Your search keyword '"Jonas Obleser"' showing total 209 results

1. Aberrant auditory prediction patterns robustly characterize tinnitus

Author

Lisa Reisinger, Gianpaolo Demarchi, Jonas Obleser, William Sedley, Marta Partyka, Juliane Schubert, Quirin Gehmacher, Sebastian Roesch, Nina Suess, Eugen Trinka, Winfried Schlee, and Nathan Weisz

Subjects

tinnitus, hearing loss, auditory cortex, Medicine, Science, Biology (General), QH301-705.5

Abstract

Phantom perceptions like tinnitus occur without any identifiable environmental or bodily source. The mechanisms and key drivers behind tinnitus are poorly understood. The dominant framework, suggesting that tinnitus results from neural hyperactivity in the auditory pathway following hearing damage, has been difficult to investigate in humans and has reached explanatory limits. As a result, researchers have tried to explain perceptual and potential neural aberrations in tinnitus within a more parsimonious predictive-coding framework. In two independent magnetoencephalography studies, participants passively listened to sequences of pure tones with varying levels of regularity (i.e. predictability) ranging from random to ordered. Aside from being a replication of the first study, the pre-registered second study, including 80 participants, ensured rigorous matching of hearing status, as well as age, sex, and hearing loss, between individuals with and without tinnitus. Despite some changes in the details of the paradigm, both studies equivalently reveal a group difference in neural representation, based on multivariate pattern analysis, of upcoming stimuli before their onset. These data strongly suggest that individuals with tinnitus engage anticipatory auditory predictions differently to controls. While the observation of different predictive processes is robust and replicable, the precise neurocognitive mechanism underlying it calls for further, ideally longitudinal, studies to establish its role as a potential contributor to, and/or consequence of, tinnitus.

Published

2024

2. Predictors of transition in patients with clinical high risk for psychosis: an umbrella review

Author

Christina Andreou, Sofia Eickhoff, Marco Heide, Renate de Bock, Jonas Obleser, and Stefan Borgwardt

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Diagnosis of a clinical high-risk (CHR) state enables timely treatment of individuals at risk for a psychotic disorder, thereby contributing to improving illness outcomes. However, only a minority of patients diagnosed with CHR will make the transition to overt psychosis. To identify patients most likely to benefit from early intervention, several studies have investigated characteristics that distinguish CHR patients who will later develop a psychotic disorder from those who will not. We aimed to summarize evidence from systematic reviews and meta-analyses on predictors of transition to psychosis in CHR patients, among characteristics and biomarkers assessed at baseline. A systematic search was conducted in Pubmed, Scopus, PsychInfo and Cochrane databases to identify reviews and meta-analyses of studies that investigated specific baseline predictors or biomarkers for transition to psychosis in CHR patients using a cross-sectional or longitudinal design. Non-peer-reviewed publications, gray literature, narrative reviews and publications not written in English were excluded from analyses. We provide a narrative synthesis of results from all included reviews and meta-analyses. For each included publication, we indicate the number of studies cited in each domain and its quality rating. A total of 40 publications (21 systematic reviews and 19 meta-analyses) that reviewed a total of 272 original studies qualified for inclusion. Baseline predictors most consistently associated with later transition included clinical characteristics such as attenuated psychotic and negative symptoms and functioning, verbal memory deficits and the electrophysiological marker of mismatch negativity. Few predictors reached a level of evidence sufficient to inform clinical practice, reflecting generalizability issues in a field characterized by studies with small, heterogeneous samples and relatively few transition events. Sample pooling and harmonization of methods across sites and projects are necessary to overcome these limitations.

Published

2023

3. Neural attentional filters and behavioural outcome follow independent individual trajectories over the adult lifespan

Author

Sarah Tune and Jonas Obleser

Subjects

EEG, ageing, speech perception, auditory attention, neural speech tracking, latent change score models, Medicine, Science, Biology (General), QH301-705.5

Abstract

Preserved communication abilities promote healthy ageing. To this end, the age-typical loss of sensory acuity might in part be compensated for by an individual’s preserved attentional neural filtering. Is such a compensatory brain–behaviour link longitudinally stable? Can it predict individual change in listening behaviour? We here show that individual listening behaviour and neural filtering ability follow largely independent developmental trajectories modelling electroencephalographic and behavioural data of N = 105 ageing individuals (39–82 y). First, despite the expected decline in hearing-threshold-derived sensory acuity, listening-task performance proved stable over 2 y. Second, neural filtering and behaviour were correlated only within each separate measurement timepoint (T1, T2). Longitudinally, however, our results raise caution on attention-guided neural filtering metrics as predictors of individual trajectories in listening behaviour: neither neural filtering at T1 nor its 2-year change could predict individual 2-year behavioural change, under a combination of modelling strategies.

Published

2024

4. Target enhancement but not distractor suppression in auditory neural tracking during continuous speech

Author

Martin Orf, Malte Wöstmann, Ronny Hannemann, and Jonas Obleser

Subjects

Behavioral neuroscience, Sensory neuroscience, Cognitive neuroscience, Science

Abstract

Summary: Selective attention modulates the neural tracking of speech in auditory cortical regions. It is unclear whether this attentional modulation is dominated by enhanced target tracking, or suppression of distraction. To settle this long-standing debate, we employed an augmented electroencephalography (EEG) speech-tracking paradigm with target, distractor, and neutral streams. Concurrent target speech and distractor (i.e., sometimes relevant) speech were juxtaposed with a third, never task-relevant speech stream serving as neutral baseline. Listeners had to detect short target repeats and committed more false alarms originating from the distractor than from the neutral stream. Speech tracking revealed target enhancement but no distractor suppression below the neutral baseline. Speech tracking of the target (not distractor or neutral speech) explained single-trial accuracy in repeat detection. In sum, the enhanced neural representation of target speech is specific to processes of attentional gain for behaviorally relevant target speech rather than neural suppression of distraction.

Published

2023

5. Neural signatures of task-related fluctuations in auditory attention and age-related changes

Author

Björn Herrmann, Burkhard Maess, Molly J. Henry, Jonas Obleser, and Ingrid S. Johnsrude

Subjects

Listening, Attention, Cognitive control, Aging, Neural oscillations, Alpha power, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Listening in everyday life requires attention to be deployed dynamically – when listening is expected to be difficult and when relevant information is expected to occur – to conserve mental resources. Conserving mental resources may be particularly important for older adults who often experience difficulties understanding speech. In the current study, we use electro- and magnetoencephalography to investigate the neural and behavioral mechanics of attention regulation during listening and the effects that aging has on these. We first show in younger adults (17–31 years) that neural alpha oscillatory activity indicates when in time attention is deployed (Experiment 1) and that deployment depends on listening difficulty (Experiment 2). Experiment 3 investigated age-related changes in auditory attention regulation. Middle-aged and older adults (54–72 years) show successful attention regulation but appear to utilize timing information differently compared to younger adults (20–33 years). We show a notable age-group dissociation in recruited brain regions. In younger adults, superior parietal cortex underlies alpha power during attention regulation, whereas, in middle-aged and older adults, alpha power emerges from more ventro-lateral areas (posterior temporal cortex). This difference in the sources of alpha activity between age groups only occurred during task performance and was absent during rest (Experiment S1). In sum, our study suggests that middle-aged and older adults employ different neural control strategies compared to younger adults to regulate attention in time under listening challenges.

Published

2023

6. Distributed networks for auditory memory differentially contribute to recall precision

Author

Sung-Joo Lim, Christiane Thiel, Bernhard Sehm, Lorenz Deserno, Jöran Lepsien, and Jonas Obleser

Subjects

Auditory retrospective attention, Auditory working memory, Perceptual precision, fMRI, Multivariate pattern decoding, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Re-directing attention to objects in working memory can enhance their representational fidelity. However, how this attentional enhancement of memory representations is implemented across distinct, sensory and cognitive-control brain network is unspecified. The present fMRI experiment leverages psychophysical modelling and multivariate auditory-pattern decoding as behavioral and neural proxies of mnemonic fidelity. Listeners performed an auditory syllable pitch-discrimination task and received retro-active cues to selectively attend to a to-be-probed syllable in memory. Accompanied by increased neural activation in fronto-parietal and cingulo-opercular networks, valid retro-cues yielded faster and more perceptually sensitive responses in recalling acoustic detail of memorized syllables. Information about the cued auditory object was decodable from hemodynamic response patterns in superior temporal sulcus (STS), fronto-parietal, and sensorimotor regions. However, among these regions retaining auditory memory objects, neural fidelity in the left STS and its enhancement through attention-to-memory best predicted individuals’ gain in auditory memory recall precision. Our results demonstrate how functionally discrete brain regions differentially contribute to the attentional enhancement of memory representations.

Published

2022

7. Neural attentional-filter mechanisms of listening success in middle-aged and older individuals

Author

Sarah Tune, Mohsen Alavash, Lorenz Fiedler, and Jonas Obleser

Subjects

Science

Abstract

Successful listening requires attentional filtering into behaviourally relevant and irrelevant sounds. Here, the authors demonstrate the role of neural speech tracking over alpha lateralization as a potential neural marker of an individual’s adaptive listening behaviour.

Published

2021

8. The circadian phase of antenatal glucocorticoid treatment affects the risk of behavioral disorders

Author

Mariana Astiz, Isabel Heyde, Mats Ingmar Fortmann, Verena Bossung, Claudia Roll, Anja Stein, Berthold Grüttner, Wolfgang Göpel, Christoph Härtel, Jonas Obleser, and Henrik Oster

Subjects

Science

Abstract

Antenatal glucocorticoid therapy is indicated for mothers at risk of preterm delivery. Here, the authors show that the circadian phase of antenatal glucocorticoid treatment affects the risk of behavioral disorders later in life in mice and in a retrospective observational study in human infants.

Published

2020

9. Neural tracking in infants – An analytical tool for multisensory social processing in development

Author

Sarah Jessen, Jonas Obleser, and Sarah Tune

Subjects

EEG, Infancy, Encoding models, Decoding models, Temporal response function, Neural tracking, Neurophysiology and neuropsychology, QP351-495

Abstract

Humans are born into a social environment and from early on possess a range of abilities to detect and respond to social cues. In the past decade, there has been a rapidly increasing interest in investigating the neural responses underlying such early social processes under naturalistic conditions. However, the investigation of neural responses to continuous dynamic input poses the challenge of how to link neural responses back to continuous sensory input. In the present tutorial, we provide a step-by-step introduction to one approach to tackle this issue, namely the use of linear models to investigate neural tracking responses in electroencephalographic (EEG) data. While neural tracking has gained increasing popularity in adult cognitive neuroscience over the past decade, its application to infant EEG is still rare and comes with its own challenges. After introducing the concept of neural tracking, we discuss and compare the use of forward vs. backward models and individual vs. generic models using an example data set of infant EEG data. Each section comprises a theoretical introduction as well as a concrete example using MATLAB code. We argue that neural tracking provides a promising way to investigate early (social) processing in an ecologically valid setting.

Published

2021

10. Personality captures dissociations of subjective versus objective hearing in noise

Author

Malte Wöstmann, Julia Erb, Jens Kreitewolf, and Jonas Obleser

Subjects

personality, neuroticism, extraversion, noise sensitivity, noise tolerance, speech-in-noise comprehension, Science

Abstract

Acoustic noise is pervasive in human environments. Some individuals are more tolerant to noise than others. We demonstrate the explanatory potential of Big-5 personality traits neuroticism (being emotionally unstable) and extraversion (being enthusiastic, outgoing) on subjective self-report and objective psycho-acoustic metrics of hearing in noise in two samples (total N = 1103). Under statistical control for demographics and in agreement with pre-registered hypotheses, lower neuroticism and higher extraversion independently explained superior self-reported noise resistance, speech-hearing ability and acceptable background noise levels. Surprisingly, objective speech-in-noise recognition instead increased with higher levels of neuroticism. In turn, the bias in subjectively overrating one's own hearing in noise decreases with higher neuroticism but increases with higher extraversion. Of benefit to currently underspecified frameworks of hearing in noise and tailored audiological treatments, these results show that personality explains inter-individual differences in coping with acoustic noise, which is a ubiquitous source of distraction and a health hazard.

Published

2021

11. Dynamic large-scale connectivity of intrinsic cortical oscillations supports adaptive listening in challenging conditions.

Author

Mohsen Alavash, Sarah Tune, and Jonas Obleser

Subjects

Biology (General), QH301-705.5

Abstract

In multi-talker situations, individuals adapt behaviorally to this listening challenge mostly with ease, but how do brain neural networks shape this adaptation? We here establish a long-sought link between large-scale neural communications in electrophysiology and behavioral success in the control of attention in difficult listening situations. In an age-varying sample of N = 154 individuals, we find that connectivity between intrinsic neural oscillations extracted from source-reconstructed electroencephalography is regulated according to the listener's goal during a challenging dual-talker task. These dynamics occur as spatially organized modulations in power-envelope correlations of alpha and low-beta neural oscillations during approximately 2-s intervals most critical for listening behavior relative to resting-state baseline. First, left frontoparietal low-beta connectivity (16 to 24 Hz) increased during anticipation and processing of a spatial-attention cue before speech presentation. Second, posterior alpha connectivity (7 to 11 Hz) decreased during comprehension of competing speech, particularly around target-word presentation. Connectivity dynamics of these networks were predictive of individual differences in the speed and accuracy of target-word identification, respectively, but proved unconfounded by changes in neural oscillatory activity strength. Successful adaptation to a listening challenge thus latches onto two distinct yet complementary neural systems: a beta-tuned frontoparietal network enabling the flexible adaptation to attentive listening state and an alpha-tuned posterior network supporting attention to speech.

Published

2021

12. Modality-specific tracking of attention and sensory statistics in the human electrophysiological spectral exponent

Author

Leonhard Waschke, Thomas Donoghue, Lorenz Fiedler, Sydney Smith, Douglas D Garrett, Bradley Voytek, and Jonas Obleser

Subjects

human, electrophysiology, EEG, Medicine, Science, Biology (General), QH301-705.5

Abstract

A hallmark of electrophysiological brain activity is its 1/f-like spectrum – power decreases with increasing frequency. The steepness of this ‘roll-off’ is approximated by the spectral exponent, which in invasively recorded neural populations reflects the balance of excitatory to inhibitory neural activity (E:I balance). Here, we first establish that the spectral exponent of non-invasive electroencephalography (EEG) recordings is highly sensitive to general (i.e., anaesthesia-driven) changes in E:I balance. Building on the EEG spectral exponent as a viable marker of E:I, we then demonstrate its sensitivity to the focus of selective attention in an EEG experiment during which participants detected targets in simultaneous audio-visual noise. In addition to these endogenous changes in E:I balance, EEG spectral exponents over auditory and visual sensory cortices also tracked auditory and visual stimulus spectral exponents, respectively. Individuals’ degree of this selective stimulus–brain coupling in spectral exponents predicted behavioural performance. Our results highlight the rich information contained in 1/f-like neural activity, providing a window into diverse neural processes previously thought to be inaccessible in non-invasive human recordings.

Published

2021

13. Circadian fluctuations in glucocorticoid level predict perceptual discrimination sensitivity

Author

Jonas Obleser, Jens Kreitewolf, Ricarda Vielhauer, Fanny Lindner, Carolin David, Henrik Oster, and Sarah Tune

Subjects

Biological Sciences, Neuroscience, Sensory Neuroscience, Endocrinology, Science

Abstract

Summary: Slow neurobiological rhythms, such as the circadian secretion of glucocorticoid (GC) hormones, modulate a variety of body functions. Whether and how endocrine fluctuations also exert an influence on perceptual abilities is largely uncharted. Here, we show that phasic increases in GC availability prove beneficial to auditory discrimination. In an age-varying sample of N = 68 healthy human participants, we characterize the covariation of saliva cortisol with perceptual sensitivity in an auditory pitch discrimination task at five time points across the sleep-wake cycle. First, momentary saliva cortisol levels were captured well by the time relative to wake-up and overall sleep duration. Second, within individuals, higher cortisol levels just prior to behavioral testing predicted better pitch discrimination ability, expressed as a steepened psychometric curve. This effect of GCs held under a set of statistical controls. Our results pave the way for more in-depth studies on neuroendocrinological determinants of sensory encoding and perception.

Published

2021

14. Large-scale network dynamics of beta-band oscillations underlie auditory perceptual decision-making

Author

Mohsen Alavash, Christoph Daube, Malte Wöstmann, Alex Brandmeyer, and Jonas Obleser

Subjects

Electronic computers. Computer science, QA75.5-76.95

Published

2021

15. Orienting auditory attention in time: Lateralized alpha power reflects spatio-temporal filtering

Author

Malte Wöstmann, Burkhard Maess, and Jonas Obleser

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The deployment of neural alpha (8–12 Hz) lateralization in service of spatial attention is well-established: Alpha power increases in the cortical hemisphere ipsilateral to the attended hemifield, and decreases in the contralateral hemisphere, respectively. Much less is known about humans’ ability to deploy such alpha lateralization in time, and to thus exploit alpha power as a spatio-temporal filter. Here we show that spatially lateralized alpha power does signify – beyond the direction of spatial attention – the distribution of attention in time and thereby qualifies as a spatio-temporal attentional filter. Participants (N = 20) selectively listened to spoken numbers presented on one side (left vs right), while competing numbers were presented on the other side. Key to our hypothesis, temporal foreknowledge was manipulated via a visual cue, which was either instructive and indicated the to-be-probed number position (70% valid) or neutral. Temporal foreknowledge did guide participants’ attention, as they recognized numbers from the to-be-attended side more accurately following valid cues. In the magnetoencephalogram (MEG), spatial attention to the left versus right side induced lateralization of alpha power in all temporal cueing conditions. Modulation of alpha lateralization at the 0.8 Hz presentation rate of spoken numbers was stronger following instructive compared to neutral temporal cues. Critically, we found stronger modulation of lateralized alpha power specifically at the onsets of temporally cued numbers. These results suggest that the precisely timed hemispheric lateralization of alpha power qualifies as a spatio-temporal attentional filter mechanism susceptible to top-down behavioural goals.

Published

2021

16. Temporal selectivity declines in the aging human auditory cortex

Author

Julia Erb, Lea-Maria Schmitt, and Jonas Obleser

Subjects

functional mri, healthy aging, spectro-temporal modulations, hearing loss, presbycusis, temporal rate coding, Medicine, Science, Biology (General), QH301-705.5

Abstract

Current models successfully describe the auditory cortical response to natural sounds with a set of spectro-temporal features. However, these models have hardly been linked to the ill-understood neurobiological changes that occur in the aging auditory cortex. Modelling the hemodynamic response to a rich natural sound mixture in N = 64 listeners of varying age, we here show that in older listeners’ auditory cortex, the key feature of temporal rate is represented with a markedly broader tuning. This loss of temporal selectivity is most prominent in primary auditory cortex and planum temporale, with no such changes in adjacent auditory or other brain areas. Amongst older listeners, we observe a direct relationship between chronological age and temporal-rate tuning, unconfounded by auditory acuity or model goodness of fit. In line with senescent neural dedifferentiation more generally, our results highlight decreased selectivity to temporal information as a hallmark of the aging auditory cortex.

Published

2020

17. Publisher Correction: Neural attentional-filter mechanisms of listening success in middle-aged and older individuals

Author

Sarah Tune, Mohsen Alavash, Lorenz Fiedler, and Jonas Obleser

Subjects

Science

Published

2021

18. Large-scale network dynamics of beta-band oscillations underlie auditory perceptual decision-making

Author

Mohsen Alavash, Christoph Daube, Malte Wöstmann, Alex Brandmeyer, and Jonas Obleser

Subjects

Network dynamics, Perceptual decision, Oscillation, MEG, Functional connectivity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Perceptual decisions vary in the speed at which we make them. Evidence suggests that translating sensory information into perceptual decisions relies on distributed interacting neural populations, with decision speed hinging on power modulations of the neural oscillations. Yet the dependence of perceptual decisions on the large-scale network organization of coupled neural oscillations has remained elusive. We measured magnetoencephalographic signals in human listeners who judged acoustic stimuli composed of carefully titrated clouds of tone sweeps. These stimuli were used in two task contexts, in which the participants judged the overall pitch or direction of the tone sweeps. We traced the large-scale network dynamics of the source-projected neural oscillations on a trial-by-trial basis using power-envelope correlations and graph-theoretical network discovery. In both tasks, faster decisions were predicted by higher segregation and lower integration of coupled beta-band (∼16–28 Hz) oscillations. We also uncovered the brain network states that promoted faster decisions in either lower-order auditory or higher-order control brain areas. Specifically, decision speed in judging the tone sweep direction critically relied on the nodal network configurations of anterior temporal, cingulate, and middle frontal cortices. Our findings suggest that global network communication during perceptual decision-making is implemented in the human brain by large-scale couplings between beta-band neural oscillations. The speed at which we make perceptual decisions varies. This translation of sensory information into perceptual decisions hinges on dynamic changes in neural oscillatory activity. However, the large-scale neural-network embodiment supporting perceptual decision-making is unclear. We addressed this question by experimenting two auditory perceptual decision-making situations. Using graph-theoretical network discovery, we traced the large-scale network dynamics of coupled neural oscillations to uncover the brain network states that support the speed of auditory perceptual decisions. We found that higher network segregation of coupled beta-band oscillations supports faster auditory perceptual decisions over trials. Moreover, when auditory perceptual decisions are relatively difficult, the decision speed benefits from higher segregation of frontal cortical areas, but lower segregation and greater integration of auditory cortical areas.

Published

2017

19. Aging affects the balance of neural entrainment and top-down neural modulation in the listening brain

Author

Molly J. Henry, Björn Herrmann, Dunja Kunke, and Jonas Obleser

Subjects

Science

Abstract

The changes that accompany age-related decreases in speech comprehension are not yet understood. Here, authors show that older adults are less able to entrain to speech-paced auditory rhythms and that the behavioural consequences can be counteracted by top-down neural modulation.

Published

2017

20. Local cortical desynchronization and pupil-linked arousal differentially shape brain states for optimal sensory performance

Author

Leonhard Waschke, Sarah Tune, and Jonas Obleser

Subjects

cognitive neuroscience, perception, sensory processing, Medicine, Science, Biology (General), QH301-705.5

Abstract

Instantaneous brain states have consequences for our sensation, perception, and behaviour. Fluctuations in arousal and neural desynchronization likely pose perceptually relevant states. However, their relationship and their relative impact on perception is unclear. We here show that, at the single-trial level in humans, local desynchronization in sensory cortex (expressed as time-series entropy) versus pupil-linked arousal differentially impact perceptual processing. While we recorded electroencephalography (EEG) and pupillometry data, stimuli of a demanding auditory discrimination task were presented into states of high or low desynchronization of auditory cortex via a real-time closed-loop setup. Desynchronization and arousal distinctly influenced stimulus-evoked activity and shaped behaviour displaying an inverted u-shaped relationship: States of intermediate desynchronization elicited minimal response bias and fastest responses, while states of intermediate arousal gave rise to highest response sensitivity. Our results speak to a model in which independent states of local desynchronization and global arousal jointly optimise sensory processing and performance.

Published

2019

21. The Benefit of Attention-to-Memory Depends on the Interplay of Memory Capacity and Memory Load

Author

Sung-Joo Lim, Malte Wöstmann, Frederik Geweke, and Jonas Obleser

Subjects

auditory working memory, retrospective attention, perceptual precision, psychophysical modeling, individual differences, Psychology, BF1-990

Abstract

Humans can be cued to attend to an item in memory, which facilitates and enhances the perceptual precision in recalling this item. Here, we demonstrate that this facilitating effect of attention-to-memory hinges on the overall degree of memory load. The benefit an individual draws from attention-to-memory depends on her overall working memory performance, measured as sensitivity (d′) in a retroactive cue (retro-cue) pitch discrimination task. While listeners maintained 2, 4, or 6 auditory syllables in memory, we provided valid or neutral retro-cues to direct listeners’ attention to one, to-be-probed syllable in memory. Participants’ overall memory performance (i.e., perceptual sensitivity d′) was relatively unaffected by the presence of valid retro-cues across memory loads. However, a more fine-grained analysis using psychophysical modeling shows that valid retro-cues elicited faster pitch-change judgments and improved perceptual precision. Importantly, as memory load increased, listeners’ overall working memory performance correlated with inter-individual differences in the degree to which precision improved (r = 0.39, p = 0.029). Under high load, individuals with low working memory profited least from attention-to-memory. Our results demonstrate that retrospective attention enhances perceptual precision of attended items in memory but listeners’ optimal use of informative cues depends on their overall memory abilities.

Published

2018

22. Correction: What do we talk about when we talk about rhythm?

Author

Jonas Obleser, Molly J Henry, and Peter Lakatos

Subjects

Biology (General), QH301-705.5

Abstract

[This corrects the article DOI: 10.1371/journal.pbio.2002794.].

Published

2017

23. What do we talk about when we talk about rhythm?

Author

Jonas Obleser, Molly J Henry, and Peter Lakatos

Subjects

Biology (General), QH301-705.5

Published

2017

24. Prediction signatures in the brain: Semantic pre-activation during language comprehension

Author

Burkhard Maess, Fahimeh Mamashli, Jonas Obleser, Liisa Helle, and Angela Dorkas Friederici

Subjects

Language, MEG, semantics, prediction, N400, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

There is broad agreement that context-based predictions facilitate lexical-semantic processing. A robust index of semantic prediction during language comprehension is an evoked response, known as the N400, whose amplitude is modulated as a function of semantic context. However, the underlying neural mechanisms that utilize relations of the prior context and the embedded word within it are largely unknown. We measured magnetoencephalography (MEG) data while participants were listening to simple German sentences in which the verbs were either highly predictive for the occurrence of a particular noun (i.e., provided context) or not. The identical set of nouns was presented in both conditions. Hence, differences for the evoked responses of the nouns can only be due to differences in the earlier context. We observed a reduction of the N400 response for highly predicted nouns. Interestingly, the opposite pattern was observed for the preceding verbs: Highly predictive (that is more informative) verbs yielded stronger neural magnitude compared to less predictive verbs. A negative correlation between the N400 effect of the verb and that of the noun was found in a distributed brain network, indicating an integral relation between the predictive power of the verb and the processing of the subsequent noun. This network consisted of left hemispheric superior and middle temporal areas and a subcortical area; the parahippocampus. Enhanced activity for highly predictive relative to less predictive verbs, likely reflects establishing semantic features associated with the expected nouns, that is a pre-activation of the expected nouns.

Published

2016

25. Acoustic detail but not predictability of task-irrelevant speech disrupts working memory

Author

Malte Wöstmann and Jonas Obleser

Subjects

Attention, Memory, age, predictability, task-irrelevant speech, acoustic detail, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Attended speech is comprehended better not only if more acoustic detail is available, but also if it is semantically highly predictable. But can more acoustic detail or higher predictability turn into disadvantages and distract a listener if the speech signal is to be ignored? Also, does the degree of distraction increase for older listeners who typically show a decline in attentional control ability? Adopting the irrelevant-speech paradigm, we tested whether younger (age 23–33 years) and older (60–78 years) listeners’ working memory for the serial order of spoken digits would be disrupted by the presentation of task-irrelevant speech varying in its acoustic detail (using noise-vocoding) and its semantic predictability (of sentence endings). More acoustic detail, but not higher predictability, of task-irrelevant speech aggravated memory interference. This pattern of results did not differ between younger and older listeners, despite generally lower performance in older listeners. Our findings suggest that the focus of attention determines how acoustics and predictability affect the processing of speech: First, as more acoustic detail is known to enhance speech comprehension and memory for speech, we here demonstrate that more acoustic detail of ignored speech enhances the degree of distraction. Second, while higher predictability of attended speech is known to also enhance speech comprehension under acoustically adverse conditions, higher predictability of ignored speech is unable to exert any distracting effect upon working memory performance in younger or older listeners. These findings suggest that features that make attended speech easier to comprehend do not necessarily enhance distraction by ignored speech.

Published

2016

26. Tell me something I don’t know

Author

Jonas Obleser

Subjects

perception, predictions, surprise, prediction error, predictive coding, auditory cortex, Medicine, Science, Biology (General), QH301-705.5

Abstract

The roles that neural oscillations play in the auditory cortex of the human brain are becoming clearer.

Published

2016

27. Dissociable neural response signatures for slow amplitude and frequency modulation in human auditory cortex.

Author

Molly J Henry and Jonas Obleser

Subjects

Medicine, Science

Abstract

Natural auditory stimuli are characterized by slow fluctuations in amplitude and frequency. However, the degree to which the neural responses to slow amplitude modulation (AM) and frequency modulation (FM) are capable of conveying independent time-varying information, particularly with respect to speech communication, is unclear. In the current electroencephalography (EEG) study, participants listened to amplitude- and frequency-modulated narrow-band noises with a 3-Hz modulation rate, and the resulting neural responses were compared. Spectral analyses revealed similar spectral amplitude peaks for AM and FM at the stimulation frequency (3 Hz), but amplitude at the second harmonic frequency (6 Hz) was much higher for FM than for AM. Moreover, the phase delay of neural responses with respect to the full-band stimulus envelope was shorter for FM than for AM. Finally, the critical analysis involved classification of single trials as being in response to either AM or FM based on either phase or amplitude information. Time-varying phase, but not amplitude, was sufficient to accurately classify AM and FM stimuli based on single-trial neural responses. Taken together, the current results support the dissociable nature of cortical signatures of slow AM and FM. These cortical signatures potentially provide an efficient means to dissect simultaneously communicated slow temporal and spectral information in acoustic communication signals.

Published

2013

28. How bodies and voices interact in early emotion perception.

Author

Sarah Jessen, Jonas Obleser, and Sonja A Kotz

Subjects

Medicine, Science

Abstract

Successful social communication draws strongly on the correct interpretation of others' body and vocal expressions. Both can provide emotional information and often occur simultaneously. Yet their interplay has hardly been studied. Using electroencephalography, we investigated the temporal development underlying their neural interaction in auditory and visual perception. In particular, we tested whether this interaction qualifies as true integration following multisensory integration principles such as inverse effectiveness. Emotional vocalizations were embedded in either low or high levels of noise and presented with or without video clips of matching emotional body expressions. In both, high and low noise conditions, a reduction in auditory N100 amplitude was observed for audiovisual stimuli. However, only under high noise, the N100 peaked earlier in the audiovisual than the auditory condition, suggesting facilitatory effects as predicted by the inverse effectiveness principle. Similarly, we observed earlier N100 peaks in response to emotional compared to neutral audiovisual stimuli. This was not the case in the unimodal auditory condition. Furthermore, suppression of beta-band oscillations (15-25 Hz) primarily reflecting biological motion perception was modulated 200-400 ms after the vocalization. While larger differences in suppression between audiovisual and audio stimuli in high compared to low noise levels were found for emotional stimuli, no such difference was observed for neutral stimuli. This observation is in accordance with the inverse effectiveness principle and suggests a modulation of integration by emotional content. Overall, results show that ecologically valid, complex stimuli such as joined body and vocal expressions are effectively integrated very early in processing.

Published

2012

29. A sparse neural code for some speech sounds but not for others.

Author

Mathias Scharinger, Alexandra Bendixen, Nelson J Trujillo-Barreto, and Jonas Obleser

Subjects

Medicine, Science

Abstract

The precise neural mechanisms underlying speech sound representations are still a matter of debate. Proponents of 'sparse representations' assume that on the level of speech sounds, only contrastive or otherwise not predictable information is stored in long-term memory. Here, in a passive oddball paradigm, we challenge the neural foundations of such a 'sparse' representation; we use words that differ only in their penultimate consonant ("coronal" [t] vs. "dorsal" [k] place of articulation) and for example distinguish between the German nouns Latz ([lats]; bib) and Lachs ([laks]; salmon). Changes from standard [t] to deviant [k] and vice versa elicited a discernible Mismatch Negativity (MMN) response. Crucially, however, the MMN for the deviant [lats] was stronger than the MMN for the deviant [laks]. Source localization showed this difference to be due to enhanced brain activity in right superior temporal cortex. These findings reflect a difference in phonological 'sparsity': Coronal [t] segments, but not dorsal [k] segments, are based on more sparse representations and elicit less specific neural predictions; sensory deviations from this prediction are more readily 'tolerated' and accordingly trigger weaker MMNs. The results foster the neurocomputational reality of 'representationally sparse' models of speech perception that are compatible with more general predictive mechanisms in auditory perception.

Published

2012

30. Implicit Versus Explicit Timing - Separate or Shared Mechanisms?

Author

Sophie K. Herbst, Jonas Obleser, and Virginie van Wassenhove

Published

2022

31. Spatial Attention and Temporal Expectation Exert Differential Effects on Visual and Auditory Discrimination.

Author

Anna Wilsch, Manuel R. Mercier, Jonas Obleser, Charles E. Schroeder, and Saskia Haegens

Published

2020

32. Does Closing the Eyes Enhance Auditory Attention? Eye Closure Increases Attentional Alpha-Power Modulation but Not Listening Performance.

Author

Malte Wöstmann, Lea-Maria Schmitt, and Jonas Obleser

Published

2020

33. Late cortical tracking of ignored speech facilitates neural selectivity in acoustically challenging conditions.

Author

Lorenz Fiedler, Malte Wöstmann, Sophie K. Herbst, and Jonas Obleser

Published

2019

34. Dopaminergic modulation of hemodynamic signal variability and the functional connectome during cognitive performance.

Author

Mohsen Alavash, Sung-Joo Lim, Christiane M. Thiel, Bernhard Sehm, Lorenz Deserno, and Jonas Obleser

Published

2018

35. Transcranial alternating current stimulation with speech envelopes modulates speech comprehension.

Author

Anna Wilsch, Toralf Neuling, Jonas Obleser, and Christoph S. Herrmann

Published

2018

36. Ear-EEG allows extraction of neural responses in challenging listening scenarios - A future technology for hearing aids?

Author

Lorenz Fiedler, Jonas Obleser, Thomas Lunner, and Carina Graversen

Published

2016

37. Ten simple rules to study distractor suppression

Author

Malte Wöstmann, Viola S. Störmer, Jonas Obleser, Douglas A Addleman, Søren Andersen, Nick Gaspelin, Joy Geng, Steven J Luck, MaryAnn Noonan, Heleen A Slagter, and Jan Theeuwes

Subjects

General Neuroscience, distractor, Brain, Humans, suppression, enhancement, inhibition, attention, target

Abstract

Distractor suppression refers to the ability to filter out distracting and task-irrelevant information. Distractor suppression is essential for survival and considered a key aspect of selective attention. Despite the recent and rapidly evolving literature on distractor suppression, we still know little about how the brain suppresses distracting information. What limits progress is that we lack mutually agreed upon principles of how to study the neural basis of distractor suppression and its manifestation in behavior. Here, we offer ten simple rules that we believe are fundamental when investigating distractor suppression. We provide guidelines on how to design conclusive experiments on distractor suppression (Rules 1–3), discuss different types of distractor suppression that need to be distinguished (Rules 4–6), and provide an overview of models of distractor suppression and considerations of how to evaluate distractor suppression statistically (Rules 7–10). Together, these rules provide a concise and comprehensive synopsis of promising advances in the field of distractor suppression. Following these rules will propel research on distractor suppression in important ways, not only by highlighting prominent issues to both new and more advanced researchers in the field, but also by facilitating communication between sub-disciplines.

Published

2022

38. Implicit temporal predictability enhances pitch discrimination sensitivity and biases the phase of delta oscillations in auditory cortex.

Author

Sophie K. Herbst and Jonas Obleser

Published

2019

39. Quantifying the individual auditory and visual brain response in 7-month-old infants watching a brief cartoon movie.

Author

Sarah Jessen, Lorenz Fiedler, Thomas F. Münte, and Jonas Obleser

Published

2019

40. Explaining flexible continuous speech comprehension from individual motor rhythms

Author

Christina Lubinus, Anne Keitel, Jonas Obleser, David Poeppel, and Johanna M. Rimmele

Subjects

General Immunology and Microbiology, otorhinolaryngologic diseases, General Medicine, General Agricultural and Biological Sciences, General Biochemistry, Genetics and Molecular Biology, General Environmental Science

Abstract

When speech is too fast, the tracking of the acoustic signal along the auditory pathway deteriorates, leading to suboptimal speech segmentation and decoding of speech information. Thus, speech comprehension is limited by the temporal constraints of the auditory system. Here we ask whether individual differences in auditory-motor coupling strength in part shape these temporal constraints. In two behavioral experiments, we characterize individual differences in the comprehension of naturalistic speech as function of the individual synchronization between the auditory and motor systems and the preferred frequencies of the systems. Obviously, speech comprehension declined at higher speech rates. Importantly, however, both higher auditory-motor synchronization and higher spontaneous speech motor production rates were predictive of better speech-comprehension performance. Furthermore, performance increased with higher working memory capacity (Digit Span) and higher linguistic, model-based sentence predictability – particularly so at higher speech rates and for individuals with high auditory-motor synchronization. These findings support the notion of an individual preferred auditory– motor regime that allows for optimal speech processing. The data provide evidence for a model that assigns a central role to motor-system-dependent individual flexibility in continuous speech comprehension.

Published

2023

41. Temporal expectations and neural amplitude fluctuations in auditory cortex interactively influence perception.

Author

Björn Herrmann, Molly J. Henry, Saskia Haegens, and Jonas Obleser

Published

2016

42. Attentional sampling of visual and auditory objects is captured by theta‐modulated neural activity

Author

Ian C. Fiebelkorn, Sabine Kastner, Michael Plöchl, and Jonas Obleser

Subjects

Periodicity, 0303 health sciences, genetic structures, medicine.diagnostic_test, General Neuroscience, Perspective (graphical), Electroencephalography, Sensory system, Visual processing, 03 medical and health sciences, Cognition, 0302 clinical medicine, Stimulus modality, Rhythm, Fixation (visual), Visual Perception, medicine, Theta Rhythm, Psychology, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology, Mirroring

Abstract

Recent evidence suggests that visual attention alternately samples two behaviourally relevant objects at approximately 4 Hz, rhythmically shifting between the objects. Whether similar attentional rhythms exist in other sensory modalities, however, is not yet clear. We therefore adapted and extended an established paradigm to investigate visual and potential auditory attentional rhythms, as well as possible interactions, on both a behavioural (detection performance, N = 33) and a neural level (EEG, N = 18). The results during unimodal attention demonstrate that both visual- and auditory-target detection fluctuate at frequencies of approximately 4-8 Hz, confirming that attentional rhythms are not specific to visual processing. The EEG recordings provided evidence of oscillatory activity that underlies these behavioural effects. At right and left occipital EEG electrodes, we detected counter-phasic theta-band activity (4-8 Hz), mirroring behavioural evidence of alternating sampling between the objects presented right and left of central fixation, respectively. Similarly, alpha-band activity as a signature of relatively suppressed sensory encoding showed a theta-rhythmic, counter-phasic change in power. Moreover, these theta-rhythmic changes in alpha power were predictive of behavioural performance in both sensory modalities. Overall, the present findings provide a new perspective on the multimodal rhythmicity of attention.

Published

2021

43. Editor's evaluation: Distinct roles of forward and backward alpha-band waves in spatial visual attention

Author

Jonas Obleser

Published

2023

44. Neural alpha oscillations and pupil size differentially index cognitive demand under competing audio-visual task conditions

Author

Frauke Kraus, Sarah Tune, Jonas Obleser, and Björn Herrmann

Subjects

General Neuroscience

Abstract

Cognitive demand is thought to modulate two often used, but rarely combined, measures: pupil size and neural alpha (8–12 Hz) oscillatory power. However, it is unclear whether these two measures capture cognitive demand in a similar way under complex audio-visual task conditions. Here we recorded pupil size and neural alpha power (using electroencephalography), while human participants of both sexes concurrently performed a visual multiple object-tracking task and an auditory gap-detection task. Difficulties of the two tasks were manipulated independent of each other. Participants’ performance decreased in accuracy and speed with increasing cognitive demand. Pupil size increased with increasing difficulty for both the auditory and the visual task. In contrast, alpha power showed diverging neural dynamics: Parietal alpha power decreased with increasing difficulty in the visual task, but not with increasing difficulty in the auditory task. Furthermore, independent of task difficulty, within-participant trial-by-trial fluctuations in pupil size were negatively correlated with alpha power. Difficulty-induced changes in pupil size and alpha power, however, did not correlate, which is consistent with their different cognitive-demand sensitivities. Overall, the current study demonstrates that the dynamics of the neurophysiological indices of cognitive demand and associated effort are multi-faceted and potentially modality-dependent under complex audio-visual task conditions.Significance StatementPupil size and oscillatory alpha power are associated with cognitive demand and effort, but their relative sensitivity under complex audio-visual task conditions is unclear as is the extent to which they share underlying mechanisms. Using an audio-visual dual-task paradigm, we show that pupil size increases with increasing cognitive demands for both audition and vision. In contrast, changes in oscillatory alpha power depend on the respective task demands: Parietal alpha power decreases with visual demand but not with auditory task demand. Hence, pupil size and alpha power show different sensitivity to cognitive demands, perhaps suggesting partly different underlying neural mechanisms.

Published

2022

45. Circadian Rhythms in Auditory Hallucinations and Psychosis

Author

Hong‐Viet V. Ngo, Henrik Oster, Christina Andreou, and Jonas Obleser

Subjects

Physiology

Abstract

Circadian rhythms are imprinted in all organisms and influence virtually all aspects of physiology and behaviour in adaptation to the 24-hour day-night cycle. This recognition of a circadian timekeeping system permeating essentially all healthy functioning of body and mind quickly leads to the realisation that, in turn, human ailments should be probed for the degree to which they are rooted in or marked by disruptions and dysregulations of circadian clock functions in the human body. In this review, we will focus on psychosis as a key mental illness and foremost one of its cardinal symptoms: auditory hallucinations. We will discuss recent empirical evidence and conceptual advances probing the potential role of circadian disruption in auditory hallucinations. Moreover, a dysbalance in excitation and inhibition within cortical networks, which in turn drive a disinhibition of dopaminergic signalling will be highlighted as central physiological mechanism. Finally, we will propose two avenues for experimentally intervening on the circadian influences to potentially alleviate hallucinations in psychotic disorders.

Published

2022

46. Acoustic cue selection and discrimination under degradation: Differential contributions of the inferior parietal and posterior temporal cortices.

Author

Mathias Scharinger, Molly J. Henry, and Jonas Obleser

Published

2015

47. Acoustic Detail Guides Attention Allocation in a Selective Listening Task.

Author

Malte Wöstmann, Erich Schröger, and Jonas Obleser

Published

2015

48. Editor's evaluation: Cortical activity during naturalistic music listening reflects short-range predictions based on long-term experience

Author

Jonas Obleser

Published

2022

49. Tracking temporal hazard in the human electroencephalogram using a forward encoding model

Author

Lorenz Fiedler, Sophie K. Herbst, and Jonas Obleser

Subjects

Adult, Male, Hazard (logic), Time Factors, Computer science, Monotonic function, Electroencephalography, Young Adult, Discrimination, Psychological, Encoding (memory), medicine, Humans, implicit timing, EEG, SMA, Predictability, Pitch Perception, Event (probability theory), medicine.diagnostic_test, Supplementary motor area, business.industry, General Neuroscience, encoding models, Motor Cortex, Pattern recognition, Cognition, General Medicine, Models, Theoretical, New Research, Anticipation, Psychological, 1.1, medicine.anatomical_structure, Cognition and Behavior, Time Perception, temporal prediction, Auditory Perception, Female, Artificial intelligence, Tracking signal, business

Abstract

Human observers automatically extract temporal contingencies from the environment and predict the onset of future events. Temporal predictions are modelled by the hazard function, which describes the instantaneous probability for an event to occur given it has not occurred yet. Here, we tackle the question of whether and how the human brain tracks continuous temporal hazard on a moment-to-moment basis, and how flexibly it adjusts to strictly implicit variations in the hazard function. We applied an encoding-model approach to human electroencephalographic (EEG) data recorded during a pitch-discrimination task, in which we implicitly manipulated temporal predictability of the target tones by varying the interval between cue and target tone (the foreperiod). Critically, temporal predictability was either solely driven by the passage of time (resulting in a monotonic hazard function), or was modulated to increase at intermediate foreperiods (resulting in a modulated hazard function with a peak at the intermediate foreperiod). Forward encoding models trained to predict the recorded EEG signal from different temporal hazard functions were able to distinguish between experimental conditions, showing that implicit variations of temporal hazard bear tractable signatures in the human electroencephalogram. Notably, this tracking signal was reconstructed best from the supplementary motor area (SMA), underlining this area’s link to cognitive processing of time. Our results underline the relevance of temporal hazard to cognitive processing, and show that the predictive accuracy of the encoding-model approach can be utilised to track abstract time-resolved stimuli.Significance StatementExtracting temporal predictions from sensory input allows to process future input more efficiently and to prepare responses in time. In mathematical terms, temporal predictions can be described by the hazard function, modelling the probability of an event to occur over time. Here, we show that the human EEG tracks temporal hazard in an implicit foreperiod paradigm. Forward encoding models trained to predict the recorded EEG signal from different temporal-hazard functions were able to distinguish between experimental conditions that differed in their build-up of hazard over time. These neural signatures of tracking temporal hazard converge with the extant literature on temporal processing and provide new evidence that the supplementary motor area tracks hazard under strictly implicit timing conditions.

Published

2022

50. Neural attentional-filter mechanisms of listening success in middle-aged and older individuals

Author

Lorenz Fiedler, Jonas Obleser, Mohsen Alavash, and Sarah Tune

Subjects

Science, General Physics and Astronomy, Electroencephalography, General Biochemistry, Genetics and Molecular Biology, Lateralization of brain function, Article, 03 medical and health sciences, 0302 clinical medicine, medicine, otorhinolaryngologic diseases, Active listening, Attention, Selective attention, 030304 developmental biology, Language, 0303 health sciences, Multidisciplinary, medicine.diagnostic_test, General Chemistry, Filter (signal processing), Chronological age, Psychology, Alpha power, 030217 neurology & neurosurgery, Cognitive psychology

Abstract

Successful listening crucially depends on intact attentional filters that separate relevant from irrelevant information. Research into their neurobiological implementation has focused on two potential auditory filter strategies: the lateralization of alpha power and selective neural speech tracking. However, the functional interplay of the two neural filter strategies and their potency to index listening success in an ageing population remains unclear. Using electroencephalography and a dual-talker task in a representative sample of listeners (N = 155; age=39–80 years), we here demonstrate an often-missed link from single-trial behavioural outcomes back to trial-by-trial changes in neural attentional filtering. First, we observe preserved attentional–cue-driven modulation of both neural filters across chronological age and hearing levels. Second, neural filter states vary independently of one another, demonstrating complementary neurobiological solutions of spatial selective attention. Stronger neural speech tracking but not alpha lateralization boosts trial-to-trial behavioural performance. Our results highlight the translational potential of neural speech tracking as an individualized neural marker of adaptive listening behaviour., Successful listening requires attentional filtering into behaviourally relevant and irrelevant sounds. Here, the authors demonstrate the role of neural speech tracking over alpha lateralization as a potential neural marker of an individual’s adaptive listening behaviour.

Published

2021