Article: Analysis of the dynamics of the olfactory evoked EEG responses generated by the brain and e-nose under natural and synthetic odorant stimulations Journal: International Journal of Computational Science and Engineering (IJCSE) 2022 Vol.25 No.4 pp.410 - 420 Abstract: Aroma and taste have a disproportionately strong effect on the human brain in comparison to the other senses, however this effect is mostly unappreciated. The capacity for olfaction to perceive, identify, and distinguish a vast number of chemicals present in the air is the consequence of complicated interactions between receptors, smell molecules, and the brain. The purpose of this article is to investigate and comprehend those complex interactions through the analysis of EEG signals recorded in response to a variety of natural and synthetic odorants administered to the mammalian olfactory system. Additionally, a prototype of a portable electronic nose (E-nose) was built, which consists of a sensor array and an Arduino microcontroller running an implementation of Freeman's KIII olfactory model. The sensor array's output is sent to the microcontroller, which generates EEG signals specific to the odorant stimuli applied. The EEG signal generated by the E-nose is then compared to EEG signals gathered from humans in terms of multiscale entropy and fractal dimension, highlighting the E-nose model's efficiency. Inderscience Publishers - linking academia, business and industry through research

Title: Analysis of the dynamics of the olfactory evoked EEG responses generated by the brain and e-nose under natural and synthetic odorant stimulations

Authors: Ramachandran Sunitha; Suma Sri Sravya Chandu; Asundi Sreedevi

Addresses: Department of Electronics and Communication Engineering, Amrita School of Engineering, Bengaluru, Amrita Vishwa Vidyapeetham, India ' Department of Electronics and Communication Engineering, Amrita School of Engineering, Bengaluru, Amrita Vishwa Vidyapeetham, India ' Deceased; formerly of: R.V. College of Engineering, India

Abstract: Aroma and taste have a disproportionately strong effect on the human brain in comparison to the other senses, however this effect is mostly unappreciated. The capacity for olfaction to perceive, identify, and distinguish a vast number of chemicals present in the air is the consequence of complicated interactions between receptors, smell molecules, and the brain. The purpose of this article is to investigate and comprehend those complex interactions through the analysis of EEG signals recorded in response to a variety of natural and synthetic odorants administered to the mammalian olfactory system. Additionally, a prototype of a portable electronic nose (E-nose) was built, which consists of a sensor array and an Arduino microcontroller running an implementation of Freeman's KIII olfactory model. The sensor array's output is sent to the microcontroller, which generates EEG signals specific to the odorant stimuli applied. The EEG signal generated by the E-nose is then compared to EEG signals gathered from humans in terms of multiscale entropy and fractal dimension, highlighting the E-nose model's efficiency.

Keywords: brain; electroencephalograph; E-nose; KIII model; olfaction; multiscale entropy; fractal dimension.

DOI: 10.1504/IJCSE.2022.124564

International Journal of Computational Science and Engineering, 2022 Vol.25 No.4, pp.410 - 420

Received: 01 Apr 2021
Accepted: 19 Oct 2021
Published online: 28 Jul 2022 *

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Title: Analysis of the dynamics of the olfactory evoked EEG responses generated by the brain and e-nose under natural and synthetic odorant stimulations

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