⚙
AI-generated deep summary
by claude@2026-07, 2026-07-03
· read from full text
ⓘ
This study used high-density EEG and behavioral measures in adults with autism spectrum disorder (ASD; n=20) and neurotypical controls (n=21) during a visual detection task with rhythmic structures ranging from fully regular to highly irregular (with parametrically varied jitter). The authors found that ASD participants showed significantly reduced neural modulation by temporal regularity and diminished coupling between neural oscillatory phase and behavior specifically under jittered conditions, indicating impaired oscillatory entrainment and reduced functional relevance of synchronization; residual post-stimulation spectral power suggested this was not explained by simple evoked responses. The degree of neural modulation by temporal regularity correlated with IQ within the ASD group, with the main limitation being the modest sample size and reliance on group-level EEG measures from a single task context. The paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.
Abstract
Rhythmic patterns in the environment enhance neural activity, perception, and action. However, natural rhythms are often imprecise, requiring flexible adaptation. In autism Spectrum Disorder (ASD), characterized by cognitive rigidity and atypical use of prior information - favoring immediate sensory input over predictive cues - entrainment to temporally variable input may be reduced at both neural and behavioral levels, though the neural mechanisms remain unclear. Here, we recorded high-density EEG and behavior in adults with ASD (n=20) and neurotypical (NT) controls (n=21) during a visual detection task with four rhythmic structures, parametrically varied from an isochronous fully regular rhythm, to a highly irregular one. Spectral analysis and temporal response function (TRF) models revealed significantly reduced modulation by temporal regularity in ASD, particularly in mildly jittered stimulation streams. Additionally, the coupling between phases of neural oscillations and behavior was diminished in ASD under the jittered conditions, suggesting reduced functional relevance of neural synchronization. Residual spectral power post-stimulation showed lower oscillatory entrainment in ASD, ruling out simple evoked-response explanations. Notably, the degree of neural modulation by temporal regularity was correlated with IQ within the ASD group, suggesting a link between temporal flexibility and individual cognitive profiles. These findings highlight impaired neural entrainment and reduced behavioral modulation by temporal structure in ASD, offering insight into inflexible responses to uncertain, volatile sensory environments. Innovation Entrainment to rhythmic events is reduced in autism, but it remains unclear whether this reflects a general, non-selective deficit in neuro-oscillatory alignment or a selective vulnerability to volatile temporal structures, such as those with embedded jitter. To address this, we recorded cortical activity and behavioral performance as participants with ASD engaged with visual sequences of varying rhythmic regularity, and examined how temporal predictability modulated oscillatory entrainment. By correlating neural entrainment with target detection and clinical profiles, we sought to uncover a key feature of the autistic phenotype: reduced temporal flexibility in adapting to unpredictable sensory environments.
Full text
2,465 characters
· extracted from
oa-html
· click to expand
Abstract
Rhythmic patterns in the environment enhance neural activity, perception, and action. However, natural rhythms are often imprecise, requiring flexible adaptation. In autism Spectrum Disorder (ASD), characterized by cognitive rigidity and atypical use of prior information - favoring immediate sensory input over predictive cues - entrainment to temporally variable input may be reduced at both neural and behavioral levels, though the neural mechanisms remain unclear. Here, we recorded high-density EEG and behavior in adults with ASD (n=20) and neurotypical (NT) controls (n=21) during a visual detection task with four rhythmic structures, parametrically varied from an isochronous fully regular rhythm, to a highly irregular one. Spectral analysis and temporal response function (TRF) models revealed significantly reduced modulation by temporal regularity in ASD, particularly in mildly jittered stimulation streams. Additionally, the coupling between phases of neural oscillations and behavior was diminished in ASD under the jittered conditions, suggesting reduced functional relevance of neural synchronization. Residual spectral power post-stimulation showed lower oscillatory entrainment in ASD, ruling out simple evoked-response explanations. Notably, the degree of neural modulation by temporal regularity was correlated with IQ within the ASD group, suggesting a link between temporal flexibility and individual cognitive profiles. These findings highlight impaired neural entrainment and reduced behavioral modulation by temporal structure in ASD, offering insight into inflexible responses to uncertain, volatile sensory environments.
Innovation Entrainment to rhythmic events is reduced in autism, but it remains unclear whether this reflects a general, non-selective deficit in neuro-oscillatory alignment or a selective vulnerability to volatile temporal structures, such as those with embedded jitter. To address this, we recorded cortical activity and behavioral performance as participants with ASD engaged with visual sequences of varying rhythmic regularity, and examined how temporal predictability modulated oscillatory entrainment. By correlating neural entrainment with target detection and clinical profiles, we sought to uncover a key feature of the autistic phenotype: reduced temporal flexibility in adapting to unpredictable sensory environments.
Competing Interest Statement
The authors have declared no competing interest.
Text is read by the "Ask this paper" AI Q&A widget below.
Extraction quality varies by source — PMC NXML preserves structure
cleanly, OA-HTML may include some navigation residue, and OA-PDF can
have broken hyphenation. The publisher copy
(via DOI)
is the canonical version.