New approach to epileptic diagnosis using visibility graph of high-frequency signal

Xiaoying Tang; Li Xia; Yezi Liao; Weifeng Liu; Yuhua Peng; Tianxin Gao; Yanjun Zeng

doi:10.1177/1550059412464449

New approach to epileptic diagnosis using visibility graph of high-frequency signal

Xiaoying Tang, Li Xia, Yezi Liao, Weifeng Liu, Yuhua Peng^*, Tianxin Gao, Yanjun Zeng

^*Corresponding author for this work

School of Medical and Technology

Research output: Contribution to journal › Article › peer-review

36 Citations (Scopus)

Abstract

A new nonlinear approach is presented for high-frequency electrocorticography (ECoG)-based diagnosis of epilepsy. The ECoG data from 3 patients with epilepsy are analyzed in this study. A recently developed algorithm in graph theory, visibility graph (VG), is applied in this research. The approach is based on the key discovery that high-frequency oscillation takes place during epileptic seizure, making it a marker of epilepsy. Therefore, the nonlinear property of the high-frequency signal may be more noticeable. Hence, a complexity measure, called graph index complexity (GIC), is computed using the VG of the patients' high-frequency ECoG subband. After comparison and statistical analysis, the nonlinear feature is proved to be effective in detection and location of the epilepsy. Two different traditional complexities, sample entropy and Lempel-Ziv, were also calculated to make a comparison and prove that GIC provides better identification.

Original language	English
Pages (from-to)	150-156
Number of pages	7
Journal	Clinical EEG and Neuroscience
Volume	44
Issue number	2
DOIs	https://doi.org/10.1177/1550059412464449
Publication status	Published - Apr 2013

Keywords

Complexity
ECoG
Epilepsy
Visual graph

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10.1177/1550059412464449

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title = "New approach to epileptic diagnosis using visibility graph of high-frequency signal",

abstract = "A new nonlinear approach is presented for high-frequency electrocorticography (ECoG)-based diagnosis of epilepsy. The ECoG data from 3 patients with epilepsy are analyzed in this study. A recently developed algorithm in graph theory, visibility graph (VG), is applied in this research. The approach is based on the key discovery that high-frequency oscillation takes place during epileptic seizure, making it a marker of epilepsy. Therefore, the nonlinear property of the high-frequency signal may be more noticeable. Hence, a complexity measure, called graph index complexity (GIC), is computed using the VG of the patients' high-frequency ECoG subband. After comparison and statistical analysis, the nonlinear feature is proved to be effective in detection and location of the epilepsy. Two different traditional complexities, sample entropy and Lempel-Ziv, were also calculated to make a comparison and prove that GIC provides better identification.",

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author = "Xiaoying Tang and Li Xia and Yezi Liao and Weifeng Liu and Yuhua Peng and Tianxin Gao and Yanjun Zeng",

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AU - Tang, Xiaoying

AU - Xia, Li

AU - Liao, Yezi

AU - Liu, Weifeng

AU - Peng, Yuhua

AU - Gao, Tianxin

AU - Zeng, Yanjun

PY - 2013/4

Y1 - 2013/4

N2 - A new nonlinear approach is presented for high-frequency electrocorticography (ECoG)-based diagnosis of epilepsy. The ECoG data from 3 patients with epilepsy are analyzed in this study. A recently developed algorithm in graph theory, visibility graph (VG), is applied in this research. The approach is based on the key discovery that high-frequency oscillation takes place during epileptic seizure, making it a marker of epilepsy. Therefore, the nonlinear property of the high-frequency signal may be more noticeable. Hence, a complexity measure, called graph index complexity (GIC), is computed using the VG of the patients' high-frequency ECoG subband. After comparison and statistical analysis, the nonlinear feature is proved to be effective in detection and location of the epilepsy. Two different traditional complexities, sample entropy and Lempel-Ziv, were also calculated to make a comparison and prove that GIC provides better identification.

AB - A new nonlinear approach is presented for high-frequency electrocorticography (ECoG)-based diagnosis of epilepsy. The ECoG data from 3 patients with epilepsy are analyzed in this study. A recently developed algorithm in graph theory, visibility graph (VG), is applied in this research. The approach is based on the key discovery that high-frequency oscillation takes place during epileptic seizure, making it a marker of epilepsy. Therefore, the nonlinear property of the high-frequency signal may be more noticeable. Hence, a complexity measure, called graph index complexity (GIC), is computed using the VG of the patients' high-frequency ECoG subband. After comparison and statistical analysis, the nonlinear feature is proved to be effective in detection and location of the epilepsy. Two different traditional complexities, sample entropy and Lempel-Ziv, were also calculated to make a comparison and prove that GIC provides better identification.

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KW - Epilepsy

KW - Visual graph

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New approach to epileptic diagnosis using visibility graph of high-frequency signal

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Keywords

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