Background: Quran memorizing causes a state of trance, which its result is the changes in the amplitude and time of P300 and N200 components in the event related potential (ERP) signal. Nevertheless, a limited number of studies that have examined the effects of Quran memorizing on brain signals to enhance relaxation and attention, and improve the lives of patients with autism and stroke, generally have not presented any analysis based on comparing structural differences relevant to features extracted from ERP signal obtained from the two groups of Quran memorizer and nonmemorizer by using the hybrid of graph theory and competitive networks.Methods: In this study, we investigated structural differences relevant to the graph obtained from the weight of neural gas (NG) and growing NG (GNG) networks trained by features extracted from the ERP signal recorded from two groups during the PRM test. In this analysis, we actually estimated the ERP signal by averaging the brain background data in the recovery phase. Then, we extracted six features related to the power and the complexity of these signals and selected optimal channels in each of the features by using the t test analysis. Then, these features extracted from the optimal channels are applied for developing the NG and GNG networks. Finally, we evaluated different parameters calculated from graphs, in which their connection matrix was obtained from the weight matrix of the networks. Results: The outcomes of this analysis show that increasing the power of low frequency components and the power ratio of low frequency components to high frequency components in the memorizers, which represents patience, concentration, and relaxation, is more than that of the nonmemorizers. These outcomes also show that the optimal channels in different features, which were often in frontal, peritoneal, and occipital regions, had a significant difference (P < 0.05). It is remarkable that two parameters of the graphs established based on two competitive networks, i.e. average path length and the average of the weights in the memorizers, were larger than the nonmemorizers, which means more data scattering in this group.Conclusion: This condition in the mentioned graphs suggests that the Quran memorizing causes a significant change in ERP signals, so that its features have usually more scattering.

Event-related potential signal, neural gas and growing neural gas networks, Quran memorizer and nonmemorizer, visual memory

Ma'ruf IJ, Suminah OH, Sulaeman ES. The Effect of Memorizing the Al Quran on Quality of Life in Stroke Patients with Aphasia Motoric Disorders. Glob J Health Sci 2019;11(7):29-46.

Hojjati A, Davod Abadi Farehani M, Sobhi-Gharamaleki N. Effectiveness of Quran tune on memory in children. Procedia Soc Behav Sci 2014;12:283-6.

Zulkurnaini NA, Murat ZH, Mohd Isa R. The Comparison Between Listening to Al-Quran and Listening to Classical Music on the Brainwave Signal for the Alpha Band. Third International Conference on Intelligent Systems Modelling and Simulation; 2012. p. 181-6.

Tumira MA, Saat RM, Yusoff MY, Abdul Rahman N, Adli DS. Addressing sleep disorder of autistic children with Qur'anic sound therapy. Biomed Life Sci 2013;8:73-9.

Al-Attas R. The Qur'an and memory a (study of the effect of religiosity and memorizing Qur'an as a factor on memory. J Alzheimer's 2011;7:1-10.

Mahjoob M, Nejati J, Hosseini A, Bakhshani NM. The effect of Holy Quran voice onmental health. J Relig Health 2016;55:38-44.

Maximo VR, Quiles MG, Nascimento MC. A consensus-based semi-supervised growing neural gas. Neural Netw 2014;11:62-73.

Auwatanamongkol S, Jirayusakul A. A Supervised Growing Neural Gas Algorithm for Cluster Analysis. Int J Hybrid Intell Syst 2007;4:217-229.

Qin AK, Suganthan PN. Robust growing neural gas algorithm with application in cluster analysis. Neural Netw 2004;17:35-48.

Ghaseminezhad MH, Karami A. A novel self-organizing map (SOM) neural network for discrete groups of data clustering. Appl Soft Comput 2011;11:3771-8.

Xu L, Xu Y, Chow TW. PolSOM: A new method for multidimensional data visualization. Pattern Recognit 2014;43:1668-75.

Ishihara S. Tests for Color-Blindness. Tokyo: Handaya and Hongo Harukicho; 1917.

Oldfield. The assessment and analysis of handedness: The Edinburgh inventory. Neuropsychologia 1971;9:97-113.

Available from: http://www.cambridgecognition.com. [Last accessed on 2017 Jun 12].

Available from: http://www.cambridgecoNGition.com. [Last accessed on 2017 Jun 12].

Ghoshuni M, Shahsavar Y, Quantifying clinical improvements in patients with depression under the treatment of transcranial direct current stimulation using event related potentials. Australas Phys Eng Sci Med 2018; 41: 973-83.

Herrmann CS, Rach S, Vosskuhl J, Struber D. Time– Frequency Analysis of Event-Related Potentials. Brain Topogr 2013;28:438-450.

Ghoshuni M, Shahsavar Y. Assessing the impact of congrent and incongrent stimulus in stroop task, using event- related potentials (ERP) in patients with depression. Biomed Eng Appl Basis Commun 2018;30:1-9.

Martinetz M, Schulten KJ. A Neural Gas Network Learns Topologies, Artificial Neural Networks. 1991. p. 397-402. North Holland, Amsterdam.

Fritzke B. A Growing Neural Gas Network Learns Topologies. Advances in Neural Information Processing Systems. Vol. 7. Cambridge MA: MIT Press; 1995. p. 625-32.

Cahill ND. Alexander Strang, Relationships between Characteristic Path Length, Efficiency. Clustering Coefficients, and Density; 2017;1:1-15.

Cepeda-Freyre HA, Eguibar JR, Cortes C. Brain Processing of Complex Geometric Forms in Visual Memory Task Increases P2 Amplitude. Brain Sci 2020;10:114-35.

Ramchurn A, Mason L, Darling S, Bunce D. Intraindividual reaction time variability affects P300 amplitude rather than latency. Human Neurosc 2014;8:1-9.