Neuroimaging data reveal that a functional locus ceruleus-noradrenaline (LC-NA) system is critical in maintaining cognitive performance during aging. However, older adults show reduced LC integrity and altered functional connectivity, demonstrating both structural declines and dysfunction. The LC-NA system mediates mechanisms of attention processing and eye tracking studies have shown that older adults are slower and more distractible compared with young adults in visual search tasks. Prior studies have shown that mindfulness meditation modulates LC noradrenergic activity, increases gray matter volume in the brainstem, and improves attentional control. Thus, in a preregistered longitudinal study, we investigated whether 30 d of guided mindfulness meditation using a mobile application improved attentional control measured with eye movements. We hypothesized that older adults would show greater benefits from the mindfulness intervention compared with young adults. In two oculomotor search tasks, we identifie...

The development of Schwann cells, which myelinate axons in the peripheral nervous system, is critically dependent on MEK/ERK signaling. While Ets-domain transcription factors ( Etv1 , Etv4 , Etv5 ) are downstream effectors of this pathway, only Etv1 has been specifically linked to Schwann cell development. Here, we examined the functions of Etv5 , which is expressed in Schwann cell precursors, neural crest cells and satellite glia, at embryonic stages and at low levels in mature Schwann cells. In hypomorphic Etv5tm1Kmm homozygous mutant mice, no overt defects in Schwann cell differentiation were observed at embryonic stages. To study the function of Etv5 in juvenile (postnatal days 21–30) and mature adult (6 month) mice, we generated Etv5 conditional knock-outs (cKOs) using a Sox10-Cre driver. In juvenile male Etv5 -cKO mice, Schwann cell numbers increased normally after a peripheral nerve crush injury, a response that was attenuated by 6 months. Transmission electron microscopy of the naive sciatic nerve ...

There is a growing imperative to understand the neurophysiological impact of our rapidly changing and diverse technological, social, chemical, and physical environments. To untangle the multidimensional and interacting effects requires data at scale across diverse populations, taking measurement out of a controlled lab environment and into the field. Electroencephalography (EEG), which has correlates with various environmental factors as well as cognitive and mental health outcomes, has the advantage of both portability and cost-effectiveness for this purpose. However, with numerous field researchers spread across diverse locations, data quality issues and researcher idle time due to insufficient participants can quickly become unmanageable and expensive problems. In programs we have established in India and Tanzania, we demonstrate that with appropriate training, structured teams, and daily automated analysis and feedback on data quality, nonspecialists can reliably collect EEG data alongside various surv...

Animal behavior is crucial for understanding both normal brain function and dysfunction. To facilitate behavior analysis of mice within their home environments, we developed DeepEthoProfile, an open-source software powered by a deep convolutional neural network for efficient behavior classification. DeepEthoProfile requires no spatial cues for either training or processing and is designed to perform reliably under real laboratory conditions, tolerating variations in lighting and cage bedding. For data collection, we introduce EthoProfiler, a mobile cage rack system capable of simultaneously recording up to 10 singly housed mice. We used 36 h of manually annotated video data sampled in 5 min clips from a 48 h video database of 10 mice. This published dataset provides a reference that can facilitate further research. DeepEthoProfile achieved an overall classification accuracy of over 83%, comparable with human-level accuracy. The model also performed on par with other state-of-the-art solutions on another pu...

Material below summarizes the article Timing Determines Tuning: A Rapid Spatial Transformation in Superior Colliculus Neurons during Reactive Gaze Shifts, published on December 2, 2019, in eNeuro and authored by Morteza Sadeh, Amirsaman Sajad, Hongying Wang, Xiaogang Yan, and John Douglas Crawford. Highlights During gaze shifts of the eyes and head, the superior colliculus rapidly transforms a visual signal related to target direction into a motor command for gaze direction. This visuomotor transition involves a relay of signals between cells with visual, visuomotor, and motor responses, each contributing to the overall transformation. The difference between the visual input and motor output seems to arise from internal noise, correlating to behavioral errors that may reflect the health of the system.

Imagine you are the parent of two children. Your oldest, a boy, was diagnosed with autism last year and just celebrated his fourth birthday. Your youngest, a girl, is six months old. You’ve heard that autism runs in families; you know this means that your daughter is at higher risk than most children. But you’ve also heard that boys tend to get autism at a higher rate than girls. Your daughter, like her brother, is a poor sleeper, and sometimes you wonder whether she is more interested in looking at the ceiling fan than at you…but other times she smiles at you or her brother and seems very engaged. You find yourself making comparisons between your two children frequently, and wondering…will she have autism too? A friend tells you that just last year, researchers were able to scan the brains of babies when they were six to twelve months old and predict, for the first time, who would develop autism by age two. Your friend then poses the inevitable question: would you want this test for your daughter?

Our ability to shift from one emotion to the next allows us to adapt our behaviors to a constantly changing and often uncertain environment. Although previous studies have identified cortical and subcortical regions involved in affective responding, none have shown how these regions track and represent transitions between different emotional states nor how such responses are modulated based on the recent emotional context. To study this, we commissioned new musical pieces designed to systematically move participants (N = 39, 20 males and 19 females) through different emotional states during fMRI and to manipulate the emotional context in which different participants heard a musical motif. Using a combination of data-driven (Hidden Markov modeling) and hypothesis-driven methods, we confirmed that spatiotemporal patterns of activation along the temporal-parietal axis reflect transitions between music-evoked emotions. We found that the spatial and temporal signatures of these neural response patterns, as well...

Haung (Ho) Yu is part of the Greater New York City Chapter of SfN (braiNY), which brings together like-minded neuroscience organizations to better neuroscience education and outreach. Over the years, braiNY have seen steady growth and increased reach. Here are three things the chapter does to impact their audiences.

This resource was featured in the NeuroJobs Career Center. Visit today to search the world’s largest source of neuroscience opportunities. As director of the Adaptive Neural Systems Laboratory and the owner of more than a half dozen patents, Ranu Jung designs neural engineering projects that drive the process of transforming basic discoveries into clinical applications. In this interview she explains how collaborative projects can at once advance the understanding of the brain and the development of medical devices. She also talks about what sparks questions for her, the advantages of adaptability, and where to find support. This article is part of Neuronline's interview series "Entrepreneurial Women Combining Neuroscience, Engineering, and Tech," which highlights the career paths and scientific accomplishments of female leaders and role models who are creatively bridging disciplines to improve lives.

Material below summarizes the article Introduction of Tau Oligomers into Cortical Neurons Alters Action Potential Dynamics and Disrupts Synaptic Transmission and Plasticity, published on September 25, 2019, in eNeuro and authored by Emily Hill, Thomas K. Karikari, Kevin G. Moffat, Magnus J. E. Richardson, and Mark J. Wall. Highlights Introduction of nanomolar concentrations of tau oligomers into cortical neurons causes significant changes in action potential kinetics in a 40-minute timeframe. Introduction of tau oligomers into the presynaptic cell of synaptically connected pairs impairs basal synaptic transmission and enhances short-term depression. Introduction of tau oligomers into the postsynaptic cell of synaptically connected pairs has no effect on basal synaptic transmission but markedly impairs synaptic plasticity (long-term potentiation).