Orthogonal acoustic dimensions define auditory field maps in human cortex

Barton, Brian; Venezia, Jonathan H.; Saberi, Kourosh; Hickok, Gregory; Brewer, Alyssa A.

doi:10.1073/pnas.1213381109

Cited by 108 publications

(197 citation statements)

References 42 publications

(140 reference statements)

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“…Our current findings indicate that spectrotemporal sound modulations also map into distinct and reproducible spatial fMRI response patterns. This result is consistent with the hypothesis of a spatial representation of acoustic features besides frequency in primate (31) and human (14,15,32) auditory cortex.…”

Section: Discussionsupporting

confidence: 82%

Reconstructing the spectrotemporal modulations of real-life sounds from fMRI response patterns

Santoro

Moerel

Martino

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

152

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Ethological views of brain functioning suggest that sound representations and computations in the auditory neural system are optimized finely to process and discriminate behaviorally relevant acoustic features and sounds (e.g., spectrotemporal modulations in the songs of zebra finches). Here, we show that modeling of neural sound representations in terms of frequency-specific spectrotemporal modulations enables accurate and specific reconstruction of real-life sounds from high-resolution functional magnetic resonance imaging (fMRI) response patterns in the human auditory cortex. Region-based analyses indicated that response patterns in separate portions of the auditory cortex are informative of distinctive sets of spectrotemporal modulations. Most relevantly, results revealed that in early auditory regions, and progressively more in surrounding regions, temporal modulations in a range relevant for speech analysis (∼2-4 Hz) were reconstructed more faithfully than other temporal modulations. In early auditory regions, this effect was frequency-dependent and only present for lower frequencies (<∼2 kHz), whereas for higher frequencies, reconstruction accuracy was higher for faster temporal modulations. Further analyses suggested that auditory cortical processing optimized for the fine-grained discrimination of speech and vocal sounds underlies this enhanced reconstruction accuracy. In sum, the present study introduces an approach to embed models of neural sound representations in the analysis of fMRI response patterns. Furthermore, it reveals that, in the human brain, even general purpose and fundamental neural processing mechanisms are shaped by the physical features of real-world stimuli that are most relevant for behavior (i.e., speech, voice).any natural and man-made sources in our environment produce acoustic waveforms (sounds) consisting of complex mixtures of multiple frequencies (Fig. 1A). At the cochlea, these waveforms are decomposed into frequency-specific temporal patterns of neural signals, typically described with auditory spectrograms (Fig. 1B). How complex sounds are further transformed and analyzed along the auditory neural pathway and in the cortex remains uncertain. Ethological considerations have led to the hypothesis that brain processing of sounds is optimized for spectrotemporal modulations, which are characteristically present in ecologically relevant sounds (1), such as in animal vocalizations [e.g., zebra finch (2), macaque monkeys (3)] and speech (2, 4-7). Modulations are regular variations of energy in time, in frequency, or in time and frequency simultaneously. Typically, in natural sounds, modulations dynamically change over time. The contribution of modulations to sound spectrograms can be made explicit using 4D (time-varying; Movies S1-S3, Left) or 3D (time-averaged; Fig. 1C) representations. Such representations highlight, for example, that the energy of human vocal sounds is mostly concentrated at lower frequencies and at lower temporal modulation rates (Fig. 1C, Left), whereas the...

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Section: Discussionsupporting

confidence: 82%

Reconstructing the spectrotemporal modulations of real-life sounds from fMRI response patterns

Santoro

Moerel

Martino

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

152

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“…Recent development in BOLD fMRI has been demonstrated for studying the rodent auditory system (Cheung et al, 2012a(Cheung et al, , 2012bGao et al, 2014;Lau et al, 2013Lau et al, , 2015Yu et al, 2009;Zhang et al, 2013), along with previous auditory fMRI studies conducted on humans (Barton et al, 2012;De Martino et al, 2013;Sigalovsky and Melcher, 2006), primates (Baumann et al, 2011;Kayser et al, 2007;Tanji et al, 2010) and songbirds (Boumans et al, 2007;Van Meir et al, 2005;Voss et al, 2007).…”

mentioning

confidence: 95%

BOLD fMRI study of ultrahigh frequency encoding in the inferior colliculus

et al. 2015

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“…If auditory object recognition is a limiting factor, then information process ing in primary auditory cortex is crucial; phase locking in auditory cortex is limited to around 30 Hz, thus we would expect a ceiling effect at the 16 x 16 image resolution (Barton et al, 2012). However, the ceiling effect at 8 x 8 pixels suggests that object recognition is instead processed further up the auditory pathway, such as in the superior temporal gyms (STG) where phase locking is reduced to <16 Hz.…”

Section: Discussionmentioning

confidence: 99%

“…Phase-locking on the auditory nerve is limited to around 4000 Hz (Joris et al, 2004). By midbrain (inferior colliculus) this limit is reduced to around 300 Hz (Baumann et al, 2011;Joris et a l, 2004) and by primary auditory cortex it is further reduced to around 30 Hz (Barton et al, 2012). In superior temporal gyrus (part of Wernicke's speech area), this limit is further reduced to < 16 Hz in the object-based rep resentation of speech (Pasley et al, 2012), which limits coincide with those established in human psychoacoustic studies Simp son et al, 2013).…”

Section: Introductionmentioning

confidence: 97%

“…Such acoustic features are encoded inde pendently in the peripheral auditory system and object-based representations emerge in primary auditory cortex (Ding and Simon, 2012;Mesgarani and Chang, 2012;Shamma et al, 2011;Teki et al, 2013). Auditory cortex main tains a two-dimensional topographic map of frequency (Humphries et al, 2010) and modulation-rate (Barton etal., 2012) that are the so-called tonotopic and periodotopic axes, where individual regions on the map independently represent sound features occurring at a specific frequency and modulation rate (Barton et al, 2012;Simon and Ding, 2010;Xiang et al, 2013). It is thought that auditory objects are formed, in cortex, according to temporal coherence between these independently-coded acoustic features (Shamma et al, 2011;Teki et al, 2013).…”

Section: Introductionmentioning

confidence: 98%

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Visual Objects in the Auditory System in Sensory Substitution: How Much Information Do We Need?

2014

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Sensory substitution devices such as The vOICe convert visual imagery into auditory soundscapes and can provide a basic 'visual' percept to those with visual impairment. However, it is not known whether technical or perceptual limits dominate the practical efficacy of such systems. By manipulating the resolution of sonified images and asking naive sighted participants to identify visual objects through a six-alternative forced-choice procedure (6AFC) we demonstrate a 'ceiling effect' at 8 x 8 pixels, in both visual and tactile conditions, that is well below the theoretical limits of the technology. We discuss our results in the context of auditory neural limits on the representation of 'auditory' objects in a cortical hierarchy and how perceptual training may be used to circumvent these limitations.

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Orthogonal acoustic dimensions define auditory field maps in human cortex

Cited by 108 publications

References 42 publications

Reconstructing the spectrotemporal modulations of real-life sounds from fMRI response patterns

Reconstructing the spectrotemporal modulations of real-life sounds from fMRI response patterns

BOLD fMRI study of ultrahigh frequency encoding in the inferior colliculus

Visual Objects in the Auditory System in Sensory Substitution: How Much Information Do We Need?

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