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Category: neuroscience

Biology-based brain model matches animals in learning, enables new discovery

A new computational model of the brain based closely on its biology and physiology not only learned a simple visual category learning task exactly as well as lab animals, but even enabled the discovery of counterintuitive activity by a group of neurons that researchers working with animals to perform the same task had not noticed in their data before, says a team of scientists at Dartmouth College, MIT, and the State University of New York at Stony Brook.

Notably, the model produced these achievements without ever being trained on any data from animal experiments. Instead, it was built from scratch to faithfully represent how neurons connect into circuits and then communicate electrically and chemically across broader brain regions to produce cognition and behavior. Then, when the research team asked the model to perform the same task that they had previously performed with the animals (looking at patterns of dots and deciding which of two broader categories they fit), it produced highly similar neural activity and behavioral results, acquiring the skill with almost exactly the same erratic progress.

“It’s just producing new simulated plots of brain activity that then only afterward are being compared to the lab animals. The fact that they match up as strikingly as they do is kind of shocking,” says Richard Granger, a professor of psychological and brain sciences at Dartmouth and senior author of a new study in Nature Communications that describes the model.

Peripheral cancer attenuates amyloid pathology in Alzheimer’s disease via cystatin-c activation of TREM2

Now online! Peripheral cancer inhibits amyloid pathology and rescues cognition of Alzheimer’s disease through secretion of cystatin-c (Cyst-C), which binds amyloid oligomers and activates TREM2 in microglia and enables microglia to degrade pre-existing plaques.

Eco-Friendly Agrochemicals: Embracing Green Nanotechnology

In the pursuit of sustainable agricultural practices, researchers are increasingly turning to innovative approaches that blend technology and environmental consciousness. A recent study led by M.R. Salvadori, published in Discover Agriculture, delves into the promising world of green nanotechnology in agrochemicals. This research investigates how nanoscale materials can enhance the effectiveness of agrochemicals while minimizing their environmental footprint. The findings suggest that this novel approach may revolutionize crop protection and nutrient delivery systems.

Nanotechnology involves manipulating materials at the nanoscale, typically between 1 and 100 nanometers. At this scale, materials exhibit unique properties that differ significantly from their bulk counterparts. These properties can be harnessed to improve the delivery and efficacy of agrochemicals. For instance, nanosized fertilizers can increase the availability of nutrients to plants, enhancing growth and reducing waste. This targeted approach is essential in combating soil nutrient depletion and ensuring food security in an era of burgeoning global population.

Traditional agrochemicals often come with the burden of negative environmental impacts, including soil and water contamination. The introduction of green nanotechnology aims to address these concerns by developing more biodegradable and environmentally friendly agrochemicals. By using nanomaterials derived from natural sources, researchers hope to create a symbiotic relationship between agricultural practices and ecological health. This paradigm shift could pave the way for a new era of environmentally responsible farming.

The cerebellar components of the human language network

Colton Casto, Evelina Fedorenko & colleagues Neuron.

Casto et al. systematically examine language-responsive regions of the cerebellum with precision fMRI. They find one region that closely resembles the neocortical language network in its selectivity for language and response to linguistic manipulations. They also find three mixed-selective regions that respond to language but also to non-linguistic inputs.

Parent-Led Early Intervention in Very Preterm Infants and Executive Function at School Age: Secondary Analysis of a Randomized Clinical Trial

Enhanced developmental intervention (EDI), initiated in the neonatal intensive care unit and continued at home for 2 years, improved executive function at school age among very preterm children compared with usual care.

All executive domains assessed showed better performance with EDI, especially for design fluency. These findings support sustained neurodevelopmental benefit for Preterm children, with implications for long-term outcomes.

Question What are the long-term effects of an enhanced early intervention on the executive functions of children born preterm?

Findings In this secondary analysis of a randomized clinical trial among 80 very low-birth-weight preterm children, it was observed that parent-led early intervention improved executive function.

Meaning Early intervention may strengthen cognitive skills, such as attention, self-regulation, and problem-solving, which could improve academic, emotional, and social outcomes, highlighting the importance of early intervention for long-term developmental success.

Dietary methionine mitigates immune-mediated damage by enhancing renal clearance of cytokines

Nutritional strategy to prevent immune-mediated damage.

Excessive immune response with the inflammatory cytokine and chemokine production may lead to tissue damage.

With Yersinia pseudotuberculosis infection in mic, the researchers found that dietary methionine enhances kidney filtration and promotes urinary excretion of inflammatory cytokines during infection and protects against anorexia, wasting, blood-brain barrier dysfunction, and lethality.

Mechanistically, methionine and its metabolite S-adenosyl methionine (SAM) activate renal mTORC1 signaling, promoting renal growth and enhanced glomerular filtration function.

By improving cytokine clearance, this pathway mitigates immune-mediated damage and reveals a nutritional strategy to promote cooperative defenses. sciencenewshighlights ScienceMission https://sciencemission.com/Dietary-methionine

Troha et al. found that dietary methionine enhances kidney filtration and promotes urinary excretion of inflammatory cytokines during infection. By improving cytokine clearance, this pathway mitigates immune-mediated damage and reveals a nutritional strategy to promote cooperative defenses.

Continue reading “Dietary methionine mitigates immune-mediated damage by enhancing renal clearance of cytokines” | >

Nanoparticles That Destroy Disease Proteins Could Unlock New Treatments for Dementia and Cancer

Scientists have developed a new nanoparticle-based strategy that could dramatically expand the range of disease-causing proteins that can be targeted by modern medicine. A newly released perspective in Nature Nanotechnology describes an emerging nanoparticle-based approach designed to remove harm

Population-level age effects on the white matter structure subserving cognitive flexibility in the human brain

New in eNeuro from Wolfe et al: Brain structures related to shifting between tasks or updating information about the environment show signs of deterioration in late adulthood.

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Cognitive flexibility, a mental process crucial for adaptive behavior, involves multi-scale functioning across several neuronal organization levels. While the neural underpinnings of flexibility have been studied for decades, limited knowledge exists about the structure and age-related differentiation of the white matter subserving brain regions implicated in cognitive flexibility. This study investigated the population-level relationship between cognitive flexibility and properties of white matter across two periods of human adulthood, aiming to discern how these associations vary over different life stages and brain tracts among men and women. We propose a novel framework to study age effects in brain structure-function associations. First, a meta-analysis was conducted to identify neural regions associated with cognitive flexibility. Next, the white matter projections of these neural regions were traced through the Human Connectome Project tractography template to identify the white matter structure associated with cognitive flexibility. Then, a cohort analysis was performed to characterize myelin-related macromolecular features using a subset of the UK Biobank magnetic resonance imaging (MRI) data, which has a companion functional/behavioral dataset. We found that the wiring of cognitive flexibility is defined by a subset of brain tracts, which present undifferentiated features early in adulthood and significantly differentiated types in later life. These MRI-derived properties are correlated with individual subprocesses of cognition, which are closely related to cognitive flexibility function. In late life, myelin-related homogeneity of specific white matter tracts implicated in cognitive flexibility declines with age, a phenomenon not observed in early life. Our findings support the age-related differentiation of white matter tracts implicated in cognitive flexibility as a natural substrate of adaptive cognitive function.

Significance Statement Cognitive flexibility function facilitates adaptation to environmental demands. Brain changes affecting structural organization during the lifespan are theorized to impact cognitive flexibility. This study characterizes how the brain’s connectivity is correlated with cognitive flexibility function throughout adulthood. By analyzing myelin-related properties of white matter, this study found that certain parts of the brain’s wiring related to cognitive flexibility become more differentiated with advanced age. These age-related features appear as a natural characteristic of the human brain that may impact specific aspects of adaptive thinking, like shifting between tasks or updating information.

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