Author:

Keywords:

Amplitude modulation, Auditory steady state response, COMPREHENSION, CORTICAL RESPONSES, Development, ENTRAINMENT, HEMISPHERIC-ASYMMETRY, INTELLIGIBILITY, Life Sciences & Biomedicine, Neural synchronization, Neuroimaging, Neurosciences, Neurosciences & Neurology, ONSET ENHANCEMENT, OSCILLATIONS, PATTERNS, Radiology, Nuclear Medicine & Medical Imaging, Science & Technology, SPEECH ENVELOPE MODULATIONS, STEADY-STATE RESPONSES, Humans, Child, Child, Preschool, Longitudinal Studies, Acoustic Stimulation, Speech Perception, Dyslexia, Reading, Electroencephalography, 11 Medical and Health Sciences, 17 Psychology and Cognitive Sciences, Neurology & Neurosurgery, 32 Biomedical and clinical sciences, 42 Health sciences

Abstract:

Neural processing of the speech envelope is of crucial importance for speech perception and comprehension. This envelope processing is often investigated by measuring neural synchronization to sinusoidal amplitude-modulated stimuli at different modulation frequencies. However, it has been argued that these stimuli lack ecological validity. Pulsatile amplitude-modulated stimuli, on the other hand, are suggested to be more ecologically valid and efficient, and have increased potential to uncover the neural mechanisms behind some developmental disorders such a dyslexia. Nonetheless, pulsatile stimuli have not yet been investigated in pre-reading and beginning reading children, which is a crucial age for developmental reading research. We performed a longitudinal study to examine the potential of pulsatile stimuli in this age range. Fifty-two typically reading children were tested at three time points from the middle of their last year of kindergarten (5 years old) to the end of first grade (7 years old). Using electroencephalography, we measured neural synchronization to syllable rate and phoneme rate sinusoidal and pulsatile amplitude-modulated stimuli. Our results revealed that the pulsatile stimuli significantly enhance neural synchronization at syllable rate, compared to the sinusoidal stimuli. Additionally, the pulsatile stimuli at syllable rate elicited a different hemispheric specialization, more closely resembling natural speech envelope tracking. We postulate that using the pulsatile stimuli greatly increases EEG data acquisition efficiency compared to the common sinusoidal amplitude-modulated stimuli in research in younger children and in developmental reading research.