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.

Related chapters from BN: Chapter 3: Neurophysiology: The Generation, Transmission, and Integration of Neural Signals; Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 3: The Chemistry of Behavior: Neurotransmitters and Neuropharmacology; Chapter 5: The Sensorimotor System
Link ID: 30046 - Posted: 12.13.2025

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.

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 30021 - Posted: 11.22.2025

By Angie Voyles Askham The adult cortex can rewire itself after injury, according to a series of classic experiments. When a monkey loses sensory input from a finger, for example, the region of the somatosensory cortex dedicated to that finger becomes overrun by inputs from the animal’s nearby fingers or face; the cortical map for the unused finger fades, and nearby maps of other body parts expand. “This is what I read in my textbook. This is what the lecturers told me in my lectures in university,” says Tamar Makin, professor of cognitive neuroscience at the University of Cambridge. But—contrary to those classic findings—such large-scale cortical reorganization did not happen in three people who lost an arm, according to a new functional imaging study Makin and her colleagues published today in Nature Neuroscience. Instead, the somatosensory map of each person’s hands, feet and lips, generated when they moved or attempted to move that body part, remained stable in the years before and after their hand was removed. “The representation of the hand persists,” says Makin, who led the study. The work is the first longitudinal look at whether amputation changes that cortical mapping. The results confirm what previous cross-sectional studies have hinted at, and they should put an end to the debate about how readily the adult cortex can shift its function, Makin says. But not everyone agrees. The study is an important contribution to the field, and it shows that maps of somatosensation driven by motor input remain stable after amputation, says Ben Godde, professor of neuroscience at Constructor University, who was not involved in the new work or the classic experiments. But that does not mean that other cortical maps are not shifting as a result of changing inputs, he says. “It’s not evidence that there’s no plasticity.” © 2025 Simons Foundation

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain; Chapter 7: Life-Span Development of the Brain and Behavior
Related chapters from MM:Chapter 5: The Sensorimotor System; Chapter 13: Memory and Learning
Link ID: 29900 - Posted: 08.23.2025

By Pam Belluck Sometimes the pain felt like lightning bolts. Or snakes biting. Or needles. “Just imagine the worst burn you’ve ever had, all over your body, never going away,” said Ed Mowery, 55, describing his life with chronic pain. “I would wake up in the middle of night, screaming at the top of my lungs.” Beginning with a severe knee injury he got playing soccer at 15, he underwent about 30 major surgeries for various injuries over the decades, including procedures on his knees, spine and ankles. Doctors put in a spinal cord stimulator, which delivers electrical pulses to relieve pain, and prescribed morphine, oxycodone and other medications, 17 a day at one point. Nothing helped. Unable to walk or sit for more than 10 minutes, Mr. Mowery, of Rio Rancho, N.M., had to stop working at his job selling electronics to engineering companies and stop playing guitar with his death metal band. Out of options four years ago, Mr. Mowery signed up for a cutting-edge experiment: a clinical trial involving personalized deep brain stimulation to try to ease chronic pain. The study, published on Wednesday, outlines a new approach for the most devastating cases of chronic pain, and could also provide insights to help drive invention of less invasive therapies, pain experts said. “It’s highly innovative work, using the experience and technology they have developed and applying it to an underserved area of medicine,” said Dr. Andre Machado, chief of the Neurological Institute at Cleveland Clinic, who was not involved in the study. Chronic pain, defined as lasting at least three months, afflicts about 20 percent of adults in the United States, an estimated 50 million people, according to the Centers for Disease Control and Prevention. In about a third of cases, the pain substantially limits daily activities, the C.D.C. reported. © 2025 The New York Times Company

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29889 - Posted: 08.16.2025

By Roni Caryn Rabin The Food and Drug Administration on Wednesday approved a medical device that offers new hope to patients incapacitated by rheumatoid arthritis, a chronic condition that afflicts 1.5 million Americans and is often resistant to treatment. The condition is usually managed with medications. The device represents a radical departure from standard care, tapping the power of the brain and nervous system to tamp down the uncontrolled inflammation that leads to the debilitating autoimmune disease. The SetPoint System is an inch-long device that is surgically implanted into the neck, where it sits in a pod wrapped around the vagus nerve, which some scientists believe is the longest nerve in the body. The device electrically stimulates the nerve for one minute each day. The stimulation can turn off crippling inflammation and “reset” the immune system, research has shown. Most drugs used to treat rheumatoid arthritis suppress the immune system, leaving patients vulnerable to serious infections. On a recent episode of the American College of Rheumatology podcast, the SetPoint implant was described as representing a “true paradigm shift” in treatment of the disease, which until now has relied almost entirely on an evolving set of pharmaceutical interventions, from gold salts to powerful agents called biologics. The F.D.A. designated the implant as a breakthrough last year in order to expedite its development and approval. It represents an early test of the promise of so-called bioelectronic medicine to modulate inflammation, which plays a key role in diseases including diabetes, heart disease and cancer. Clinical trials are already underway testing vagus nerve stimulation to manage inflammatory bowel disease in children, lupus and other conditions. Trials for patients with multiple sclerosis and Crohn’s disease are also planned. In a yearlong randomized controlled trial of 242 patients that included a sham-treatment arm, over half of the participants using the SetPoint implant alone achieved remission or saw their disease recede. Measures of joint pain and swelling fell by 60 percent and 63 percent, respectively. © 2025 The New York Times Company

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain; Chapter 15: Emotions, Aggression, and Stress
Related chapters from MM:Chapter 5: The Sensorimotor System; Chapter 11: Emotions, Aggression, and Stress
Link ID: 29873 - Posted: 08.02.2025

By Tom Zeller Jr. During the week between two experimental infusions at the Danish Headache Center, where I had agreed to be a test subject, I rented a small flat in central Copenhagen, near Assistens Cemetery. This is where many notable Danes have been laid to rest, and I took some time that September to visit the monuments, which were shrouded in manicured stands of mature poplars and willows. The accompanying article is adapted from “The Headache: The Science of a Most Confounding Affliction — and a Search for Relief,” by Tom Zeller Jr. (Mariner Books, 310 pages). Copyright © 2025. Reprinted by permission. The grave of Niels Bohr, one of the 20th century’s leading figures in theoretical physics, is marked by a gray stone pillar with an owl perched on top. Hans Christian Andersen, the author who gave us “The Little Mermaid” and “The Ugly Duckling,” among other treasured stories, resides here too. But it felt most appropriate to my mission that Danish philosopher Søren Kierkegaard, who thought suffering was where life’s meaning is forged, occupied his own leafy corner of the park. In the Kierkegaardian tradition, suffering is redemptive — the feedstock of enlightenment — and rather than wallow in its insults and pains, the sufferer should embrace its power to transform. “Even the heaviest suffering cannot be heavier than a mountain,” he once wrote. “And thus, if the sufferer believes that his suffering is beneficial to him — yes, then he moves mountains. In order to move a mountain, you must get under it.” I was thinking of Kierkegaard when I first presented my arm to Lanfranco Pellesi, then a researcher at the Danish Headache Center, for my initial infusion. Pellesi had an early interest in studying near-death experiences, before turning his attention to pain, and then from pain to headaches. It struck me as such an obvious trajectory — one that followed an almost inevitable path — and I asked him how he made sense of that progression. “I think probably it links to the problem of conscience — where it is, where it’s not.”

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29861 - Posted: 07.19.2025

By Celina Ribeiro Some say it was John Sattler’s own fault. The lead-up to the 1970 rugby league grand final had been tense; the team he led, the South Sydney Rabbitohs, had lost the 1969 final. Here was an opportunity for redemption. The Rabbitohs were not about to let glory slip through their fingers again. Soon after the starting whistle, Sattler went in for a tackle. As he untangled – in a move not uncommon in the sport at the time – he gave the Manly Sea Eagles’ John Bucknall a clip on the ear. Seconds later – just three minutes into the game – the towering second rower returned favour with force: Bucknall’s mighty right arm bore down on Sattler, breaking his jaw in three places and tearing his skin; he would later need eight stitches. When his teammate Bob McCarthy turned to check on him, he saw his captain spurting blood, his jaw hanging low. Forty years later Sattler would recall that moment. One thought raged in his shattered head: “I have never felt pain like this in my life.” But he played on. Tackling heaving muscular players as they advanced. Being tackled in turn, around the head, as he pushed forward. All the while he could feel his jaw in pieces. At half-time the Rabbitohs were leading. In the locker room, Sattler warned his teammates, “Don’t play me out of this grand final.” McCarthy told him, “Mate, you’ve got to go off.” He refused. “I’m staying.” Sattler played the whole game. The remaining 77 minutes. At the end, he gave a speech and ran a lap of honour. The Rabbitohs had won. The back page of the next day’s Sunday Mirror screamed “BROKEN JAW HERO”. © 2025 Guardian News & Media Limited

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29857 - Posted: 07.16.2025

Sydney Lupkin Jerry Abrams, a 64-year-old marketing strategist in Minneapolis, used to run marathons. But two decades of degenerative spine disease have left him unable to run — and he's grieving. For Abrams, losing running felt like "the loss of a loved one – that friend who's been with you every day you needed him. "You know, having that taken away from you because of pain is the hardest thing of all," he says. The constant pain in his lower back makes running impossible. Sometimes, when the pain isn't under control, he can't get out of bed. Abrams has tried taking opioids. They help, but he feels he has to be careful because they're potentially addictive. He's also worried about building up a tolerance to them "I don't ever want to be in a situation where I need surgery and need to recover and opioid medication no longer does what it needs to do," he explains. The Food and Drug Administration approved a new non-opioid drug earlier this year called Journavx. It's a pill for severe acute pain that works by blocking plain signals from where someone hurts. It's offered hope for the 1 in 5 Americans who suffer from chronic pain, but it's also just out of reach. Journavx is the first new kind of painkiller in more than 20 years, and the medical community is cautiously optimistic that Journavx doesn't have the same addictive potential as opioids do. But the new pills are expensive, and not everyone has been able to access them, thanks to a narrowly-focused FDA approval and limited insurance coverage Abrams' doctor wanted him to be able to try Journavx. But the FDA only approved the medication for short-term use for acute pain, which is usually defined as lasting less than three months, such as right after surgery. Because Abrahm's pain is chronic, his insurance wouldn't cover it. A single Journavx pill costs around $15 without insurance, according to Vertex Pharmaceuticals, the drug's manufacturer. © 2025 npr

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain; Chapter 4: The Chemistry of Behavior: Neurotransmitters and Neuropharmacology
Related chapters from MM:Chapter 5: The Sensorimotor System; Chapter 4: Development of the Brain
Link ID: 29849 - Posted: 07.12.2025

Sammie Seamon Peter was working late, watching two roulette tables in play at a London casino, when he felt something stir behind his right eye. It was just a shadow of sensation, a horribly familiar tickle. But on that summer night in 2018, as chips hit the tables and gamblers’ conversation swelled, panic set in. He knew he only had a few minutes. Peter found his boss, muttered that he had to leave, now, and ran outside. By then, the tickle had escalated; it felt like a red-hot poker was being shoved through his right pupil. Tears flowed from that eye, which was nearly swollen shut, and mucus from his right nostril. Half-blinded, gripping at his face, he stumbled along the street, eventually escaping into a company car that whisked him home, where he blacked out. Every day that followed, Peter, then in his early 40s, would experience the same attack at 10am, 2pm and 6pm, like perfect clockwork. “Oh God, here it comes,” he’d think to himself, before fireworks exploded in his temple and the poker stabbed into the very roots of his teeth, making him scream and sometimes vomit. “It just grows, and it thumps, and it thumps, and it thumps with my heartbeat,” said Peter, recalling the pain. Peter had experienced these inexplicable episodes since he was a kid, always in the summer. An attack left him shaking and exhausted, and waiting on the next bout was a kind of psychological torture – within the short respites, he dreaded the next. Once, when Peter felt one starting, he threw on his shoes and sprinted through the streets of south London. He didn’t care which turns he took. Maybe if he ran fast enough, his lungs full of air, he could outrun the thing. His heart pumped in his chest, more from fear than the exercise itself. When the pain escalated to an unbearable pitch, he slowed to a stop, dry heaving, and sat down to press on his eye. He was three miles away from home. © 2025 Guardian News & Media Limited

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29761 - Posted: 04.26.2025

Humberto Basilio What Rina Green calls her “living hell” began with an innocuous backache. By late 2022, two years later, pain flooded her entire body daily and could be so intense that she couldn’t get out of bed. Painkillers and physical therapy offered little relief. She began using a wheelchair. Green has fibromyalgia, a mysterious condition with symptoms of widespread and chronic muscle pain and fatigue. No one knows why people get fibromyalgia, and it is difficult to treat. But eight months ago, Green received an experimental therapy: pills containing living microorganisms of the kind that populate the healthy human gut. Her pain decreased substantially, and Green, who lives in Haifa, Israel, and is now 38, can go on walks — something she hadn’t done since her fibromyalgia diagnosis. Green was one of 14 participants in a trial of microbial supplements for the condition. All but two reported an improvement in their symptoms. The trial is so small that “we should take the results with a grain of salt”, says co-organizer Amir Minerbi, a pain scientist at the Technion — Israel Institute of Technology in Haifa. “But it is encouraging [enough] to move forward.” The trial results and data from other experiments linking fibromyalgia to gut microbes are published today in Neuron1. Fibromyalgia affects up to 4% of the global population and occurs in the absence of tissue damage. In 2019, Minerbi and his colleagues discovered that the gut microbiomes — the collection of microbes living in the intestines — of women with fibromyalgia differed significantly from those of healthy women2. This led the scientists to wonder whether a dose of microbes from healthy people would ease the pain and fatigue caused by the condition. After all, previous research3 had shown that gut microbes might indirectly influence an array of chemical signals tied to pain perception. The team transplanted minuscule samples of microbe-laden faeces from both women with fibromyalgia and healthy women into mice without any microbes in their bodies. The researchers found that mice that received microbes from women with fibromyalgia showed signs of greater sensitivity to pain in response to pressure, heat and cold than did mice that got microbes from healthy women. The first group also showed more evidence of spontaneous pain. © 2025 Springer Nature Limited

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain; Chapter 13: Homeostasis: Active Regulation of the Internal Environment
Related chapters from MM:Chapter 5: The Sensorimotor System; Chapter 9: Homeostasis: Active Regulation of the Internal Environment
Link ID: 29760 - Posted: 04.26.2025

Jon Hamilton Researchers created an assembloid by integrating four organoids that represent the four components of the human sensory pathway, along which pain stimuli signals are conveyed to the brain. Stimulation of the sensory organoid (top) by pain-inducing substances, such as capsaicin, triggers neuronal activity in that organoid which is then transmitted to the adjacent spinal-cord organoid, the thalamic organoid and, finally, to the cortical organoid (bottom) Researchers integrated four organoids that represent the four components of the human sensory pathway, along which pain signals are conveyed to the brain. Stimulation of the sensory organoid (top) by substances, such as capsaicin, triggers neuronal activity that is then transmitted throughout the rest of the organoids. Pasca lab/Stanford Medicine Scientists have re-created a pain pathway in the brain by growing four key clusters of human nerve cells in a dish. This laboratory model could be used to help explain certain pain syndromes, and offer a new way to test potential analgesic drugs, a Stanford team reports in the journal Nature. "It's exciting," says Dr. Stephen Waxman, a professor at Yale School of Medicine who was not involved in the research. © 2025 npr

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain; Chapter 7: Life-Span Development of the Brain and Behavior
Related chapters from MM:Chapter 5: The Sensorimotor System; Chapter 13: Memory and Learning
Link ID: 29739 - Posted: 04.12.2025

By Mitch Leslie Unlike the combative immune cells that protect us from pathogens, regulatory T cells (Tregs) are nurturers. They salve inflammation, promote healing of injured tissue, and rein in immune attacks to curb self-inflicted damage. Now, a study of mice reported today in Science suggests some Tregs also act on nerve cells to quell a specific type of pain—but only in females. Why only female rodents seem to benefit remains unclear, but researchers hope they might someday enlist these Tregs to address pain conditions, many of which disproportionately affect women. “It’s a very impressive paper,” says neuroscientist Gila Moalem-Taylor of the University of New South Wales Sydney, who wasn’t connected to the research. The study “uses elegant, sophisticated methods to conclusively demonstrate the mechanisms” by which the cells reduce one kind of sensitivity to pain, she says. Tregs, a type of white blood cell, are best known for their role in keeping the immune system in balance and preventing autoimmunity. But researchers have recently found that they also help control pain. For example, a 2021 study by neuroscientist Allan Basbaum of the University of California San Francisco (UCSF) and colleagues showed that Tregs reduce mice’s sensitivity to pain triggered by other immune cells that reside in the brain and spinal cord. That research and additional work suggested Tregs influence pain by targeting various immune cells and tamping down inflammation. But these studies left open the possibility that Tregs might also directly affect pain-sensing nerve cells. Basbaum, his postdoc Élora Midavaine, UCSF dermatologist Sakeen Kashem, and their colleagues launched the new study to nail down how the regulatory cells curb pain. They focused on Tregs that dwell in the meninges—the membranes that sheathe the brain and spinal cord—and in similar nearby membranes. The cells are much more abundant in these structures than elsewhere in the nervous system. To find out whether the cells affect pain perception, the scientists used genetically engineered mice whose Tregs are vulnerable to a toxin produced by the bacteria that cause diphtheria. Injecting this toxin into the meninges in the lower back killed about 90% of the Tregs in the membranes without harming Tregs in the rest of the body.

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29729 - Posted: 04.05.2025

Vicki Hird Does a worm feel pain if it gets trodden on? Does a fly ache when its wings are pulled off? Is an ant happy when it finds a food source? If so, they may be sentient beings, which means they can “feel”, a bit or a lot, like we do. Invertebrate sentience is becoming an ever livelier topic of debate and with new science we are getting new insights. But Dr Andrew Crump at the Royal Veterinary College, who helped ensure that new UK laws recognising animal sentience were amended to include large cephalopod molluscs and decapod crustaceans – octopuses, lobsters, crabs to you and me – says this is not at all straightforward. Nervous systems are hugely complex, and identifying consciousness and sentience – and not just automatic pain reflexes – is hard. Are responses or reactions you see from an animal – be it a wolf or a wolf ant – feelings or just automatic reflexes? Crump and his colleagues found that bees, for example, were not simple stimulus-response robots, but reacted to stimuli in sophisticated, context-dependent ways. They were found to learn colour cues for their decisions on feeding – choosing painful overheated sugars they previously avoided when non-heated options had a low sugar concentration. So they made trade-offs by processing in the brain then modifying their behaviour. In fact, new research has shown that many responses in the larger invertebrates were complex, long-lasting, and pretty consistent with criteria for pain that had been produced initially for vertebrates such as rats. Octopuses, for example, can perform amazing feats of learning to avoid painful environments and choose painkilling environments. All this establishes and quantifies “feelings” in beings that are very different from us. The work of Crump and other scientists meant that the Animal Welfare (Sentience) Act 2022 recognised for the first time in UK law (vertebrate sentience was previously covered by EU regulation) that certain invertebrates can “feel”, requiring modifications to their treatment in areas such as farming and research. © 2025 Guardian News & Media Limited

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain; Chapter 6: Evolution of the Brain and Behavior
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29684 - Posted: 02.26.2025

By Fred Schwaller Andrea West remembers the first time she heard about a new class of migraine medication that could end her decades of pain. It was 2021 and she heard a scientist on the radio discussing the promise of gepants, a class of drug that for the first time seemed to prevent migraine attacks. West followed news about these drugs closely, and when she heard last year that atogepant was approved for use in the United Kingdom, she went straight to her physician. West had endured migraines for 70 years. Since she started taking the drug, she hasn’t had one. “It’s marvellous stuff. It’s genuinely changed my life,” she says. For ages, the perception of migraine has been one of suffering with little to no relief. In ancient Egypt, physicians strapped clay crocodiles to people’s heads and prayed for the best. And as late as the seventeenth century, surgeons bored holes into people’s skulls — some have suggested — to let the migraine out. The twentieth century brought much more effective treatments, but they did not work for a significant fraction of the roughly one billion people who experience migraine worldwide. Now there is a new sense of progress running through the field, brought about by developments on several fronts. Medical advances in the past few decades — including the approval of gepants and related treatments — have redefined migraine as “a treatable and manageable condition”, says Diana Krause, a neuropharmacologist at the University of California, Irvine. At the same time, research is leading to a better understanding about the condition — and pointing to directions for future work. Studies have shown, for example, that migraine is a broad phenomenon that originates in the brain and can manifest in many debilitating symptoms, including light sensitivities and aura, brain fog and fatigue. “I used to think that disability travels with pain, and it’s only when the pain gets severe that people are impaired. That’s not only false, but we have treatments to do something about it,” says Richard Lipton, a neurologist at the Albert Einstein College of Medicine in New York City. © 2025 Springer Nature Limited

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain; Chapter 2: Functional Neuroanatomy: The Cells and Structure of the Nervous System
Related chapters from MM:Chapter 5: The Sensorimotor System; Chapter 2: Neurophysiology: The Generation, Transmission, and Integration of Neural Signals
Link ID: 29681 - Posted: 02.22.2025

By Gina Kolata The Food and Drug Administration approved a new medication Thursday to treat pain from an injury or surgery. It is expensive, with a list price of $15.50 per pill. But unlike opioid pain medicines, it cannot become addictive. That is because the drug, suzetrigine, made by Vertex Pharmaceuticals and to be sold as Journavx, works only on nerves outside the brain, blocking pain signals. It cannot get into the brain. Researchers say they expect it to be the first of a new generation of more powerful nonaddictive drugs to relieve pain. To test the drug, Vertex, which is based in Boston, conducted two large clinical trials, each with approximately 1,000 patients who had pain from surgery. They were randomly assigned to get a placebo; to get the opioid sold as Vicodin, a widely used combination pain medicine of acetaminophen (Tylenol) and hydrocodone; or to get suzetrigine. In one trial, patients had an abdominoplasty, or tummy tuck. In the other, they had a bunionectomy. Side effects of suzetrigine reported by patients were similar to the ones reported by those taking the placebo. The company also submitted data from a 250-person study that assessed the drug’s safety and tolerability in patients with pain from surgery, trauma or accidents. Suzetrigine eased pain as much as the combination opioid. Both were better than the placebo at relieving pain. Suzetrigine’s price, though, is much higher than that of acetaminophen plus hydrocodone. Patients are expected to take two pills a day, for a total cost of $31 a day. The older drug, said Dr. John D. Loeser, an emeritus pain expert at the University of Washington, is “dirt cheap” at pennies per pill. But suzetrigine does not have opioids’ unpleasant side effects like nausea and drowsiness, and it is nonaddictive. © 2025 The New York Times Company

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain; Chapter 4: The Chemistry of Behavior: Neurotransmitters and Neuropharmacology
Related chapters from MM:Chapter 5: The Sensorimotor System; Chapter 4: Development of the Brain
Link ID: 29653 - Posted: 02.01.2025

By Laura Sanders Scratching an itch can bring a contradictory wave of pleasure and misery. A mouse study on scratching, reported in the Jan. 31 Science, fleshes out this head-scratching paradox and could point out ways to better curb pernicious itch in people. First, the bad news: Scratching itchy ears led to a round of inflammation. Itch-provoking substances, such as the oil in poison ivy, activate mast cells, immune sentries that release itch signals and kick off inflammation. But so does scratching, the new study suggests. “The act of scratching is actually triggering the inflammation by synergizing with mast cells to make them more effective,” says study coauthor Daniel Kaplan, a dermatologist and immunologist at the University of Pittsburgh. Mice that couldn’t scratch their itchy ears, thanks to tiny cones of shame, had less inflammation than mice that scratched. The same was true for mice that didn’t sense the itch, the researchers report. Kaplan relates the results to a mosquito bite. “Most of the time, it’ll go away in five, 10 minutes,” he says. “But if you start scratching it, now, you get a really big, inflamed, itchy lesion on your skin that can stick around for several days. It’s a lot worse. And I think this could be a mechanism that explains why.” Now onto the good news: Scratching lessened the amount of potentially harmful bacteria (Staphylococcus aureus) on mice’s skin, perhaps through the heightened immune reaction it prompts. “That was a clear demonstration that scratching can have a benefit in the context of an acute infection,” Kaplan says. But too much scratching can rip the skin and usher in more bacteria, he cautions. “In that sense, scratching, through a different mechanism, also makes things even worse.” © Society for Science & the Public 2000–2025.

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29648 - Posted: 02.01.2025

By Jennifer Kahn Here’s a strange story: One day two summers ago, I woke up because my arms — both of them — hurt. Not the way they do when you’ve slept in a funny position, but as if the tendons in my forearms and hands were moving through mud. What felt like sharp electric shocks kept sparking in my fingers and sometimes up the inside of my biceps and across my chest. Holding anything was excruciating: a cup, a toothbrush, my phone. Even doing nothing was miserable. It hurt when I sat with my hands in my lap, when I stood, when I lay flat on the bed or on my side. The slightest pressure — a bedsheet, a watch band, a bra strap — was intolerable. It was August, and every doctor seemed to be away on vacation. The ones I did manage to see were politely stumped. It wasn’t carpal tunnel, tennis elbow or any other injury they could identify. I did nothing unusual the day before: an hour of work on my laptop, followed by a visit with a friend. We sat in her backyard and talked. For the first few weeks, I could barely sleep. Over the following months, I lost weight — almost a pound a week. I couldn’t drive, or cook, or use my laptop for work, or even hold a book or a pen. I would have been bored, except the pain was so tiring that I could barely function. I spent the days shuffling around the house listening to audiobooks and doing voice-to-text searches for “nerve pain arms” with my phone flat on the table, then carefully, painfully, scrolling through the results. I think we’re past the point where I have to explain that chronic pain is not the result of imbalanced humors or a wandering uterus or possession by demons. But for more modern skeptics, this is where I should add that chronic pain also isn’t just “all in your head” or “not really that bad” — or any of the other ways in which people who suffer from it are still regularly gaslit and dismissed. Personally, I never had to contend with not being believed, almost certainly because I’m an otherwise healthy, reasonably well-off white woman with a clean medical history and no significant record of anxiety or depression. Instead, I was taken seriously. A whole gamut of tests was run. My wrists were X-rayed. I had an M.R.I. on my cervical spine. Each new doctor ordered new blood tests: some for vitamin deficiencies, others for autoimmune diseases like rheumatoid arthritis. © 2025 The New York Times Company

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29628 - Posted: 01.15.2025

By Lisa Sanders, M.D. The 62-year-old woman shifted in her seat. The flight to Honolulu was full, the mood a little giddy. The unbroken ocean and sky filled the window. She and her daughter were four hours into the trip from Los Angeles to the wedding of a close family friend; it was going to be a great week. Then, she caught herself scratching lightly at a place on her forearm, just below the crease of her elbow. She lifted her arm to look at the spot. Nothing there. Immediately she was filled with dread. She reached over her head to touch the call button. She needed ice, lots of ice, and she needed it right away. The mild itch had already exploded into spasms of an intense sensation — it seemed wrong to call it an itch; surely there was a better word for it. The fierce intensity of the feeling shocked her. It was a feeling that insisted she scratch. Except scratching never helped. And she had the scars to prove it. She had suffered episodes of itching like this a few times in the past couple of years, though never quite as bad as it was on this flight. Her doctor back home had no idea what caused the crazy itch or what more she might do about it. These attacks came out of nowhere but immediately brought life to a standstill as she tried to ease the unbearable sensation. A bout could last for hours and almost always ended with her arm a bloody mess. When her daughter first saw her mother raking her nails over the invisible injury and the distress she felt fighting this unwinnable battle, she had offered her a Valium. And it helped. The itch was still there but the intensity somehow lessened. On the flight, the woman retrieved the pills she now carried with her all the time. The little bags of ice brought by the flight attendant melted slowly, numbing the hand that pressed them against her arm and easing the itch. She knew from experience that as soon as the ice was removed, the itch would roar back. The attendant brought an ice bucket. But within the hour, she needed more ice. More Valium. She was drenched with the condensation. Her clothes were dotted with blood. She didn’t care. She just had to get through it. © 2024 The New York Times Company

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29583 - Posted: 12.04.2024

Heather Margonari The opioid crisis remains a significant public health challenge in the United States. In 2022, over 2.5 million American adults had an opioid use disorder, and opioids accounted for nearly 76% of overdose deaths. Some patients are fearful of using opioids after surgery due to concerns about dependence and potential side effects, even when appropriately prescribed by a doctor to manage pain. Surgery is often the first time patients receive an opioid prescription, and their widespread use raises concerns about patients becoming long-term users. Leftover pills from a patient’s prescriptions may also be misused. Researchers like us are working to develop a personalized and comprehensive surgical experience that doesn’t use opioids. Our approach to opioid-free surgery addresses both physical and emotional well-being through effective anesthesia and complementary pain-management techniques. What is opioid-free anesthesia? Clinicians have used morphine and other opioids to manage pain for thousands of years. These drugs remain integral to anesthesia. Help us raise up the voices of experts. Most surgical procedures use a strategy called balanced anesthesia, which combines drugs that induce sleep and relax muscles with opioids to control pain. However, using opioids in anesthesia can lead to unwanted side effects, such as serious cardiac and respiratory problems, nausea and vomiting, and digestive issues. Concerns over these adverse effects and the opioid crisis have fueled the development of opioid-free anesthesia. This approach uses non-opioid drugs to relieve pain before, during and after surgery while minimizing the risk of side effects and dependency. Studies have shown that opioid-free anesthesia can provide similar levels of pain relief to traditional methods using opioids. Copyright © 2010–2024, The Conversation US, Inc.

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29575 - Posted: 11.27.2024

Terry Gross We've all had bug bites, or dry scalp, or a sunburn that causes itch. But what if you felt itchy all the time — and there was no relief? Journalist Annie Lowrey suffers from primary biliary cholangitis (PBC), a degenerative liver disease in which the body mistakenly attacks cells lining the bile ducts, causing them to inflame. The result is a severe itch that doesn't respond to antihistamines or steroids. "It feels like being trapped inside your own body," Lowrey says of the disease. "I always describe it as being like a car alarm. Like, you can't stop thinking about it." PBC is impacts approximately 80,000 people in the U.S., the majority of whom are women. At its worst, Lowrey says, the itch caused her to dig holes in her skin and scalp. She's even fantasized about having limbs amputated to escape the itch. Lowrey writes about living with PBC in the Atlantic article, "Why People Itch and How to Stop It." She says a big part of her struggle is coming to terms with the fact that she may never feel fully at ease in her skin. "I talked to two folks who are a lot older than I was, just about like, how do you deal with it? How do you deal with the fact that you might itch and never stop itching? … And both of them were kind of like, 'You put up with it, stop worrying about it and get on with your life,'" she says. "I think I was mentally trapped ... and sometimes it's like, OK, ... go do something else. Life continues on. You have a body. It's OK." © 2024 npr

Related chapters from BN: Chapter 8: General Principles of Sensory Processing, Touch, and Pain
Related chapters from MM:Chapter 5: The Sensorimotor System
Link ID: 29556 - Posted: 11.13.2024