Over the past ten years, an in situ chemical synthesis approach to biological systems has emerged, in which functional materials are assembled within tissues such as the brain – either constructed throughout the intact tissue (hydrogel-tissue chemistry/HTC), or genetically targeted to cell types (genetically-targeted chemical assembly/GTCA). Resulting hybrid materials are endowed with diverse capabilities, including anchoring and labeling of RNA and protein, in situ sequencing, transparency, reversible size changes, and electrical insulation or conduction.

Speech in everyday life is often masked by background noise, making comprehension effortful. Characterizing brain activity patterns when individuals listen to masked speech can help clarify the mechanisms underlying such effort. In the current study, we used functional magnetic resonance imaging (fMRI) in humans of either sex to investigate how neural signatures of story listening change in the presence of masking noise. We show that, as speech masking increases, spatial and temporal activation patterns in auditory regions become more idiosyncratic to each listener. In contrast, spatial activity patterns in brain networks linked to effort (e.g. cinguloopercular network) are more similar across listeners when speech is highly masked and less intelligible, suggesting shared neural processes. Moreover, at times during stories when one meaningful event ended and another began, neural activation increased in frontal, parietal, and medial cortices. This event-boundary response appeared little affected by backgro...

Neuronline is a benefit of SfN membership. Renew your membership now to make sure you don’t lose access.

Neuronline is a benefit of SfN membership. Renew your membership now to make sure you don’t lose access.

Felix Schneider discusses his paper, “Neuron Replating, a Powerful and Versatile Approach to Study Early Aspects of Neuron Differentiation,” published in Vol. 8, Issue 3 of eNeuro, with Editor-in-Chief Christophe Bernard. 

Neuronline is a benefit of SfN membership. Renew your membership now to make sure you don’t lose access.

Felix Schneider discusses his paper, “Neuron Replating, a Powerful and Versatile Approach to Study Early Aspects of Neuron Differentiation,” published in Vol. 8, Issue 3 of eNeuro, with Editor-in-Chief Christophe Bernard. 

Mirror invariance is the cognitive tendency to perceive mirror-image objects as identical. Mirrored letters, however, are distinct orthographic units and must be identified as different despite having the same shape. Consistent with this phenomenon, a small, localized region in the ventral visual stream, the Visual Word Form Area (VWFA), exhibits repetition suppression to both identical and mirror pairs of objects but only to identical, not mirror, pairs of letters ( [Pegado et al., 2011][1]), a phenomenon named mirror invariance “breaking”. The ability of congenitally blind individuals to “break” mirror invariance for pairs of mirrored Braille letters has been demonstrated behaviorally ( [de Heering et al., 2018][2], [Korczyk et al., 2024][3]). However, its neural underpinnings have not yet been investigated. Here, in an fMRI repetition suppression paradigm, congenitally blind individuals (8 males and 10 females) recognized pairs of everyday objects and Braille letters in identical (“p” and “p”), mirror (...

Speech in everyday life is often masked by background noise, making comprehension effortful. Characterizing brain activity patterns when individuals listen to masked speech can help clarify the mechanisms underlying such effort. In the current study, we used functional magnetic resonance imaging (fMRI) in humans of either sex to investigate how neural signatures of story listening change in the presence of masking noise. We show that, as speech masking increases, spatial and temporal activation patterns in auditory regions become more idiosyncratic to each listener. In contrast, spatial activity patterns in brain networks linked to effort (e.g., cingulo-opercular network) are more similar across listeners when speech is highly masked and less intelligible, suggesting shared neural processes. Moreover, at times during stories when one meaningful event ended and another began, neural activation increased in frontal, parietal, and medial cortices. This event-boundary response appeared little affected by backg...

In a dense-sampling resting–state functional magnetic resonance imaging study, Wang et al. (2025) recorded two individuals’ functional connectivity patterns over 30 consecutive days to find a marker of the passage of time in the human brain. The authors measured the similarity of brain connectivity patterns over days, focusing on key regions involved in spatial navigation and declarative memory that have been previously shown to exhibit slow changes in activity patterns over time: the entorhinal cortex (EC) and the hippocampus (HPC). The authors show that connectivity pattern similarity decreased over time—more temporally distant resting-states had more distinct functional connectivity profiles. This result is consistent with the idea that brain activity intrinsically drifts over time (Driscoll et al., 2022). Additionally, the authors observed an anatomical gradient such that the anterior HPC showed stronger temporal drift than the posterior HPC, and the anterolateral EC showed stronger temporal drift than...