DuffyFBartelsPBurchfielJ. Significance probability mapping: An aid in the topographic analysis of brain electrical activity. Electroencephalogr Clin Neurophysiol1981; 51: 455–462.
ThatcherRWWalkerRAGersonIGeislerFH. EEG discriminant analysis of mild head trauma. Electroenceph Clin Neurophysiol1989; 73: 94–106.
5.
EbersoleJSWadePB. Spike voltage topography identifies two types of frontotemporal epileptic foci. Neurology1991; 41: 1425–1433.
6.
LantzGRydingERosénI. Three-dimensional localization of interictal epileptiform activity with dipole analysis: Comparison with intracranial recordings and SPECT findings. J Epilepsy1994; 7: 117–129.
7.
WongPK. The importance of source behavior in distinguishing populations of epileptic foci. J Clin Neurophysiol1991; 10: 314–322.
8.
EbersoleJSWadePB. Spike voltage topography and equivalent dipole localization in complex partial epilepsy. Brain Topogr1990; 3: 21–34.
9.
SaltzbergBBurtonWDBurchNRFletcherJMichaelsR. Electrophysiological measures of regional neural interactive coupling. Linear and non-linear dependence relationships among multiple channel electroencephalographic recordings. Int. J Biomed Comput1986; 18: 77–87.
10.
GotmanJGloorP. Automatic recognition and quantification of interictal epileptic activity in the human scalp. Electroencephalogr Clin Neurophysiol1976; 41: 513–529.
11.
GotmanJ. Automatic recognition of epileptic seizures in the EEG. Electroencephalogr Clin Neurophysiol1982; 54: 530–540.
12.
SalinskyMCOkenBSKramerREMoreheadL. A comparison of quantitative EEG frequency analysis and conventional EEG in patients with focal brain lesions. Electroencephalogr Clin Neurophysiol1992; 83: 358–366.
13.
JordanSENowackiRNuwerM. Computerized electroencephalography in the evaluation of early dementia. Brain Topogr1989; 1: 271–282.
14.
HierDBMangoneCAGangellenR. Quantitative measurement of delta activity in Alzheimer's disease. Clin Electroencephalogr1991; 22: 178–182.
15.
DuffyFHAlbertMSMcAnultyG. Brain electrical activity in patients with presenile and senile dementia of the Alzheimer's type. Ann Neurol1984; 16: 439–448.
16.
IhlRMaurerKDierksTFrölichLPerisicI. Staging in dementia of the Alzheimer type: Topography of electrical brain activity reflects the severity of the disease. Psychiat Res1989; 29: 399–401.
17.
DierksTPerisicIFrölichLIhlRMaurerK. Topography of the quantitative electroencephalogram in dementia of the Alzheimer type: Relation to severity of dementia. Psychiat Res Neuroimaging1991; 40: 181–194.
18.
HelkalaELLaulumaaVSoininenHPartanenJRiekkinenPJ. Different patterns of cognitive decline related to normal or deteriorating EEG in a 3-year follow-up study of patients with Alzheimer's disease. Neurology1991; 41: 528–532.
19.
CorbenLAChiDSnyderAZStroandtM. Replication of a study of the frequency analysis of the resting awake EEG in mild probable Alzheimer's disease. Electroencephalogr Clin Neurophysiol1990; 75: 148–154.
20.
DuffyFHJensenFErbaGBurchfielJLLombrosoCT. Extraction of clinical information from electroencephalographic background activity — the combined use of brain electrical activity mapping and intravenous sodium thiopental. Ann Neurol1984; 15: 22–30.
21.
LombrosoCTDuffyFH. Brain electrical activity mapping in the epilepsies. In: AkimotoHKazamatsuriHSeinoMWardA, eds. Advances in Epileptology: Proceedings of XIIIth Epilepsy International Symposium. New York: Raven Press, 1982: 173–179.
22.
LombrosoCTDuffyFH. Brain electrical activity mapping as an adjunct to CT scanning. In: CangerRAngeleriFPerryJK, eds. Advances in Epileptology: Proceedings of XIth Epilepsy International Symposium. New York: Raven Press, 1980: 83–88.
23.
NuwerMR. Frequency analysis and topographic mapping of EEG and evoked potentials in epilepsy. Electroencephalogr Clin Neurophysiol1988; 69: 118–126.
OkenBSChiappaKHSalinskyM. Computerized EEG frequency analysis: Sensitivity and specificity in patients with focal lesions. Neurology1989; 39: 1281–1287.
28.
NagataKYunokiKArakiGMizukamiM. Topographic electroencephalographic study of transient ischemic attacks. Electroencephalogr Clin Neurophysiol1984; 58: 291–301.
29.
NagataKTagawaKHiroiSShishidoFUemuraK. Electroencephalographic correlates of blood flow and oxygen metabolism provided by positron emission tomography in patients with cerebral infarction. Electroencephalogr Clin Neurophysiol1989; 72: 16–30.
30.
NuwerMRJordanSEAhnSS. Evaluation of stroke using EEG frequency analysis and topographic mapping. Neurology1987; 37: 1153–1159.
31.
ChiappaKHBurkeSRYoungRR. Results of electroencephalographic monitoring during 367 carotid endarterectomies: Use of a dedicated minicomputer. Stroke1979; 10: 381–388.
DuffyFHDencklaMBMcAnultyGBHolmesJA. Neurophysiological studies in dyslexia. In: PlumF ed. Language, Communication and the Brain. New York: Raven Press, 1988: 149–170.
34.
DuffyFHDencklaMBBartelsPSandiniG. Dyslexia: Regional differences in brain electrical activity by topographic mapping. Ann Neurol1980; 7: 412–420.
35.
DuffyFHDencklaMBBartelsPSandiniGKiesslingLS. Dyslexia: Automated diagnosis by computerized classification of brain electrical activity Ann Neurol1980; 7: 421–428.
MannCALubarJFZimmermanAWMillerCAMuenchenRA. Quantitative analysis of EEG in boys with attention-defecit hyperactivity disorder: Controlled study with clinical implications. Pediatr Neurol1992; 8: 30–36.
38.
GalinDRazJFeinGJohnstoneJHerronJYinglingC. EEG spectra in dyslexic and normal readers during oral and silent reading. ELectroencephalogr Clin Neurophysiol1992; 82: 87–101.
39.
BadianNMcAnultyGBDuffyFHAlsH. Prediction of dyslexia in kindergarten boys. Ann Dyslexia1990; 40: 152–169.
40.
HooshmandHBecknerERadfarF. Technical and clinical aspects of topographic brain mapping. Clin Electroencephalogr1989; 20: 235–247.
DuffyFHBurchfielJLLombrosoCT. Brain electrical activity mapping (BEAM): A method for extending the clinical utility of EEG and evoked potential data. Ann Neurol1979; 5: 309–321.
48.
GarberJHWeilburgJBDuffyFHManschreckTC. Clinical use of topographic brain electrical activity mapping in psychiatry. J Clin Psychiat1989; 50: 205–211.
49.
DuffyFH. Clinical use of brain electrical activity mapping. In: DuffyFHIyerVGSurwilloWW, eds. Clinical Electroencephalography and Topographic Brain Mapping. New York: Springer-Verlag, 1989: 222–237.
50.
DuffyFH. Topographic mapping of brain electrical activity: Clinical applications and issues. In: MaurerK, ed. Topographic Brain Mapping of EEG and Evoked Potentials. Heidelberg, Germany: Springer-Verlag, 1989: 19–52.
51.
ThatcherRWCantorDSMcAlasterRGeislerFKrauseP. Comprehensive predictions of outcome in closed head-injured patients: The development of prognostic equations. Ann New York Acad Sciences1991; 620: 82–101.
52.
JohnERPrichepLSEastonP. Standardized varimax descriptors of event related potentials: Evaluation of psychiatric patients. Psychiatry Research: Neuroimaging1994; 55: 13–40.
SchergMEbersoleJS. Brain source imaging of focal and multifocal epileptiform EEG activity. Neurophysiol Clinique1994; 24: 51–60.
55.
WongPK. Source modelling of the rolandic focus. Brain Topogr1991; 4: 105–112.
56.
Van der MeijWVan HuffelenACWienekeGHWillemseJ. Sequential EEG mapping may differentiate “epileptic” from “non-epileptic” rolandic spikes. Electroencephalogr Clin Neurophysiol1992; 82: 408–414.
57.
BickfordRAllenB. A simple add-on personal computer procedure for color displays of electrophysiological data: Advantages and pitfalls. In: DuffyFH, ed. Topographic Mapping of Brain Electrical Activity. Boston: Butterworths, 1986: 203–216.
58.
ColluraTFJacobsECBraunDSBurgessRC. EView — a workstation-based viewer for intensive clinical electroencephalography. IEEE Transactions on Biomedical Engineering1993; 40: 736–743.
59.
MausAEndresenJ. Misuse of computer-generated results. Med Biol Eng Comput1979; 17: 126–129.
AbtK. Significance testing of many variables — Problems and solutions. Neuropsychobiol1983; 9: 47–51.
62.
OkenBSCkH.Statistical issues concerning computerized analysis of brainwave topography. Ann Neurol1986; 19: 493–494.
63.
DuffyFHBartelsPHNeffRN. A response to Oken and Chiappa. Ann Neurol1986; 19: 494–495.
64.
DuffyFH. Clinical decision making in quantified electroencephalographic analysis. In: Samson-DollfusDGotmanJGuieuJDEtevenonP, eds. Statistics and Topography in Quantitative EEG. Paris: Elsevier, 1988: 9–26.
65.
BartelsPH. Numerical evaluation of cytologic data VIII. Computation of the principal components. Anal Quant Cytol1981; 3: 83–90.
66.
BartelsPH. Numerical evaluation of cytologic data IX. Search for data structure by principal components transformation. Anal Quant Cytol1981; 3: 167–177.
67.
DuffyFJonesKBartelsPMcAnultyGAlbertM. Unrestricted principal components analysis of brain electrical activity: Issues of data dimensionality, artifact, and utility. Brain Topogr1992; 4: 291–307.
68.
SemlitschHVAndererPSchusterPPresslichO. A solution for reliable and valid reduction of ocular artifacts, applied to the P300 ERP. Pschophysiol1986; 23: 695–703.
69.
BergPSchergM. Dipole modelling of eye activity and its application to the removal of eye artifacts from EEG and MEG. Clin. Physics Physiol. Measurement1991; 12supplA: 49–54.
70.
LinsOGPictonTWBergPSchergM. Ocular artefacts in recording EEGs and event related potentials II: Source dipoles and source components. Brain Topogr1993; 6: 65–78.
71.
BergPSchergM. A multiple source approach to the correction of eye artifacts. Electroencephalogr Clin Neurophysiol1994; 90: 229–241.
72.
NunezPL. Electric Fields of the Brain. New York: Oxford University Press, 1981.
73.
FauxSFShentonMEMcCarleyRWNestorGMarcyBLudwigA. Preservation of P300 event-related potential topographic asymmetries in schizophrenia with use of either linked-ear or nose reference sites. Electroencephalogr Clin Neurophysiol1990; 75: 378–391.
74.
GonzalezASLPascualMRDValdesSPABiscayLRMacKadoCFigueredoRACastroTC. Brain electrical field measurements unaffected by linked earlobes reference. Electroencephalogr Clin Neurophysiol1990; 75: 155–160.
75.
LehmannD. Spatial analysis of EEG and evoked potential data. In: DuffyFH, ed. Topographic Mapping of Brain Electrical Activity. Boston: Butterworths, 1986: 29–62.
76.
BertrandOPerrinFPernierJ. A theoretical justification of the average reference in topographic evoked potential studies. Electroencephalogr Clin Neurophysiol1985; 62: 462–464.
77.
DesmedtJTombergC. Topographic analyses in brain mapping can be compromised by the average reference. Brain Topogr1990; 3: 35–42.
78.
DesmedtJTombergCNoelPOzakiI. Beware of the average reference in brain mapping. Electroencephalogr Clin Neurophysiol1990; 41: 22–27.
79.
HjorthB. An on-line transformation of scalp potentials into orthogonal source derivations. Electroencephalogr Clin Neurophysiol1975; 39: 526–530.
80.
NunezPLPilgreenKL. The spline-Laplacian in clinical neurophysiology: A method to improve EEG spatial resolution. J Clin Neurophysiol1991; 8: 397–413.
HughesJRDencklaMB. Outline of a pilot study of electroencephalographic correlates of dyslexia. In: BentonALPearlD, eds. Dyslexia: An Appraisal of Current Knowledge. Oxford, England: Oxford University Press, 1978: 237–240.
88.
DuffyFHMcAnultyG. Neurophysiological heterogeneity and the definition of dyslexia: Preliminary evidence for plasticity. Neuropsychologia1990; 28: 555–571.
89.
ZarJH. Biostatistical Analysis. Englewood Cliffs, N. J.: Prentice Hall, 1984.
90.
OkenBSChiappaKH. Short-term variability in EEG frequency analysis. Electroencephalogr Clin Neurophysiol1988; 69: 191–198.
91.
LeuchterAFSparJEWalterDOWeinerH. Electroencephalographic spectra and coherence in the diagnosis of Alzheimer's-type and multi-infarct dementia. Arch Gen Psychiat1987; 44: 993–998.
92.
LeuchterAFNewtonTFCookIAWalterDORosenberg-ThompsonSLachenbrichPA. Changes in brain functional connectivity in Alzheimer's-type and multi-infarct dementia. Brain1992; 115: 1543–1561.
93.
ByringRJarvilehtoT. Auditory and visual evoked potentials of schoolboys with spelling disabilities. Dev Med Child Neurol1985; 27: 141–148.
94.
SavageCRWeilburgJBDuffyFHBaerLSheraDMJenikeMA. Low level sensory processing in obcessive-compulsive disorder: An evoked potential study. Biol Psychiatr1994; 35: 247–252.
VasileRDuffyFMcAnultyGMooneyJJBloomindaleKSchildkrautJJ. Abnormal flash visual evoked potentials in melancholia: A replication study. Biol Psychiatr1992; 31: 325–336.
97.
MorstynRDuffyFHMcCarleyRW. Altered P300 topography in schizophrenia. Arch Gen Psychiat1983; 40: 729–734.
98.
FauxSFTorelloMMcCarleyRWShentonMDuffyFH. P300 topography alterations in schizophrenia: A replication study. Electroencephalogr Clin Neurophysiol1987; 40: 688–694.
99.
FauxSFTorelloMMcCarleyRWShentonMDuffyFH. P300 in schizophrenia: Confirmation and statistical validation of temporal region deficit in P300 topography. Biol Psychiatry1987; 23: 776–790.
100.
FauxSFShentonMMcCarleyRWTorelloMDuffyFH. P300 in schizophrenia: Differentiation of schizophrenics and normal controls is enhanced by the Goodin Subtraction Procedure. Int J Neurosci1988; 39: 117–135.
101.
McCarleyRWShentonMEO'DonnellBFFauxSFKikinisRNestorPGJoleszFA. Auditory P300 abnormalities and left posterior superior temporal gyrus volume reduction in schizophrenia. Arch Gen Psychiatr1993; 50: 190–197.
102.
DuffyFHMcAnultyGBJonesKAlsHAlbertM. Brain electrical correlates of psychological measures: Strategies and problems. Brain Topogr1993; 4: 291–307.
103.
CuffinBNCohenDYunokuchiKManiewskiRPurcellCCosgroveGRIvesJKennedyJSchomerD. MEG versus EEG localization test using implanted sources in the human brain. Ann Neurol1990; 28: 811–817.
104.
CohenDCuffinBN. EEG versus MEG localization accuracy: Theory and experiment. Brain Topogr1991; 4: 95–103.
105.
CuffinBNCohenDYunokuchiKManiewskiRPurcellCCosgroveGRIvesJKennedyJSchomerD. Tests of EEG localization accuracy using implanted sources in the human brain. Ann Neurol1991; 29: 132–138.
