Diane S. Lazard

Bilateral reorganization of posterior temporal cortices in post-lingual deafness and its relation to cochlear implant outcome

Post‐lingual deafness induces a decline in the ability to process phonological sounds or evoke phonological representations. This decline is paralleled with abnormally high neural activity in the right posterior superior temporal gyrus/supramarginal gyrus (PSTG/SMG). As this neural plasticity negatively relates to cochlear implantation (CI) success, it appears important to understand its determinants. We addressed the neuro‐functional mechanisms underlying this maladaptive phenomenon using behavioral and functional magnetic resonance imaging (fMRI) data acquired in 10 normal‐hearing subjects and 10 post‐lingual deaf candidates for CI. We compared two memory tasks where subjects had to evoke phonological (speech) and environmental sound representations from visually presented items. We observed dissociations in the dynamics of right versus left PSTG/SMG neural responses as a function of duration of deafness. Responses in the left PSTG/SMG to phonological processing and responses in the right PSTG/SMG to environmental sound imagery both declined. However, abnormally high neural activity was observed in response to phonological visual items in the right PSTG/SMG, i.e., contralateral to the zone where phonological activity decreased. In contrast, no such responses (overactivation) were observed in the left PSTG/SMG in response to environmental sounds. This asymmetry in functional adaptation to deafness suggests that maladaptive reorganization of the right PSTG/SMG region is not due to balanced hemispheric interaction, but to a specific take‐over of the right PSTG/SMG region by phonological processing, presumably because speech remains behaviorally more relevant to communication than the processing of environmental sounds. These results demonstrate that cognitive long‐term alteration of auditory processing shapes functional cerebral reorganization. Hum Brain Mapp, 2013.

Understanding the deafened brain: implications for cochlear implant rehabilitation

The cochlear implant (CI), by enabling oral communication in severely to profoundly deaf subjects, is one of the major medical advances over the last fifty years. Despite the globally very satisfactory results, individual outcomes vary considerably. The objective of this review is to describe the various factors influencing the results of CI rehabilitation with particular emphasis on the better understanding of neurocognitive mechanisms provided by functional brain imaging. The following aspects will be discussed: 1. Peripheral predictors such as the degree of preservation of nerve structures and the positioning of the electrode array. 2. The duration of auditory deprivation whose influence on brain reorganization is now becoming more clearly understood. 3. The age of initiation of hearing rehabilitation in subjects with pre-lingual deafness influencing the possibility of physiological maturation of nerve structures. 4. The concepts of sensitive period, decoupling and cross-modality. 5. In post-lingually deaf adults, brain plasticity can allow adaptation to the disability induced by deafness, subsequently potentiating CI rehabilitation, particularly as a result of audiovisual interactions. 6. Several studies provide concordant evidence that implanted patients present different phonological analysis and primary linguistic capacities. The results of CI rehabilitation are dependent on factors situated between the cochlea and cortical associative areas. The importance of higher cognitive influences on the functional results of cochlear implantation justify adaptation of coding strategies, as well as global cognitive management of deaf patients by utilising brain plasticity capacities.

Congenital cholesteatoma: risk factors for residual disease and retraction pockets--a report on 117 cases.

Objectives: To define predictors of residuals and retraction pockets (RP) in children operated on for congenital cholesteatoma (CC).

Evolution of non-speech sound memory in postlingual deafness: implications for cochlear implant rehabilitation

Neurofunctional patterns assessed before or after cochlear implantation (CI) are informative markers of implantation outcome. Because phonological memory reorganization in post-lingual deafness is predictive of the outcome, we investigated, using a cross-sectional approach, whether memory of non-speech sounds (NSS) produced by animals or objects (i.e. non-human sounds) is also reorganized, and how this relates to speech perception after CI. We used an fMRI auditory imagery task in which sounds were evoked by pictures of noisy items for post-lingual deaf candidates for CI and for normal-hearing subjects. When deaf subjects imagined sounds, the left inferior frontal gyrus, the right posterior temporal gyrus and the right amygdala were less activated compared to controls. Activity levels in these regions decreased with duration of auditory deprivation, indicating declining NSS representations. Whole brain correlations with duration of auditory deprivation and with speech scores after CI showed an activity decline in dorsal, fronto-parietal, cortical regions, and an activity increase in ventral cortical regions, the right anterior temporal pole and the hippocampal gyrus. Both dorsal and ventral reorganizations predicted poor speech perception outcome after CI. These results suggest that post-CI speech perception relies, at least partially, on the integrity of a neural system used for processing NSS that is based on audio-visual and articulatory mapping processes. When this neural system is reorganized, post-lingual deaf subjects resort to inefficient semantic- and memory-based strategies. These results complement those of other studies on speech processing, suggesting that both speech and NSS representations need to be maintained during deafness to ensure the success of CI.

Speech Processing: From Peripheral to Hemispheric Asymmetry of the Auditory System

Language processing from the cochlea to auditory association cortices shows side‐dependent specificities with an apparent left hemispheric dominance. The aim of this article was to propose to nonspeech specialists a didactic review of two complementary theories about hemispheric asymmetry in speech processing. Starting from anatomico‐physiological and clinical observations of auditory asymmetry and interhemispheric connections, this review then exposes behavioral (dichotic listening paradigm) as well as functional (functional magnetic resonance imaging and positron emission tomography) experiments that assessed hemispheric specialization for speech processing. Even though speech at an early phonological level is regarded as being processed bilaterally, a left‐hemispheric dominance exists for higher‐level processing. This asymmetry may arise from a segregation of the speech signal, broken apart within nonprimary auditory areas in two distinct temporal integration windows—a fast one on the left and a slower one on the right—modeled through the asymmetric sampling in time theory or a spectro‐temporal trade‐off, with a higher temporal resolution in the left hemisphere and a higher spectral resolution in the right hemisphere, modeled through the spectral/temporal resolution trade‐off theory. Both theories deal with the concept that lower‐order tuning principles for acoustic signal might drive higher‐order organization for speech processing. However, the precise nature, mechanisms, and origin of speech processing asymmetry are still being debated. Finally, an example of hemispheric asymmetry alteration, which has direct clinical implications, is given through the case of auditory aging that mixes peripheral disorder and modifications of central processing.

Faster phonological processing and right occipito-temporal coupling in deaf adults signal poor cochlear implant outcome

The outcome of adult cochlear implantation is predicted positively by the involvement of visual cortex in speech processing, and negatively by the cross-modal recruitment of the right temporal cortex during and after deafness. How these two neurofunctional predictors concur to modulate cochlear implant (CI) performance remains unclear. In this fMRI study, we explore the joint involvement of occipital and right hemisphere regions in a visual-based phonological task in post-lingual deafness. Intriguingly, we show that some deaf subjects perform faster than controls. This behavioural effect is associated with reorganized connectivity across bilateral visual, right temporal and left inferior frontal cortices, but with poor CI outcome. Conversely, preserved normal-range reaction times are associated with left-lateralized phonological processing and good CI outcome. These results suggest that following deafness, involvement of visual cortex in the context of reorganized right-lateralized phonological processing compromises its availability for audio-visual synergy during adaptation to CI.