Mikel Lizarazu

Out‐of‐synchrony speech entrainment in developmental dyslexia

Developmental dyslexia is a reading disorder often characterized by reduced awareness of speech units. Whether the neural source of this phonological disorder in dyslexic readers results from the malfunctioning of the primary auditory system or damaged feedback communication between higher‐order phonological regions (i.e., left inferior frontal regions) and the auditory cortex is still under dispute. Here we recorded magnetoencephalographic (MEG) signals from 20 dyslexic readers and 20 age‐matched controls while they were listening to ∼10‐s‐long spoken sentences. Compared to controls, dyslexic readers had (1) an impaired neural entrainment to speech in the delta band (0.5–1 Hz); (2) a reduced delta synchronization in both the right auditory cortex and the left inferior frontal gyrus; and (3) an impaired feedforward functional coupling between neural oscillations in the right auditory cortex and the left inferior frontal regions. This shows that during speech listening, individuals with developmental dyslexia present reduced neural synchrony to low‐frequency speech oscillations in primary auditory regions that hinders higher‐order speech processing steps. The present findings, thus, strengthen proposals assuming that improper low‐frequency acoustic entrainment affects speech sampling. This low speech‐brain synchronization has the strong potential to cause severe consequences for both phonological and reading skills. Interestingly, the reduced speech‐brain synchronization in dyslexic readers compared to normal readers (and its higher‐order consequences across the speech processing network) appears preserved through the development from childhood to adulthood. Thus, the evaluation of speech‐brain synchronization could possibly serve as a diagnostic tool for early detection of children at risk of dyslexia. Hum Brain Mapp 37:2767–2783, 2016.

Developmental evaluation of atypical auditory sampling in dyslexia: Functional and structural evidence.

Whether phonological deficits in developmental dyslexia are associated with impaired neural sampling of auditory information at either syllabic‐ or phonemic‐rates is still under debate. In addition, whereas neuroanatomical alterations in auditory regions have been documented in dyslexic readers, whether and how these structural anomalies are linked to auditory sampling and reading deficits remains poorly understood. In this study, we measured auditory neural synchronization at different frequencies corresponding to relevant phonological spectral components of speech in children and adults with and without dyslexia, using magnetoencephalography. Furthermore, structural MRI was used to estimate cortical thickness of the auditory cortex of participants. Dyslexics showed atypical brain synchronization at both syllabic (slow) and phonemic (fast) rates. Interestingly, while a left hemispheric asymmetry in cortical thickness was functionally related to a stronger left hemispheric lateralization of neural synchronization to stimuli presented at the phonemic rate in skilled readers, the same anatomical index in dyslexics was related to a stronger right hemispheric dominance for neural synchronization to syllabic‐rate auditory stimuli. These data suggest that the acoustic sampling deficit in development dyslexia might be linked to an atypical specialization of the auditory cortex to both low and high frequency amplitude modulations. Hum Brain Mapp 36:4986–5002, 2015.

Numbers are not like words: Different pathways for literacy and numeracy

Literacy and numeracy are two fundamental cognitive skills that require mastering culturally-invented symbolic systems for representing spoken language and quantities. How numbers and words are processed in the human brain and their temporal dynamics remain unclear. Using MEG (magnetoencephalography), we find brain activation differences for literacy and numeracy from early stages of processing in the temporal-occipital and temporal-parietal regions. Native speakers of Spanish were exposed to visually presented words, pseudowords, strings of numbers, strings of letters and strings of symbols while engaged in a go/no-go task. Results showed more evoked neuromagnetic activity for words and pseudowords compared to symbols at ~120-130ms in the left occipito-temporal and temporal-parietal cortices (angular gyrus and intra-parietal sulcus) and at ~200ms in the left inferior frontal gyrus and left temporal areas. In contrast, numbers showed more activation than symbols at similar time windows in homologous regions of the right hemisphere: occipito-temporal and superior and middle temporal cortices at ~100-130ms. A direct comparison between the responses to words and numbers confirmed this distinct lateralization for the two stimulus types. These results suggest that literacy and numeracy follow distinct processing streams through the left and right hemispheres, respectively, and that the temporal-parietal and occipito-temporal regions may interact during processing alphanumeric stimuli.

Is there a common oscillatory brain mechanism for producing and predicting language

ABSTRACT Recent proposals have suggested that language prediction is supported by the neurophysiological mechanisms involved in language production. Both prediction and production in language imply information processing percolating down from abstract semantic representations to lower-level processing steps, either for articulation (action) or active sensation (perception). Language production studies have repeatedly reported desynchronisation of oscillatory beta power (13–30 Hz) over the left frontal cortex during word generation. Crucially, predictive coding theories propose that the beta frequency channel mediates top-down propagation of information during prediction. The present study evaluates initial experimental evidence on pre-stimulus activity during speech production and discusses the similar oscillatory dynamics involved in preparation for perception of words. We try to better characterise what processing dynamics the pre-stimulus beta-band activity represents, illustrating with some results from our lab. This evidence motivates the need for more fine-grained psycholinguistic paradigms to better characterise whether prediction and production are supported by similar neurophysiological mechanisms.

Amodal Atypical Neural Oscillatory Activity in Dyslexia: A Cross-Linguistic Perspective

It has been proposed that atypical neural oscillations in both the auditory and the visual modalities could explain why some individuals fail to learn to read and suffer from developmental dyslexia. However, the role of specific oscillatory mechanisms in reading acquisition is still under debate. In this article, we take a cross-linguistic approach and argue that both the phonological and orthographic specifics of a language (e.g., linguistic rhythm, orthographic depth) shape the oscillatory activity thought to contribute to reading development. The proposed theoretical framework should allow future research to test cross-linguistic hypotheses that will shed light on the heterogeneity of auditory and visual disorders and their underlying brain dysfunction(s) in developmental dyslexia, and inform clinical practice by helping us to diagnose dyslexia across languages.

Low frequency overactivation in dyslexia: Evidence from resting state Magnetoencephalography

In this study, we compared the brain activation profiles obtained from resting state Magnetoencephalographic (MEG) activity in 15 dyslexic patients with the profiles of 15 normal controls, using power spectral density (PSD) analysis. We first estimated intracranial dipolar MEG sources on a dense grid on the cortical surface and then projected these sources on a standardized atlas with 68 regions of interest (ROIs). Averaging the PSD values of all sources in each ROI across all control subjects resulted in a normative database that was used to convert the PSD values of dyslexic patients into z-scores in eight distinct frequency bands. We found that dyslexic patients exhibited statistically significant overactivation in the delta band (0.1-4 Hz) in the right temporal (entorhinal and insula), left inferior frontal (Brocas area), and right inferior frontal regions. Overactivation may be interpreted as a compensatory mechanism for reading characterizing dyslexic patients. These findings suggest that resting-state MEG activation maps may be used as specific biomarkers that can help with the diagnosis of and assess the efficacy of intervention in dyslexia.

From Auditory Rhythm Processing to Grapheme-to-Phoneme Conversion: How Neural Oscillations Can Shed Light on Developmental Dyslexia

Developmental dyslexia is frequently associated with phonological difficulties such as poor phonological awareness, access, or short term memory skills, that further impede the acquisition of letter-to-sound mappings. Some hypotheses suggest that phonological disorders in dyslexia are themselves caused by a more basic auditory processing deficit. Here, we review evidence showing that a high sensitivity to auditory rhythmic cues may be critical for phonological and reading development. Moreover, the brain signature of prosodic and rhythmic processing difficulties in dyslexia may reside in atypical right hemisphere synchronization to slow frequency auditory modulations, that would then generate left hemisphere-based dyslexic reading symptoms. Overall, the data presented in this chapter suggests that interventions aimed at facilitating the extraction of rhythmic and temporally regular patterns in auditory sequences could improve reading in dyslexia through the enhancement of phonological skills.

Word and object recognition during reading acquisition: MEG evidence

Highlights • This MEG study investigates the effect of reading acquisition on children’s brain.• Children’s left language network is activated by written words as reading improves.• Reading expertise does not have a strong impact on children’s spoken words analysis.• In object recognition the left hemisphere involvement increases as reading improves.

The Role of Slow Speech Amplitude Envelope for Speech Processing and Reading Development

This study examined the putative link between the entrainment to the slow rhythmic structure of speech, speech intelligibility and reading by means of a behavioral paradigm. Two groups of 20 children (Grades 2 and 5) were asked to recall a pseudoword embedded in sentences presented either in quiet or noisy listening conditions. Half of the sentences were primed with their syllabic and prosodic amplitude envelope to determine whether a boost in auditory entrainment to these speech features enhanced pseudoword intelligibility. Priming improved pseudoword recall performance only for the older children both in a quiet and a noisy listening environment, and such benefit from the prime correlated with reading skills and pseudoword recall. Our results support the role of syllabic and prosodic tracking of speech in reading development.