By Steven Strogatz Neuroscience has made progress in deciphering how our brains think and perceive our surroundings, but a central feature of cognition is still deeply mysterious: namely, that many of our perceptions and thoughts are accompanied by the subjective experience of having them. Consciousness, the name we give to that experience, can’t yet be explained — but science is at least beginning to understand it. In this episode, the consciousness researcher Anil Seth and host Steven Strogatz discuss why our perceptions can be described as a “controlled hallucination,” how consciousness played into the internet sensation known as “the dress,” and how people at home can help researchers catalog the full range of ways that we experience the world. Steven Strogatz (00:03): I’m Steve Strogatz, and this is The Joy of Why, a podcast from Quanta Magazine that takes you into some of the biggest unanswered questions in math and science today. In this episode, we’re going to be discussing the mystery of consciousness. The mystery being that when your brain cells fire in certain patterns, it actually feels like something. It might feel like jealousy, or a toothache, or the memory of your mother’s face, or the scent of her favorite perfume. But other patterns of brain activity don’t really feel like anything at all. Right now, for instance, I’m probably forming some memories somewhere deep in my brain. But the process of that memory formation is imperceptible to me. I can’t feel it. It doesn’t give rise to any sort of internal subjective experience at all. In other words, I’m not conscious of it. (00:54) So how does consciousness happen? How is it related to physics and biology? Are animals conscious? What about plants? Or computers, could they ever be conscious? And what is consciousness exactly? My guest today, Dr. Anil Seth, studies consciousness in his role as the co-director of the Sussex Center for Consciousness Science at the University of Sussex, near Brighton, England. The Center brings together all sorts of disciplinary specialists, from neuroscientists to mathematicians to experts in virtual reality, to study the conscious experience. Dr. Seth is also the author of the book Being You: A New Science of Consciousness. He joins us from studios in Brighton, England. Anil, thanks for being here. All Rights Reserved © 2023

Keyword: Consciousness
Link ID: 28812 - Posted: 06.03.2023

Davide Castelvecchi The wrinkles that give the human brain its familiar walnut-like appearance have a large effect on brain activity, in much the same way that the shape of a bell determines the quality of its sound, a study suggests1. The findings run counter to a commonly held theory about which aspect of brain anatomy drives function. The study’s authors compared the influence of two components of the brain’s physical structure: the outer folds of the cerebral cortex — the area where most higher-level brain activity occurs — and the connectome, the web of nerves that links distinct regions of the cerebral cortex. The team found that the shape of the outer surface was a better predictor of brainwave data than was the connectome, contrary to the paradigm that the connectome has the dominant role in driving brain activity. “We use concepts from physics and engineering to study how anatomy determines function,” says study co-author James Pang, a physicist at Monash University in Melbourne, Australia. The results were published in Nature on 31 May1. ‘Exciting’ a neuron makes it fire, which sends a message zipping to other neurons. Excited neurons in the cerebral cortex can communicate their state of excitation to their immediate neighbours on the surface. But each neuron also has a long filament called an axon that connects it to a faraway region within or beyond the cortex, allowing neurons to send excitatory messages to distant brain cells. In the past two decades, neuroscientists have painstakingly mapped this web of connections — the connectome — in a raft of organisms, including humans. The authors wanted to understand how brain activity is affected by each of the ways in which neuronal excitation can spread: across the brain’s surface or through distant interconnections. To do so, the researchers — who have backgrounds in physics and neuroscience — tapped into the mathematical theory of waves.

Keyword: Brain imaging; Development of the Brain
Link ID: 28811 - Posted: 06.03.2023

By Daniel Bergner If severe mental illness, untreated, underlies the feeling of encroaching anarchy and menace around the homeless encampments of San Francisco or in the subways of New York City, then the remedy appears obvious. Let’s rescue those who, as New York’s mayor, Eric Adams, says, “slip through the cracks” of our mental health care systems; let’s give people “the treatment and care they need.” It sounds so straightforward. It sounds like a clear way to lower the odds of tragic incidents occurring, like the chokehold killing of Jordan Neely, a homeless, psychiatrically troubled man, or the death of Michelle Alyssa Go, who was pushed off a Times Square subway platform to her death by a homeless man with schizophrenia. Improving order and safety in public spaces and offering compassionate care seem to be convergent missions. But unless we confront some rarely spoken truths, that convergence will prove illusory. The problems with the common-sense approach, as it’s currently envisioned, run beyond the proposed solutions we usually read about: funding more beds on hospital psychiatric wards, establishing community-based programs to oversee treatment when people are released from the hospital and providing housing for those whose mental health is made increasingly fragile by the constant struggle for shelter. The most difficult problems aren’t budgetary or logistical. They are fundamental. They involve the involuntary nature of the care being called for and the flawed antipsychotic medications that are the mainstay of treatment for people dealing with the symptoms of psychosis, like hallucinatory voices or paranoid delusions, which can come with a range of severe psychiatric conditions. © 2023 The New York Times Company

Keyword: Schizophrenia
Link ID: 28810 - Posted: 06.03.2023

John Michael Streicher Opioid drugs such as morphine and fentanyl are like the two-faced Roman god Janus: The kindly face delivers pain relief to millions of sufferers, while the grim face drives an opioid abuse and overdose crisis that claimed nearly 70,000 lives in the U.S. in 2020 alone. Scientists like me who study pain and opioids have been seeking a way to separate these two seemingly inseparable faces of opioids. Researchers are trying to design drugs that deliver effective pain relief without the risk of side effects, including addiction and overdose. One possible path to achieving that goal lies in understanding the molecular pathways opioids use to carry out their effects in your body. How do opioids work? The opioid system in your body is a set of neurotransmitters your brain naturally produces that enable communication between neurons and activate protein receptors. These neurotransmitters include small proteinlike molecules like enkephalins and endorphins. These molecules regulate a tremendous number of functions in your body, including pain, pleasure, memory, the movements of your digestive system and more. Analysis of the world, from experts Opioid neurotransmitters activate receptors that are located in a lot of places in your body, including pain centers in your spinal cord and brain, reward and pleasure centers in your brain, and throughout the neurons in your gut. Normally, opioid neurotransmitters are released in only small quantities in these exact locations, so your body can use this system in a balanced way to regulate itself. The opioids your body produces and opioid drugs bind to the same receptors. The problem comes when you take an opioid drug like morphine or fentanyl, especially at high doses for a long time. These drugs travel through the bloodstream and can activate every opioid receptor in your body. You’ll get pain relief through the pain centers in your spinal cord and brain. But you’ll also get a euphoric high when those drugs hit your brain’s reward and pleasure centers, and that could lead to addiction with repeated use. When the drug hits your gut, you may develop constipation, along with other common opioid side effects. Targeting opioid signal transduction How can scientists design opioid drugs that won’t cause side effects? One approach my research team and I take is to understand how cells respond when they receive the message from an opioid neurotransmitter. Neuroscientists call this process opioid receptor signal transduction. Just as neurotransmitters are a communication network within your brain, each neuron also has a communication network that connects receptors to proteins within the neuron. When these connections are made, they trigger specific effects like pain relief. So, after a natural opioid neurotransmitter or a synthetic opioid drug activates an opioid receptor, it activates proteins within the cell that carry out the effects of the neurotransmitter or the drug. © 2010–2023, The Conversation US, Inc.

Keyword: Drug Abuse; Pain & Touch
Link ID: 28809 - Posted: 06.03.2023

by Adam Kirsch Giraffes will eat courgettes if they have to, but they really prefer carrots. A team of researchers from Spain and Germany recently took advantage of this preference to investigate whether the animals are capable of statistical reasoning. In the experiment, a giraffe was shown two transparent containers holding a mixture of carrot and courgette slices. One container held mostly carrots, the other mostly courgettes. A researcher then took one slice from each container and offered them to the giraffe with closed hands, so it couldn’t see which vegetable had been selected. In repeated trials, the four test giraffes reliably chose the hand that had reached into the container with more carrots, showing they understood that the more carrots were in the container, the more likely it was that a carrot had been picked. Monkeys have passed similar tests, and human babies can do it at 12 months old. But giraffes’ brains are much smaller than primates’ relative to body size, so it was notable to see how well they grasped the concept. Such discoveries are becoming less surprising every year, however, as a flood of new research overturns longstanding assumptions about what animal minds are and aren’t capable of. A recent wave of popular books on animal cognition argue that skills long assumed to be humanity’s prerogative, from planning for the future to a sense of fairness, actually exist throughout the animal kingdom – and not just in primates or other mammals, but in birds, octopuses and beyond. In 2018, for instance, a team at the University of Buenos Aires found evidence that zebra finches, whose brains weigh half a gram, have dreams. Monitors attached to the birds’ throats found that when they were asleep, their muscles sometimes moved in exactly the same pattern as when they were singing out loud; in other words, they seemed to be dreaming about singing. © 2023 Guardian News & Media Limited

Keyword: Evolution; Learning & Memory
Link ID: 28808 - Posted: 05.31.2023

Emily Waltz Researchers have been exploring whether zapping a person’s brain with electrical current through electrodes on their scalp can improve cognition.Credit: J.M. Eddin/Military Collection/Alamy After years of debate over whether non-invasively zapping the brain with electrical current can improve a person’s mental functioning, a massive analysis of past studies offers an answer: probably. But some question that conclusion, saying that the analysis spans experiments that are too disparate to offer a solid answer. In the past six years, the number of studies testing the therapeutic effects of a class of techniques called transcranial electrical stimulation has skyrocketed. These therapies deliver a painless, weak electrical current to the brain through electrodes placed externally on the scalp. The goal is to excite, disrupt or synchronize signals in the brain to improve function. Researchers have tested transcranial alternating current stimulation (tACS) and its sister technology, tDCS (transcranial direct current stimulation), on both healthy volunteers and those with neuropsychiatric conditions, such as depression, Parkinson’s disease or addiction. But study results have been conflicting or couldn’t be replicated, leading researchers to question the efficacy of the tools. The authors of the new analysis, led by Robert Reinhart, director of the cognitive and clinical neuroscience laboratory at Boston University in Massachusetts, say they compiled the report to quantify whether tACS shows promise, by comparing more than 100 studies of the technique, which applies an oscillating current to the brain. “We have to address whether or not this technique is actually working, because in the literature, you have a lot of conflicting findings,” says Shrey Grover, a cognitive neuroscientist at Boston University and an author on the paper. © 2023 Springer Nature Limited

Keyword: Learning & Memory
Link ID: 28807 - Posted: 05.31.2023

By Christina Caron A new study suggests that, for some patients, the anesthetic ketamine is a promising alternative to electroconvulsive therapy, or ECT, currently one of the quickest and most effective therapies for patients with difficult-to-treat depression. The study is the largest head-to-head comparison of the two treatments. Patients who don’t respond to at least two antidepressants — about one-third of clinically depressed patients — have a condition that clinicians refer to as “treatment-resistant.” Their options for relief are limited. Doctors typically recommend up to 12 sessions of ECT, which has a long-established efficacy, but is tainted by the stigma of historical misuse and frightening Hollywood images of people strapped to tables, writhing in agony. Today’s ECT is much safer and done under general anesthesia, but the procedure remains underutilized. The study, published on Wednesday in The New England Journal of Medicine, found that ketamine, when administered intravenously, was at least as effective as ECT in patients with treatment-resistant depression who do not have psychosis. (For people with psychosis, ketamine, even in very low doses, can worsen psychosis-like symptoms.) “The results were very surprising to us,” said Dr. Amit Anand, lead author of the study and a professor of psychiatry at Harvard Medical School who studies mood disorders at Mass General Brigham. His team had initially hypothesized that ketamine would be nearly as effective as ECT. Instead, Dr. Anand said, they found that ketamine performed even better than that. This is significant in part because some patients are uncomfortable with ECT’s potential side effects, such as temporary memory loss, muscle pain or weakness. (In rare cases it can result in permanent gaps in memory.) © 2023 The New York Times Company

Keyword: Depression; Drug Abuse
Link ID: 28806 - Posted: 05.31.2023

By Scientific American Custom Media Megan Hall: How does the stomach tell the brain it’s full? How do cells in our body grow and divide? James Rothman realized that the fundamental biology behind these processes are basically the same. In 2010, he shared The Kavli Prize in Neuroscience with Richard Scheller and Thomas Südhof for their work detailing how nerve cells communicate with each other on a microscopic level. Three years later, he received the Nobel Prize. Hall: James Rothman was pleasantly surprised when he received The Kavli Prize in Neuroscience. James Rothman: I'd always thought of myself as a biochemist first and a cell biologist second. And I never really thought of myself as a neuroscientist. Hall: He did apply to a neuroscience program in grad school… Rothman: It all just made a whole lot of sense, except for the fact that I wasn't admitted. Hall: But James is not the kind of person to worry about labels. In fact, he’s explored a range of scientific disciplines. As an undergrad at Yale, he studied physics, maybe in part because he grew up in the 50s. Rothman: Scientists and doctors were really the most admired in the 1950s. And it was the physicists in particular. Einstein, Oppenheimer, people like that. Hall: But his father worried about his career options, so he convinced James to try a biology course. Rothman: And I just fell in love. Hall: So, he ditched physics and decided to go to Harvard Medical School to learn more about biology. Rothman: In the end I never finished medical school. Hall: But, while he was there, he stumbled upon his life’s work. Rothman: I was a first-year medical student and I was listening to a lecture in our course on histology and cell biology. Hall: The professor was showing images that had been captured by scientists only a few decades before. They showed, for the first time, how complex the cell is. Rothman: The cell is not just, like a dumb little liquid inside. It's a highly organized place. It's more like a city than anything else. © 2023 Scientific American,

Keyword: Biomechanics
Link ID: 28805 - Posted: 05.31.2023

By Linda Searing Getting regular exercise may reduce a woman’s chances of developing Parkinson’s disease by as much as 25 percent, according to research published in the journal Neurology. It involved 95,354 women, who were an average of age 49 and did not have Parkinson’s when the study began. The researchers compared the women’s physical exercise levels over nearly three decades, including such activities as walking, cycling, gardening, stair climbing, house cleaning and sports participation. In that time, 1,074 women developed Parkinson’s. The study found that as a woman’s exercise level increased, her risk for Parkinson’s decreased. Those who got the most exercise — based on timing and intensity — developed the disease at a 25 percent lower rate than those who exercised the least. The researchers wrote that the study’s findings “suggest that physical activity may help prevent or delay [Parkinson’s disease] onset.” Parkinson’s disease is a neurodegenerative disorder, meaning it is a progressive disease that affects the nervous system and parts of the body controlled by nerves. It is sometimes referred to as a movement disorder because of the uncontrollable tremors, muscle stiffness, and gait and balance problems it can cause, but people with Parkinson’s also may experience sleep problems, depression, memory issues, fatigue and more. The symptoms generally stem from the brain’s lack of production of dopamine, a chemical that helps control muscle movement. No cure exists for Parkinson’s, but treatments to relieve symptoms include medication, lifestyle adjustments and surgical procedures, such as deep brain stimulation.

Keyword: Parkinsons
Link ID: 28804 - Posted: 05.31.2023

By Yasemin Saplakoglu Is this the real life? Is this just fantasy? Those aren’t just lyrics from the Queen song “Bohemian Rhapsody.” They’re also the questions that the brain must constantly answer while processing streams of visual signals from the eyes and purely mental pictures bubbling out of the imagination. Brain scan studies have repeatedly found that seeing something and imagining it evoke highly similar patterns of neural activity. Yet for most of us, the subjective experiences they produce are very different. “I can look outside my window right now, and if I want to, I can imagine a unicorn walking down the street,” said Thomas Naselaris, an associate professor at the University of Minnesota. The street would seem real and the unicorn would not. “It’s very clear to me,” he said. The knowledge that unicorns are mythical barely plays into that: A simple imaginary white horse would seem just as unreal. So “why are we not constantly hallucinating?” asked Nadine Dijkstra, a postdoctoral fellow at University College London. A study she led, recently published in Nature Communications, provides an intriguing answer: The brain evaluates the images it is processing against a “reality threshold.” If the signal passes the threshold, the brain thinks it’s real; if it doesn’t, the brain thinks it’s imagined. They’ve done a great job, in my opinion, of taking an issue that philosophers have been debating about for centuries and defining models with predictable outcomes and testing them. Such a system works well most of the time because imagined signals are typically weak. But if an imagined signal is strong enough to cross the threshold, the brain takes it for reality. All Rights Reserved © 2023

Keyword: Attention
Link ID: 28803 - Posted: 05.27.2023

By Matteo Wong If you are willing to lie very still in a giant metal tube for 16 hours and let magnets blast your brain as you listen, rapt, to hit podcasts, a computer just might be able to read your mind. Or at least its crude contours. Researchers from the University of Texas at Austin recently trained an AI model to decipher the gist of a limited range of sentences as individuals listened to them—gesturing toward a near future in which artificial intelligence might give us a deeper understanding of the human mind. The program analyzed fMRI scans of people listening to, or even just recalling, sentences from three shows: Modern Love, The Moth Radio Hour, and The Anthropocene Reviewed. Then, it used that brain-imaging data to reconstruct the content of those sentences. For example, when one subject heard “I don’t have my driver’s license yet,” the program deciphered the person’s brain scans and returned “She has not even started to learn to drive yet”—not a word-for-word re-creation, but a close approximation of the idea expressed in the original sentence. The program was also able to look at fMRI data of people watching short films and write approximate summaries of the clips, suggesting the AI was capturing not individual words from the brain scans, but underlying meanings. The findings, published in Nature Neuroscience earlier this month, add to a new field of research that flips the conventional understanding of AI on its head. For decades, researchers have applied concepts from the human brain to the development of intelligent machines. ChatGPT, hyperrealistic-image generators such as Midjourney, and recent voice-cloning programs are built on layers of synthetic “neurons”: a bunch of equations that, somewhat like nerve cells, send outputs to one another to achieve a desired result. Yet even as human cognition has long inspired the design of “intelligent” computer programs, much about the inner workings of our brains has remained a mystery. Now, in a reversal of that approach, scientists are hoping to learn more about the mind by using synthetic neural networks to study our biological ones. It’s “unquestionably leading to advances that we just couldn’t imagine a few years ago,” says Evelina Fedorenko, a cognitive scientist at MIT. Copyright (c) 2023 by The Atlantic Monthly Group.

Keyword: Brain imaging; Language
Link ID: 28802 - Posted: 05.27.2023

By Oliver Whang Gert-Jan Oskam was living in China in 2011 when he was in a motorcycle accident that left him paralyzed from the hips down. Now, with a combination of devices, scientists have given him control over his lower body again. “For 12 years I’ve been trying to get back my feet,” Mr. Oskam said in a press briefing on Tuesday. “Now I have learned how to walk normal, natural.” In a study published on Wednesday in the journal Nature, researchers in Switzerland described implants that provided a “digital bridge” between Mr. Oskam’s brain and his spinal cord, bypassing injured sections. The discovery allowed Mr. Oskam, 40, to stand, walk and ascend a steep ramp with only the assistance of a walker. More than a year after the implant was inserted, he has retained these abilities and has actually showed signs of neurological recovery, walking with crutches even when the implant was switched off. “We’ve captured the thoughts of Gert-Jan, and translated these thoughts into a stimulation of the spinal cord to re-establish voluntary movement,” Grégoire Courtine, a spinal cord specialist at the Swiss Federal Institute of Technology, Lausanne, who helped lead the research, said at the press briefing. Jocelyne Bloch, a neuroscientist at the University of Lausanne who placed the implant in Mr. Oskam, added, “It was quite science fiction in the beginning for me, but it became true today.” A brave new world. A new crop of chatbots powered by artificial intelligence has ignited a scramble to determine whether the technology could upend the economics of the internet, turning today’s powerhouses into has-beens and creating the industry’s next giants. Here are the bots to know: © 2023 The New York Times Company

Keyword: Robotics; Brain imaging
Link ID: 28801 - Posted: 05.27.2023

By Emily Underwood It’s a classic science fiction trope: Astronauts on an interstellar journey are kept in sleek, refrigerated pods in a state of suspended animation. Although such pods remain purely fictional, scientists have pursued research into inducing a hibernation-like state in humans to lessen the damage caused by medical conditions such as heart attacks and stroke, and to reduce the stress and costs of future long-distance space sojourns. In a study published today in Nature Metabolism, scientists report that they can trigger a similar state in mice by targeting part of their brain with pulses of ultrasound. Some experts are calling it a major technical step toward achieving this feat in humans, whereas others say it’s a stretch to extrapolate the results to our species. "It’s an amazing paper,” says Frank van Breukelen, a biologist who studies hibernation at the University of Nevada, Las Vegas and co-authored an editorial accompanying the study. The work builds on a flurry of recent studies that pinpoint specific populations of neurons in a region called the preoptic area (POA) of the hypothalamus. These cells act like an on-off switch for “torpor”—a sluggish, energy-saving state the animals enter when they’re dangerously cold or malnourished. In previous studies, scientists genetically engineered these neurons to respond to light or certain chemicals, and found they could cause mice to enter a torpid state even when they were warm and well-fed. Such invasive techniques can’t be easily translated to people, however, Breukelen notes. “That’s really not going to happen in people.” The new ultrasound study, led by bioengineer Hong Chen and her team at Washington University in St. Louis required no genetic engineering. Chen knew from previous research that some neurons have specialized pores called TRPM2 ion channels that change shape in response to ultrasonic waves, including the subset of POA cells that controls mouse torpor. To see what effect that had on the animals’ behavior, her team next glued miniature, speakerlike devices on the heads of mice to focus these waves on the POA.

Keyword: Sleep; Brain imaging
Link ID: 28800 - Posted: 05.27.2023

By Amber Dance Maybe it starts with a low-energy feeling, or maybe you’re getting a little cranky. You might have a headache or difficulty concentrating. Your brain is sending you a message: You’re hungry. Find food. Studies in mice have pinpointed a cluster of cells called AgRP neurons near the underside of the brain that may create this unpleasant hungry, even “hangry,” feeling. They sit near the brain’s blood supply, giving them access to hormones arriving from the stomach and fat tissue that indicate energy levels. When energy is low, they act on a variety of other brain areas to promote feeding. By eavesdropping on AgRP neurons in mice, scientists have begun to untangle how these cells switch on and encourage animals to seek food when they’re low on nutrients, and how they sense food landing in the gut to turn back off. Researchers have also found that the activity of AgRP neurons goes awry in mice with symptoms akin to those of anorexia, and that activating these neurons can help to restore normal eating patterns in those animals. Understanding and manipulating AgRP neurons might lead to new treatments for both anorexia and overeating. “If we could control this hangry feeling, we might be better able to control our diets,” says Amber Alhadeff, a neuroscientist at the Monell Chemical Senses Center in Philadelphia. AgRP neurons appear to be key players in appetite: Deactivating them in adult mice causes the animals to stop eating — they may even die of starvation. Conversely, if researchers activate the neurons, mice hop into their food dishes and gorge themselves. © 2023 Annual Reviews

Keyword: Obesity
Link ID: 28799 - Posted: 05.27.2023

By Carolyn Wilke Costello the octopus was napping while stuck to the glass of his tank at the Rockefeller University in New York. He snoozed quietly for half an hour, and then entered a more active sleep stage, his skin cycling through colors and textures used for camouflage — typical behavior for a cephalopod. But soon things became strange. A minute later, Costello scuttled along the glass toward his tank’s sandy bottom, curling his arms over his body. Then he spun like a writhing cyclone. Finally, Costello swooped down and clouded half of his tank with ink. As the tank’s filtration system cleared the ink, Eric Angel Ramos, a marine scientist, noticed that Costello was grasping a pipe with unusual intensity, “looking like he was trying to kill it,” he said. “This was not a normal octopus behavior,” said Dr. Ramos, who is now at the University of Vermont. It’s not clear when or if Costello woke up during the episode, Dr. Ramos said. But afterward, Costello returned to normal, eating and later playing with his toys. “We were completely dumbfounded,” said Marcelo O. Magnasco, a biophysicist at Rockefeller. Perhaps Costello was having a nightmare, he and a team of researchers speculated. They shared this idea and other possible explanations in a study uploaded this month to the bioRxiv website. It has yet to be formally reviewed by other scientists. After the incident, Dr. Ramos reviewed the footage of Costello’s activity, which was recorded as part of a behavior and cognition study (the lab was also observing another octopus, Abbott; both were named after the heptapod aliens in the movie “Arrival”). In total, the team found three more shorter instances that appeared similar. To Dr. Magnasco, the behaviors exhibited in Costello’s longest spell evoked the acting out of a dream. The curling of arms over his body looked like a defensive posture, he said. In the footage, the animal is seen perhaps trying to make himself look larger, and then he tries an evasive maneuver — inking. When he fails to escape, it seems like Costello seeks to subdue a threat by strangling the pipe, Dr. Magnasco said, adding, “This is the sequence of a fight.” © 2023 The New York Times Company

Keyword: Sleep; Evolution
Link ID: 28798 - Posted: 05.27.2023

By Robert Martone Neurological conditions can release a torrent of new creativity in a few people as if opening some mysterious floodgate. Auras of migraine and epilepsy may have influenced a long list of artists, including Pablo Picasso, Vincent van Gogh, Edvard Munch, Giorgio de Chirico, Claude Monet and Georges Seurat. Traumatic brain injury (TBI) can result in original thinking and newfound artistic drive. Emergent creativity is also a rare feature of Parkinson’s disease. But this burst of creative ability is especially true of frontotemporal dementia (FTD). Although a few rare cases of FTD are linked to improvements in verbal creativity, such as greater poetic gifts and increased wordplay and punning, enhanced creativity in the visual arts is an especially notable feature of the condition. Fascinatingly, this burst of creativity indicates that the potential to create may rest dormant in some of us, only to be unleashed by a disease that also causes a loss of verbal abilities. The emergence of a vibrant creative spark in the face of devastating neurological disease speaks to the human brain’s remarkable potential and resilience. A new study published in JAMA Neurology examines the roots of this phenomenon and provides insight into a possible cause. As specific brain areas diminish in FTD, the researchers find, they release their inhibition, or control, of other regions that support artistic expression. Frontotemporal dementia is relatively rare—affecting about 60,000 people in the U. S.—and distinct from the far more common Alzheimer’s disease, a form of dementia in which memory deficits predominate. FTD is named for the two brain regions that can degenerate in this disease, specifically the frontal and temporal lobes.

Keyword: Alzheimers; Attention
Link ID: 28797 - Posted: 05.27.2023

By Jennie Erin Smith José Echeverría spends restless days in a metal chair reinforced with boards and padded with a piece of foam that his mother, Nohora Vásquez, adjusts constantly for his comfort. The chair is coming loose and will soon fall apart. Huntington’s disease, which causes José to move his head and limbs uncontrollably, has already left one bed frame destroyed. At 42, he is still strong. José’s sister Nohora Esther Echeverría, 37, lives with her mother and brother. Just two years into her illness, her symptoms are milder than his, but she is afraid to walk around her town’s steep streets, knowing she could fall. A sign on the front door advertises rum for sale that does not exist. The family’s scarce resources now go to food — José and Nohora Esther must eat frequently or they will rapidly lose weight — and medical supplies, like a costly cream for Jose’s skin. Huntington’s is a hereditary neurodegenerative disease caused by excess repetitions of three building blocks of DNA — cytosine, adenine, and guanine — on a gene called huntingtin. The mutation results in a toxic version of a key brain protein, and a person’s age at the onset of symptoms relates, roughly, to the number of repetitions the person carries. Early symptoms can include mood disturbances — Ms. Vásquez remembers how her late husband had chased the children out of their beds, forcing her to sleep with them in the woods — and subtle involuntary movements, like the rotations of Nohora Esther’s delicate wrists. The disease is relatively rare, but in the late 1980s a Colombian neurologist, Jorge Daza, began observing a striking number of cases in the region where Ms. Vásquez lives, a cluster of seaside and mountain towns near Barranquilla. Around the same time, American scientists led by Nancy Wexler were working with an even larger family with Huntington’s in neighboring Venezuela, gathering and studying thousands of tissue samples from them to identify the genetic mutation responsible. © 2023 The New York Times Company

Keyword: Huntingtons; Genes & Behavior
Link ID: 28796 - Posted: 05.23.2023

By Laura Sanders Scientists can see chronic pain in the brain with new clarity. Over months, electrodes implanted in the brains of four people picked up specific signs of their persistent pain. This detailed view of chronic pain, described May 22 in Nature Neuroscience, suggests new ways to curtail the devastating condition. The approach “provides a way into the brain to track pain,” says Katherine Martucci, a neuroscientist who studies chronic pain at Duke University School of Medicine. Chronic pain is incredibly common. In the United States from 2019 to 2020, more adults were diagnosed with chronic pain than with diabetes, depression or high blood pressure, researchers reported May 16 in JAMA Network Open. Chronic pain is also incredibly complex, an amalgam influenced by the body, brain, context, emotions and expectations, Martucci says. That complexity makes chronic pain seemingly invisible to an outsider, and very difficult to treat. One treatment approach is to stimulate the brain with electricity. As part of a clinical trial, researchers at the University of California, San Francisco implanted four electrode wires into the brains of four volunteers with chronic pain. These electrodes can both monitor and stimulate nerve cells in two brain areas: the orbitofrontal cortex, or OFC, and the anterior cingulate cortex, or ACC. The OFC isn’t known to be a key pain influencer in the brain, but this region has lots of neural connections to pain-related areas, including the ACC, which is thought to be involved in how people experience pain. But before researchers stimulated the brain, they needed to know how chronic pain was affecting it. For about 3 to 6 months, the implanted electrodes monitored brain signals of these people as they went about their lives. During that time, the participants rated their pain on standard scales two to eight times a day. © Society for Science & the Public 2000–2023.

Keyword: Pain & Touch; Brain imaging
Link ID: 28795 - Posted: 05.23.2023

By Priyanka Runwal Researchers have for the first time recorded the brain’s firing patterns while a person is feeling chronic pain, paving the way for implanted devices to one day predict pain signals or even short-circuit them. Using a pacemaker-like device surgically placed inside the brain, scientists recorded from four patients who had felt unremitting nerve pain for more than a year. The devices recorded several times a day for up to six months, offering clues for where chronic pain resides in the brain. The study, published on Monday in the journal Nature Neuroscience, reported that the pain was associated with electrical fluctuations in the orbitofrontal cortex, an area involved in emotion regulation, self-evaluation and decision making. The research suggests that such patterns of brain activity could serve as biomarkers to guide diagnosis and treatment for millions of people with shooting or burning chronic pain linked to a damaged nervous system. “The study really advances a whole generation of research that has shown that the functioning of the brain is really important to processing and perceiving pain,” said Dr. Ajay Wasan, a pain medicine specialist at the University of Pittsburgh School of Medicine, who wasn’t involved in the study. About one in five American adults experience chronic pain, which is persistent or recurrent pain that lasts longer than three months. To measure pain, doctors typically rely on patients to rate their pain, using either a numerical scale or a visual one based on emojis. But self-reported pain measures are subjective and can vary throughout the day. And some patients, like children or people with disabilities, may struggle to accurately communicate or score their pain. “There’s a big movement in the pain field to develop more objective markers of pain that can be used alongside self-reports,” said Kenneth Weber, a neuroscientist at Stanford University, who was not involved in the study. In addition to advancing our understanding of what neural mechanisms underlie the pain, Dr. Weber added, such markers can help validate the pain experienced by some patients that is not fully appreciated — or is even outright ignored — by their doctors. © 2023 The New York Times Company

Keyword: Pain & Touch; Brain imaging
Link ID: 28794 - Posted: 05.23.2023

By Carl Zimmer One of the greatest transformations in the history of life occurred more than 600 million years ago, when a single-celled organism gave rise to the first animals. With their multicellular bodies, animals evolved into a staggering range of forms, like whales that weigh 200 tons, birds that soar six miles into the sky and sidewinders that slither across desert dunes. Scientists have long wondered what the first animals were like, including questions about their anatomy and how they found food. In a study published on Wednesday, scientists found tantalizing answers in a little-known group of gelatinous creatures called comb jellies. While the first animals remain a mystery, scientists found that comb jellies belong to the deepest branch on the animal family tree. The debate over the origin of animals has endured for decades. At first, researchers relied largely on the fossil record for clues. The oldest definitive animal fossils date back about 580 million years, although some researchers have claimed to find even older ones. In 2021, for example, Elizabeth Turner, a Canadian paleontologist, reported finding 890-million-year-old fossils of possible sponges. Sponges would make sense as the oldest animal. They are simple creatures, with no muscles or nervous system. They anchor themselves to the ocean floor, where they filter water through a maze of pores, trapping bits of food. Sponges are so simple, in fact, that it can come as a surprise that they are animals at all, but their molecular makeup reveals their kinship. They make certain proteins, such as collagen, that are produced only by animals. What’s more, their DNA shows they are more closely related to animals than to other forms of life. Starting in the 1990s, as scientists gathered DNA from more animal species, they tried to draw the animal family tree. In some studies, the sponges ended up on the deepest branch of the tree. In this scenario, animals evolved a nervous system only after the sponges branched off. © 2023 The New York Times Company

Keyword: Evolution
Link ID: 28793 - Posted: 05.23.2023