The functional neuroanatomy of tinnitus

Lockwood, Alan H.; Salvi, Richard; Coad, Mary Lou; Towsley, M. L.; Wack, David S.; Murphy, Benjamin W.

doi:10.1212/wnl.50.1.114

Cited by 556 publications

(363 citation statements)

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“…Tinnitus would reflect an integrated interneuronal neurotransmission pathway including the frontal, temporal, and parietal lobes, thalamus, and cerebellum (Shulman, 2005). A major hypothesis on the pathophysiological mechanisms is that tinnitus would involve a lesion leading to deafferentation of excitatory inputs on thalamic relay cells (Tonndorf, 1987;Moller, 1997;Lockwood et al, 1998). This would lead to a thalamic deactivation (Llinás et al, 2005), disrupting in turn thalamo-cortical interactions (Jeanmonod et al, 1996;Llinás et al, 1999), and leading to the appearance of tinnitus.…”

Section: Discussionmentioning

confidence: 99%

Involvement of cortico-subcortical circuits in normoacousic chronic tinnitus: A source localization EEG study

Houdayer

Teggi

Velikova

et al. 2015

Clinical Neurophysiology

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HIGHLIGHTS• We used sLORETA to study the cerebral activity in normoacousic tinnitus sufferers.• EEG sources were decreased in left temporal and inferior parietal gyri in patients.• Cortico-thalamo-cortical circuits can be involved without thalamic deafferentation. ABSTRACTObjective: To better characterize brain circuits dysfunctions in normoacousic tinnitus sufferers. Methods: 17 normoacousic chronic, unilateral high-pitched tinnitus sufferers (6 females, 43.6 ± 9.8 y.o, disease duration 22 ±35 months) underwent a 29-channel resting-state electroencephalography (EEG -5 min opened-eyes, 5 min closed-eyes) and auditory oddball paradigm for event-related potentials analyses (ERPs -NI, P2 and P300). Cortical 3D distribution of current source density was computed with sLORETA. Results were compared with 17 controls (9 females, 45.7 ± 15.1 y.o). Results: Eyes opened, tinnitus sufferers had lower alpha and beta sources in the left inferior parietal lobule. Eyes closed, tinnitus sufferers had decreased alpha sources in the left inferior temporal and post-central gyri, and low gamma sources in the left middle temporal gyrus. EEG data did not correlate with tinnitus sufferers' clinical features. Subjects with tinnitus had shorter Nl and P2 latencies. P300 did not differ between groups. sLORETA solutions showed decreased sources of these ERPs in the left inferior temporal gyrus in the tinnitus group. Conclusions: We showed cortico-thalamo-cortical involvements in normoacousic tinnitus with hyperexcitability of the left auditory cortex and inferior temporal gyrus. Significance: This might reflect processes of maladaptive cortical plasticity and memory consolidation. Further validation is needed to establish the value of this tool in customizing therapeutic approach.

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Section: Discussionmentioning

confidence: 99%

Involvement of cortico-subcortical circuits in normoacousic chronic tinnitus: A source localization EEG study

Houdayer

Teggi

Velikova

et al. 2015

Clinical Neurophysiology

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“…An early study using PET reported more extensive auditory cortical activation in response to a 2-kHz tone in a group of four TI patients with mild-to-moderate hearing loss (>2 kHz from 30 to 70 dB) compared to controls with hearing levels of 25 dB or better from 0.25 to 8 kHz (Lockwood et al, 1998). While 2 kHz corresponded to the edge of the hearing loss, the TI pitch was matched near the peak of hearing loss, not the lesion edge.…”

Section: Human Neuroimaging Studiesmentioning

confidence: 98%

“…Instead we illustrate some of the neural changes that occur in higher centres of the auditory system that receive inputs from the dorsal cochlear nucleus. Lockwood et al (1998) studied four patients with high-frequency hearing loss who were able to control the loudness of their troublesome TI by performing an oral facial movement. In two patients, the movement decreased TI loudness and this specifically reduced activity in the left primary and nonprimary auditory cortex, contralateral to the TI percept.…”

Section: Voluntary Modulation Of Ti By Somatomotor Movementsmentioning

confidence: 99%

The mechanisms of tinnitus: Perspectives from human functional neuroimaging

2009

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In this review, we highlight the contribution of advances in human neuroimaging to the current understanding of central mechanisms underpinning tinnitus and explain how interpretations of neuroimaging data have been guided by animal models. The primary motivation for studying the neural subtrates of tinnitus in humans has been to demonstrate objectively its representation in the central auditory system and to develop a better understanding of its diverse pathophysiology and of the functional interplay between sensory, cognitive and affective systems. The ultimate goal of neuroimaging is to identify subtypes of tinnitus in order to better inform treatment strategies. The three neural mechanisms considered in this review may provide a basis for TI classification. While human neuroimaging evidence strongly implicates the central auditory system and emotional centres in TI, evidence for the precise contribution from the three mechanisms is unclear because the data are somewhat inconsistent. We consider a number of methodological issues limiting the field of human neuroimaging and recommend approaches to overcome potential inconsistency in results arising from poorly matched participants, lack of appropriate controls and low statistical power. AbstractIn this review, we highlight the contribution of advances in human neuroimaging to the current understanding of central mechanisms underpinning tinnitus and explain how interpretations of neuroimaging data have been guided by animal models. The primary motivation for studying the neural subtrates of tinnitus in humans has been to demonstrate objectively its representation in the central auditory system and to develop a better understanding of its diverse pathophysiology and of the functional interplay between sensory, cognitive and affective systems. The ultimate goal of neuroimaging is to identify subtypes of tinnitus in order to better inform treatment strategies. The three neural mechanisms considered in this review may provide a basis for TI classification. While human neuroimaging evidence strongly implicates the central auditory system and emotional centres in TI, evidence for the precise contribution from the three mechanisms is unclear because the data are somewhat inconsistent. We consider a number of methodological issues limiting the field of human neuroimaging and recommend approaches to overcome potential inconsistency in results arising from poorly matched participants, lack of appropriate controls and low statistical power.

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“…Finally, excellent critical literature summaries on the neurobiology of tinnitus have emerged which detail the aspects touched upon below (e.g. Baguley, 2002;Bauer, 2004;Eggermont, 2005;Eggermont & Roberts, 2004;Kaltenbach, 2006;Kaltenbach, Zhang, & Afman, 2000;Lockwood et al, 1998Lockwood et al, , 2005Møller, 2006;Salvi, Lockwood, & Burkard, 2000).…”

Section: Tinnitus Backgroundmentioning

confidence: 99%

“…These methods have been applied with success in human tinnitus patients to identify various brain areas active during phantom perceptions, and to examine the effects of some treatments (see for example Giraud et al, 1999;Mirz et al, 1999;Reyes et al, 2002). There is now good evidence from PET and magnetic encephalography that a reorganization of the frequency axis in the human auditory cortex occurs much as described above (Lockwood et al, 1998;Mühlnickel et al, 1998). Nevertheless, a more recent study using neuromagnetic recordings (this permitted identification of highly specific brain locations) suggested that equivalent dipole activity at the edge of hearing loss was no more active than control locations (Weisz, Wienburch, Dohrmann, & Elbert, 2005).…”

Section: Cortical Reorganization and Tinnitusmentioning

confidence: 99%

The role of central nervous system plasticity in tinnitus

Saunders

2007

Journal of Communication Disorders

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Tinnitus is a vexing disorder of hearing characterized by sound sensations originating in the head without any external stimulation. The specific etiology of these sensations is uncertain but frequently associated with hearing loss. The "neurophysiogical" model of tinnitus has enhanced appreciation of central nervous system (CNS) contributions. The model assumes that plastic changes in the primary and non-primary auditory pathways contribute to tinnitus with the former perhaps sustaining them, and the latter contributing to perceived severity and emotionality. These plastic changes are triggered by peripheral injury, which results in new patterns of brain activity due to anatomic alterations in the connectivity of CNS neurons. These alterations may change the balance between excitatory and inhibitory brain processes, perhaps producing cascades of new neural activity flowing between brainstem and cortex in a self-sustaining manner that produces persistent perceptions of tinnitus. The bases of this model are explored with an attempt to distinguish phenomenological from mechanistic explanations.Learning outcomes-(1) Readers will learn that the variables associated with the behavioral experience of tinnitus are as complex as the biological variables. (2) Readers will understand what the concept of neuroplastic brain change means, and how it is associated with tinnitus. (3) Readers will learn that there may be no one brain location associated with tinnitus, and it may result from interactions between multiple brain areas. (4) Readers will learn how disinhibition, spontaneous activity, neural synchronization, and tonotopic reorganization may contribute to tinnitus.

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The functional neuroanatomy of tinnitus

Cited by 556 publications

References 10 publications

Involvement of cortico-subcortical circuits in normoacousic chronic tinnitus: A source localization EEG study

Involvement of cortico-subcortical circuits in normoacousic chronic tinnitus: A source localization EEG study

The mechanisms of tinnitus: Perspectives from human functional neuroimaging

The role of central nervous system plasticity in tinnitus

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