Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations

Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations

To define the neural networks responsible of an epileptic seizure, it is useful to perform advanced signal processing techniques. In this context, electrophysiological signals present three types of waves: oscillations, spikes, and a mixture of both. Recent studies show that spikes and oscillations...

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Main Authors: N. Jmail, M. Zaghdoud, A. Hadriche, T. Frikha, C. Ben Amar, C. Bénar
Format: Article
Language:English
Published: Elsevier 2018-02-01
Series:Heliyon
Subjects:
Biomedical engineering
Neurology
Online Access:http://www.sciencedirect.com/science/article/pii/S2405844017324453
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spelling doaj-9ba46a11658242fab30189bbec3bc3f32020-11-25T01:44:10ZengElsevierHeliyon2405-84402018-02-014210.1016/j.heliyon.2018.e00530Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillationsN. Jmail0M. Zaghdoud1A. Hadriche2T. Frikha3C. Ben Amar4C. Bénar5Miracl Laboratory, Sfax University, Sfax, TunisiaREGIM Laboratory, Sfax University, Sfax, TunisiaREGIM Laboratory, Sfax University, Sfax, TunisiaCES Laboratory, Sfax University, Sfax, TunisiaREGIM Laboratory, Sfax University, Sfax, TunisiaInserm, INS, Institut de Neurosciences des Systèmes, Aix Marseille University, Marseille, FranceTo define the neural networks responsible of an epileptic seizure, it is useful to perform advanced signal processing techniques. In this context, electrophysiological signals present three types of waves: oscillations, spikes, and a mixture of both. Recent studies show that spikes and oscillations should be separated properly in order to define the accurate neural connectivity during the pre-ictal, seizure and inter-ictal states. Retrieving oscillatory activity is a sensitive task due to the frequency overlap between oscillations and transient activities. Advanced filtering techniques have been proposed to ensure a good separation between oscillations and spikes. It would be interesting to apply them in real time for instantaneous monitoring, seizure warning or neurofeedback systems. This requires improving execution time. This constraint can be overcome using embedded systems that combine hardware and software in an optimized architecture. We propose here to implement a stationary wavelet transform (SWT) as an adaptive filtering technique retaining only pre-ictal gamma oscillations, as validated in previous work, on a partial dynamic configuration. Then, the same architecture is used with further modifications to integrate spatio temporal mapping for an early recognition of seizure build-up. Data that contains transient, pre-ictal gamma oscillations and a seizure was simulated. the method on real intracerebral signals was also tested. The SWT was integrated on an embedded architecture. This architecture permits a spatio temporal mapping to detect the accurate time and localization of seizure build-up, while reducing computation time by a factor of around 40. Embedded systems are a promising venue for real-time applications in clinical systems for epilepsy.http://www.sciencedirect.com/science/article/pii/S2405844017324453Biomedical engineeringNeurology
collection DOAJ
language English
format Article
sources DOAJ
author N. Jmail
M. Zaghdoud
A. Hadriche
T. Frikha
C. Ben Amar
C. Bénar
spellingShingle N. Jmail
M. Zaghdoud
A. Hadriche
T. Frikha
C. Ben Amar
C. Bénar
Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations
Heliyon
Biomedical engineering
Neurology
author_facet N. Jmail
M. Zaghdoud
A. Hadriche
T. Frikha
C. Ben Amar
C. Bénar
author_sort N. Jmail
title Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations
title_short Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations
title_full Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations
title_fullStr Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations
title_full_unstemmed Integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations
title_sort integration of stationary wavelet transform on a dynamic partial reconfiguration for recognition of pre-ictal gamma oscillations
publisher Elsevier
series Heliyon
issn 2405-8440
publishDate 2018-02-01
description To define the neural networks responsible of an epileptic seizure, it is useful to perform advanced signal processing techniques. In this context, electrophysiological signals present three types of waves: oscillations, spikes, and a mixture of both. Recent studies show that spikes and oscillations should be separated properly in order to define the accurate neural connectivity during the pre-ictal, seizure and inter-ictal states. Retrieving oscillatory activity is a sensitive task due to the frequency overlap between oscillations and transient activities. Advanced filtering techniques have been proposed to ensure a good separation between oscillations and spikes. It would be interesting to apply them in real time for instantaneous monitoring, seizure warning or neurofeedback systems. This requires improving execution time. This constraint can be overcome using embedded systems that combine hardware and software in an optimized architecture. We propose here to implement a stationary wavelet transform (SWT) as an adaptive filtering technique retaining only pre-ictal gamma oscillations, as validated in previous work, on a partial dynamic configuration. Then, the same architecture is used with further modifications to integrate spatio temporal mapping for an early recognition of seizure build-up. Data that contains transient, pre-ictal gamma oscillations and a seizure was simulated. the method on real intracerebral signals was also tested. The SWT was integrated on an embedded architecture. This architecture permits a spatio temporal mapping to detect the accurate time and localization of seizure build-up, while reducing computation time by a factor of around 40. Embedded systems are a promising venue for real-time applications in clinical systems for epilepsy.
topic Biomedical engineering
Neurology
url http://www.sciencedirect.com/science/article/pii/S2405844017324453
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