Your search keyword '"Lucas Spierer"' showing total 2 results

1. Language context modulates reading route: an electrical neuroimaging study

Author

Marina Laganaro, Jean-Marie Annoni, Lucas Spierer, Diego De León Rodríguez, René M. Müri, and Karin A. Buetler

Subjects

Computer science, Speech recognition, media_common.quotation_subject, Grapheme, Context (language use), 610 Medicine & health, lcsh:RC321-571, dual-route model, German, Behavioral Neuroscience, topography, reading, Reading (process), grapheme-phoneme conversion, bilingual, Original Research Article, EEG, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Biological Psychiatry, media_common, Orthographic depth, Contrast (statistics), language.human_language, Pseudoword, Psychiatry and Mental health, Neuropsychology and Physiological Psychology, pseudoword, Neurology, language, orthographic depth, Orthography, ERP, Cognitive psychology, Neuroscience

Abstract

Introduction: The Orthographic Depth Hypothesis (Katz&Feldman, 1983) posits that different reading routes are engaged depending on the type of grapheme/phoneme correspondence of the language being read. Shallow orthographies with consistent grapheme/phoneme correspondences favor encoding via non-lexical pathways, where each grapheme is sequentially mapped to its corresponding phoneme. In contrast, deep orthographies with inconsistent grapheme/phoneme correspondences favor lexical pathways, where phonemes are retrieved from specialized memory structures. This hypothesis, however, lacks compelling empirical support. The aim of the present study was to investigate the impact of orthographic depth on reading route selection using a within-subject design.Method: We presented the same pseudowords (PWs) to highly proficient bilinguals and manipulated the orthographic depth of PW reading by embedding them among two separated German or French language contexts, implicating respectively shallow or deep orthography. High density electroencephalography was recorded during the task.Results: The topography of the ERPs to identical PWs differed 300-360ms post-stimulus onset when the PWs were read in different orthographic depth context, indicating distinct brain networks engaged in reading during this time window. The brain sources underlying these topographic effects were located within left inferior frontal (German>French), parietal (French>German) and cingular areas (German>French).Conclusion: Reading in a shallow context favors non-lexical pathways, reflected in a stronger engagement of frontal phonological areas in the shallow versus the deep orthographic context. In contrast, reading PW in a deep orthographic context recruits less routine non-lexical pathways, reflected in a stronger engagement of visuo-attentional parietal areas in the deep versus shallow orthographic context. These collective results support a modulation of reading route selection by orthographic depth.

Published

2014

2. Retraction: Spontaneous pre-stimulus fluctuations in the activity of right fronto-parietal areas influence inhibitory control performance

Author

Lucas Spierer, Camille F. Chavan, Michael Mouthon, and Aurélie L. Manuel

Subjects

Brain activity and meditation, media_common.quotation_subject, Stimulus (physiology), Electroencephalography, electrical source estimation, inferior frontal, lcsh:RC321-571, Behavioral Neuroscience, topography, Perception, Inhibitory control, Go/Nogo, medicine, Original Research Article, EEG, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Biological Psychiatry, media_common, medicine.diagnostic_test, Cognition, Fronto parietal, Retraction, Electrophysiology, Psychiatry and Mental health, Neuropsychology and Physiological Psychology, Neurology, Inhibitory Control, Psychology, Neuroscience, Pre-stimulus period

Abstract

Inhibitory control refers to the ability to suppress planned or ongoing cognitive or motor processes. Electrophysiological indices of inhibitory control failure have been found to manifest even before the presentation of the stimuli triggering the inhibition, suggesting that pre-stimulus brain-states modulate inhibition performance. However, previous electrophysiological investigations on the state-dependency of inhibitory control were based on averaged event-related potentials, a method eliminating the variability in the ongoing brain activity not time-locked to the event of interest. These studies thus left unresolved whether spontaneous variations in the brain-state immediately preceding unpredictable inhibition-triggering stimuli also influence inhibitory control performance. To address this question, we applied single-trial EEG topographic analyses on the time interval immediately preceding NoGo stimuli in conditions where the responses to NoGo trials were correctly inhibited (correct rejection) vs. committed (false alarms) during an auditory spatial Go/NoGo task. We found a specific configuration of the EEG voltage field manifesting more frequently before correctly inhibited responses to NoGo stimuli than before false alarms. There was no evidence for an EEG topography occurring more frequently before false alarms than before correct rejections. The visualization of distributed electrical source estimations of the EEG topography preceding successful response inhibition suggested that it resulted from the activity of a right fronto-parietal brain network. Our results suggest that the fluctuations in the ongoing brain activity immediately preceding stimulus presentation contribute to the behavioral outcomes during an inhibitory control task. Our results further suggest that the state-dependency of sensory-cognitive processing might not only concern perceptual processes, but also high-order, top-down inhibitory control mechanisms.

Published

2013