By Siddhant Pusdekar Deer mice, common across North America, come in two varieties: One lives in prairies, whereas the other inhabits forests. The life of the forest mouse requires greater dexterity—a skill it possesses thanks to its higher number of corticospinal tract axons, according to a January preprint. The existence of “genetically tractable subspecies of deer mice with different behavioral niches” made the discovery possible, says Eiman Azim, associate professor of molecular neurobiology at the Salk Institute for Biological Studies, who wasn’t involved in the study. It enabled the researchers to link genetically driven changes in corticospinal abundance and morphology to dexterity. The new work reveals one way dexterous skill may emerge, while also suggesting neuroscience should investigate “behaviors that evolved for the natural niches” to discover fresh insights, says Ariel Levine, a senior investigator at the U.S. National Institute of Neurological Disorders and Stroke, who wasn’t involved in the study. Dexterity in primates coevolved with direct connections between layer 5 cortical neurons and motor neurons in the spinal cord, Levine says. In rodents, cats and less dexterous monkeys, however, corticospinal neurons connect to motor neurons via interneurons. Direct cortical-motor neuron connections exist in juvenile mice, but they are pruned during development, a 2017 paper showed. Artificially stopping the pruning process created adult lab mice with greater skill at gathering food pellets.

Keyword: Evolution; Development of the Brain
Link ID: 30196 - Posted: 04.11.2026

Marielle Segarra When neurosurgeon and journalist Dr. Sanjay Gupta set out to write a book about pain, it wasn't because he felt like he had all the answers. It was because he was still so often mystified by it. "Most of my patients come to me for pain. Head pain, back pain, neck pain, whatever it might be," he says. "If that's what the majority of your professional life is, you should understand it as best you can." His 2025 book, It Doesn't Have to Hurt: Your Smart Guide to a Pain-Free Life, gathers the latest developments in pain science, based on his own experience with patients and conversations with researchers and doctors. What he found may challenge your own understanding of pain and even give you the tools to help you feel better. There's evidence, for example, that just learning about pain and how it works "seems to be pain relieving" for those with chronic pain conditions, he says. Gupta, who also serves as the chief medical correspondent for CNN, explains what we still don't know about pain and shares a few effective new treatments. This interview has been edited for length and clarity. In your book, you say that one of the most significant developments emerging in pain treatment is the fact that the brain is at the center of any pain experience. Can you tell us more about why that matters? What I think has become clear — and I'm not the first person to say this — is the idea that if the brain doesn't decide you have pain, then you don't have pain. © 2026 npr

Keyword: Pain & Touch; Attention
Link ID: 30189 - Posted: 04.04.2026

Lynne Peeples In 2021, dermatologist David Ozog was on holiday with his family in the Bahamas, when his 18-year-old son had a massive stroke. The teenager was airlifted to Florida, and then to Chicago for surgery. As his son was lying partially paralysed in a hospital bed, Ozog got a call from a colleague who had an unconventional suggestion. The colleague, a dermatologist at Harvard Medical School in Boston, Massachusetts, told Ozog about research he was conducting with the US Department of Defense. Early results hinted that red and near-infrared light applied to the head might protect neural tissue after brain injury. He urged Ozog to consider trying it on his son. Ozog stayed up until 4 a.m. that night reading scientific papers and, ultimately, ordering several panels made of red and near-infrared light-emitting diodes (LEDs). “I started sneaking them into the hospital,” says Ozog, who works at Henry Ford Health in Grand Rapids, Michigan. Today, his son is walking and back in university. Ozog cannot prove that light therapy made a difference, but he thinks that it helped. He has since become a convert to an idea that, at the time, was considered fringe. “I thought the same thing,” he says, “How could shining this thing on you possibly have any biologic effect?” But what was at the margins of medicine just a few years ago is now edging towards the mainstream. Red-light devices are increasingly appearing in dermatology offices, wellness centres, locker rooms and homes. According to some projections, the global market will surpass US$1 billion by 2030, propelled by a surge of companies promising benefits for everything from ageing skin to attention deficit hyperactivity disorder (ADHD) — claims echoed widely across social media. Experts warn that there is considerable hype about red-light therapy. But a growing body of legitimate science has been exploring the benefits for several conditions. Clinical studies have reported improvements in peripheral neuropathy1, retinal degeneration2 and certain neurological disorders3. For some indications, expert groups now recommend red-light regimens1. Researchers are also uncovering how red and near-infrared light might exert these effects. Mitochondria — the power plants of the cell — are emerging as a central piece of the puzzle. © 2026 Springer Nature Limited

Keyword: Stroke; Parkinsons
Link ID: 30182 - Posted: 03.28.2026

by Pam Belluck Tango is the national dance of Argentina, known for its passion, precision and heart. In a hospital in Buenos Aires, it has another purpose: as a therapy for patients with Parkinson’s disease. Once a week, about a dozen patients come to Ramos Mejía Hospital to dance — a session that uses the movements of tango to help address issues of balance, stiffness and coordination. The goal is to give them approaches to movement that they can use in their daily lives, as well as a social and emotional boost from moving to music. The program began about 15 years ago, inspired by a patient who had danced tango since childhood and found it offered strategies that improved her mobility and gait problems, said Dr. Nélida Garretto, a neurologist who helped spearhead the sessions. Dr. Tomoko Arakaki, another neurologist leading the program, said Parkinson’s patients can struggle with the stop-and-start motions of walking and can benefit from practicing the “slow, short steps” and pauses of tango. Dr. Garretto said that because tango involves “multitasking with motor stimuli, visual stimuli and auditory stimuli,” it can help patients execute the series of small movements in everyday activities. First, warm-up exercises, usually in a circle, “try to tune everyone in, to prepare the body, to awaken the body,” said Manuel Firmani, a professional tango dancer leading the workshops. Some are done standing, some seated, depending on “the state people are in,” he said. After exercises focusing on posture, balance and other skills, dancing begins. Each patient is paired with a partner who doesn’t have Parkinson’s, often friends, relatives or volunteers. © 2026 The New York Times Company

Keyword: Parkinsons
Link ID: 30173 - Posted: 03.25.2026

By Helena Kudiabor Two neurobiologists who helped decipher how the somatosensory system detects touch and pain have won this year’s Brain Prize, the world’s largest award in neuroscience. Patrik Ernfors, professor of tissue biology at the Karolinska Institutet, and David Ginty, professor of neurobiology at Harvard University, will share the 10 million Danish kroner (about $1.6 million) prize. The award was announced today by the Lundbeck Foundation, which founded the Brain Prize in 2011. The honorees will be officially awarded at a ceremony in Copenhagen in May. Research by Ernfors and Ginty has “created a blueprint for understanding normal touch and for pinpointing where things go wrong in disorders such as chronic pain,” said Andreas Meyer-Lindenberg, chair of the Brain Prize selection committee, in a press release announcing the winners. Ernfors was honored for his contributions to classifying the neurons that make up the sensory nervous system in mice. Historically, neuroscientists differentiated among different somatosensory neurons based on a handful of functional features, such as conduction velocity, individual markers and cell morphology, Ernfors says. He and his colleagues have instead classified different types of neurons based on the constellation of genes they express. For example, in one of his most-cited analyses, Ernfors and his colleagues distinguished 622 mouse sensory neurons based on their gene expression patterns. “Now that we know what kinds of neurons there are, we can establish where they project peripherally, centrally, how they connect to each other and what makes them active or inactive,” Ernfors explains. © 2026 Simons Foundation

Keyword: Pain & Touch
Link ID: 30149 - Posted: 03.07.2026

By Delthia Ricks Susan E. Leeman, who helped reshape scientific understanding of how the brain sends chemical signals throughout the body, did not hesitate to leave the laboratory when her research demanded it — even if it meant visiting slaughterhouses. In the late 1960s, while running a small lab at Brandeis University, she was trying to isolate a stress hormone and needed large quantities of the bovine hypothalamus, a cow’s version of the structure found deep in all mammalian brains. When supplies ran short at a local meatpacker in Boston, Dr. Leeman traveled to Chicago, home at the time to the sprawling Union Stock Yards, to secure fresh tissue. What ultimately emerged was not the hormone that she sought but an elusive chemical called Substance P. Discovered decades earlier but never fully understood, it was finally identified by Dr. Leeman in 1970 as a neuropeptide, released by cells in the brain or spinal cord in response to pain. Three years later, she identified another neuropeptide. The two discoveries established her as a leading figure in neuroendocrinology. Dr. Leeman died on Jan. 20 in Manhattan, at the home of her daughter Eve Leeman, where she had been living. She was 95. Her death was confirmed by another daughter, Jennifer Leeman. Although Substance P was identified in 1931 by Ulf von Euler and John Gaddum, researchers working in London, it was Dr. Leeman who discovered that it was a neuropeptide — a tiny, protein-like molecule released by neurons, or nerve cells in the brain and spinal cord, that transmits signals to target tissues. It was the first neuropeptide discovered in what would become a large class known as tachykinins. Dr. Leeman found that Substance P relays pain signals and amplifies the sensation of pain by triggering inflammation. It has since been linked to chronic pain syndromes, arthritis pain and migraines. © 2026 The New York Times Company

Keyword: Pain & Touch
Link ID: 30135 - Posted: 02.25.2026

By Alexa Robles-Gil Every elephant has about 1,000 whiskers on its trunk. They play a crucial role for the animals, which have thick skin and poor eyesight. Elephants cannot regrow these hairs, meaning a lost one creates a permanent sensory blind spot on a trunk, which they use for almost everything in daily life. And as such an important feature, they are also unique among mammalian facial hairs. “Elephant whiskers are aliens,” said Andrew Schulz, a mechanical engineer at the Max Planck Institute for Intelligent Systems in Germany. In a study published Thursday in the journal Science, Dr. Schulz and his colleagues identified the structural features that give elephant whiskers a kind of “built-in” intelligence, providing the sensitivity that the largest mammals on land need to navigate their world. While other animals like rats can move their whiskers around, a behavior known as “whisking,” elephants lack the necessary muscles. That leaves their whiskers essentially stationary, even if they protrude from the flexible trunk. This puzzled Dr. Schulz, who had previously studied the movement of their trunks. “If elephant trunk whiskers can’t move, there’s probably something built into them that allows them to” function in a way similar to mammals that whisk, Dr. Schulz said. To find out, Dr. Schulz gathered scientists from many fields. Engineers, neuroscientists, biologists and material scientists were among the few who studied whiskers from baby and adult Asian elephants. (All elephant whiskers came from animals that had died naturally, and were donated by a zoo veterinarian; “We did not go up and pluck whiskers from elephants,” Dr. Schulz said.) © 2026 The New York Times Company

Keyword: Pain & Touch; Evolution
Link ID: 30123 - Posted: 02.14.2026

Mariana Lenharo Exercise pumps up your muscles — but it might also be pumping up your neurons. According to a study published today in Neuron1, repeated exercise sessions on a treadmill strengthen the wiring in a mouse’s brain, making certain neurons quicker to activate. This ‘rewiring’ was essential for mice in the study to gradually improve their running endurance. The work reveals that the brain — in mice and, presumably, in humans — is actively involved in the development of endurance, the ability to get better at a physical activity with repeated practice, says Nicholas Betley, a neuroscientist at the University of Pennsylvania in Philadelphia, and a co-author of the paper. “You go for a run, and your lungs expand, your heart gets pumping better, your muscles break down and rebuild. All this great stuff happens, and the next time, it gets easier,” Betley says. “I didn’t expect that the brain was coordinating all of that.” Betley and his colleagues were curious about what happens in the brain as people get stronger through exercise. They decided to focus on the ventromedial hypothalamus, a brain region that regulates appetite and blood sugar. The team then zeroed in on a group of neurons in that region that produce a protein called steroidogenic factor 1 (SF1), which is known to play a part in regulating metabolism2. A previous study3 found that the deletion of the gene that codes for SF1 impairs endurance in mice. © 2026 Springer Nature Limited

Keyword: Obesity; Learning & Memory
Link ID: 30120 - Posted: 02.14.2026

Jon Hamilton Parkinson's disease does more than cause tremor and trouble walking. It can also affect sleep, smell, digestion and even thinking. That may be because the disease disrupts communication in a brain network that links the body and mind, a team reports in the journal Nature. "It almost feels like a tunnel is jammed, so no traffic can go normally," says Hesheng Liu, a brain scientist at Changping Laboratory and Peking University in Beijing and an author of the study. The finding fits nicely with growing evidence that Parkinson's is a network disorder, rather than one limited to brain areas that control specific movements, says Peter Strick, a professor and chair of neurobiology at the University of Pittsburgh who was not involved in the study. Other degenerative brain diseases affect other brain networks in different ways. Alzheimer's, for example, tends to reduce connectivity in the default mode network, which supports memory and sense of self. ALS (amyotrophic lateral sclerosis) primarily damages the motor system network, which controls movement. Understanding the network affected by Parkinson's, which affects about 1 million people in the United States, could change the way doctors treat the disease. A mystery solved? People with Parkinson's often have symptoms that vary in ways that are hard to explain. For example, someone who usually is unable to stand may suddenly leap when faced with an emergency. And Parkinson's patients who can still walk may freeze if they try to carry on a conversation. © 2026 npr

Keyword: Parkinsons
Link ID: 30116 - Posted: 02.11.2026

By Corinna da Fonseca-Wollheim The placid chords of a Debussy prelude splashed through a darkened auditorium during a recital by the pianist Nicolas Namoradze at the University of California, San Francisco, on a November evening. A translucent image of Namoradze’s brain appeared above him on a screen: Electrical currents of different wavelengths, associated with varying levels of alertness, registered as colorful activity coursing through the model like storm fronts on a weather map. With each chord, clouds of green and blue bloomed, then faded as the sound receded. As the recital progressed with works by Bach, Beethoven and Scriabin, the image of the gently rotating brain showed a complex choreography of signals that sometimes ping-ponged between different areas or flickered simultaneously across the organ’s hemispheres. As a visual spectacle accompanying Namoradze’s pellucid playing, it was mesmerizing: an X-ray, seemingly, of virtuosity at work. But to the scientists in the audience, attendees at a conference on the neuroscience of music and dance, it was more than entertainment. It was evidence of a breakthrough in experiment design — one that opens up possibilities in an area that has long eluded scientific study: how music activates the brain, not in listeners, but in performers. It was also a reminder of the value artists can bring to scientific inquiry as active participants shaping studies of their craft. The neuroscientist Theodore Zanto, a member of the Neuroscape lab at U.C.S.F. that created the “Glass Brain” animations, said in an interview the next day that he was surprised — and moved — by the result. “It’s probably the cleanest real-time representation of what’s happening inside the brain during a piano performance,” he said. © 2026 The New York Times Company

Keyword: Hearing; Brain imaging
Link ID: 30115 - Posted: 02.11.2026

By Natalia Mesa A region of the cerebellum shows language specificity akin to that of cortical language regions, indicating that it might be part of the broader language network, according to a new brain-imaging study. “This is the first time we see an area outside of the core left-hemisphere language areas that behaves so similarly to those core areas,” says study investigator Ev Fedorenko, associate professor of brain and cognitive sciences at the Massachusetts Institute of Technology. Initially thought to coordinate only movement, the cerebellum also contributes to cognitive processes, such as social reward, abstract reasoning and working memory, according to studies from the past decade. But despite the fact that people with cerebellar lesions have subtle language struggles, the region’s contributions to that skill have been ignored until recently, Fedorenko says. With this new work, “I think it becomes harder to dismiss language responses as somehow artifactual.” Fedorenko and her team analyzed nearly 1,700 whole-brain functional MRI experiments conducted over the course of 15 years. They originally collected and analyzed those scans to identify language-selective regions of the neocortex, but they reanalyzed many of them to determine the cerebellum’s role in linguistic processing. Four cerebellar regions activated robustly when participants performed language-related tasks, such as reading passages of text or listening to someone else reading the passages aloud, in line with previous work. But only one region responded exclusively to these language-related tasks; it did not activate during a variety of nonlinguistic tasks—including movement, arithmetic tasks and a spatial working memory task—or when participants listened to music or watched videos of faces and bodies. The findings were published last month in Neuron. © 2026 Simons Foundation

Keyword: Language
Link ID: 30110 - Posted: 02.07.2026

By Calli McMurray In 2010, Ardem Patapoutian unmasked a piece of cellular machinery that had long evaded identification: PIEZO channels, pores wrenched open by changes in a cell’s membrane tension to allow ions to flow through, thereby converting mechanical force into electrical activity. The discovery marked a turning point for the field of mechanosensation—a process that can be unwieldy to study, says Arthur Beyder, associate professor of physiology and medicine at the Mayo Clinic, because “it reaches its fingers into everything.” The field needed “something to grab onto,” he says, to untangle these processes from other sensory ones—and PIEZO channels provided the first handhold. The PIEZO discovery garnered much attention, and since then, a flurry of studies have outlined how the channels contribute to touch, itch and proprioception. In 2021, Patapoutian shared the Nobel Prize in Physiology or Medicine for his contributions to this work. Now, a growing cadre of researchers is using these receptors as a tool to explore interoception, or the brain’s sense of what the internal organs are doing. “We’re seeing a resurgence and an expansion of research in this area,” says Miriam Goodman, professor of molecular and cellular physiology at Stanford University. The field, she adds, is in the middle of a “PIEZO-driven renaissance.” Even a body at rest is in constant motion: The heart pumps blood, the lungs expand and contract, the gut squeezes food, and the bladder stretches with urine. Biologists had intuited that mechanical force was a key part of these processes—and also part of how organs communicate with the brain—but for decades they did not have a way to dive into the molecular mechanisms behind them. © 2026 Simons Foundation

Keyword: Pain & Touch
Link ID: 30101 - Posted: 01.31.2026

By Laura Sanders The brain’s “little brain” may hold big promise for people with language trouble. Tucked into the base of the brain, the fist-sized cerebellum is most known for its role in movement, posture and coordination. A new study maps the language system in this out-of-the-way place. These results, published January 22 in Neuron, uncover a spot in the cerebellum that shows strong and selective activity for language. The new study is “excellent,” says neurologist and cerebellum researcher Jeremy Schmahmann of Massachusetts General Hospital and Harvard Medical School in Boston. His work and that of others have shown that the cerebellum contributes to language and thinking more generally. The new research scrutinized the cerebellum in detail, “confirming and extending previous observations and contributing to our understanding” of the cerebellum’s activity, he says. Neuroscientist Colton Casto combed through about 15 years of brain scanning data collected by study coauthor Evelina Fedorenko, a cognitive neuroscientist at MIT, and her colleagues. Putting the data all together, the scans of 846 people showed brain activity in four spots in the right side of the cerebellum as people read or listened to a story. Three of these spots were also active when people did other things, such as working out a math problem, or listening to music or watching a movie without words. But one spot was more discerning, says Casto, of MIT and Harvard University. This region didn’t respond to nonverbal movies or math. It also ignored orchestral or jazz music, which, like language, relies on syntax and patterns and sound. Instead, this spot is attuned specifically to words. “You have to be reading or listening to language to fully recruit this region,” Casto says. © Society for Science & the Public 2000–2026.

Keyword: Language
Link ID: 30091 - Posted: 01.24.2026

Allison Aubrey If you feel a lift after exercise, you're in good company. Movement can boost mood, and according to the results of a new study, it can also help relieve symptoms of depression. As part of a review of evidence by the Cochrane collaboration — an independent network of researchers — scientists evaluated 73 randomized controlled trials that included about 5,000 people with depression, many of whom also tried antidepressant medication. "We found that exercise was as effective as pharmacological treatments or psychological therapies as well," says Andrew Clegg, a professor at the University of Lancashire in the U.K. The findings are not a surprise to psychiatrist Dr. Stephen Mateka, medical director of psychiatry at Inspira Health. "This new Cochrane review reinforces the evidence that exercise is one of the most evidence-based tools for improving mood," says Mateka. He explains how it mirrors some of the effects of medication. "Exercise can help improve neurotransmitter function, like serotonin as well as dopamine and endorphins. So there is certainly overlap between exercise and how antidepressants offer relief," Mateka says. And there's another powerful effect too. Exercise can trigger the release of brain growth factors, explains Dr. Nicholas Fabiano of the University of Ottawa. He says depression can decrease neuroplasticity, making it harder for the brain to adapt and change. "The brain in depression is thought to be less plastic. So there's less what we call neurotrophic factors, or BDNF," Fabiano explains. He calls it the Miracle-Gro for the brain. "And we know that exercise can also boost it. So I think exercise is a fundamental pillar we really need to counsel patients on," he says. © 2026 npr

Keyword: Depression
Link ID: 30077 - Posted: 01.14.2026

By Bethany Brookshir Women of reproductive age are more likely than other people to report gut problems like irritable bowel syndrome (IBS), and can feel dismissed by doctors, as clinicians often put the pain down to diet, stress or hormones. It was never just “in their heads.” A complex interplay between an important hormone, chemical signals, rare populations of gut cells and the output of gut bacteria could explain why, researchers report December 18 in Science. While the findings are in mice, they suggest new opportunities for treatment. Gut pain is a visceral experience — literally, pain in the viscera, from nerves that spread throughout the torso and abdomen. “It can be bloating, it can be a sharp pain or it can be just sort of a constant, dull pain,” says David Julius, a neurophysiologist at University of California, San Francisco. About 10 percent of the global population — mostly women —suffers symptoms of IBS, which can occur with diarrhea, constipation or a mix between the two. “What makes this so bad is that these women are feeling this pain, they go into the physician … and they were just ignored,” says Holly Ingraham, a physiologist also at the University of California, San Francisco. Ingraham and Julius knew that the hormone estrogen played a role in this type of pain, which can fluctuate with the menstrual cycle and pregnancy. In a 2023 paper, they showed that female mice are more sensitive to this visceral pain than males. Without estrogen, that extra sensitivity disappeared. The researchers immediately went looking for cells that might sense estrogen in the gut. To affect a given organ, its cells must have proteins called receptors that recognize estrogen and set off signals in response. © Society for Science & the Public 2000–2025

Keyword: Pain & Touch; Sexual Behavior
Link ID: 30056 - Posted: 12.20.2025

By Kelly Servick In the past 20 years, mice with glowing cables sprouting from their heads have become a staple of neuroscience. They reflect the rise of optogenetics, in which neurons are engineered to contain light-sensitive proteins called opsins, allowing pulses of light to turn them on or off. The method has powered thousands of basic experiments into the brain circuits that drive behavior and underlie disease. As this research tool matured, hopes arose for using it as a treatment, too. Compared with the electrical or magnetic brain stimulation approaches already in use, optogenetics offers a way to more precisely target and manipulate the exact cell types underlying brain disorders. So far only one optogenetic application—addressing certain kinds of vision loss by introducing opsins into cells in the eye—has made it into human trials. But its promising early results, along with the discovery of more sensitive and sophisticated opsins, are inspiring researchers to look beyond the eye, developing treatments that would act on peripheral nerves or deep in the brain. Initial tests of these strategies in animal models of epilepsy, amyotrophic lateral sclerosis (ALS), and other neurological disorders have been encouraging, researchers reported last month at the annual meeting of the Society for Neuroscience (SfN) in San Diego. One company is hoping to launch a human trial for an optogenetic pain treatment by 2027. “We definitely don’t want to oversell the idea of using optogenetics [on human brains] any time soon, but we also are firmly convinced that this is now the right moment to be thinking about this seriously,” University of Geneva neurologist and neuroscientist Christian Lüscher told an SfN session he chaired, in which participants presented a newly published road map for bringing optogenetics to the clinic. Still, the presenters acknowledged major remaining challenges, including possible risks of inserting genes for opsins—many of which are derived from algae or other microbes—into a person’s nerves or brain cells. © 2025 American Association for the Advancement of Science.

Keyword: Pain & Touch; Epilepsy
Link ID: 30046 - Posted: 12.13.2025

By Carl Zimmer Last year, Ardem Patapoutian got a tattoo. An artist drew a tangled ribbon on his right arm, the diagram of a protein called Piezo. Dr. Patapoutian, a neuroscientist at Scripps Research in San Diego discovered Piezo in 2010, and in 2021 he won a Nobel Prize for the work. Three years later, he decided to memorialize the protein in ink. Piezo, Dr. Patapoutian had found, allows nerve endings in the skin to sense pressure, helping to create the sense of touch. “It was surreal to feel the needle as it was etching the Piezo protein that I was using to feel it,” he recalled. Dr. Patapoutian is no longer studying how Piezo informs us about the outside world. Instead, he has turned inward, to examine the flow of signals that travel from within the body to the brain. His research is part of a major new effort to map this sixth, internal sense, which is known as interoception. Scientists are discovering that interoception supplies the brain with a remarkably rich picture of what is happening throughout the body — a picture that is mostly hidden from our consciousness. This inner sense shapes our emotions, our behavior, our decisions, and even the way we feel sick with a cold. And a growing amount of research suggests that many psychiatric conditions, ranging from anxiety disorders to depression, might be caused in part by errors in our perception of our internal environment. Someday it may become possible to treat those conditions by retuning a person’s internal sense. But first, Dr. Patapoutian said, scientists need a firm understanding of how interoception works. “We’ve taken our body for granted,” he said. Everyone has a basic awareness of interoception, whether it’s a feeling of your heart racing, your bladder filling or a flock of butterflies fluttering in your stomach. And neuroscientists have long recognized interoception as one function of the nervous system. Dr. Charles Sherrington, a Nobel Prize-winning neuroscientist, first proposed the existence of “intero-ceptors,” in 1906. © 2025 The New York Times Company

Keyword: Obesity; Stress
Link ID: 30030 - Posted: 11.26.2025

By Caroline Hopkins Legaspi In a study published Monday in JAMA Neurology, researchers linked obstructive sleep apnea, a condition that causes temporary pauses in breathing during sleep, with Parkinson’s disease. Parkinson’s disease is a progressive nervous system disorder that causes tremors, stiffness, and difficulty speaking, moving and swallowing. It is the second-most common neurodegenerative disease in the United States, after Alzheimer’s disease, with 90,000 people diagnosed each year. There is no cure for Parkinson’s disease, said Dr. Lee Neilson, a neurologist at Oregon Health & Science University who led the study. But the researchers did find that treating sleep apnea with a continuous positive airway pressure (or CPAP) machine was associated with a reduced likelihood of developing Parkinson’s. So identifying those at highest risk for the neurological condition — and intervening early, Dr. Neilson said, “might make the biggest impact.” The researchers analyzed medical records from more than 11 million U.S. veterans treated through the Department of Veterans Affairs between 1999 and 2022. The group was predominantly male with an average age of 60, representing those at highest risk for sleep apnea, experts said. The researchers found that about 14 percent of the participants had been diagnosed with sleep apnea between 1999 and 2022, according to their medical records. When the researchers looked at their health six years after those diagnoses, they found that the veterans with sleep apnea were nearly twice as likely to have developed Parkinson’s disease compared with those who had not been diagnosed with sleep apnea. This held even after controlling for other factors that could influence the development of sleep apnea or Parkinson’s disease, including high body mass index and conditions like diabetes, high blood pressure, traumatic brain injuries and depression. © 2025 The New York Times Company

Keyword: Sleep; Parkinsons
Link ID: 30029 - Posted: 11.26.2025

Davide Castelvecchi Pigeons can sense Earth’s magnetic field by detecting tiny electrical currents in their inner ears, researchers suggest. Such an inner compass could help to explain how certain animals can achieve astonishing feats of long-distance navigation. The team performed advanced brain mapping as well single-cell RNA sequencing of pigeon inner-ear cells. Both lines of evidence point to the inner ear as the birds’ ‘magnetoreception’ organ. The results appeared in the Science on 20 November 1. “This is probably the clearest demonstration of the neural pathways responsible for magnetic processing in any animal,” says Eric Warrant, a sensory biology researcher at the University of Lund in Sweden. Studies have suggested that various animals, including turtles, trout and robins, can sense the direction and strength of magnetic fields, although the evidence has sometimes been contested — and the mechanisms have remained controversial. Bird-brained navigation Two leading hypotheses have led the research into how birds sense magnetic fields. One is a quantum-physics effect in retina cells where birds ‘see’ magnetic fields. Another is that microscopic iron oxide particles in the beak could act as tiny compass needles. However, it’s largely unknown where magnetic information is sensed in animals’ brains and how sensory neurons confer sensitivity to electromagnetic changes. In 2011, researchers found hints that magnetic fields triggered pigeons’ vestibular system, the organ that enables vertebrates to sense accelerations (including gravity) and helps them to stay balanced2. The structure is made of three fluid-filled loops which are mutually perpendicular, so they can communicate to the brain the direction of an acceleration by breaking it down into three ‘x, y, z’ components. © 2025 Springer Nature Limited

Keyword: Animal Migration; Hearing
Link ID: 30024 - Posted: 11.22.2025

By Laura Sanders SAN DIEGO — A diet low in the amino acid glutamate may ease migraines, a small study suggests. A month of staying away from high-glutamate foods led to fewer migraines in a group of 25 people with Gulf War Illness. The specifics of these veterans’ migraines, part of a collection of symptoms resulting from the Gulf War, may differ from those of other people who suffer from migraines. But if the underlying relationship between glutamate and migraines is similar, the diet could help the estimated 1 billion people worldwide who have migraines. Current drugs for treating migraines, including a new class of compounds that block a chemical messenger called CGRP, can help. But existing drugs don’t work for everyone, says neuroscientist Ian Meng of the University of New England in Biddeford, Maine. A dietary change could be a low-risk and accessible way to bring relief. Glutamate is both a signal that excites nerve signals in the brain and an amino acid found in tomatoes, processed meats, aged cheese, mushrooms and, of course, monosodium glutamate, or MSG. For a month, 25 veterans of the Gulf War ate a low-glutamate diet full of whole fruits and veggies and avoided high-glutamate foods including soy sauce, mushrooms and ultraprocessed foods. Before this diet, 64 percent of these people reported having a migraine in the previous week. After a month of a low-glutamate diet, that number dropped to about 12 percent, neuroscientist Ashley VanMeter said November 16 in a news briefing at the annual meeting of the Society for Neuroscience. After the one-month diet ended, 88 percent of the people in the study chose to remain on the diet. “They feel that [the diet] is definitely benefiting them,” said VanMeter, of Georgetown University in Washington, D.C. © Society for Science & the Public 2000–2025.

Keyword: Pain & Touch
Link ID: 30021 - Posted: 11.22.2025