The team recruited 14 patients between 17 and 50 years of age, to participate. After a brief warmup, participants rode a stationary bike for 20 minutes at a pace they could maintain for the duration. Researchers recorded the participants’ brain activity before and after the cycling session using intracranial electroencephalography (iEEG), which utilizes implanted electrodes to measure neural activity in the brain. The recordings showed an increased rate of ripples originating in the hippocampus and connecting with cortical regions of the brain known to be involved in learning and memory performance.
“We’ve known for years that physical exercise is often good for cognitive functions like memory, and this benefit is associated with changes in brain health, largely from behavioral studies and noninvasive brain imaging,” says the study’s corresponding author. “By directly recording brain activity, our study shows, for the first time in humans, that even a single bout of exercise can rapidly alter the neural rhythms and brain networks involved in memory and cognitive function.”
The author says the results apply beyond the epileptic patients who participated. ScienceMission sciencenewshighlights.
A single session of physical exercise can spawn a boost of neural activity in brain networks that underlie learning and memory, according to a new study.
The researchers measured neural activity in the brains of patients with epilepsy before and after they completed a bout of physical exercise. The results showed that a single exercise session produced in the participants a burst of high-frequency brain waves, called ripples, emanating from the hippocampus to areas of the brain involved in learning and recall.
Neuroscientists have documented ripples relevant to memory in mice and rats, but they had not confirmed the link in humans, mainly because electrodes need to be implanted in the brain to obtain recordings. Instead, researchers had theorized the ripples’ role in humans, based on studies in people that measured changes in oxygenated blood in the brain after exercise. This new study marks the first time researchers have been able to see the neurons in action in people following exercise, the authors report.
When patients undergo general anesthesia, doctors can choose among several drugs. Although each of these drugs acts on neurons in different ways, they all lead to the same result: a disruption of the brain’s balance between stability and excitability, according to a new MIT study.
This disruption causes neural activity to become increasingly unstable, until the brain loses consciousness, the researchers found. The discovery of this common mechanism could make it easier to develop new technologies for monitoring patients while they are undergoing anesthesia.
“What’s exciting about that is the possibility of a universal anesthesia-delivery system that can measure this one signal and tell how unconscious you are, regardless of which drugs they’re using in the operating room,” says Earl Miller, the Picower Professor of Neuroscience and a member of MIT’s Picower Institute for Learning and Memory.
Miller, Edward Hood Taplin Professor of Medical Engineering and Computational Neuroscience Emery Brown, and their colleagues are now working on an automated control system for delivery of anesthesia drugs, which would measure the brain’s stability using EEG and then automatically adjust the drug dose. This could help doctors ensure that patients stay unconscious throughout surgery without becoming too deeply unconscious, which can have negative side effects following the procedure.
Miller and Ila Fiete, a professor of brain and cognitive sciences, the director of the K. Lisa Yang Integrative Computational Neuroscience Center (ICoN), and a member of MIT’s McGovern Institute for Brain Research, are the senior authors of the new study, which appears today in Cell Reports. MIT graduate student Adam Eisen is the paper’s lead author.
Yang et al. identify USP39 as a deubiquitinase hijacked by H5 AIV. USP39 catalytically deubiquitinates PB2 to prevent its degradation and maintain polymerase activity. Meanwhile, it promotes PB2-PB1 association for RNP assembly. The dual-function mechanism facilitates viral replication, enhances pathogenicity, and represents a promising anti-H5 therapeutic target.
It’s well known that alcohol consumption is an age-old method for coping with stress. But recent research led by the University of Massachusetts Amherst has found that when such self-medication begins in early adulthood, negative cognitive effects start to show up in middle age—even after long periods of total abstinence. The study is published in the journal Alcohol, Clinical and Experimental Research.
These negative effects include a decreased ability to cope with changing situations, an increased likelihood to drink when stressed, and the kinds of cognitive decline associated with dementia and Alzheimer’s disease. The new research helps us understand how alcohol rewires the brain’s circuitry and can help suggest new approaches for helping people adapt to the long-term effects of alcohol use.
Researchers have long known that stress and alcohol have a mutually reinforcing relationship: Alcohol can help take the edge off stressful situations, but in so doing it can decrease the brain’s ability to manage stress on its own, meaning one has to keep drinking, and drinking more, in order to relieve stress from a bad day. At the same time, the more one drinks, the more stress can accrue from increasingly poor decision-making. It can be a vicious cycle that gets harder to break the more the brain’s circuitry changes. But what about the long-term effects of stress and alcohol?
Stanford Medicine scientists are launching a clinical trial of prenatal transplants, using stem cells from the mother, to treat a rare genetic disease called Fanconi anemia before a baby is born.
Now, Cortical Labs is ready to scale up the operation. As Bloomberg reports, the company says it’s working on “biological data centers” in Melbourne, Australia, and Singapore. Simply put, instead of relying on Nvidia chips like AI companies, Cortical Labs is planning to outfit its futuristic facilities with racks of CL1 biological computers, powered by many more human brain cells, instead.
The company refers to this approach as “wetware,” an unsettling new take on software and hardware terminology. Simply put, the computers send electrical signals to neurons derived from human blood stem cells. The chips embedded within record those neurons’ responses as the output.
The company teamed up with DayOne Data Centers, to develop the two facilities. The Melbourne data center will house 120 CL1 units, while DayOne is planning to deploy as many as 1,000 units at the one in Singapore.
Dr. Nicolas Rouleau is a neuroscientist, bioengineer, and Assistant Professor of Health Sciences at Wilfrid Laurier University. He wrote the award-winning essay, ‘An Immortal Stream of Consciousness: The scientific evidence for the survival of consciousness after permanent bodily death,’ in which he argues that the transmissive theory of consciousness may actually be more consistent with emerging scientific insights than the dominant assumption that the brain generates consciousness.
In this conversation with Hans Busstra, Rouleau shares the main arguments from his essay, which touch upon his collaboration with Dr. Michael Persinger, the inventor of the ‘God Helmet,’ and his work with Michael Levin on ‘mind blindness’—the idea that science may be searching for mind in too restricted a place by focusing almost exclusively on neurons.
Further reading and scientific references discussed in this video:
Rouleau’s BICS Essay: ‘An Immortal Stream of Consciousness: The scientific evidence for the survival of consciousness after permanent bodily death.’ https://www.bigelowinstitute.org/inde…
Rouleau, N., Levin, M., et al. (2025) (Preprint; forthcoming in Philosophical Transactions of the Royal Society). Brains and Where Else? Mapping Theories of Consciousness to Unconventional Embodiments. https://tinyurl.com/439rrn8z.
Materials from a new class of magnets could host permanent dissipationless spin currents when they enter a superconducting state.
Superconductors are famous for transporting electric charge with zero resistance. This ability underpins technologies such as MRI scanners, quantum computers, and sensitive magnetometers known as superconducting quantum interference devices. However, in the field of spintronics—which seeks to process information using electron spin rather than charge—achieving a similar long-range dissipationless transport has remained elusive. In ordinary metals, electron spins are highly susceptible to scattering and spin-orbit coupling, both of which cause spin currents to decay over short distances. Although research in superconducting spintronics based on ferromagnets has made progress [1, 2], ferromagnets produce stray magnetic fields that interfere with external circuit elements, and their internal magnetic fields tend to destroy superconductivity.
All the essential ingredients to make the DNA and RNA underpinning life on Earth have been discovered in samples collected from the asteroid Ryugu, scientists said Monday.
The discovery comes after these building blocks of life were detected on another asteroid called Bennu, suggesting they are abundant throughout the solar system.
One longstanding theory is that life first began on Earth when asteroids carrying fundamental elements crashed into our planet long ago.
