Hemispheric Lateralization of Auditory Working Memory Regions During Stochastic Resonance: An fMRI Study

Background The auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of auditory working memory brain regions in the presence of background noise, but few studies have focused on the lateralization of these regions...

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Published inJournal of magnetic resonance imaging Vol. 51; no. 6; pp. 1821 - 1828
Main Authors Othman, Elza Azri, Yusoff, Ahmad Nazlim, Mohamad, Mazlyfarina, Abdul Manan, Hanani, Abd Hamid, Aini Ismafairus, Giampietro, Vincent
Format Journal Article
LanguageEnglish
Published Hoboken, USA John Wiley & Sons, Inc 01.06.2020
Wiley Subscription Services, Inc
Subjects
Adolescent
Adult
auditory cortex
Background noise
Brain
Brain - diagnostic imaging
Brain Mapping
Cerebral hemispheres
Cognitive ability
Correlation analysis
Cross-Sectional Studies
Field strength
fMRI
Frontal gyrus
Functional Laterality
Functional magnetic resonance imaging
Hearing
Hemispheric laterality
Humans
Information processing
lateralization
Magnetic Resonance Imaging
Medical imaging
Memory, Short-Term
Neuroimaging
Noise levels
Population studies
Prefrontal cortex
Regression analysis
Resonance
Short term memory
Sound pressure
Statistical analysis
Statistical methods
Statistical tests
Stochastic resonance
Variance analysis
white noise
Young Adult
Young adults
fMRI
lateralization
white noise
auditory cortex
prefrontal cortex
Online AccessGet full text
ISSN1053-1807
1522-2586
1522-2586
DOI10.1002/jmri.27016

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Abstract Background The auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of auditory working memory brain regions in the presence of background noise, but few studies have focused on the lateralization of these regions during stochastic resonance. Purpose To investigate the effects of stochastic resonance on lateralization of auditory working memory regions, and also to examine the brain‐behavior relationship during stochastic resonance. Study Type Cross‐sectional. Population/Subjects Forty healthy young adults (18–24 years old). Field Strength/Sequence 3.0T, T1, and T2*‐weighted imaging. Assessment The auditory working memory performance was assessed using a backward recall task. Functional magnetic resonance imaging (fMRI) was used to measure brain activity during task performance. Functional MRI data were analyzed using SPM12 and WFU PickAtlas. Statistical Tests One‐way independent analyses of variance (ANOVA) were conducted on the behavioral and functional data to examine the main effect of noise level on performance (P < 0.01) and brain activity (P < 0.0042). Hemispheric lateralization was determined by calculating the laterality index. A paired samples t‐test was performed to compare brain activity between hemispheres (P < 0.05). Pearson's correlation analysis and simple linear regression (P < 0.0042) were used to examine the relationship between brain activity and behavioral performance. Results Performance was significantly enhanced during the 50 and 55 dB sound pressure level (SPL) conditions via the stochastic resonance mechanism [F(1,195) = 49.17, P < 0.001]. Activity of the right superior frontal gyrus in the 55 dB SPL condition was significantly positively correlated with performance (R2 = 0.681, P < 0.001). Data Conclusion Our findings demonstrate changes in the lateralization of auditory working memory regions during stochastic resonance and suggest that the right superior frontal gyrus may be a strategic structure involved in the enhancement of auditory working memory performance. Level of Evidence: 2 Technical Efficacy: Stage 4 J. Magn. Reson. Imaging 2020;51:1821–1828.
AbstractList BackgroundThe auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of auditory working memory brain regions in the presence of background noise, but few studies have focused on the lateralization of these regions during stochastic resonance.PurposeTo investigate the effects of stochastic resonance on lateralization of auditory working memory regions, and also to examine the brain‐behavior relationship during stochastic resonance.Study TypeCross‐sectional.Population/SubjectsForty healthy young adults (18–24 years old).Field Strength/Sequence3.0T, T1, and T2*‐weighted imaging.AssessmentThe auditory working memory performance was assessed using a backward recall task. Functional magnetic resonance imaging (fMRI) was used to measure brain activity during task performance. Functional MRI data were analyzed using SPM12 and WFU PickAtlas.Statistical TestsOne‐way independent analyses of variance (ANOVA) were conducted on the behavioral and functional data to examine the main effect of noise level on performance (P < 0.01) and brain activity (P < 0.0042). Hemispheric lateralization was determined by calculating the laterality index. A paired samples t‐test was performed to compare brain activity between hemispheres (P < 0.05). Pearson's correlation analysis and simple linear regression (P < 0.0042) were used to examine the relationship between brain activity and behavioral performance.ResultsPerformance was significantly enhanced during the 50 and 55 dB sound pressure level (SPL) conditions via the stochastic resonance mechanism [F(1,195) = 49.17, P < 0.001]. Activity of the right superior frontal gyrus in the 55 dB SPL condition was significantly positively correlated with performance (R2 = 0.681, P < 0.001).Data ConclusionOur findings demonstrate changes in the lateralization of auditory working memory regions during stochastic resonance and suggest that the right superior frontal gyrus may be a strategic structure involved in the enhancement of auditory working memory performance.Level of Evidence: 2Technical Efficacy: Stage 4J. Magn. Reson. Imaging 2020;51:1821–1828.
Background The auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of auditory working memory brain regions in the presence of background noise, but few studies have focused on the lateralization of these regions during stochastic resonance. Purpose To investigate the effects of stochastic resonance on lateralization of auditory working memory regions, and also to examine the brain‐behavior relationship during stochastic resonance. Study Type Cross‐sectional. Population/Subjects Forty healthy young adults (18–24 years old). Field Strength/Sequence 3.0T, T1, and T2*‐weighted imaging. Assessment The auditory working memory performance was assessed using a backward recall task. Functional magnetic resonance imaging (fMRI) was used to measure brain activity during task performance. Functional MRI data were analyzed using SPM12 and WFU PickAtlas. Statistical Tests One‐way independent analyses of variance (ANOVA) were conducted on the behavioral and functional data to examine the main effect of noise level on performance (P < 0.01) and brain activity (P < 0.0042). Hemispheric lateralization was determined by calculating the laterality index. A paired samples t‐test was performed to compare brain activity between hemispheres (P < 0.05). Pearson's correlation analysis and simple linear regression (P < 0.0042) were used to examine the relationship between brain activity and behavioral performance. Results Performance was significantly enhanced during the 50 and 55 dB sound pressure level (SPL) conditions via the stochastic resonance mechanism [F(1,195) = 49.17, P < 0.001]. Activity of the right superior frontal gyrus in the 55 dB SPL condition was significantly positively correlated with performance (R2 = 0.681, P < 0.001). Data Conclusion Our findings demonstrate changes in the lateralization of auditory working memory regions during stochastic resonance and suggest that the right superior frontal gyrus may be a strategic structure involved in the enhancement of auditory working memory performance. Level of Evidence: 2 Technical Efficacy: Stage 4 J. Magn. Reson. Imaging 2020;51:1821–1828.
The auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of auditory working memory brain regions in the presence of background noise, but few studies have focused on the lateralization of these regions during stochastic resonance.BACKGROUNDThe auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of auditory working memory brain regions in the presence of background noise, but few studies have focused on the lateralization of these regions during stochastic resonance.To investigate the effects of stochastic resonance on lateralization of auditory working memory regions, and also to examine the brain-behavior relationship during stochastic resonance.PURPOSETo investigate the effects of stochastic resonance on lateralization of auditory working memory regions, and also to examine the brain-behavior relationship during stochastic resonance.Cross-sectional.STUDY TYPECross-sectional.Forty healthy young adults (18-24 years old).POPULATION/SUBJECTSForty healthy young adults (18-24 years old).3.0T, T1 , and T2 *-weighted imaging.FIELD STRENGTH/SEQUENCE3.0T, T1 , and T2 *-weighted imaging.The auditory working memory performance was assessed using a backward recall task. Functional magnetic resonance imaging (fMRI) was used to measure brain activity during task performance. Functional MRI data were analyzed using SPM12 and WFU PickAtlas.ASSESSMENTThe auditory working memory performance was assessed using a backward recall task. Functional magnetic resonance imaging (fMRI) was used to measure brain activity during task performance. Functional MRI data were analyzed using SPM12 and WFU PickAtlas.One-way independent analyses of variance (ANOVA) were conducted on the behavioral and functional data to examine the main effect of noise level on performance (P < 0.01) and brain activity (P < 0.0042). Hemispheric lateralization was determined by calculating the laterality index. A paired samples t-test was performed to compare brain activity between hemispheres (P < 0.05). Pearson's correlation analysis and simple linear regression (P < 0.0042) were used to examine the relationship between brain activity and behavioral performance.STATISTICAL TESTSOne-way independent analyses of variance (ANOVA) were conducted on the behavioral and functional data to examine the main effect of noise level on performance (P < 0.01) and brain activity (P < 0.0042). Hemispheric lateralization was determined by calculating the laterality index. A paired samples t-test was performed to compare brain activity between hemispheres (P < 0.05). Pearson's correlation analysis and simple linear regression (P < 0.0042) were used to examine the relationship between brain activity and behavioral performance.Performance was significantly enhanced during the 50 and 55 dB sound pressure level (SPL) conditions via the stochastic resonance mechanism [F(1,195) = 49.17, P < 0.001]. Activity of the right superior frontal gyrus in the 55 dB SPL condition was significantly positively correlated with performance (R2 = 0.681, P < 0.001).RESULTSPerformance was significantly enhanced during the 50 and 55 dB sound pressure level (SPL) conditions via the stochastic resonance mechanism [F(1,195) = 49.17, P < 0.001]. Activity of the right superior frontal gyrus in the 55 dB SPL condition was significantly positively correlated with performance (R2 = 0.681, P < 0.001).Our findings demonstrate changes in the lateralization of auditory working memory regions during stochastic resonance and suggest that the right superior frontal gyrus may be a strategic structure involved in the enhancement of auditory working memory performance.DATA CONCLUSIONOur findings demonstrate changes in the lateralization of auditory working memory regions during stochastic resonance and suggest that the right superior frontal gyrus may be a strategic structure involved in the enhancement of auditory working memory performance.2 Technical Efficacy: Stage 4 J. Magn. Reson. Imaging 2020;51:1821-1828.LEVEL OF EVIDENCE2 Technical Efficacy: Stage 4 J. Magn. Reson. Imaging 2020;51:1821-1828.
The auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of auditory working memory brain regions in the presence of background noise, but few studies have focused on the lateralization of these regions during stochastic resonance. To investigate the effects of stochastic resonance on lateralization of auditory working memory regions, and also to examine the brain-behavior relationship during stochastic resonance. Cross-sectional. Forty healthy young adults (18-24 years old). 3.0T, T , and T *-weighted imaging. The auditory working memory performance was assessed using a backward recall task. Functional magnetic resonance imaging (fMRI) was used to measure brain activity during task performance. Functional MRI data were analyzed using SPM12 and WFU PickAtlas. One-way independent analyses of variance (ANOVA) were conducted on the behavioral and functional data to examine the main effect of noise level on performance (P < 0.01) and brain activity (P < 0.0042). Hemispheric lateralization was determined by calculating the laterality index. A paired samples t-test was performed to compare brain activity between hemispheres (P < 0.05). Pearson's correlation analysis and simple linear regression (P < 0.0042) were used to examine the relationship between brain activity and behavioral performance. Performance was significantly enhanced during the 50 and 55 dB sound pressure level (SPL) conditions via the stochastic resonance mechanism [F(1,195) = 49.17, P < 0.001]. Activity of the right superior frontal gyrus in the 55 dB SPL condition was significantly positively correlated with performance (R = 0.681, P < 0.001). Our findings demonstrate changes in the lateralization of auditory working memory regions during stochastic resonance and suggest that the right superior frontal gyrus may be a strategic structure involved in the enhancement of auditory working memory performance. 2 Technical Efficacy: Stage 4 J. Magn. Reson. Imaging 2020;51:1821-1828.
Author Othman, Elza Azri
Abdul Manan, Hanani
Giampietro, Vincent
Yusoff, Ahmad Nazlim
Abd Hamid, Aini Ismafairus
Mohamad, Mazlyfarina
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lateralization
white noise
auditory cortex
prefrontal cortex
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Snippet Background The auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of...
The auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of auditory...
BackgroundThe auditory and prefrontal cortex supports auditory working memory processing. Many neuroimaging studies have shown hemispheric lateralization of...
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SubjectTerms Adolescent
Adult
auditory cortex
Background noise
Brain
Brain - diagnostic imaging
Brain Mapping
Cerebral hemispheres
Cognitive ability
Correlation analysis
Cross-Sectional Studies
Field strength
fMRI
Frontal gyrus
Functional Laterality
Functional magnetic resonance imaging
Hearing
Hemispheric laterality
Humans
Information processing
lateralization
Magnetic Resonance Imaging
Medical imaging
Memory, Short-Term
Neuroimaging
Noise levels
Population studies
Prefrontal cortex
Regression analysis
Resonance
Short term memory
Sound pressure
Statistical analysis
Statistical methods
Statistical tests
Stochastic resonance
Variance analysis
white noise
Young Adult
Young adults
Title Hemispheric Lateralization of Auditory Working Memory Regions During Stochastic Resonance: An fMRI Study
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fjmri.27016
https://www.ncbi.nlm.nih.gov/pubmed/31794119
https://www.proquest.com/docview/2401715581
https://www.proquest.com/docview/2320875227
Volume 51
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