Multiplexed and Robust Representations of Sound Features in Auditory Cortex

Walker, Kerry M. M.; Bizley, Jennifer K.; King, Andrew J.; Schnupp, Jan W. H.

doi:10.1523/jneurosci.2074-11.2011

Cited by 114 publications

(117 citation statements)

References 59 publications

(76 reference statements)

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“…formant frequency) that are robust to variation in other physical parameters of the sound (e.g. azimuthal location) and such responses have been found in secondary mammalian and avian auditory areas [91,92]. In terms of higher-level categorization, research in starlings points to a role of the Caudio-Medial Nidopallium (NCM) for classifying behaviorally relevant classes of songs [93] and research in primates suggests that both the Superior Temporal Gyrus (STG) and the ventrolateral Prefontral Cortex (vPFC) could be involved in semantic discrimination [94][95][96][97][98].…”

Section: Animal Vocalizationsmentioning

confidence: 86%

Neural processing of natural sounds

2014

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Natural sounds have unique statistical structure that makes them perceptually salient. The auditory system is finely tuned to this natural structure. Selective neurons found at the higher levels of the auditory system respond selectively to vocalizations used in communication. On-line Summary1. Natural sounds include animal vocalizations, environmental sounds such as wind, water and fire noises and non-vocal sounds made by animals and humans for communication. These natural sounds have characteristic statistical properties that make them perceptually salient and that drive auditory neurons in optimal regimes for information transmission. 2.Recent advances in statistics and computer sciences have allowed neuro-physiologists to extract the stimulus-response function of complex auditory neurons from responses to natural sounds. These studies have shown a hierarchical processing that leads to the neural detection of progressively more complex natural sound features and have demonstrated the importance of the acoustical and behavioral contexts for the neural responses.3. High-level auditory neurons have shown to be exquisitely selective for conspecific calls.This fine selectivity could play an important role for species recognition, for vocal learning in songbirds and, in the case of the bats, for the processing of the sounds used in echolocation. Research that investigates how communication sounds are categorized into behaviorally meaningful groups (e.g. call types in animals, words in human speech) remains in its infancy. Animals and humans also excel at separating communication sounds from each otherand from background noise. Neurons that detect communication calls in noise have been found but the neural computations involved in sound source separation and natural auditory scene analysis remain overall poorly understood. Thus, future auditory research will have to focus not only on how natural sounds are processed by the auditory system but also on the computations that allow for this processing to occur in natural listening situations. 5.The complexity of the computations needed in the natural hearing task might require a high-dimensional representation provided by ensemble of neurons and the use of natural sounds might be the best solution for understanding the ensemble neural code.The final publication is available at Nature via http://www.nature.com/nrn/journal/v15/n6/full/nrn3731.html PrefaceWe might be forced to listen to a high frequency tone at our audiologist's office or we might enjoy falling asleep with a white-noise machine but the sounds that really matter to us are the voices of our companions or music from our favorite radio station; the auditory system has evolved to process behaviorally relevant natural sounds. Research has shown not only that our brain is optimized for natural hearing tasks but also that using natural sounds to probe the auditory system is the best way to understand the neural computations that allow us to comprehend speech or appreciate music.

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Section: Animal Vocalizationsmentioning

confidence: 86%

Neural processing of natural sounds

2014

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“…Indeed, the available cortical and imaging data indicates it is not (King and Middlebrooks 2010;Ahveninen et al 2014) and could be based instead on a logical representation of space operating as a network of neural interconnections. The temporally complex and integrative nature of auditory cortical processing (Walker et al 2011;Bizley and Cohen 2013) and the need to integrate nonauditory cues (e.g., Goossens and van Opstal 1999) suggests that auditory space and the objects within it will ultimately depend on diverse inputs. Importantly, our stimuli were two spectro-temporally complex stimuli chosen so that their various components would strongly bind to one of two perceptual objects.…”

Section: Discussionmentioning

confidence: 99%

Six Degrees of Auditory Spatial Separation

Carlile

Fox

Orchard-Mills

et al. 2016

JARO

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The location of a sound is derived computationally from acoustical cues rather than being inherent in the topography of the input signal, as in vision. Since Lord Rayleigh, the descriptions of that representation have swung between Blabeled line^and Bopponent process^models. Employing a simple variant of a twopoint separation judgment using concurrent speech sounds, we found that spatial discrimination thresholds changed nonmonotonically as a function of the overall separation. Rather than increasing with separation, spatial discrimination thresholds first declined as two-point separation increased before reaching a turning point and increasing thereafter with further separation. This Bdipper^function, with a minimum at 6°of separation, was seen for regions around the midline as well as for more lateral regions (30 and 45°). The discrimination thresholds for the binaural localization cues were linear over the same range, so these cannot explain the shape of these functions. These data and a simple computational model indicate that the perception of auditory space involves a local code or multichannel mapping emerging subsequent to the binaural cue coding.

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“…The presence of multiple auditory cortical areas on the ectosylvian gyrus (EG) of this species was first demonstrated by using 2‐deoxyglucose autoradiography (Wallace et al, 1997) and subsequently confirmed by using optical imaging of intrinsic signals (Nelken et al, 2004) and single‐unit recording (Kelly et al, 1986; Kelly and Judge, 1994; Kowalski et al, 1995; Bizley et al, 2005). Although most electrophysiological recording studies have focused on the primary auditory cortex (A1) (Phillips et al, 1988; Kowalski et al, 1996; Schnupp et al, 2001; Fritz et al, 2003; Rabinowitz et al, 2011; Keating et al, 2013), the nonprimary auditory fields in this species are now receiving increasing attention (Nelken et al, 2008; Bizley et al, 2009, 2010, 2013; Walker et al, 2011; Atiani et al, 2014). …”

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confidence: 99%

Cortico‐cortical connectivity within ferret auditory cortex

Bizley

Bajo

Nodal³

et al. 2015

J of Comparative Neurology

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Despite numerous studies of auditory cortical processing in the ferret (Mustela putorius), very little is known about the connections between the different regions of the auditory cortex that have been characterized cytoarchitectonically and physiologically. We examined the distribution of retrograde and anterograde labeling after injecting tracers into one or more regions of ferret auditory cortex. Injections of different tracers at frequency‐matched locations in the core areas, the primary auditory cortex (A1) and anterior auditory field (AAF), of the same animal revealed the presence of reciprocal connections with overlapping projections to and from discrete regions within the posterior pseudosylvian and suprasylvian fields (PPF and PSF), suggesting that these connections are frequency specific. In contrast, projections from the primary areas to the anterior dorsal field (ADF) on the anterior ectosylvian gyrus were scattered and non‐overlapping, consistent with the non‐tonotopic organization of this field. The relative strength of the projections originating in each of the primary fields differed, with A1 predominantly targeting the posterior bank fields PPF and PSF, which in turn project to the ventral posterior field, whereas AAF projects more heavily to the ADF, which then projects to the anteroventral field and the pseudosylvian sulcal cortex. These findings suggest that parallel anterior and posterior processing networks may exist, although the connections between different areas often overlap and interactions were present at all levels. J. Comp. Neurol. 523:2187–2210, 2015. © 2015 Wiley Periodicals, Inc.

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Multiplexed and Robust Representations of Sound Features in Auditory Cortex

Cited by 114 publications

References 59 publications

Neural processing of natural sounds

Neural processing of natural sounds

Six Degrees of Auditory Spatial Separation

Cortico‐cortical connectivity within ferret auditory cortex

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