Postdoctoral Fellow Halie Olson has been named to The Transmitter’s Rising Stars of Neuroscience, reports Francisco J. Rivera Rosario and Lauren Schneider for The Transmitter. The award “recognizes early-career researchers who have made outstanding scientific contributions to the field and demonstrated a commitment to mentoring and community-building.”
Prof. Laura Lewis speaks with New Scientist reporter Grace Wade about the importance of sleep research. Lewis notes that understanding the dynamics of how the brain transitions into sleep could help lead to new treatments for insomnia. “With sleep onset, it has been really difficult for us to find that moment,” says Lewis, where brain mechanisms drive the transition to sleep. “If we knew when that was, then we could start to say, what is the brain region or circuit that is making somebody fall asleep?”
A new study from researchers at MIT shows that lack of focus after a poor night’s sleep often corresponds with a surge of cerebrospinal fluid in the brain, which usually flows while we’re asleep. “We like to think we’re in control—that willpower, caffeine, and determination can overcome a missed night of sleep,” writes Bill Murphy Jr. for Inc. “However, this research suggests otherwise. When your brain needs to clean itself, it’s going to find a way to do it, whether you’re ready for it or not.”
Researchers at MIT examined how lack of sleep can impact a person’s attention, and “found that during these moments of brain fog, a wave of cerebrospinal fluid (CSF) is released out of the brain - a process which normally occurs whilst we are sound asleep, and helps to wash away waste products built up during the day,” reports Shaheena Uddin for The Independent.
Prof. Laura Lewis and her colleagues have discovered that momentary lapses in attention that often follow a bad night’s sleep are caused by the brain attempting to flush fluid out of its system, a process that normally occurs during sleep, reports Carissa Wong for New Scientist. “If you don’t have these waves [of fluid flowing] at night because you’re kept awake all night, then your brain starts to kind of sneak them in during the daytime, but they come with this cost of attention,” says Lewis.
Researchers at MIT have found that momentary lapses in attention, often described as zoning out, coincide with waves of fluid flowing out of the brain, reports Ian Sample for The Guardian. “The moment somebody’s attention fails is the moment this wave of fluid starts to pulse,” says Prof. Laura Lewis. “It’s not just that your neurons aren’t paying attention to the world, there’s this big change in fluid in the brain at the same time.”
Prof. Laura Lewis speaks with Quanta Magazine reporter Yasemin Saplakoglu about her quest to better understand how the brain transitions to sleep. “Our brains can really rapidly transform us from being aware of our environments to being unconscious, or even experiencing things that aren’t there,” said Lewis. “This raises deeply fascinating questions about our human experience.”
In an effort to develop non-invasive ways to treat depression, PTSD, brain tumors and other conditions, researchers from MIT Lincoln Lab are looking to better understand human consciousness, reports Steph Solis for Axios. “There's the goal to analyze how it could help understand or treat PTSD and mood disorders in veterans,” says Solis of the inspiration for this research, “and then there's the existential question that stumps neuroscientists — how does our human experience arise from brain activity?”
Research Scientist Robert Ajemian speaks with National Geographic reporter Erika Engelhaupt about loci, an ancient technique that “transforms any familiar space into a storage system for new information.” “It’s shocking to me that this is so understudied when this was the dominant form of information storage for literally all of civilization, until the printing press,” says Ajemian.
Researchers from MIT and Harvard Medical School produced two new papers about the impact of a specific cytokine, or immune molecule, known as IL-17, on the brain when you’re sick. “Cytokines are well-known players in the immune response, helping to control inflammation and coordinate the responses of other immune cells,” reports Genetic Engineering & Biotechnology News. “A growing body of evidence suggests that some cytokines also influence the brain, leading to behavioral changes during illness.”
A team of researchers from MIT and Harvard Medical School are “deciphering the action of small immune system proteins in the brain and showing how, by exciting or inhibiting populations of neurons, they modulate anxiety and social behaviors,” writes Soline Roy of Le Figaro.
A new study co-authored by Prof. David Rand found that there was a “20 percent reduction in belief in conspiracy theories after participants interacted with a powerful, flexible, personalized GPT-4 Turbo conversation partner,” writes Annie Duke for The Washington Post. “Participants demonstrated increased intentions to ignore or unfollow social media accounts promoting the conspiracies, and significantly increased willingness to ignore or argue against other believers in the conspiracy,” writes Duke. “And the results appear to be durable, holding up in evaluations 10 days and two months later.”
Prof. Ed Boyden and Prof. Li-Huei Tsai have “found that if gamma waves through non-invasive stimulation, were put back into baseline frequency, it could slow down the process in certain brain diseases such as Alzheimer’s,” reports Hansa Bhargava for Forbes.
Writing for Scientific American, former postdoctoral fellow Aza Allsop PhD '16 and his colleagues spotlight bias in the scientific community. “When the significant contributions of Black scientists are excluded, we all lose,” they write. “This is why it is time that awarding committees and beyond finally begin acknowledging the significant discoveries made by Black scientists that benefit all of humanity—and giving them the proper recognition they deserve.”
New Yorker reporter Rivka Galchen visits the lab of Prof. Hugh Herr to learn more about his work aimed at the “merging of body and machine.” Herr and his team are developing bionic prosthetics that can be completely controlled by the human brain and are designed to allow users “to walk approximately as quickly and unthinkingly as anyone else.” Herr imagines a future where “we will be able to sculpt our own brains and bodies, and therefore our own identities and experiences.”