Age-related hearing loss increases full-brain connectivity while reversing directed signaling within the dorsal–ventral pathway for speech

Speech comprehension difficulties are ubiquitous to aging and hearing loss, particularly in noisy environments. Older adults’ poorer speech-in-noise (SIN) comprehension has been related to abnormal neural representations within various nodes (regions) of the speech network, but how senescent changes...

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Bibliographic Details
Published in:Brain Structure and Function 2019-11, Vol.224 (8), p.2661-2676
Main Authors: Bidelman, Gavin M., Mahmud, Md Sultan, Yeasin, Mohammed, Shen, Dawei, Arnott, Stephen R., Alain, Claude
Format: Article
Language:English
Subjects:
Acoustic Stimulation
Aged
Aging
Aging - physiology
Aging - psychology
Audiometry
Biomedical and Life Sciences
Biomedicine
Brain - physiopathology
Brain Mapping - methods
Cell Biology
Comprehension - physiology
Cortex (auditory)
Cortex (frontal)
Cortex (motor)
EEG
Electroencephalography
Evoked Potentials, Auditory
Female
Frontal gyrus
Hearing loss
Hearing Loss - physiopathology
Hearing protection
Hemispheric laterality
Humans
Male
Middle Aged
Neural networks
Neural Pathways - physiopathology
Neurology
Neurosciences
Older people
Original Article
Signal transduction
Speech
Speech Perception - physiology
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Summary:Speech comprehension difficulties are ubiquitous to aging and hearing loss, particularly in noisy environments. Older adults’ poorer speech-in-noise (SIN) comprehension has been related to abnormal neural representations within various nodes (regions) of the speech network, but how senescent changes in hearing alter the transmission of brain signals remains unspecified. We measured electroencephalograms in older adults with and without mild hearing loss during a SIN identification task. Using functional connectivity and graph-theoretic analyses, we show that hearing-impaired (HI) listeners have more extended (less integrated) communication pathways and less efficient information exchange among widespread brain regions (larger network eccentricity) than their normal-hearing (NH) peers. Parameter optimized support vector machine classifiers applied to EEG connectivity data showed hearing status could be decoded (> 85% accuracy) solely using network-level descriptions of brain activity, but classification was particularly robust using left hemisphere connections. Notably, we found a reversal in directed neural signaling in left hemisphere dependent on hearing status among specific connections within the dorsal–ventral speech pathways. NH listeners showed an overall net “bottom-up” signaling directed from auditory cortex (A1) to inferior frontal gyrus (IFG; Broca’s area), whereas the HI group showed the reverse signal (i.e., “top-down” Broca’s → A1). A similar flow reversal was noted between left IFG and motor cortex. Our full-brain connectivity results demonstrate that even mild forms of hearing loss alter how the brain routes information within the auditory–linguistic–motor loop.
ISSN:1863-2653
1863-2661
0340-2061
DOI:10.1007/s00429-019-01922-9