Decomposing the role of alpha oscillations during brain maturation

Tröndle, Marius; Popov, Tzvetan; Dziemian, Sabine; Langer, Nicolas

doi:10.7554/elife.77571

Cited by 29 publications

(26 citation statements)

References 103 publications

(208 reference statements)

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“…This is an important distinction, because unadjusted alpha power (i.e., including aperiodic signal) is likely to reflect a mixture of different physiological processes and may be misleading when used to link alpha rhythms to specific cognitive states. For example, we were able to replicate previous findings of a decreased aperiodic slope and intercept with increasing age (Tröndle et al, 2022;Cellier et al, 2021, Cesnaite et al, 2023. The markedly steeper slope in our 6-21 year olds (see Fig 3C) relative to both the 22-36 and 37-76 year olds may reflect a higher prevalence of low-, relative to high-frequency activity in the youngest participants, increased neural "noise" in older age (McIntosh et al, 2010), and/or developmental changes in skull thickness.…”

Section: Discussionsupporting

confidence: 78%

“…For the sake of simplicity, and to facilitate testing of a large number of people very quickly, we also decided not to collect additional demographic or clinical information from the participants, other than their age and gender. There was no indication that peak alpha frequency or power differed between male and female participants in our dataset, although differences between groups in one, or both, of these measures have been described in previous studies (Cragg et al, 2011;Tröndle et al, 2022). Due to the open nature of our recruitment process, we may have included participants, by design, whose alpha oscillations may be classed as "atypical" relative to the healthy population.…”

Section: Discussionmentioning

confidence: 89%

“…Peak occipital alpha frequency is typically slower in young children, at around 6 Hz, and peaking at around 10 Hz in older children and adults (Marshall et al, 2002). The total power of this peak alpha oscillation has also been shown across many studies to decrease with advancing age, both during childhood (Tröndle et al, 2022) and into older adulthood (Whitford et al, 2007). This may reflect a change in white matter integrity and/or loss of grey matter volume throughout the lifespan (Grandy et al, 2013).…”

Section: Introductionmentioning

confidence: 95%

“…However, a more recent analytic approach, of dissociating the periodic from aperiodic EEG signal, has shown that older adults may simply experience more broadband 1/f 'noise' in their visual systems (Voytek et al, 2015), which may have confounded previous analyses of IAF. In an analysis of 2529 people aged 5-22 years old, Tröndle et al (2022) found that, after correcting for aperiodic signal, alpha power may in fact increase rather than decrease during childhood and adolescence, and decrease between 60-79 years old (Cesnaite et al, 2023). We aimed to address these questions in a large sample of participants.…”

Section: Introductionmentioning

confidence: 96%

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Developmental changes in individual alpha frequency: Recording EEG data during public engagement events

Turner

Baylan

Bracco

et al. 2023

Preprint

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Statistical power in cognitive neuroimaging experiments is often very low. Low sample size can reduce the likelihood of detecting real effects (false negatives) and increase the risk of detecting non-existing effects by chance (false positives). Here we document our experience of leveraging a relatively unexplored method of collecting a large sample size for simple electroencephalography (EEG) studies: by recording EEG in the community during public engagement and outreach events. We collected data from 346 participants (189 females, age range 6-76 years) over 6 days, totalling 29 hours, at local science festivals. Occipital alpha activity (6-15 Hz) was filtered from 30 seconds of signal, recorded from a single electrode placed on the occipital midline (Oz) while participants rested with their eyes closed. A total of 289 good quality datasets were obtained. Using this community-based approach, we were able to replicate controlled, lab-based findings: IAF increased during childhood, reaching a peak frequency of 10.28 Hz at 28.1 years old, and slowed again in middle and older age. Total alpha power decreased linearly, but the aperiodic-adjusted alpha power did not change over the lifespan. Aperiodic slopes and intercepts were highest in the youngest participants. There were no associations between these EEG indexes and self-reported fatigue, measured by the Multidimensional Fatigue Inventory. Finally, we present a set of important considerations for researchers who wish to collect EEG data within public engagement and outreach environments.

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Section: Discussionsupporting

confidence: 78%

Section: Discussionmentioning

confidence: 89%

Section: Introductionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 96%

See 2 more Smart Citations

Developmental changes in individual alpha frequency: Recording EEG data during public engagement events

Turner

Baylan

Bracco

et al. 2023

Preprint

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“…The rhythmic and aperiodic components are important to disentangle as they are probably generated by different mechanisms. Aperiodic signal is believed to represent excitation-inhibition balance (Gao et al, 2017) and is modulated, e.g ., by brain maturation (McSweeney et al, 2021; Hill et al, 2022; Tröndle et al, 2022), aging (Voytek et al, 2015; Wilson et al, 2022) and several neurological and psychiatric conditions (Molina et al, 2020; Ostlund et al, 2021; Semenova et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Human sensorimotor beta event characteristics and aperiodic signal are highly heritable

Pauls

Salmela

Korsun

et al. 2023

Preprint

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Individuals' phenotypes, including the brain's structure and function, are largely determined by genes and their interplay. The resting brain generates salient rhythmic patterns which can be characterized non-invasively using functional neuroimaging such as magnetoencephalography (MEG). One of these rhythms, the somatomotor ('rolandic') beta rhythm, shows intermittent high amplitude 'events' which predict behavior across tasks and species. Beta rhythm is altered in neurological disease. The aperiodic ('1/f') signal present in electrophysiological recordings is also modulated by some neurological conditions and aging. Both sensorimotor beta and aperiodic signal could thus serve as biomarkers of sensorimotor function. Knowledge about the extent to which these brain functional measures are heritable could shed light on the mechanisms underlying their generation. We investigated the heritability and variability of human spontaneous sensorimotor beta rhythm and aperiodic activity in 210 healthy adult siblings' spontaneous MEG activity. Both the overall beta spectral power as well as time-resolved beta event amplitude parameters were highly heritable, whereas the heritabilities for peak frequency and measures of event duration remained nonsignificant. Interestingly, the most heritable trait was the aperiodic 1/f signal, with a heritability of 0.94 in the right hemisphere. Human sensorimotor neural activity can thus be dissected into different components with variable heritability. We postulate that differences in heritability in part reflect different underlying signal generating mechanisms. The 1/f signal and beta event amplitude measures may depend more on fixed, anatomical parameters, whereas beta event duration and its modulation reflect dynamic characteristics, guiding their use as potential disease biomarkers.

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Human sensorimotor resting state beta events and aperiodic signals response show good test-retest reliability

Amande M. Pauls,

Nurmi,

Ala-Salomäki

et al. 2024

Clinical Neurophysiology

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Decomposing the role of alpha oscillations during brain maturation

Cited by 29 publications

References 103 publications

Developmental changes in individual alpha frequency: Recording EEG data during public engagement events

Developmental changes in individual alpha frequency: Recording EEG data during public engagement events

Human sensorimotor beta event characteristics and aperiodic signal are highly heritable

Human sensorimotor resting state beta events and aperiodic signals response show good test-retest reliability

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