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Medical & Biological Engineering & Computing

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01.03.2008 | Original Article

A novel method for automated classification of epileptiform activity in the human electroencephalogram-based on independent component analysis

verfasst von: Marzia De Lucia, Juan Fritschy, Peter Dayan, David S. Holder

Erschienen in: Medical & Biological Engineering & Computing | Ausgabe 3/2008

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Abstract

Diagnosis of several neurological disorders is based on the detection of typical pathological patterns in the electroencephalogram (EEG). This is a time-consuming task requiring significant training and experience. Automatic detection of these EEG patterns would greatly assist in quantitative analysis and interpretation. We present a method, which allows automatic detection of epileptiform events and discrimination of them from eye blinks, and is based on features derived using a novel application of independent component analysis. The algorithm was trained and cross validated using seven EEGs with epileptiform activity. For epileptiform events with compensation for eyeblinks, the sensitivity was 65 ± 22% at a specificity of 86 ± 7% (mean ± SD). With feature extraction by PCA or classification of raw data, specificity reduced to 76 and 74%, respectively, for the same sensitivity. On exactly the same data, the commercially available software Reveal had a maximum sensitivity of 30% and concurrent specificity of 77%. Our algorithm performed well at detecting epileptiform events in this preliminary test and offers a flexible tool that is intended to be generalized to the simultaneous classification of many waveforms in the EEG.

Vorheriger Artikel Independent component analysis applied to the removal of motion artifacts from electrocardiographic signals

Nächster Artikel Imaging of small spherical structures in CT: simulation study using measured point spread function

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Acir N, Guzelis C (2004) Automatic spike detection in EEG by two-stage procedure based on support vector machine. Comput Biol Med 34:561–575CrossRef

Barbati G, Porcaro C, Zappasodi F, Rossini PM, Tecchio F (2004) Optimization of an independent component analysis approach for artefact identification and removal in magnetoencephalographic signals. Clin Neurophysiol 115:1220–1232CrossRef

Bell A, Sejnowski T (1995) An information-maximization approach to blind separaton and blind deconvolution. Neural Comput 7:1129–1159CrossRef

Bell AJ, Sejnowski TJ (1996) Learning the higher-order structure of a natural sound. Netw Comput Neural Syst 7:261–266MATHCrossRef

Binnie CD, Holder DS (1999) Electroencephalography. In: Vinken PJ, Bruyn GW (eds) Handbook of clinical neurology. Amsterdam

Calhoun VD, Adali T, Pearlson GD, Pekar JJ (2001) Spatial and temporal independent component analysis of functional MRI containing a pair of task-related waveforms. Hum Brain Map 13:43–53CrossRef

De Lucia M, Fritschy J, Dayan P, Holder DS (2006) The classification of spikes in EEG recordings using features derived from ICA. In: IET 3rd international conference MEDSIP 2006. Advances in Medical, Signal and Information Processing, issue 520, p. 39

Diambra L, Malta P (1999) Nonlinear models for detecting epileptic spikes. Phys Rev E 59(1):929–937CrossRef

Dumermuth G (1977) Fundamentals of spectral analysis in electroencephalography. In: A.Rèmond (ed), EEG informatics. A didactic review of methods and applications of EEG data processing. Elsevier, Amsterdam, pp 83–105

10.

Faure C (1985) Attributed strings for recognition of epileptic transients in EEG. Int J Biomed Comput 16:217–229CrossRef

11.

Franaszczuk PJ, Bergey GK (1999) An autoregressive method for the measurement of synchronization of interictal and ictal EEG signals. Biol Cybern 81:3–9MATHCrossRef

12.

Fritschy J, Horesh L, Holder DS, Bayford RH (2005) Using the GRID to improve the computation speed of electrical impedance tomography (EIT) reconstruction algorithms. Physiol Meas 26(2):209–215CrossRef

13.

Fritschy J, Horesh L, Holder DS, Bayford RH (2005) Applications of GRID in clinical neurophysiology and electrical impedance tomography of brain function. Stud Health Technol Inform 112:138–145

14.

Goelz H, Jones RD, Bones PJ (2000) Wavelet analysis of transient biomedical signals and its application to detection of epileptiform activity in the EEG. Clin Electroencephalogr 31:181–191

15.

Gotman J, Gloor P (1976) Automatic recognition and quantification of interictal epileptic activity in the human scalp EEG. Electroenceph clin Neurophysiol 41:513–529CrossRef

16.

Gotman J, Ives JR, Gloor P (1979) Automatic recognition of interictal epileptic activity in prolonged EEG recordings. Electroenceph clin Neurophysiol 46:510–520CrossRef

17.

Hastie T, Tibshirani R, Friedman J (2001) The elements of Statistical Learning: Data Mining, Inference and Prediction. Springer Series in Statistics

18.

Hughes JR (1994) EEG in clinical practice, 2nd edn. Butterworth-Heinemann, Newton, MAJR. Hughes EEG in Clinical Practice

19.

Hyvarinen A (1999) Survey on independent component analysis. Neural Comput Surv 2:94–128

20.

Hyvarinen A (1999) Fast and robust fixed-point algorithms for independent component analysis. IEEE Trans Neural Netw 10 (3):626–634CrossRef

21.

Hyvarinen A, Oja E (1997) A fast fixed-point algorithm for independent component analysis. Neural Comput 9(7):1483–1492CrossRef

22.

Hyvarinen A, Oja E (2000) Independent component analysis: algorithms and applications. Neural Netw 13:411–430CrossRef

23.

Jasper H (1958) The ten–twenty electrode system of the international federation. Electroencephalogr Clin Neurophysiol 10:371–375

24.

Jung T, Makeig S, Mckeown MJ, Bell AJ, Lee T, Sejnowski TJ (2001) Imaging brain dynamics using independent component analysis. Proc IEEE 89(7):1107–1122CrossRef

25.

Kalayci T, Ozdamar O (1995) Wavelet preprocessing for automated neural network detection of EEG spikes. IEEE Eng Med Biol Mag 14(2):160–166CrossRef

26.

Kobayashi K, Akiyama T, Nakahori T (2002a) Systematic source estimation of spikes by a combination of independent component analysis and RAP-MUSIC. I: principles and simulation study. Clin Neurophysiol 113:713–724CrossRef

27.

Kobayashi K, Akiyama T, Nakahori T (2002b) Systematic source estimation of spikes by a combination of independent component analysis and RAP-MUSIC. II: preliminary clinical application. Clin Neurophysiol 113:725–734CrossRef

28.

Kobayashi K, James C, Nakahori T, Akiyama T, Gotman J (1999) Isolation of epileptiform discharges from unaveraged EEG by independent component analysis. Clin Neurophysiol 110(10):1755–1763

29.

Latka M, Was Z, Kozik A, West B (2003) Wavelet Analysis of epileptic spikes. Phys Rev E 67:052902CrossRef

30.

McKeown MJ, Brown GG, Jung TP, Kindermann SS, Bell AJ, Sejnowski TJ (1998) Analysis of fMRI data by blind separation into independent spatial components. Hum Brain Mapp 6:160–188CrossRef

31.

McKeown MJ, Jung TP, Makeig S, Brown G, Kindermann SS, Lee TW, Sejnowski TJ (1998) Spatially independent activity pattern in functional MRI data during the stroop color-naming task. Proc Natl Acad Sci USA 95:803–810CrossRef

32.

Ossadtchi A, Baillet S, Moscher JC, Thyerlei D, Sutherling W, Leahy RM (2004) Automated interictal spike detection and source localization in magnetoencephalography using independent components analysis and spatio-temporal clustering. Clin Neurophysiol 115(3):508–522CrossRef

33.

Ozdamar O, Kalayci T (1998) Detection of spikes with artificial neural networks using raw EEG. Comput Biomed Res 31:122–142CrossRef

34.

Pham D-T, Garrat P, Jutten C (1992) Separation of a mixture of independent sources through a maximum likelihood approach. In: Proceedings of EUSIPCO, pp 771–774

35.

Ramabhadran B, Frost JD Jr, Glover JR, Ktonas PY (1999) An automated system for epileptogenic focus localization in the electroencephalogram. J Clin Neurophysiol 16:59–68CrossRef

36.

Schlesinger MI, Hlavàc V (2002) Ten lectures on statistical and structural pattern recognition. Kluwer, DordrechtMATH

37.

Shoker L, Sanei S, Wang W, Chambers JA (2005) Removal of eyey blinking artifact from the electro-encephalogram, incorporating a new constrained blind source separation algorithm. Med Biol Eng Comput 43:290–295CrossRef

38.

Vigario RN (1997) Extraction of ocular artefacts from EEG using independent component analysis. Electroencephal Clin Neurophysiol 103:395–404CrossRef

39.

Vigario R, Jousmaki V, Hamalainen M, Hari R, Oja E (1998) Independent component analysis for identification of artefacts in magnetoencephalographic recordings. Adv Neural Inf Process Syst 10:229–235

40.

Webber WR, Litt B, Wilson K, Lesser RP (1994) Practical detection of epileptiform discharge (EDs) in the EEG using an artificial neural network: a comparison of raw and parameterized EEG data. Electroencephalogr Clin Neurophysiol 91(3):194–204CrossRef

41.

Wilson SB, Emerson R (2002) Spike detection: a review and comparison of algorithms. Clin Neurophysiol 113:1873–1881CrossRef

42.

Wilson SB, Scheuer ML, Emerson RG, Gabor AJ (2004) Seizure detection: evaluation of the Reveal algorithm. Clin Neurophysiol 115(10):2280–2291

43.

Wilson SB, Turner CA, Emerson RG, Scheuer ML (1999) Spike detection II: automatic, perception-based detection and clustering. Clin Neurophysiol 110:404–411CrossRef

Titel: A novel method for automated classification of epileptiform activity in the human electroencephalogram-based on independent component analysis
verfasst von: Marzia De Lucia
Juan Fritschy
Peter Dayan
David S. Holder
Publikationsdatum: 01.03.2008
Verlag: Springer-Verlag
Erschienen in: Medical & Biological Engineering & Computing / Ausgabe 3/2008
Print ISSN: 0140-0118
Elektronische ISSN: 1741-0444
DOI: https://doi.org/10.1007/s11517-007-0289-4

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