Scientists found that having both gum disease and cavities was associated with a sharply higher risk of stroke and heart problems. Regular dental care may be an easy, overlooked way to protect not just your smile, but your brain.
Category: neuroscience – Page 3
Cannabis Survey Shows Rising CBD Use in Pets
“The long-term use of CBD is associated with less intense aggressive behaviors in dogs.”
Can cannabidiol (CBD) help dogs in the same way it helps humans? This is what a recent study published in Frontiers in Veterinary Science hopes to address as a team of scientists investigated the benefits of incorporating CBD products into dog products. This study has the potential to help scientists, legislators, and the public better understand the health benefits of CBD for both humans and animals.
For the study, the researchers analyzed data obtained from the Dog Aging Project (DAP), which is an organization designed to gain insight into dog aging, lifestyle, diet, and environmental factors. Surveys were conducted from 47,444 dog owners between December 2019 and December 2023, with the first surveys being s baseline regarding a dog’s overall health status, while the second survey was used to ascertain the amount of CBD or hemp the owners fed their dogs while also assessing changes in behavior and/or health.
In the end, the researchers found that healthy dogs were less likely to use CBD, whereas dogs with limiting health conditions like dementia, epilepsy, or cancer were more likely to use CBD. Additionally, CBD-use dogs were found to exhibit less aggressive behavior compared to non-use dogs. Finally, the team found that states where CBD was legal had higher rates of dogs using CBD.
Michelson–Morley experiment
In 1885, Michelson began a collaboration with Edward Morley, spending considerable time and money to confirm with higher accuracy Fizeau’s 1851 experiment on Fresnel’s drag coefficient, [ 5 ] to improve on Michelson’s 1881 experiment, [ 1 ] and to establish the wavelength of light as a standard of length. [ 6 ] [ 7 ] John Brashear made the high-quality optics for the Interferometer in his Allegheny-Observatory-affiliated shop. At this time Michelson was professor of physics at the Case School of Applied Science, and Morley was professor of chemistry at Western Reserve University (WRU), which shared a campus with the Case School on the eastern edge of Cleveland. Michelson suffered a mental health crisis in September 1885, from which he recovered by October 1885. Morley ascribed this breakdown to the intense work of Michelson during the preparation of the experiments. In 1886, Michelson and Morley successfully confirmed Fresnel’s drag coefficient—this result was also considered as a confirmation of the stationary aether concept. [ A 2 ]
This result strengthened their hope of finding the aether wind. Michelson and Morley created an improved version of the Michelson experiment with more than enough accuracy to detect this hypothetical effect. The experiment was performed in several periods of concentrated observations between April and July 1887, in the basement of Adelbert Dormitory of WRU (later renamed Pierce Hall, demolished in 1962). [ A 11 ] [ A 12 ]
As shown in the diagram to the right, the light was repeatedly reflected back and forth along the arms of the interferometer, increasing the path length to 11 m (36 ft). At this length, the drift would be about 0.4 fringes. To make that easily detectable, the apparatus was assembled in a closed room in the basement of the heavy stone dormitory, eliminating most thermal and vibrational effects. Vibrations were further reduced by building the apparatus on top of a large block of sandstone (Fig. 1), about a foot thick and five feet (1.5 m) square, which was then floated in a circular trough of mercury. They estimated that effects of about 0.01 fringe would be detectable.
Visualizing neural connections in 3D with a new microscopy technique
Leiden researchers can now visualize the connections between brain cells. Their microscopy technique could significantly advance the human quest to understand brain functions. The study is published in the Proceedings of the National Academy of Sciences.
How does information flow through the brain? To understand this, researchers map the brain at every scale, from small networks of cells to the entire nervous system. This provides insight into how our brains work and how connections between cells may become disrupted in disease.
The research group led by Professor Sense Jan van der Molen uses a microscope that reveals how a brain structure is built. It can do so down to the level of a synapse, the tiny junction through which one neuron communicates with another cell.
Autistic children born preterm often show more complex needs—but share similar genetic background
A new study shows that children born preterm who are later diagnosed with autism often present with more extensive support needs and a higher number of co-occurring conditions than autistic children born at full term. Surprisingly, however, the researchers found no differences in genetic variants across the genome, nor in specific genes already linked to autism, between the groups—a result that contradicted their initial hypothesis.
The study was conducted at KIND (Center of Neurodevelopmental Disorders at Karolinska Institutet) and published in October 2025 in the journal Genome Medicine.
“We did not observe any genetic differences between preterm and full-term autistic children, which was unexpected. We initially thought that preterm children might show fewer of the genetic factors associated with autism, as their early birth can be viewed as an environmental factor,” says Yali Zhang, doctoral student at Tammimies research group at KIND and first author of the study.
Comprehensive map reveals neuronal dendrites in the mouse brain in greater detail
Understanding the shape or morphology of neurons and mapping the tree-like branches via which they receive signals from other cells (i.e., dendrites) is a long-standing objective of neuroscience research. Ultimately, this can help to shed light on how information flows through the brain and pin-point differences associated with specific neurological or psychiatric disorders.
The X. William Yang Lab at the Jane and Terry Semel Institute and the Department of Psychiatry and Biobehavioral Sciences at University of California, Los Angeles (UCLA) have devised new sophisticated methods to map neuronal dendrites in the mouse brain, which combine large-scale data collection with genetic labeling techniques and computational tools.
Their research approach, outlined in a paper published in Nature Neuroscience, allowed them to create a comprehensive map of two genetic types of neurons in the mouse brain, known as D1-and D2-type striatal medium spiny neurons (MSNs).
A phenotypic brain organoid atlas and biobank for neurodevelopmental disorders
Wang and colleagues present a phenotypic brain organoid atlas for neurodevelopmental disorders, revealing disease-specific cellular and molecular alterations that illuminate NDD pathogenesis. Integrating patient brain organoids, imaging, and exome sequencing, this resource provides a powerful platform to advance research and therapeutic discovery.