Effects of Noise on the Behavioral and Neural Categorization of Speech

Pearson

Harrison

2020

Preprint

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Categorical judgments of otherwise identical phonemes are biased toward hearing words (i.e., "Ganong effect") suggesting lexical context influences perception of even basic speech primitives. Lexical biasing could manifest via late stage post-perceptual mechanisms related to decision or alternatively, top-down linguistic inference which acts on early perceptual coding. Here, we exploited the temporal sensitivity of EEG to resolve the spatiotemporal dynamics of these context-related influences on speech categorization. Listeners rapidly classified sounds from a /gi/ - /ki/ gradient presented in opposing word-nonword contexts (GIFT-kift vs. giss-KISS), designed to bias perception toward lexical items. Phonetic perception shifted toward the direction of words, establishing a robust Ganong effect behaviorally. ERPs revealed a neural analog of lexical biasing emerging within ~200 ms. Source analyses uncovered a distributed neural network supporting the Ganong including middle temporal gyrus (MTG), inferior parietal lobe (IPL), and middle frontal cortex. Yet, among Ganong-sensitive regions, only left MTG and IPL predicted behavioral susceptibility to lexical influence. Our findings confirm lexical status rapidly constrains sub-lexical categorical representations for speech within several hundred milliseconds but likely does so outside the purview of canonical "auditory-linguistic" brain areas.

Section: Discussionsupporting

confidence: 75%

Lexical influences on categorical speech perception are driven by a temporoparietal circuit

Pearson

Harrison

2020

Preprint

Self Cite

“…The introduction of acoustic degradation (i.e., noise) prolongs and weakens the ERPs, indicating predictable masking on speech processing (Bidelman and Howell, 2016;Bidelman et al, 2018;Billings et al, 2009). However, we have recently shown that speech categories-those carrying a strong phonetic identity-are more resilient to noise degradation than their phonetically ambiguous counterparts (Bidelman et al, 2020a). Categorization recruits a wide variety of frontal, temporal, and parietal brain regions (Al-Fahad et al, 2020;Chang et al, 2010;Myers et al, 2009).…”

Section: Introductionmentioning

confidence: 93%

Auditory cortex is susceptible to lexical influence as revealed by informational vs. energetic masking of speech categorization

Carter

2020

Preprint

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Speech perception requires the grouping of acoustic information into meaningful phonetic units via the process of categorical perception (CP). Environmental masking influences speech perception and CP. However, it remains unclear at which stage of processing (encoding, decision, or both) masking affects categorization of speech signals. The purpose of this study was to determine whether linguistic interference influences the early acoustic-phonetic conversion process inherent to CP. To this end, we measured source level, event related brain potentials (ERPs) from auditory cortex (AC) and inferior frontal gyrus (IFG) as listeners rapidly categorized speech sounds along a /da/ to /ga/ continuum presented in three listening conditions: quiet, and in the presence of forward (informational masker) and time-reversed (energetic masker) 2-talker babble noise. Maskers were matched in overall SNR and spectral content and thus varied only in their degree of linguistic interference (i.e., informational masking). We hypothesized a differential effect of informational versus energetic masking on behavioral and neural categorization responses, where we predicted increased activation of frontal regions when disambiguating speech from noise, especially during lexical-informational maskers. We found (1) informational masking weakens behavioral speech phoneme identification above and beyond energetic masking; (2) low-level AC activity not only codes speech categories but is susceptible to higher-order lexical interference; (3) identifying speech amidst noise recruits a cross hemispheric circuit (ACleft → IFGright) whose engagement varies according to task difficulty. These findings provide corroborating evidence for top-down influences on the early acoustic-phonetic analysis of speech through a coordinated interplay between frontotemporal brain areas.

“…Forty-nine young adults (male: 15, female: 34; aged 18 to 33 years) were recruited as participants from the University of Memphis student body to participate into our ongoing studies on the neural basis of speech perception and auditory categorization (Bidelman et al, 2020b;Bidelman & Walker, 2017b;Mankel et al, 2020). All participants had normal hearing sensitivity (i.e., <25 dB HL between 500-2000 Hz).…”

Section: Participantsmentioning

confidence: 99%

“…Since we were interested to decode prototypical (Tk1/5) from ambiguous speech (Tk3)a marker of categorical processing (Bidelman, 2015;Bidelman & Walker, 2019b;Liebenthal et 10 al., 2010b)-we merged Tk1 and Tk5 responses since they reflect prototypical vowel categories ("u" vs. "a'). In contrast, Tk3 reflects a bistable percept-an category-ambiguous sound listeners sometimes label as "u" or "a" (Bidelman et al, 2020a;Bidelman & Walker, 2017b;Mankel et al, 2020). To ensure an equal number of trials and signal to noise ratio (SNR) for prototypical and ambiguous stimuli, we considered only 50% of the data from the merged (Tk1/5) samples.…”

Section: Eeg Source Localizationmentioning

confidence: 99%

“…In particular, several studies have shown that the efficiency of listeners' speech categorization varies in accordance with their underlying brain activity (Bidelman et al, 2013a;Bidelman & Alain, 2015;Bidelman & Lee, 2015b;Perlovsky, 2011). For example, Bidelman et al demonstrated that brain responses in the time frame of 180-320 ms were more robust for phonetic prototypes vs. ambiguous speech tokens, thereby reflecting category-level processing (Bidelman et al, 2020a). Other studies have shown links between N1-P2 amplitudes of the auditory cortical ERPs and the strength of listeners' speech identification (Bidelman & Walker, 2017a) and labeling speeds (Al-Fahad et al, 2020) in speech categorization tasks (Bidelman et al, 2014;Bidelman & Alain, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Data-driven machine learning models for decoding speech categorization from evoked brain responses

Mahmud

Yeasin

2020

Preprint

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Categorical perception (CP) of audio is critical to understand how the human brain perceives speech sounds despite widespread variability in acoustic properties. Here, we investigated the spatiotemporal characteristics of auditory neural activity that reflects CP for speech (i.e., differentiates phonetic prototypes from ambiguous speech sounds). We recorded high density EEGs as listeners rapidly classified vowel sounds along an acoustic-phonetic continuum. We used support vector machine (SVM) classifiers and stability selection to determine when and where in the brain CP was best decoded across space and time via source-level analysis of the event related potentials (ERPs). We found that early (120 ms) whole-brain data decoded speech categories (i.e., prototypical vs. ambiguous speech tokens) with 95.16% accuracy [area under the curve (AUC) 95.14%; F1-score 95.00%]. Separate analyses on left hemisphere (LH) and right hemisphere (RH) responses showed that LH decoding was more robust and earlier than RH (89.03% vs. 86.45% accuracy; 140 ms vs. 200 ms). Stability (feature) selection identified 13 regions of interest (ROIs) out of 68 brain regions (including auditory cortex, supramarginal gyrus, and Brocas area) that showed categorical representation during stimulus encoding (0-260 ms). In contrast, 15 ROIs (including fronto-parietal regions, Brocas area, motor cortex) were necessary to describe later decision stages (later 300 ms) of categorization but these areas were highly associated with the strength of listeners categorical hearing (i.e., slope of behavioral identification functions). Our data-driven multivariate models demonstrate that abstract categories emerge surprisingly early (~120 ms) in the time course of speech processing and are dominated by engagement of a relatively compact fronto-temporal-parietal brain network.