Neuronal representations of distance in human auditory cortex

Kopčo, Norbert; Huang, Scott C.-H.; Belliveau, John W.; Raij, Tommi; Tengshe, Chinmayi; Ahveninen, Jyrki

doi:10.1073/pnas.1119496109

Cited by 49 publications

(59 citation statements)

References 60 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Previous studies addressed this issue by comparing sounds of different spectral structure: complex tones elicited stronger behavioral looming bias (2, 11) and larger neural differences (14-16) than did noise with equal intensity increase, indicating that intensity changes did not directly cause looming bias. However, studies with a different spatial task (17) or species (10) found the opposite effect (i.e., stronger looming bias for noise than tonal sounds), calling into question these results.An early fMRI study that contrasted static sounds with sounds increasing or decreasing in intensity found activity in the right planum temporale (4), which is associated with processing of auditory motion in any spatial direction (18,19), consistent with the idea that sound intensity changes can be perceived as motion in distance. The contrast between sounds increasing vs. decreasing in intensity, however, revealed a different network, including superior temporal sulcus and amygdala, which may reflect a warning process for approaching objects (4,9,20).…”

mentioning

confidence: 72%

“…An early fMRI study that contrasted static sounds with sounds increasing or decreasing in intensity found activity in the right planum temporale (4), which is associated with processing of auditory motion in any spatial direction (18,19), consistent with the idea that sound intensity changes can be perceived as motion in distance. The contrast between sounds increasing vs. decreasing in intensity, however, revealed a different network, including superior temporal sulcus and amygdala, which may reflect a warning process for approaching objects (4,9,20).…”

mentioning

confidence: 72%

“…Interaural level differences (ILDs) are also known to act as cues for distance perception (18,29). Relative changes in frequencyspecific ILDs can be easily extracted from loudness predictions (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…of ILDs (35), which is arguably a prominent auditory distance cue (18,29,36). Further experiments and/or modeling analyses will be required to clarify the perceptual weighting of these potential distance cues.…”

Section: Spectral Contrast Manipulation Affected Auditory Distance Pementioning

confidence: 99%

See 3 more Smart Citations

Asymmetries in behavioral and neural responses to spectral cues demonstrate the generality of auditory looming bias

Baumgartner

Reed

Tóth

et al. 2017

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

View full text Add to dashboard Cite

Studies of auditory looming bias have shown that sources increasing in intensity are more salient than sources decreasing in intensity. Researchers have argued that listeners are more sensitive to approaching sounds compared with receding sounds, reflecting an evolutionary pressure. However, these studies only manipulated overall sound intensity; therefore, it is unclear whether looming bias is truly a perceptual bias for changes in source distance, or only in sound intensity. Here we demonstrate both behavioral and neural correlates of looming bias without manipulating overall sound intensity. In natural environments, the pinnae induce spectral cues that give rise to a sense of externalization; when spectral cues are unnatural, sounds are perceived as closer to the listener. We manipulated the contrast of individually tailored spectral cues to create sounds of similar intensity but different naturalness. We confirmed that sounds were perceived as approaching when spectral contrast decreased, and perceived as receding when spectral contrast increased. We measured behavior and electroencephalography while listeners judged motion direction. Behavioral responses showed a looming bias in that responses were more consistent for sounds perceived as approaching than for sounds perceived as receding. In a control experiment, looming bias disappeared when spectral contrast changes were discontinuous, suggesting that perceived motion in distance and not distance itself was driving the bias. Neurally, looming bias was reflected in an asymmetry of late eventrelated potentials associated with motion evaluation. Hence, both our behavioral and neural findings support a generalization of the auditory looming bias, representing a perceptual preference for approaching auditory objects.auditory looming bias | electroencephalography | distance motion perception | sound externalization | head-related transfer functions I magine yourself alone in the wilderness. Suddenly, a threatening sound permeates the darkness. Is it approaching? This is a critical question when it comes to your survival because approaching objects usually pose a greater threat than receding objects (1). The phenomenon that approaching sounds are more salient than receding sounds is commonly termed "auditory looming bias." Looming bias is reflected in a broad variety of psychophysical tasks related to salience and alertness: bias in loudness-change estimates (2-4) and judgments of duration (5), improved discriminability of motion speed (6), underestimated distances for egocentrically moving (4) or bypassing sounds (7,8), and reduced reaction time for auditory (3, 9) and visual (3) targets preceded by looming sounds. In animals, looming biases result in faster learning speed during associative conditioning (10) and longer duration of attention (11). This list shows that looming bias triggers a variety of percepts across a wide range of psychoacoustic tasks. Despite its broad behavioral significance, the mechanisms underlying auditory looming bias are still poorly ...

show abstract

mentioning

confidence: 72%

mentioning

confidence: 72%

Section: Resultsmentioning

confidence: 99%

Section: Spectral Contrast Manipulation Affected Auditory Distance Pementioning

confidence: 99%

See 2 more Smart Citations

Asymmetries in behavioral and neural responses to spectral cues demonstrate the generality of auditory looming bias

Baumgartner

Reed

Tóth

et al. 2017

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

View full text Add to dashboard Cite

show abstract

“…In humans, the putative posterior auditory “ where ” pathway, encompassing the planum temporale (PT) and posterior superior temporal gyrus (STG), is strongly activated by horizontal sound direction changes (Ahveninen et al, 2006; Brunetti et al, 2005; Deouell et al, 2007; Tata et al, 2005), movement (Baumgart et al, 1999; Formisano et al, 2003; Krumbholz et al, 2005; Warren et al, 2002), intensity-independent distance cues (Kopco et al, 2012), and under conditions where separation of multiple sound sources is required (Zündorf et al, 2013). However, it is still unclear how the human AC encodes the acoustic space: Is there an orderly topographic organization of neurons representing different spatial origins of sounds, or are sound locations, even at the level of non-primary cortices, computed by neurons that are broadly tuned to more basic cues such as ITD and ILD, using a “two-channel” rate code (McAlpine, 2005; Middlebrooks et al, 1994; Middlebrooks et al, 1998; Stecker et al, 2003; Werner-Reiss et al, 2008)?…”

Section: Non-invasive Studies Of Spatial Processing In Human Auditmentioning

confidence: 99%

Psychophysics and neuronal bases of sound localization in humans

Ahveninen¹,

Kopčo²,

Jä̈askëlainen³

2014

Hearing Research

Self Cite

View full text Add to dashboard Cite

Localization of sound sources is a considerable computational challenge for the human brain. Whereas the visual system can process basic spatial information in parallel, the auditory system lacks a straightforward correspondence between external spatial locations and sensory receptive fields. Consequently, the question how different acoustic features supporting spatial hearing are represented in the central nervous system is still open. Functional neuroimaging studies in humans have provided evidence for a posterior auditory “where” pathway that encompasses non-primary auditory cortex areas, including the planum temporale (PT) and posterior superior temporal gyrus (STG), which are strongly activated by horizontal sound direction changes, distance changes, and movement. However, these areas are also activated by a wide variety of other stimulus features, posing a challenge for the interpretation that the underlying areas are purely spatial. This review discusses behavioral and neuroimaging studies on sound localization, and some of the competing models of representation of auditory space in humans.

show abstract

Spatial Hearing in Rooms and Effects of Reverberation

Zahorik

2021

Springer Handbook of Auditory Research

View full text Add to dashboard Cite

Neuronal representations of distance in human auditory cortex

Cited by 49 publications

References 60 publications

Asymmetries in behavioral and neural responses to spectral cues demonstrate the generality of auditory looming bias

Asymmetries in behavioral and neural responses to spectral cues demonstrate the generality of auditory looming bias

Psychophysics and neuronal bases of sound localization in humans

Spatial Hearing in Rooms and Effects of Reverberation

Contact Info

Product

Resources

About