethatpovertyaffectsthebraininmeasurablewaysisapowerfulmessagetopolicymakers.Abrainimageisworthathousandwords.Braindata,however,representadouble-edgedsword,becausepolicymakersmaybeliabletothinkthateffectsobservedonbrainstructureandfunctionarethenimmutable.Theyarenot,becauseweknowthatthebrainisplastic,andbehaviouralinterventionscanimproveoutcomes.Astudyofbrainmechanismsmustalso,therefore,emphasisethismessageandseektoidentifypathwaystoremediateobserveddeficits.
Third,workineducation,thesocialsciences,andthecognitivescienceshasgeneratedalargebodyofempiricaldataonoutcomesthatarecorrelatedwithSES.Butthesecorrelationaldataareopentomisunderstandingandmisinterpretationiftheunderlyingmechanismsarenotunderstood.Herearethreeexamplesofempiricaldataandthreerespectivepossibleinterpretations.
(1) Gapsinchildren’sIQs(cognitiveability)acrosslevelsofSESareevidentfrominfancyandthesegapswidenthroughchildhoodandadolescence(vonStumm&Plomin,2015).Someprocessmustbegettingworseacrosschildhoodtomakethegapswiden.
(2) Whenchildrenaresplitintobrighterandlessbrightgroupsaroundtwoyearsofageandthenfollowedup,overtimebrighterchildrenfrompoorerbackgroundsfallbackcomparedtotheirpeers,andbyage10,theyhavebeenovertakenbylessbrightclassmatesfromricherfamilies(Feinstein,2003).Withage,children’srankintheirclassisincreasinglyconstrainedbyenvironmentalfactorssuchasSES.Fromdatalikethese,policymakershaveconcludedthatearlypotentialislostthroughenvironmentalfactorssuchaspoorchildcare,poorearlyyearseducation,
4
poorschoolingandlackofaccesstohealthservices(HMGovernment,2003).
(3) Onewaytomeasuresocialmobilityistoassesswhetherchildrenreacha
higherlevelofeducationalattainmentthantheirparents.Onthismeasure,however,atleasthalfthevariabilitycanbelinkedtogenes(Ayorechetal.,2017).Geneticswouldseemtoplacelimitsonhowmuchsocialmobilitycanbeinfluencedbyinterventions.Dogenesrestrictwhetherchildrencanescapepovertythrougheducation?
ThischapteroutlinesonemethodologywithincognitiveneurosciencetoinvestigatethemechanismsunderlyingSESeffectsonbrainandcognition:multi-levelneurocomputationalmodelsofcognitivedevelopment.Themodelpresentedherewasappliedtoeachoftheaboveempiricaleffects.Itgeneratedalternativeinterpretationsofeachsetofempiricaldata(Thomas,Forrester&Ronald,2013;Thomasetal.,2018;Thomas&Meaburn,2018).SESeffectsonbrainandcognitivedevelopmentWebeginwitha(very)briefoverviewoftheexistingempiricalliterature.WeknowthatdifferencesinSEShavemarkedeffectsoncognitivedevelopment(Farahetal.,2006).Theseeffectsarenotuniformacrossallareasofcognition,butareparticularlymarkedinthedevelopmentoflanguageandcognitivecontrol(oftenreferredtoas‘executivefunctions’).HackmanandFarah(2009)consideredthesedifferentialeffectsintermsofrelativelyindependent,anatomicallydefinedneurocognitivesystemsinthebrain.StrongesteffectsofSESwereobservedforthelanguagesystem(leftperisylvianregions)andtheexecutivesystem(prefrontalregions,decomposedintoworkingmemorysystem[lateralprefrontal],cognitivecontrol[anteriorcingulate]andrewardprocessing[ventromedialprefrontal]).SESexplained32%ofthevarianceinthelanguagecompositebehaviouralmeasure,6%incognitivecontrol,and6%inworkingmemory.
EffectsofSEShavebeenobservedonmeasuresofbrainstructureusingmagneticresonanceimaging.Forexample,Nobleetal.(2015)reportedeffectsoffamilyincomelevelsoncorticalsurfaceareainacross-sectionalsampleof1099childrenintheUSAaged3-20years.Therelationshipwasnon-linear,withthestrongesteffectsobservedinthelowestincomefamilies;differencesinincomeathigherlevelswereassociatedwithsmallerchangesincorticalsurfacearea.However,SESonlyexplainedafewpercentagepointsofthevariance;therewasagreatdealofvariationinbrainstructuremeasuresnotexplainedbySES.Notably,thestrongesteffectsofSESonbrainstructurewerefoundinregionssupportinglanguage,reading,executivefunctionsandspatialskills,consistentwithbehaviouralevidence.
SEShasalsobeenfoundtoimpactonneuraldevelopmentatmuchearlierages.Betancourtetal.(2016)examinedtherelationshipbetweenSESmeasures(income-to-needsratioandmaternaleducation)inasampleofAfrican-Americanfemaleinfantsaged5weeks.TheyobservedthatlowerSESwasassociatedwithsmallercorticalgreyanddeepgreymattervolumes,pointingtothebiologicalembeddingofadversityveryearlyindevelopment.
5
Thelinkbetweenbrainstructureandfunctionisindirectandnotwellunderstood.Nevertheless,researchershaveobserveddifferencesinbrainfunctionassociatedwithSESbothwithfunctionalmagneticresonanceimaging(regionaloxygenatedbloodflowdifferences)andwithelectrophysiology(measurementofvoltagepotentialsonthescalpassociatedwithneuralactivity).Forexample,usingfunctionalmagneticresonanceimaging,Raizadaetal.(2008)foundthattheweakerlanguageskillsobservedin5-year-oldchildrenfromlowerSESbackgroundswereassociatedwithreducedhemisphericfunctionalspecialisationinleftinferiorfrontalgyrus.Specialisationtothelefthemisphereisamarkerofthefunctionalmaturationoflanguagesystems.Usingelectrophysiologywithasampleof3-8yearolds,Stevens,LauingerandNeville(2009)demonstratedreducedneuralsignaturesofselectiveattentioninchildrenfromlow-SESfamilies(indexedbymaternaleducation).Inanauditoryprocessingtaskwherethechildrenhadtoattendselectivelytooneoftwosimultaneouslypresentednarrativestories,theneuralprocessingdifferencesthatcharacterisedthelow-SESchildrenwererelatedspecificallytoareducedabilitytofilteroutirrelevantinformation.
Thesefewexamplesillustratethegeneralmethodsfromafastgrowingneuroscienceliterature(forwiderreviewsofstructuralandfunctionalbrainimagingandSESseeFarah,2017;Pavlakisetal.,2015).Importantly,cognitiveneuroscientistsdonotyetunderstandthecausalpathwaysofthesecognitiveandbraineffects,notleastbecausetheSESmeasurerepresentsadistalcauseanddoesnotisolatetheproximalcausesthatinfluencecognitiveandbraindevelopment.SomedifferencesassociatedwithlowSESmayrepresentdeficits(e.g.,poorerbraindevelopmentcausedprenatallybypoormaternalnutritionorpostnatallybychronicstress).Othersmayrepresentadaptations(e.g.,apparentpoorerselectiveattentionmayreflecthighervigilanceappropriatetoamoredangerousenvironment;apparentlyimpulsivitymayreflectmaximisingshort-termrewardsbecauselong-termrewardshaveprovedunreliable).
Hackman,FarahandMeaney(2010)classedpotentialcausalmechanismsintothreetypes,basedonresearchnaturalisticresearchwithhumansandexperimentalresearchwithanimalmodels:(1)thoseoperatingprenatallyonfoetaldevelopment,(2)thoseaffectingpostnatalparentalnurturing,and(3)thoseaffectingpostnatalcognitivestimulation.Explanatorymodelstendtodistinguishwhatislostfromlow-SESfamilies(resources,goodnutrition,learningopportunities)fromwhatisadded(stress,toxins,childhoodadversityexperiences)(Sheridan&McLaughlin,2016).Causalexplanationsarelikelytobecomplex:allthreeclassesoffactorscouldberesponsible;orcombinationscoulddifferperbrainsystem.Thecombinationoffactorsmaydependondetailsofthespecificpopulationandlocalfactors,intermsofabsolutelevelsofresources/poverty,wheretheeconomicandenvironmentalrestrictionslieinaparticularsociety,andtherelativelevelsofpoverty(inequality).
Againstthisbackgroundof(hopefully)remediableenvironmentaleffects,wealsoknowthatinWesternsocieties,afairproportionofchildren’svariabilityincognitiveandeducationaloutcomes,andindeedbrainstructure,canbepredictedbytheirgenotypes–thatis,abilitiesare‘heritable’(Plominetal.,2016).Thetermheritableisoftenmisunderstoodtorelatetonecessaryoutcomes(becausechildren’sgenesaren’tchangeable)butthisinterpretationisincorrect.Indifferentenvironments,geneticeffectsmaybeincreasedor
6
decreased:observedgeneticeffectsarenotinevitableordeterministic.Theyshowwhatis,notwhatcanbe.Nevertheless,wecantakemeasuresofheritabilityascurrentsummarystatistics:giventhecurrentrangeoffamilyandeducationalenvironmentsthatchildrenareraisedin,andwhichshapetheworldtheycanexplore,heritabilityisastatisticthatcapturehowmuchvarianceiscurrentlybeingpredictedbygeneticsimilarity.
Therehasbeenaflurryofnewfindingswithrespecttolifeoutcomes,SESandbehaviouralgenetics.Forexample,researchershavereportedthateducationalachievementis‘highly’heritable,withasmuchas60%ofthevarianceinexaminationresultsin16yearoldsexplainedbygeneticsimilarity(Krapohletal.,2014).Thesegeneticeffectsappeargeneralacrosstopicsratherthanspecifictodifferentacademicsubjects(Rimfeldetal.,2015).DirectmeasuresofDNAvariationhavepointedtoregionsofthegenomeassociatedwithacademicachievement,albeitwithcoarseeducationalmeasuresastheoutcome(yearsofschoolingcompleted)andsmalleramountsofvarianceexplained(e.g.,11-13%variance;Leeetal.,2018).Notably,variationsinSEShavebeenreportedtopartlyalignwithgeneticvariation(e.g.,Trzaskowskietal.,2014).Moreover,socialmobility–whereanindividual’sSESdiffersfromthatoftheirparents,suchasineducationalattainment–hasitselfbeenreportedaspartlyheritable,withonestudyobservingthatjustunderhalfofthevarianceinsocialmobilitywaslinkedtogeneticvariation(Ayorechetal.,2017),andanotherreportingthatdirectmeasuresofDNAvariationcouldexplainaround3%ofthevarianceinupwardeducationalmobility(Belskyetal.,2018).
Evidenceoftheroleofgeneticvariationininfluencingcognitive,educationalandlifeoutcomes,andofthepossiblecorrelationsbetweenthegeneticvariationandSESgradients,drivesthedebatebetweensocialcausationandsocialselectionaccounts(Farah,2017).Underasocialcausationaccount,SESeffectsandtheirpersistenceacrossgenerationsaredrivenbytheenvironmentsinwhichchildrenareraised.Underasocialselectionaccount,SES-relateddifferencesinbrainandcognitionareundergeneticcontrol,withpopulationstratificationofgenotypesaccordingtoSES.
Ourconcernhereisnotthecompetingmeritsoftheseaccounts,butmerelythechallengeposedbyrespectivedataontherolesofenvironmentalfactorsandgeneticfactorsonbrainandcognitivedevelopment.Howcanthesebodiesofempiricaldatabereconciledintoacoherentcausalaccount?Giventhecomplexityandmulti-facetednatureofbothbraindevelopmentandcognitivedevelopment,howcanwebegintoformulateandtestcompetingexplanationsforthepathwaysbywhichSESeffectsoperate–andtheirimplicationsforintervention?Evenunderasocialcausationaccount,onemustaccepttheroleofgeneticvariationincontributingtodifferencesinoutcomes.Evenunderasocialselectionaccount,onemustacceptthatdifferencesinexperienceswillinfluencedevelopment.NeurocomputationalmodellingOnemethodusedincognitiveneurosciencetoformulateandtestcausalaccountsiscomputationalmodelling.Modelscanbeformulatedatdifferentlevelsofdescription:ofindividualneurons,ofcircuitsofneurons,orofwholebrainsystems.Ineachofthesecases,modelsseektocaptureempiricalevidence
7
onpatternsofbrainactivationoranatomicalstructure.Modelscanalsobeformulatedatacognitivelevel:althoughcertainconstraintsmaybeincludedfromneuroscienceaboutthenatureofcomputation,thetargetisthentocaptureempiricaldataonhigh-levelbehaviour.Multi-levelmodelsincludeconstraintsfromseverallevelsofdescriptionandseektocapturedatabothatthelevelofbrainandbehaviour(Thomas,Forrester&Ronald,2016).Modelsmaybeconstructedtosimulatethecharacteristicsofthestaticpropertiesofasystematagivenpointintime,ortheymaybeconstructedtocapturedevelopmentalchange,wheretrajectoriesofbehaviouraresimulatedastheyalterovertime(Elmanetal.,1996;Mareschal&Thomas,2007).
Howmightweconstructamulti-levelcomputationalmodeltoexplainSESeffectsonbrainandcognitivedevelopment?Minimally,weneedtostipulateaneutrallyconstraineddevelopmentalmechanismwhichacquiresatargetbehaviourthroughinteractionwithastructuredlearningenvironment;weneedtostipulatehowgrowthofthatdevelopmentalmechanismandinteractionswiththestructuredlearningenvironmentmightalterasaconsequenceofvariationsinSES;andweneedtostipulateseparatelyhowgeneticvariationmightalterthepropertiesofthedevelopmentalmechanism,forexampleintermsofhowitgrows,operates,andrespondstostimulation.Thomas,ForresterandRonald(2013)beganthislineofresearchbyconstructinganartificialneuralnetworkmodeloftheeffectsofvariationinSESonlanguageacquisition,focusingonthespecificdomainofinflectionalmorphology(thatis,alteringthesoundsofwordstochangetheirmeaning,suchasinformingthepasttenseofaverb).Themodelwasabletosimulatehowchildren’slanguageskillsalteredacrosstheSESgradient,aswellasgeneratingtestablepredictionsaboutchildren’slanguageoutcomes(seealso,Thomas&Knowland,2014;Thomas,2018,forthemodel’sextensiontoconsideringdelayandgiftedness).Thomas,ForresterandRonald(2016)andThomas(2016)showedhowthesamemodel,treatedmoreabstractly,couldbeextendedintoamulti-levelformat,toincorporateageneticlevelofdescriptionandindicesofbrainstructureaswellasbehaviour.Inthefollowingsections,wedemonstratehowthemodelcanbeappliedtoconsideringSESeffectsonbrainandcognitivedevelopment(Thomasetal.,2018;Thomas&Meaburn,2018).ModelassumptionsandsimplificationsAschematicofthemodelisshowninFigure1.Inthemodel,cognitivedevelopmentoccursthroughtheinteractionofanexperience-dependentmechanismwithastructuredlearningenvironment.Themechanismisanartificialneuralnetwork,whichembodiescomputationalconstraintsfromneuralprocessing(Elmanetal.,1996).Theseconstraintsare,respectively,anetworkofsimplenon-linearintegrate-and-fireprocessingunits,distributedrepresentationsofknowledge,associativeerror-drivenlearningalteringnetworkconnectivitystrengthsandunitthresholds,andnetworkdevelopmentincludingphasesofgrowthandpruning.Thestructuredlearningenvironmentisdrawnfromthefieldoflanguagedevelopment.Thesingleprocessingstructureisassumedtoliewithinalargercognitivearchitecturebutisnotintendedinthismodeltocorrespondtoanyspecificbrainregion.
8
Themechanismlearnsinput-outputmappingsthatdrivebehaviourrelevanttoitsdomain.Accuracyofinput-outputmappingsisusedasameasureofbehaviouralperformance.Structuralpropertiesoftheartificialneuralnetwork,includingthetotalnumberofconnectionsandthetotalstrengthofexcitatoryandinhibitoryconnections,areusedasanaloguesofbrainstructuremeasuressuchascorticalthickness,corticalsurfacearea,greymattervolume,andwhitemattervolume(Thomas,2016).
Individualdifferencesfactors,suchasSESandgeneticvariationarenotconsideredinisolationbutintermsofhowtheymodulatetheabovespecies-universalmechanismsthatunderpindevelopmentacrossallchildren.Inthissense,themodelconstruesindividualdifferencesasoperatingwithinadevelopmentalframework(Karmiloff-Smith,1998).VariousoptionsareavailabletoimplementtheeffectofSES:asamodulationofthelevelofstimulationavailableinthelearningenvironment(seeThomas,Forrester&Ronald,2013);asamodulationofthegrowthofthenetworkanditsprocessingproperties;orbothoftheseeffectsoperatinginacorrelatedfashion(seeThomasetal.,2018).Eachnetworkrepresentsasimulatedchildundergoingdevelopmentinafamilyenvironment.Eachfamilyisassignedavalue,between0and1,torepresentitsSES,whichisthenusedtomodulatethelearningenvironmentorthenetworkstructure.
Geneticvariationisassumedtooperatebyinfluencingtheneurocomputationalpropertiesoftheprocessingmechanism,intermsofitscapacity,plasticity,andnoisinessofprocessing(thesearebroadcharacterisationsoftheroleofalargersetofparameters,showinTable1).Sincebehaviouralgeneticresearchoncognitionhasindicatedthatcommongeneticvariationamountstolargenumbersofsmallgeneticeffectsonawiderangeofneuralproperties,geneticvariationisimplementedviaapolygeniccodingscheme:anartificialgenomecontainssetsofgeneswhicheachinfluencevariationonaneurocomputationalproperty(14properties,eachinfluencedby8-10genes);thecombinationofsmallvariationsacrossalargesetofpropertiesproducesnetworkswithanormaldistributionoflearningproperties(Thomas,Forrester&Ronald,2016,fordetails).Thecombinationofsimulatedchildrenwithdifferentlearningabilities,interactingwithenvironmentswithdifferentlevelsofstimulation,producesapopulationofchildrenwithdifferentdevelopmentaltrajectoriesinbothbehaviourandbrainstructure.Atanypointindevelopment,cross-sectionscanbetakenofbehaviourorstructureacrossthepopulation,andcorrelationsderivedtoSESorgeneticvariation.
9
Figure1.StructureofneurocomputationalmodelsimulatingSESeffectsoncognitiveandbraindevelopment.Anexperience-dependentdevelopmentalmechanism(artificialneuralnetwork)interactswithastructuredlearningenvironmenttoacquireacognitivebehaviour.Themulti-levelmodelembodiesconstraintsatthelevelofgenes,brainstructure(connections,units),behaviour,andenvironment.Individualdifferencesfactors(SES,geneticvariation)areconsideredwithrespecttohowtheymodulatespeciesuniversalmechanismssupportingcognitivedevelopment.SimulationdesignAsinglenetworkwastrainedonitsfamily-specificsetofinput-outputmappings.Peritssourcecognitivedomain,inthiscasetheinputswerephonologicalrepresentationsofverbstemsandtheoutputswereinflectedformsofEnglishverbs.Lifespandevelopmentcorrespondedto1000exposures(or‘epochs’)ofthenetworktothetrainingset.Thetrainingsetcomprisedamaximumof500input-outputmappings.Thedevelopmentof1000individualchildrenwassimulated.Genomeswererandomlyinitialisedtoproducegeneticvariationinlearningabilityacrossthepopulation.Pairsof‘twin’networkswerecreatedwhicheithersharedthesamegenome(identical)orshared50%ofgenesonaverage(fraternal)andtwinpairsraisedinthesamefamily.Thisdesignenabledtheuseoftwincorrelationstocomputeheritabilitylevels.SESwasallowedtovarywidelyacrossfamiliestocapturethepotentialeffectsofpoverty.Inthesimulationsdescribedhere,SESwasimplementedasmodulationofthelevelofstimulationinthelearningenvironment,andwasallowedtovarybetween0and
StructuredlearningEnvironment
Experience-dependentdevelopmentalmechanismExperiencemodifiesprocessingStructurewhichmodifiesfunction
Behaviourdevelopsfrominteractionofmechanismwithenvironment
Geneticvariation
Socioeconomicstatus
(maybecorrelated)
Potentiallyinfluencesgrowthofmechanism
Poten
tiallyinfluence
s
learningenviro
nment
Influencesgrowth,capacity,plasticity,maintenanceofmechanism
Individualdifferencesfactors Speciesuniversalfactors
10
1.Afamilywithavalueof0.6wouldgenerateatrainingsetthatonlycontaineda(randomlysampled)subsetof60%ofthefulltrainingset(seeThomas,2016,forfurtherdetails,includingspecificationofneurocomputationalpropertiesandcalibrationoftheirrange;resultsarereportedfortheG-wideE-wideconditioninthatpaper).Simulation1:SESeffectsonIQchangeacrossdevelopmentThomasetal.(2018)firstconsidereddevelopmentaltrajectoriesofbehaviour.Thepopulationwassplitintothreegroups,thoseintheupperquartileofSES(trainingsetswith>75%ofavailableexperiences),thoseinthemiddletwoquartiles,andthoseinthelowestquartile(<25%ofavailableexperiences).Figure2(a)showsthelatentgrowthtrajectoriesofIQforchildrenfromlow,middle,andhighSESgroupsintheempiricaldataofvonStummandPlomin(2015),foraroundfifteenthousandUKchildrenfollowedfrominfancytoadolescence.Itshowsdivergingtrajectorieswithage.TheSESgapwidens.Figure2(b)showssimulateddataofIQscoresinthemodel,whereIQwascomputedaccordingtothepopulationdistributionateachmeasurementpoint[IQscore=((individualperformance–populationmean)/populationstandarddeviationX15)+100].Figure2(c)showsthedevelopmentaltrajectoriesofperformancewithoutthetransformationtoIQscores.Thesimulationisabletocatchthelowerinitiallevelsofperformanceattheyoungestage,aswellasthedivergenceofthetrajectoriesacrossdevelopmentaltime.
OnemightconcludefromtheempiricaldatathattheconditionsproducingSESdifferencesincognitivedevelopmentmustworsenovertimetoproducethedivergence.ThesimulationsreproducedthedivergingpatternwithaconsistentSESeffectovertime.Inthemodel,divergenceoccurredduetonon-lineartrajectoriesofdevelopment.IncreasinggapsbetweenSESgroupsdonot,then,necessarilyimplyworseningSEScausalfactors.
11
Figure2.(a)EmpiricallongitudinaldatafromaUKsampleoftwins(N=14,853children)plottingIQchangeoverdevelopmentfrominfancytoadolescence,splitbysocioeconomicstatusandshownseparatelybygender(reproducedwithpermissionfromvonStumm&Plomin,2015).HighSES=>1standarddeviation(SD)aboveSESmean;low=<1SDbelowSESmean;middle=<1SDaboveSESmeanand>1SDbelowSESmean.(b)SimulationdataplottingIQchangeacrosschildren’sdevelopmentwhereSESiscapturedbydifferencesincognitivestimulation.HighSES=upperquartile,MiddleSES=middletwoquartiles,LowSES=lowerquartile.(c)Equivalentmeanperformanceontask(proportioncorrect)forsimulatedSESgroups.(a)(b) (c)Simulation2:SESanddevelopmentaleffectsonpopulationrankorderThomasandMeaburn(2018)usedthesamemodeltosimulatetheanalysisreportedbyFeinstein(2003).Theempiricaldatafromthe1970BirthCohortSurveyarere-plottedinFigure3.Around1,300UKchildrenwereclassifiedintohigh(upperquartile)andlow(lowerquartile)cognitiveabilityat22monthsand
80
85
90
95
100
105
110
115
120
25 50 100 250 500 1000
IQ
Development
High
Middle
Low
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
25 50 100 250 500 1000
Performan
ce
Development
High
Middle
Low
12
thenfollowedlongitudinallyto10yearsofage,withhighSES(top24%)andlowSES(bottom13%)subgroupstrackedseparately.Childrenaredepictedbythemeanpopulationrankorderoftheirgroup,where100ishighperformanceand1islowperformance.Somewherebetween5and10yearsofage,initiallyhigh-ability/low-SESchildrenfellbelowtherankoflow-ability/high-SESchildren.Followingpublicationofthesedata,thefindingswerecriticisedontwogrounds.First,thattheydonotrepresentarealeffectbutinsteadregressiontothemeanofinitiallyextremescoresthroughmeasurementerror(Jerrim&Vignoles,2013).Second,thatthemostemotivefinding,ofthecross-overofhigh-ability/low-SESandlow-ability/high-SESgroupsbetween5and10,washardtoreplicateanddependedoncut-offsusedtodefinegroups;forexample,crossing-overwasmorelikelyunderlessextremedefinitionsofhighandlowcognitiveability(Washbrook&Lee,2015;e.g.,Figure1).Figure3.Longitudinalempiricaldatafromthe1970BirthCohortSurveyfollowingthepopulationrankofchildrenoncognitiveabilitytasks,splitbyability(high,low)at22months,andfamilysocio-economicstatus(re-plottedfromFeinstein,2003).Y-axisshowsmeanpopulationrankofeachgroup,whereahigherrankmarksbetterperformanceonage-appropriatecognitivetests.
Figure4depictsthecomputationalsimulationofthesedata(Thomas&
Meaburn,2018).Earlyintraining(25epochsoutof1000epochs),simulatedchildrenweresplitintohighandlow‘ability’groupsbasedonbehaviour(accuracyofinput-outputmappings).Highabilitywasdefinedaspopulationrank>650(where1000isgood,1ispoor),lowabilityaspopulationrank<350.ThesegroupsweresubdividedbySES,asameansplit(simulatedSESvaried0to1;highSES>.5,lowSES<.5).Performanceofthegroupswasthenfollowedoverdevelopment.Figure4(a)depictsthemeanpopulationrankofeachgroup.AsintheFeinstein(2003)data,high-ability/high-SESandlow-ability/low-SESgroupsbroadlyheldtheirmeanrank.High-ability/low-SESshoweddecliningrankand
0
10
20
30
40
50
60
70
80
90
100
22 40 60 120
Averagepo
sitio
ninth
edistrib
ution
MonthsofAge
HighSES,HighAbilityat22m(n=105)
HighSES,LowAbilityat22m(n=55)
LowSES,HighAbilityat22m(n=36)
LowSES,LowAbilityat22m(n=53)
13
low-ability/high-SESshowascendingrank,suchthatthegroupsconverged.Notably,theydidnotcrossover.Figure4(b)showsthesamedatabutforperformance.Itisincludedtoemphasisethatweareobservingmodulationsindevelopmentaltrajectories,andthatchangesinrelativerankpositionsmayexaggeratesmalldifferencesinindividualswhoareneverthelessallshowingdevelopmentalimprovementswithage.
Cruciallyhere,therewasnonoiseinthemeasurementofperformanceinthegroups.Theconvergenceofthetrajectories,atleastinthesimulation,cannothaverisenfromregressiontothemeanfollowingmeasurementerror(Jerrim&Vignoles,2013).Itisarealreflectionoftheoperationofconstraintsondevelopment.Figure4(c)takesthesamepopulationofchildrenbutnowaltersthedefinitionofhighandlowabilitytobelessextreme(highability:populationrank>500;lowability:populationrank<500)andthedefinitionofSESmoreextreme(high:SES>.75;low:SES<.25).Nowthetrajectoriesofhigh-ability/low-SESandlow-ability/high-SESdidcrossover.Thesimulationscapturedtheempiricalobservationthatthecrossoverpatternissensitivetogroupdefinitions(Washbrook&Lee,2015).
OnesimpleinterpretationoftheFeinsteindataisthatchangesinchildren’spopulationrankperformanceincognitiveabilitytestsstemfromenvironmentalcauses.Forthesimulation,wehaveavailabletousthefullsetofparametersthatinfluenceseachsimulatedchild’sdevelopmentaltrajectory:boththestipulatedenvironmentaleffect,intermsofthelevelofcognitivestimulation,andthestipulatedgeneticindividualdifferences,intermsoftheneurocomputationalpatternsofeachartificialneuralnetwork.Wecanthenusetheseparametersinamultipleregressionanalysistoseewhichpredictedpopulationrankchangeacrossdevelopment.
Wasalltherankchangeduetotheenvironmentalmanipulation?Table1showstheresultsofthismultipleregression,withtheenvironmentalparametermarkedinbold,andtherespectiveinfluenceofeachneurocomputationalparameterbelow.First,itisworthnotingthatinthesimulation,sinceenvironmentaldifferencesactedthroughoutdevelopment,theyinfluencedmeasuresofabilityevenattheearlystageofdevelopment,hereexplaining22.7%ofthevarianceatthefirsttimepoint.Earlymeasurementdoesnotgiveanunbiasedmeasureof‘genetic’abilityfreefromSESinfluences.Second,asexpected,environmentaldifferencesdidaccountforasignificantamountofvarianceinchildren’schangeinrankacrossdevelopment,upto10%atthefinaltimepoint.Butnotably,anumberofneurocomputationalparametersalsocontributedtochangeinrank.Theseincludedparametersinfluencingthecapacityandplasticityofthemechanism,andconsequentlytheshapeofthedevelopmentaltrajectory.
Inotherwords,themodelhighlightsthatchildrendevelopatdifferentrates.Somechildrenarelatebloomers,othersslowlaterindevelopment.Thiswillcausechangesinpopulationrankorderthatarenotsolelyrelatedtovariationsinenvironmentalstimulation.Itisnotnecessary,therefore,toconcludefromtheFeinsteinplotthattheonlycauseofchangesinchildren’spopulationrankisduetoenvironmentalcausessuchasSES.Inturn,thisimpliesthatnotallthechangeinrankwouldberemovedbyreducingSESdisparities.
14
Figure4.Simulationsoflongitudinalchangeinrankandchangeinperformanceacrossdevelopmentinthecomputermodel.Rank1000=best,rank1=worst.SESparametervariesbetween1(highest)and0(lowest).(a)Meanchangeinrankforhighandlowabilitygroupsdefinedattime1(epoch25),wherehighisrank>650andlowisrank<350,splitbySES,wherehigh>.5andlow<.5.(b)Equivalentperformanceontask(proportioncorrect).(c)Meanchangeinrankwherehighabilityistime1rank>500andlowabilityisrank<500,andwherehighSES>.75andlowSES<.25.(d)Equivalentperformanceontaskforthesegroupcriteria.
(a)
0100200300400500600700800900
1000
25 50 100 250 500 1000
Meanrnakinpop
ulation
Epochsoftraining(development)
HighSESHighAbility
LowSESHighAbility
HighSESLowAbility
LowSESLowAbility
00.10.20.30.40.50.60.70.80.91
25 50 100 250 500 1000
Meanpe
rforman
ceontask
Epochsoftraining(development)
HighSESHighAbility
LowSESHighAbility
HighSESLowAbility
LowSESLowAbility
01002003004005006007008009001000
25 50 100 250 500 1000
Meanrnakinpop
ulation
Epochsoftraining(development)
HighSESHighAbility
LowSESHighAbility
HighSESLowAbility
LowSESLowAbility
00.10.20.30.40.50.60.70.80.91
25 50 100 250 500 1000
Meanpe
rforman
ceontask
Epochsoftraining(development)
HighSESHighAbility
LowSESHighAbility
HighSESLowAbility
LowSESLowAbility
(c)
(b) (d)
15
Table1.Levelofenvironmentalstimulationandneurocomputationalparametersaspredictorsofdevelopmentalchangeinthemodel,measuredbyindividual’schangeinpopulationrankperformanceacrossdevelopment(scoresshowstandardisedbetacoefficientsfromalinearregressionmodel).Neurocomputationalparametersarelabelledaccordingtotheirapproximateprocessingrole.Bothenvironmentalstimulationandnetworkparametersexplainvarianceinrankchange(environmentismarkedbybold).Therightmostcolumnindicatespredictorsofwhetheranindividual’sperformance(rank)asanadultexceedstherankofthequalityoftheirenvironment,asanindicatorofsocialmobility.Time1=25epochsoftraining,Time2=50,Time3=100,Time4=250,Time5=500,Time6=1000. PredictorsofdevelopmentalchangeinPopulation
rankagainstTime1
Finalrank
vs.SESrank
Parameter Neuralnetwork
processingrole
Time2 Time3 Time4 Time5 Time6
Modelfit(R2) 0.181* 0.312* 0.368* 0.379* 0.384* 0.466*
SES Environment 0.158* 0.274* 0.332* 0.337* 0.333* -0.361*
Hidden Units Capacity -0.069+ -0.089* -0.079* -0.07* -0.053+ 0.356*
Architecture Capacity -0.185* -0.212* -0.171* -0.142* -0.129* 0.297*
Sparseness Capacity 0.028 0.037 0.036 0.032 0.036 0.016
Pruning Onset Capacity 0.044 0.074* 0.077* 0.074* 0.067* 0.061*
Pruning
probability Capacity 0.021 0.017 0.004 -0.002 -0.006 -0.007
Pruning
Threshold Capacity 0.033 0.013 0.006 0.023 0.025 -0.002
Learning
algorithm
Capacity /
plasticity -0.064+ -0.074* -0.107* -0.119* -0.138* 0.172*
Learning Rate Plasticity -0.148* -0.159* -0.177* -0.186* -0.199* -0.004
Momentum Plasticity -0.077* -0.091* -0.109* -0.108* -0.105* -0.089*
Weight variance Plasticity 0.006 0.004 0.033 0.043 0.052+ -0.1*
Unit activation
function
Plasticity /
signal -0.107* -0.147* -0.178* -0.184* -0.188* -0.053+
Noise Signal 0.019 0.036 0.069* 0.101* 0.116* -0.143*
Response
threshold Signal -0.223* -0.292* -0.304* -0.308* -0.309* 0.11*
Weight Decay Signal -0.004 -0.015 -0.011 -0.003 -0.003 -0.015
+ p < 0.05 * p < .01
16
Simulation3:GeneticconstraintsonsocialmobilityThemodelconsideredSESeffectsagainstthebackgroundofgeneticallyinfluencedvariationsinlearningability.Thus,thesesimulationswereabletocapturethehighheritabilityofbehaviour.Forexample,heritabilityofbehaviourshowninFigure4(a)atthefinalmeasurementpointwas51%underanadditivemodel,computedfromthetwindesign.Thegeneticcomponentalsoallowsthesimulationtoaddressdataonsocialmobility.Inthemodel,socialmobilityisdefinedasadevelopmentaloutcomethatisgreaterorlesserthantheSESofthefamilyinwhichthechildisraised(Thomas&Meaburn,2018).Thiscanbemeasuredasthedifferenceinpopulationrankorderofafamily’sSEScomparedtothesimulatedchild’spopulationrankorderabilityattheendoftraining.Forexample,iftheSESrankwas500andtheabilityrankwas600,thiswouldqualifyasupwardssocialmobility;iftheSESrankwas500andthefinalabilityrankwas400,thiswouldqualifyasdownwardssocialmobility.Table1,rightmostcolumn,showstheresultsofamultiplelinearregressionpredictingtherankdisparitymeasureofsocialmobilityfromeachsimulatedchild’sparameters.Notably,SESitselfpredictedareliableamountofthedisparitymeasure.MuchofthisrelationshipwasdrivenbynetworksthatfellbelowexpectedlevelsinhighSESenvironments,lessbynetworksthatfinishedaboveexpectedlevelsinlowSESenvironments.Severaloftheneurocomputationalparametersrelatingtothenetwork’scapacitywerereliablepredictorsofthedisparitymeasure.Theseindexedwhetherthenetworkhadthecapacitytobesttakeadvantageoftheinformationthatwasavailableintheenvironment.
Totheextentthatthecapacityoflearningmechanismsisgeneticallyinfluenced,thissimulationthereforecapturedgeneticinfluencesonperformanceandonsocialmobility.ItisthesamesimulationthatcapturedempiricaldataonwideningIQgapsfromSESacrossdevelopment.ThesamesimulationthatcapturedtherestrictiveeffectsofSESonchildrendeemedhigh-abilityearlyindevelopment.Thesediversebehaviouraleffectswerecapturedinasinglemechanisticframework.Simulation4:SESeffectsonbrainstructureCanthemodelalsocapturedataonbrainstructure?Thelinksbetweenmodelandbraincanonlybeweak,becausethemodelhasaverylimiteddegreeofbiologicalrealism,necessitatedbytherequirementtomakecontactwithhigh-levelbehaviour.Moreover,thereisstillcontroversyhowthephysicalpropertiesthatstructuralbrainimagingmeasuresrelatetocognitivefunction.Despitethefactthatcognitiveabilityshowsbroadlyamonotonicallyincreasingfunctionwithage,someofthebrainstructuremeasuresreducefrommiddlechildhoodonwards(greymattervolume,corticalthickness),whileothersincrease(whitemattervolume,corticalsurfacearea);andtheunderlyingbiologicalmechanismsarestillamatterofdebate(Natuetal.,2018;Nobleetal.,2015).
Themodeldidnotsimulatethegrowthofeachnetwork,rathercapturingvariabilityintheoutcomeofthegrowthamongstitsparametersintermsofnetworkarchitecture(pathwayslinkinginputandoutput),numberofprocessingunits,anddensenessofconnectivity.Itdid,however,simulateareductioninconnectivityfrommid-childhoodonwards,intermsofapruningprocesswithvariablytimedonsetthatremovedunusedconnections(seeThomas,Knowland
17
&Karmiloff-Smith,2011).Fortheartificialneuralnetwork,twostructuralmeasuresofferedpossibleanaloguestobrainmeasures:thetotalstrengthofconnectionsinthenetworkandthetotalnumberofconnections.Duringtraining,thetotalstrengthincreasesasthoseusefulindrivingbehaviourarestrengthened,whilethenumberofconnectionsreducesasthosenotusefulfordrivingbehaviourareremoved.Thesetwonetworkmeasuresprovidepossibleanaloguestocorticalsurfacearea/whitematterdensityandcorticalthickness/greymatterdensity,respectively,byvirtueoftheirsimilardevelopmentaltrajectories.
Figure5takesamid-pointindevelopmentforthesimulatedpopulationconsideredintheprevioussections.Figure5(a)re-plotsdatafromasampleofover1000USchildrenaged3-20linkingcorticalsurfaceareatofamilyincome(Nobleetal.,2015).Asmallamountofvarianceisexplained,withanon-linearfunctionthatexhibitsstrongereffectsonbrainstructureatthelowestincomelevels.Figure5(b)plotstotalconnectionstrengthforthesimulatedpopulationagainstlevelofstimulation.Again,smallamountsofvarianceareexplained,andanon-linearfunctiongivesabestfit.Thus,thesamesimulatedpopulationthatcapturescross-sectionalempiricaldataonSESeffectsonbehaviourcanalsocapturecross-sectionalpatternsobservedinbrainstructuredata.
Themodelofferstwobenefitsatthislevel.First,itprovidesacandidatehypothesisaboutthefunctionalrelevanceofthebrainstructuremeasures–thattheyrepresentchangesofconnectivityarisingfromexperience-dependentdevelopmentalchange.Second,becausethefunctioningofanartificialneuralnetworkiswellunderstood–intermsofactivationsofnetworksofintegrate-and-fireneurons,andlearningalgorithmsthatupdateconnectivityandthresholds–itthendemonstrateshowindicesofnetworkstructureonlyserveasanindirectmeasureoffunction,andhowfunctionmodulatesstructureasaconsequenceof(variable)experience.
18
Figure5.Empiricaldatare-plottedfromNobleetal.(2015)showingtherelationshipbetweenannualfamilyincome($)andcorticalsurfacearea(mm2)inasampleof1099USchildrenbetweentheageof3and20.(b)Computersimulationdatashowingtherelationshipbetweenlevelofcognitivestimulationintheenvironmentinwhichchildrenareraised,andthetotalmagnitudeofconnectionstrengthsineachartificialneuralnetwork,assessedatamid-pointindevelopment(500epochsoftraining).Bothplotsshowanon-linear(log)relationshipbetweentheenvironmentalmeasureandthestructuralmeasure,aswellasmuchunexplainedvariability(linearandnon-linearfitsareshown,alongwithrespectiveR2values).(a)(b)
y=5409.4x+6318.8R²=0.05492
y=1637.1ln(x)+10624R²=0.0593
0
5000
10000
15000
20000
25000
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1
Magnitude
ofcon
nections
Environment(SES)
y=0.0368x+167071R²=0.0263
y=3057.5ln(x)+136686R²=0.03077
100000
120000
140000
160000
180000
200000
220000
240000
0 50000 100000 150000 200000 250000 300000 350000
MRIcorticalsu
rfacearea
Environment(Income$)
19
DiscussionAmulti-levelneurocomputationalmodelwasabletocapturebothbehaviouraldataandbrainstructuredataontheeffectsofdifferencesinsocioeconomicstatusondevelopment.Itdidsowhilealsoincorporatingthecontributionofgeneticvariationtocognitivedevelopment,leadingtohighheritabilityofbehaviour;andbyassumingthatSESoperatesviadifferencesinlevelsofcognitivestimulation.Variationbetweenindividualswasconceivedasthemodulationoftrajectoriesofdevelopment,drivenbyspeciesuniversalmechanisms.
Inthesimulationdatapresented,SESwasimplementedasvariationsinthelevelofcognitivestimulation.However,amodellingframeworkprovidestheopportunitytoimplementandcomparealternativehypotheses,forexampleinhowwelltheycapturetheeffectsizeandshape(linear,log)ofSESeffectsonparticularmeasuresofbehaviourandbrainstructure.Thomasetal.(2018)comparedtwoalternativehypotheses:thatSESmayinsteadinfluencethegrowthofthenetworksthemselves(perthefindingsofBetancourtetal.,2016),andthereforeprocessingcapacity;orthatSESmayinfluencebothnetworkgrowthandcognitivestimulation,inacorrelatedmanner.Thecomputationalmodelthereforeprovidesafoundationtohypothesistestdifferentcausalaccountsofempiricaldata.
Thomasetal.(submitted)havearguedthatonceabasicdevelopmentalmodelofcognitivevariationexists,itprovidesthebasistoexploreinterventions,forexample,byalteringthequantityandqualityofcognitivestimulationthatindividualsexperience.Thenextstepforthemodel,then,istoexplorewhetherthegapsbetweenindividualsatdifferenceSESlevelscanbeclosedoreliminatedbyinterventionsthatequaliseenvironments,forinstancebysupplementingthestimulationreceivedbychildrenfromlow-SESfamilies.ThomasandMeaburn(2018)carriedoutthesesimulations,consideringtheextenttowhichopportunitiestoclosegapsdependedontheoriginofindividualdifferences(e.g.,howheritabletheywere)andwhetherinterventionsweremodulatedbychangesinplasticitywithage(Thomas&Johnson,2006).Thebroadpatternwasthatequalisedandenrichedenvironmentsimprovedpopulationmeansunderallconditions;whenheritabilitywashigher,improvementsweresmallerandgapsreducedless;butearlierinterventionsservedtoreducegapsmorethanlateinterventions.
Theresearchdescribedhereispresentedtoarguefortheutilityofneurocomputationalmodellingasoneresearchtooltofurthertheneuroscienceofpoverty.Oneshouldbecautious,however,toseesuchmodelsincontext.Modelsdonotdemonstratewhatisactuallythecase:theydemonstratethesufficiencyofparticularmechanisticaccountstoexplaintheobservedempiricaldata;andtherefore,indirectly,whatanygivenpatternofempiricaldatamustimplyaboutcausalmechanisms.Bydemonstratingthepossiblecausalexplanationsofdata,theydoatleastencouragetheavoidanceofmisinterpretationofthosedata.Forexample,thepatternofwideningIQgapsacrossSESgroupsacrossdevelopmentmightbeinterpretedtomeanthattheactionofSESdifferencesworsens;themodelshowedthepatternwouldemergeevenstaticcausalSESfactors.ThedeclineofpopulationrankforearlyhighabilitychildrenfromlowSESbackgroundscouldbeinterpretedtomeanthat
20
populationranksareentirelydependentonenvironmentalfactors;themodelshowedthattheempiricaldataareconsistentwithalimitedroleofenvironmentinchildren’srespectiveabilities.TheinfluentialroleofSESoncognitivedevelopmentandeducationalattainmentmightbetakenassupportingasocialcausationaccountofSESdifferences,andoftheprimaryroleofenvironmentinchildren’soutcome.ThemodeldisplayedrealisticSESeffectsbothonbehaviourandnetworkstructurewhilstdisplayinghighheritabilityofindividualdifferences,evenindeedtheheritabilityofdifferencesinsocialmobility.
Clearly,themodelpresentedhereishighlysimplified.Whileitsharedsomeprinciplesofneuralprocessing,itisnotamodelofbrainfunction.Itisessentiallyamachine-learningmechanismthatacquiresasmallsetofinput-outputmappings,representingatbestasinglecomponentofalargersystem.AmorerealisticmodelofSESeffectsondevelopmentwouldneedtodepictagoal-oriented,adaptive,autonomousagent,witharepertoireofbehavioursthatcanalteritssubjectiveenvironment;toincludeseparatecognitive,affectiveandreward-basedaspects;andprovideapathwayfornon-cognitivedimensions(diet,chronicstress,fitness)toalteritsprocessingproperties.Andclearly,thereisagreatdealmoretophenomenasuchassocialmobility(andthesocietalstructuresthatsupportorhinderit)thannotionsofcognitivestimulationandpropertiesofdevelopmentalmechanisms.
Nevertheless,thekeymotivationforconstructingamodelofthecurrentlevelofsimplicityistoemphasisetheimportanceofderivingcausal,mechanisticaccountstoexplainthelargebodyofcorrelationalevidencethathasaccumulatedonhowSESisassociatedwithdifferencesincognitive,educational,andlifeoutcomes.Computationalmodellingisbutoneamongstseveralneurosciencemethodsthatcanshedlightonmechanism,methodssuchasbrainimaging,anatomy,animalmodels,andgenetics.MechanisticinsightsultimatelyprovidethebasistoderivetargetedinterventionsthatcanamelioratetheconsequencesofdifferencesinSES,andespeciallypoverty(Thomas,2017).Thepotentialofmechanisticinsightstoinforminterventionisthemotivatingfactorbehindtheinvolvementofneuroscienceinasocialissuesuchaspoverty–evenifthewiderambitionistoaltersocietalstructuresthatcontributetopovertyinthefirstplace.
21
AcknowledgementsThisworkwassupportedbyMRCgrantMR/R00322X/1andaWellcomeTrust/BirkbeckISSFCareerDevelopmentAwardheldattheUniversityofWesternOntario,Canada.
22
ReferencesAyorech,Z.,Krapohl,E.,Plomin,R.,&vonStumm,S.(2017).Geneticinfluenceon
intergenerationaleducationalattainment.PsychologicalScience,28(9),1302–1310.
Belsky,D.W.,Domingue,B.W.,Wedow,R.,Arseneault,L.Boardman,J.D.,Caspi,A.,…&Harris,K.M.(2018).Geneticanalysisofsocial-classmobilityinfivelongitudinalstudies.ProceedingsoftheNationalAcademyofSciences,Jul2018,201801238;DOI:10.1073/pnas.1801238115
Betancourt,L.M.,Avants,B.,Farah,M.J.,Brodsky,N.L.,Wu,J.,Ashtari,M.,&Hurt,H.(2016).Effectofsocioeconomicstatus(SES)disparityonneuraldevelopmentinfemaleAfrican-Americaninfantsatage1month.DevelopmentalScience,19(6),947-956.doi:10.1111/desc.12344.
Elman,J.L.,Bates,E.A.,Johnson,M.H.,Karmiloff-Smith,A.,Parisi,D.,&Plunkett,K.(1996).Rethinkinginnateness:Aconnectionistperspectiveondevelopment.Cambridge,MA:MITPress.
Farah,M.J.(2017).Theneuroscienceofsocioeconomicstatus:Correlates,causes,andconsequences.Neuron,96,September27,2017,56-71.
Farah,M.J.,Shera,D.M.,Savage,J.H.,Betancourt,L.,Giannetta,J.M.,Brodsky,N.L.,…&Hurt,H.(2006).Childhoodpoverty:Specificassociationswithneurocognitivedevelopment.BrainResearch,1110,166–174.
Feinstein,L.(2003).InequalityintheearlycognitivedevelopmentofBritishchildreninthe1970cohort.Economica,70(277),73–98.
HackmanD.A.,Gallop,R.,Evans,G.W.&Farah,M.J.(2015).Socioeconomicstatusandexecutivefunction:Developmentaltrajectoriesandmediation.DevelopmentalScience,18(5),686–702.
Hackman,D.A.,&Farah,M.J.(2009).Socioeconomicstatusandthedevelopingbrain.TrendsinCognitiveSciences,13(2),65-73.
Hackman,D.A.,Farah,M.J.&Meaney,M.J.(2010).Socioeconomicstatusandthebrain.NatureReviewsNeuroscience,11,651–659.
HMGovernment(2003).Everychildmatters.GreenPaper,Cm5860Jerrim,J.&Vignoles,A.(2013).Socialmobility,regressiontothemeanandthe
cognitivedevelopmentofhighabilitychildrenfromdisadvantagedhomes.JournaloftheRoyalStatisticalSociety:SeriesA(StatisticsinSociety),176(4),887-906.
Karmiloff-Smith,A.(1998).Developmentitselfisthekeytounderstandingdevelopmentaldisorders.TrendsinCognitiveSciences,2,389–398.doi:10.1016/S1364-6613(98)01230-3
Krapohl,E.,Rimfeld,K.,Shakeshaft,N.G.,Trzaskowski,M.,McMillan,A.,Pingault,J.B.,Asbury,K.,Harlaar,N.,Kovas,Y.,Dale,P.S.,&Plomin,R.(2014).Thehighheritabilityofeducationalachievementreflectsmanygeneticallyinfluencedtraits,notjustintelligence.Proc.Natl.Acad.Sci.USA111,15273–15278.
Lee,J.J.etal.(2018).Genediscoveryandpolygenicpredictionfromagenome-wideassociationstudyofeducationalattainmentin1.1millionindividuals.NatureGenetics,50,August2018,1112–1121.https://doi.org/10.1038/s41588-018-0147-3
Mareschal,D.,&Thomas,M.S.C.(2007).Computationalmodellingindevelopmentalpsychology.IEEETransactionsonEvolutionaryComputation
23
(SpecialIssueonAutonomousMentalDevelopment),11,137–150.doi:10.1109/TEVC.2006.890232
Natu,V.S.,Gomez,J.,Barnett,M.,Jeska,B.,Kirilina,E.,Jaeger,C.,Zhen,Z.,Cox,S.,Weiner,K.S.,Weiskopf,N.,&Grill-Spector,K.(2018).Apparentthinningofvisualcortexduringchildhoodisassociatedwithmyelination,notpruning.bioRxiv368274;doi:https://doi.org/10.1101/368274
Noble,K.G.,Houston,S.M.,Brito,N.H.etal.(2015).Familyincome,parentaleducationandbrainstructureinchildrenandadolescents.NatureNeuroscience,18,773–778.
Pavlakis,A.E.,Noble,K.,Pavlakis,S.G.,Ali,N.,&Frank,Y.(2015).BrainImagingandElectrophysiologyBiomarkers:IsThereaRoleinPovertyandEducationOutcomeResearch?PediatricNeurology,52(4),383-388.
Plomin,R.,DeFries,J.C.,Knopik,V.S.,&Neiderhiser,J.M.(2016).Top10replicatedfindingsfrombehavioralgenetics.PerspectivesonPsychologicalScience,11(1),3–23.https://doi.org/10.1177/1745691615617439
Raizada,R.D.S.,Richards,T.L.,Meltzoff,A.,&Kuhl,P.K.(2008).Socioeconomicstatuspredictshemisphericspecialisationoftheleftinferiorfrontalgyrusinyoungchildren.NeuroImage,40(3),1392–1401.http://doi.org/10.1016/j.neuroimage.2008.01.021
Rimfeld,K.,Kovas,Y.,Dale,P.S.,&Plomin,R.(2015).Pleiotropyacrossacademicsubjectsattheendofcompulsoryeducation.ScientificReports,5,11713
Sheridan,M.A.&McLaughlin,K.A.(2016).Neurobiologicalmodelsoftheimpactofadversityoneducation.CurrentOpinioninBehavioralSciences,10,108–113.
Stevens,C.,Lauinger,B.,&Neville,H.(2009).Differencesintheneuralmechanismsofselectiveattentioninchildrenfromdifferentsocioeconomicbackgrounds:anevent-relatedbrainpotentialstudy.DevelopmentalScience,12(4),634–646.doi:10.1111/j.1467-7687.2009.00807.x
Thomas,M.S.C.(2016).Domoreintelligentbrainsretainheightenedplasticityforlongerindevelopment?Acomputationalinvestigation.DevelopmentalCognitiveNeuroscience,19,258-269.
Thomas,M.S.C.(2017).Ascientificstrategyforlifechances.ThePsychologist,30,22-26.
Thomas,M.S.C.(2018).Aneurocomputationalmodelofdevelopmentaltrajectoriesofgiftedchildrenunderapolygenicmodel:Whenaregiftedchildrenheldbackbypoorenvironments?Intelligence,69,200-212
Thomas,M.S.C.&Meaburn,E.(2018).Neurocomputationalmodellingofsocialmobility–Underwhatmodelsofindividualdifferencescaninterventionsnarrowthegaps?Manuscriptinpreparation,2018.
Thomas,M.S.C.&Johnson,M.H.(2006).Thecomputationalmodellingofsensitiveperiods.DevelopmentalPsychobiology,48(4),337-344.
Thomas,M.S.C.&Knowland,V.C.P.(2014).Modellingmechanismsofpersistingandresolvingdelayinlanguagedevelopment.JournalofSpeech,Language,andHearingResearch,57(2),467-483.
Thomas,M.S.C.,Coecke,S.,&Dick,F.(2018).Aneurocomputationalbasisforsocioeconomiceffectsonthedevelopmentofbehaviourandbrainstructure.Manuscriptinpreparation,2018.
24
Thomas,M.S.C.,Fedor,A.,Davis,R.,Yang,J.,Alireza,H.,Charman,T.,MastersonJ.,&Best,W.(submitted).Computationalmodellingofinterventionsfordevelopmentaldisorders.Manuscriptsubmittedforpublication,2018.
Thomas,M.S.C.,Forrester,N.A.,&Ronald,A.(2016).Multi-scalemodelingofgene-behaviorassociationsinanartificialneuralnetworkmodelofcognitivedevelopment.CognitiveScience,40(1),51-99.
Thomas,M.S.C.,Knowland,V.C.P.,&Karmiloff-Smith,A.(2011).Mechanismsofdevelopmentalregressioninautismandthebroaderphenotype:Aneuralnetworkmodelingapproach.PsychologicalReview,118(4),637-654.
Thomas,M.S.C.,Ronald,A.,&Forrester,N.A.(2013).Modelingsocio-economicstatuseffectsonlanguagedevelopment.DevelopmentalPsychology,49(12),2325-43.
Trzaskowski,M.,Harlaar,N.,Arden,R.,Krapohl,E.,Rimfeld,K.,McMillan,A.,...&Plomin,R.(2014).Geneticinfluenceonfamilysocioeconomicstatusandchildren’sintelligence.Intelligence,42,83–88.
vonStumm,S.&Plomin,R.(2015).Socioeconomicstatusandthegrowthofintelligencefrominfancythroughadolescence.Intelligence,48,30–36.https://doi.org/10.1016/j.intell.2014.10.002
Washbrook,E.&Lee,R.(2015).BeyondtheFeinsteinchart:InvestigatingdifferentialachievementtrajectoriesinaUScohort.LongitudinalandLifeCourseStudies,6(3),359-368.