Adam Gazzaley

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Age-Related Changes in 1/f Neural Electrophysiological Noise

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ABSTRACT

Aging is associated with performance decrements across multiple cognitive domains. The neural noise hypothesis, a dominant view of the basis of this decline, posits that aging is accompanied by an increase in spontaneous, noisy baseline neural activity. Here we analyze data from two different groups of human subjects: intracranial electrocorticography from 15 participants over a 38 year age range (15–53 years) and scalp EEG data from healthy younger (20 –30 years) and older (60 –70 years) adults to test the neural noise hypothesis from a 1/f noise perspective. Many natural phenomena, including electrophysiology, are characterized by 1/f noise. The defining characteristic of 1/f is that the power of the signal frequency content decreases rapidly as a function of the frequency ( f ) itself. The slope of this decay, the noise exponent (), is often1 for electrophysiological data and has been shown to approach white noise (defined as  0) with increasing task difficulty.Weobserved, in both electrophysiological datasets, that aging is associated with a flatter (more noisy) 1/f power spectral density, even at rest, and that visual cortical 1/f noise statistically mediates age-related impairments in visual working memory. These results provide electrophysiological support for the neural noise hypothesis of aging.





AUTHORS

  • Bradley Voytek

  • Mark A. Kramer

  • John Case

  • Kyle Q. Lepage

  • Zachary Tempesta

  • Robert T. Knight

  • Adam Gazzaley

Date: 2015

DOI: 10.1523/JNEUROSCI.2332-14.2015

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Age-related top down suppression deficit in the early stages of cortical visual memory processing

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Authors:

  • Adam Gazzaley

  • Wesley Clapp

  • Jon Kelley

  • Kevin McEvoy

  • Robert T. Knight

  • Mark D'Esposito

Date: 2008

DOI: 10.1073/pnas.0806074105

PubMed: 18765818

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Abstract:

In this study, electroencephalography (EEG) was used to examine the relationship between two leading hypotheses of cognitive aging, the inhibitory deficit and the processing speed hypothesis. We show that older adults exhibit a selective deficit in suppressing task-irrelevant information during visual working memory encoding, but only in the early stages of visual processing. Thus, the employment of suppressive mechanisms are not abolished with aging but rather delayed in time, revealing a decline in processing speed that is selective for the inhibition of irrelevant information. EEG spectral analysis of signals from frontal regions suggests that this results from excessive attention to distracting information early in the time course of viewing irrelevant stimuli. Subdividing the older population based on working memory performance revealed that impaired suppression of distracting information early in the visual processing stream is associated with poorer memory of task-relevant information. Thus, these data reconcile two cognitive aging hypotheses by revealing that an interaction of deficits in inhibition and processing speed contributes to agerelated cognitive impairment.

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Top-down enhancement and suppression of the magnitude and speed of neural activity

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Authors:

  • Adam Gazzaley

  • Jeffrey W. Cooney

  • Kevin McEvoy

  • Robert T. Knight

  • Mark D'Esposito

Date: 2005

PubMed: 15814009

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Abstract:

Top-down modulation underlies our ability to selectively attend to relevant stimuli and to ignore irrelevant stimuli. Theories addressing neural mechanisms of top-down modulation are driven by studies that reveal increased magnitude of neural activity in response to directed attention, but are limited by a lack of data reporting modulation of neural processing speed, as well as comparisons with a perceptual (passive view) baseline necessary to evaluate the presence of enhancement and suppression. Utilizing functional MRI (fMRI) and event-related potential recordings (ERPs), we provide converging evidence that both the magnitude of neural activity and the speed of neural processing are modulated by top-down influences. Furthermore, both enhancement and suppression occur relative to a perceptual baseline depending on task instruction. These findings reveal the fine degree of influence that goal-directed attention exerts upon activity within the visual association cortex. We further document capacity limitations in top-down enhancement corresponding with working memory performance deficits.