Characterisation of the BOLD response time course at different levels of the auditory pathway in non-human primates

Human listeners are bombarded by acoustic information that the brain rapidly organizes into coherent percepts of objects and events in the environment, which aids speech and music perception. The efficiency of auditory object recognition belies the critical constraint that acoustic stimuli necessarily require time to unfold. Using magentoencephalography (MEG), we studied the time course of the neural processes that transform dynamic acoustic information into auditory object representations. Participants listened to a diverse set of 36 tokens comprising everyday sounds from a typical human environment. Multivariate pattern analysis was used to decode the sound tokens from the MEG recordings. We show that sound tokens can be decoded from brain activity beginning 90 milliseconds after stimulus onset with peak decoding performance occurring at 155 milliseconds post stimulus onset. Decoding performance was primarily driven by differences between category representations (e.g., environmental vs. instrument sounds), although within-category decoding was better than chance. Representational similarity analysis revealed that these emerging neural representations were related to harmonic and spectrotemporal differences among the stimuli, which correspond to canonical acoustic features processed by the auditory pathway. Our findings begin to link the processing of physical sound properties with the perception of auditory objects and events in cortex.

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Response time of cardiac mitochondrial oxygen consumption to heart rate steps

AJP Heart and Circulatory Physiology ◽

10.1152/ajpheart.1991.260.2.h613 ◽

1991 ◽

Vol 260 (2) ◽

pp. H613-H625 ◽

Cited By ~ 11

Author(s):

J. H. Van Beek ◽

N. Westerhof

Keyword(s):

Heart Rate ◽

Response Time ◽

Time Course ◽

Mean Transit Time ◽

Impulse Response Function ◽

Heart Tissue ◽

Experimental Information ◽

O2 Consumption ◽

Mean Response Time ◽

The Mean

We investigated the time course of cardiac mitochondrial O2 consumption following steps in heart rate in 16 isolated rabbit hearts perfused with Tyrode solution. The time course was characterized by the mean response time, i.e., the first statistical moment (mean time) of the impulse response function. Like the mean transit time for an indicator, it provides an important characteristic of the response time course. The venous O2 content transients during steps in heart rate were measured and corrected for O2 diffusion and vascular transport using a mathematical model with experimental information derived from O2 washout following steps in arterial O2 concentration or perfusion flow. We deduce from these washout experiments that the effective O2 solubility in heart tissue is 86 +/- 13% (mean +/- SE) of solubility in water. The measured venous mean response time following a step in heart rate at 37 degrees C was 17.6 +/- 1.1 s. The mean response time of cardiac mitochondrial O2 consumption to changes in heart rate after correction for O2 transport was 7.7 +/- 0.7 s.

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The Impact of Cognitive Distraction on Driver Perception Response Time Under Different Levels of Situational Urgency

IEEE Access ◽

10.1109/access.2019.2960830 ◽

2019 ◽

Vol 7 ◽

pp. 184572-184580 ◽

Cited By ~ 3

Author(s):

Zhi Zhang ◽

Yingshi Guo ◽

Wei Yuan ◽

Chang Wang

Keyword(s):

Response Time ◽

Cognitive Distraction ◽

The Impact ◽

Different Levels

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Simple transformations capture auditory input to cortex

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1922033117 ◽

2020 ◽

Vol 117 (45) ◽

pp. 28442-28451

Author(s):

Monzilur Rahman ◽

Ben D. B. Willmore ◽

Andrew J. King ◽

Nicol S. Harper

Keyword(s):

Auditory Nerve ◽

Time Course ◽

Primary Auditory Cortex ◽

Auditory Pathway ◽

Auditory Nerve Fiber ◽

Neural Responses ◽

Auditory Periphery ◽

Cortical Responses ◽

Combined Models ◽

Simple Models

Sounds are processed by the ear and central auditory pathway. These processing steps are biologically complex, and many aspects of the transformation from sound waveforms to cortical response remain unclear. To understand this transformation, we combined models of the auditory periphery with various encoding models to predict auditory cortical responses to natural sounds. The cochlear models ranged from detailed biophysical simulations of the cochlea and auditory nerve to simple spectrogram-like approximations of the information processing in these structures. For three different stimulus sets, we tested the capacity of these models to predict the time course of single-unit neural responses recorded in ferret primary auditory cortex. We found that simple models based on a log-spaced spectrogram with approximately logarithmic compression perform similarly to the best-performing biophysically detailed models of the auditory periphery, and more consistently well over diverse natural and synthetic sounds. Furthermore, we demonstrated that including approximations of the three categories of auditory nerve fiber in these simple models can substantially improve prediction, particularly when combined with a network encoding model. Our findings imply that the properties of the auditory periphery and central pathway may together result in a simpler than expected functional transformation from ear to cortex. Thus, much of the detailed biological complexity seen in the auditory periphery does not appear to be important for understanding the cortical representation of sound.

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Temporal Features of Spectral Integration in the Inferior Colliculus: Effects of Stimulus Duration and Rise Time

Journal of Neurophysiology ◽

10.1152/jn.91300.2008 ◽

2009 ◽

Vol 102 (1) ◽

pp. 167-180 ◽

Cited By ~ 8

Author(s):

Donald Gans ◽

Kianoush Sheykholeslami ◽

Diana Coomes Peterson ◽

Jeffrey Wenstrup

Keyword(s):

Inferior Colliculus ◽

Rise Time ◽

Low Frequency ◽

Auditory Pathway ◽

Spectral Integration ◽

Auditory Responses ◽

Temporal Features ◽

Vocal Signals ◽

Inhibitory Interactions ◽

Different Levels

This report examines temporal features of facilitation and suppression that underlie spectrally integrative responses to complex vocal signals. Auditory responses were recorded from 160 neurons in the inferior colliculus (IC) of awake mustached bats. Sixty-two neurons showed combination-sensitive facilitation: responses to best frequency (BF) signals were facilitated by well-timed signals at least an octave lower in frequency, in the range 16–31 kHz. Temporal features and strength of facilitation were generally unaffected by changes in duration of facilitating signals from 4 to 31 ms. Changes in stimulus rise time from 0.5 to 5.0 ms had little effect on facilitatory strength. These results suggest that low frequency facilitating inputs to high BF neurons have phasic-on temporal patterns and are responsive to stimulus rise times over the tested range. We also recorded from 98 neurons showing low-frequency (11–32 kHz) suppression of higher BF responses. Effects of changing duration were related to the frequency of suppressive signals. Signals <23 kHz usually evoked suppression sustained throughout signal duration. This and other features of such suppression are consistent with a cochlear origin that results in masking of responses to higher, near-BF signal frequencies. Signals in the 23- to 30-kHz range—frequencies in the first sonar harmonic—generally evoked phasic suppression of BF responses. This may result from neural inhibitory interactions within and below IC. In many neurons, we observed two or more forms of the spectral interactions described here. Thus IC neurons display temporally and spectrally complex responses to sound that result from multiple spectral interactions at different levels of the ascending auditory pathway.

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The Rapid Emergence of Auditory Object Representations in Cortex Reflect Central Acoustic Attributes

Journal of Cognitive Neuroscience ◽

10.1162/jocn_a_01472 ◽

2020 ◽

Vol 32 (1) ◽

pp. 111-123 ◽

Cited By ~ 2

Author(s):

Mattson Ogg ◽

Thomas A. Carlson ◽

L. Robert Slevc

Keyword(s):

Time Course ◽

Music Perception ◽

Brain Activity ◽

Auditory Pathway ◽

Stimulus Onset ◽

Object Representations ◽

Human Environment ◽

Require Time ◽

Acoustic Information ◽

Auditory Object

Human listeners are bombarded by acoustic information that the brain rapidly organizes into coherent percepts of objects and events in the environment, which aids speech and music perception. The efficiency of auditory object recognition belies the critical constraint that acoustic stimuli necessarily require time to unfold. Using magnetoencephalography, we studied the time course of the neural processes that transform dynamic acoustic information into auditory object representations. Participants listened to a diverse set of 36 tokens comprising everyday sounds from a typical human environment. Multivariate pattern analysis was used to decode the sound tokens from the magnetoencephalographic recordings. We show that sound tokens can be decoded from brain activity beginning 90 msec after stimulus onset with peak decoding performance occurring at 155 msec poststimulus onset. Decoding performance was primarily driven by differences between category representations (e.g., environmental vs. instrument sounds), although within-category decoding was better than chance. Representational similarity analysis revealed that these emerging neural representations were related to harmonic and spectrotemporal differences among the stimuli, which correspond to canonical acoustic features processed by the auditory pathway. Our findings begin to link the processing of physical sound properties with the perception of auditory objects and events in cortex.

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