10.2217/NPY.11.45 2011 Future Medicine Ltd

495

ISSN 1758-2008

Neuropsychiatry

(2011) 1(5), 495–514

Summary

The human brainweighsapproximately 3 lbsandconsumes 40–60%

ofbloodglucose. This disproportionateamountofenergyisusedtocreateelectricity in

approximately 100 billioninterconnectedneurons. Quantitative EEG is a real-time movieof

theelectricalactivityofthepreconsciousandconsciousmind at frequenciesofapproximately

1–300 Hz. Numerousstudieshavecross-validatedelectricalneuroimagingbystructural MRI,

functional MRI anddiffusionspectralimagingandtherebydemonstratedhow quantitative

EEG canaid in linking a patient’ssymptomsandcomplaintstofunctionalspecialization in the

brain. Electricalneuroimagingprovides an inexpensivemillisecondmeasureoffunctional

modules, includingtheanimationofstructuresthroughphaseshiftandphase lock. Today,

neuropsychiatristsusethesemethodsto link a patient’ssymptomsandcomplaintsto

functionalspecialization in thebrainandusethisinformationtoimplementtreatment via

brain–computer Interfaces andneurofeedbacktechnology.

†

Authorforcorrespondence: NeuroImaging Laboratory, Applied Neuroscience Research Institute, St Petersburg, FL 33722, USA;

Tel.: +1 727 244 0240;

Review

Robert W Thatcher

†

Neuropsychiatryand quantitative

EEG in the 21st Century

Practice points

Useconventionalclinicalevaluationtoderive a diagnosisandidentifypatientsymptoms.

Measureeyes open andeyesclosedartifact-free quantitative EEG.

Calculate auto- andcross-spectratoidentifyscalplocationsandnetworkdeviationsfrom normal.

Use EEG tomographyto link thepatient’ssymptomsandcomplaintstofunctionalsystems in thebrain.

Identifyand separate the ‘weak’ systemsfromcompensatorysystems.

Use Z-score biofeedbacktotargetthederegulatedbrainsubsystemstoreinforce optimal andhomeostatic

statesoffunctionwhiletheclinicianmonitorsthepatient’ssymptomreduction.

Use quantitative EEG toevaluatepre- versus post-treatment and follow-upevaluationstodetermine

treatmentefficacy (e.g., medications, repetitive transcranialmagneticstimulation, electroconvulsivetherapy,

brain–computerinterfacesandbiofeedback, amongothers).

Neuropsychiatry

(2011) 1(5)

futuresciencegroup

496

eview

Thatcher

EEG isthemeasurementofthebrain-gener

atedelectrical potential betweenlocations on

thescalpand/orwithrespectto a reference.

Quantitative EEG (qEEG) invovlestheuse

ofcomputerstopreciselyquantifyelectrical

potentialsofapproximately 1–300

Hz, repre

sentingsubsecondmeasuresofsummatedlocal

fieldpotentialsgenerated in groupsofcortical

pyramidal neurons

[1]

. In thelast 40

years, over

90,000 qEEGstudieshavebeenlisted in the

National Library ofMedicine’sdatabase

[201]

Toreviewthisvastliterature, itisbesttousethe

searchterms ‘EEG and x’ where ‘x’ is a topic such

asschizophrenia, dyslexia, attentiondeficit, reli

ability, validity, obsessive–compulsivedis

orders,

evidenced-basedmedicine, anxietyorphobia,

amongothers. A readingofthestudiesand

abstractsshowsthatthevastmajorityofthese

studiesareqEEGstudiesinvolvingcomputer

analyses (e.g., spectralanalyses, ratiosof power,

coherenceorphase, amongothers). The search

term ‘EEG’ and not ‘qEEG’ isnecessarybecause

the National Library ofMedicinesearchesarti

cletitles/abstracts, andtheserarelyifeveruse

theterm ‘qEEG’ in the title (e.g., thisauthor

haspublishedsixbooksandover 200 total

publicationsandneverusedtheterm ‘qEEGor

QEEG’ in the title orabstract). This iswhy a

small ‘q’ isused in thispapertoemphasizethat

thesummationofelectricalpotentialsgenerated

by pyramidal neuronsynapsesarethesourcesof

the EEG andthe ‘q’ designatesquantification

asopposedto ‘eye-ball’ orvisualexamination

ofthe EEG tracesorsquiggleswithoutquanti

ficationasused in clinicalroutine. This article

iswrittenwith a specialemphasis on theuseof

qEEG after visualexaminationbypsychiatrists,

neuropsychiatrists, clinicalpsychologists, psy

chologists, neuro

psychologistsandneuroscien-

tistswhoaretheprimaryusersandpublishersof

psychiatric-relatedarticlesusingqEEG.

Historically, visuallyrecognized EEG pat

ternsandotherelectrophysiologicalmeasures

(evokedpotentialsand event-related potential)

wereusedtodiscernetiologicalaspectsofbrain

dysfunctionrelatedtopsychiatricdisorders

withreasonablesuccess, but not at thelevelthat

qEEGcanbeusedas a standalonediagnostic

methodforpsychiatricdisorders

[2]

. Instead,

qEEG was usedas an indicatoroforganicityor a

physiologicaletiologyofunknownoriginsimilar

tohow a clinicalbloodtestisusedaswellas an

objectiveevaluationoftreatmentefficacy upon

follow-up. In the 1960s and 1970s, priortothe

adventof MRI or PET scansor modern knowl

edgeofbrainfunction, it was speculatedthatthe

developmentof large qEEGdatabasesofpatients

with different clinicaldisorders will result in the

developmentofqEEGdiagnosticmeasuresthat

provideindicationsofpsychiatricdisorders

[3]

However, it was quicklyshownthatonly a sta

tisticalapproachisfeasible due tothenumberof

measuresandthefactthatthe EEG changeswith

age. As a consequence, ageregressionandstrati

fiedreference normative databasesweredevel

opedbyMatousekand Petersen in 1973

[4,5]

and

laterby John

[3,6–8]

, Duffy

[9]

, Thatcher

[10]

and

CongedoandLubar

[11]

, amongothers

[12–17]

The Stockholm, Sweden, normsofMatousek

and Petersen wereindependentlyreplicatedby

John andcollaborators in New York, USA

[3,6]

Subsequent replicationsof different qEEGnor

mativedatabasesdemonstratedthestatistical

stabilityandvalueofusingreference normative

databasestoaid in identifyingdeviant EEG fea

turesand in linkingthelocationof deviant fea

turestosymptomsandcomplaints

[2–8,12,16,18]

The referencedatabaseprovides a statistical

matchtoreliable quantitative featuresavailable

in the 1970s and 1980s. However, thespectral

methods in the 1970s relied upon the Fourier

transformthatdid not havesufficient temporal

resolutiontomeasurehigh-speeddynamics such

as rapid shifts in phasedifferencesandphase

lock. This problem was solved in thelate 1980s

withtheapplicationofjoint time–frequency

analysis (JTFA), where a time seriesof real-

time measuresofphasedifferencesisproduced.

JTFA providedprecisemeasuresofphaseshift

and lock durationsacrossthe human lifespan

for all combinationsoftheten- or 20-electrode

systemsand normative JTFA databasesthatwere

soondeveloped

[12,19]

Effortsare still beingundertaken in a fewlabo

ratoriestorecordandclassifyqEEGfromthou

sandsofpatientswiththe belief that a standalone

diagnosiscanbedevelopedfor different psychiat

ricdisorders. However, asexplainedby John

[2,3]

and Duffy

[9]

, itisunlikelythatqEEGcanserve

as a standalonediagnosticmeasureno matter how

large thedatabases. Forexample, meta-analyses

ofevidenced-basedmedicinecriteriaonlyshow

moderate to strong effectsizesforparticular EEG

features in schizophrenia

[4]

and obsessive–com

pulsivedisorder, post-traumatic stress disorder,

panicdisorder, generalizedanxietydisorderand

phobias

[2,20–22]

. This scientificliteratureshows

thatthereare a widevarietyof different changes