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Anna Bawden Health and social affairs correspondent An epilepsy drug could help prevent the breathing of patients with sleep apnoea from temporarily stopping, according to research. Obstructive sleep apnoea is a common breathing problem that affects about one in 20 people, according to the National Institute for Health and Care Excellence in England. Patients often snore loudly, their breathing starts and stops during the night and they may wake up several times. Not only does this cause tiredness but it can also increase the risk of high blood pressure, stroke, heart disease and type 2 diabetes. An international study has identified that an epilepsy medication is associated with a marked reduction in sleep apnoea symptoms. The findings, presented at the European Respiratory Society Congress in Vienna, Austria, demonstrated there were possible options for those unable to use mechanical breathing aids such as continuous positive airway pressure (Cpap) machines. Prof Jan Hedner, from Sahlgrenska university hospital and the University of Gothenburg in Sweden, said: “The standard treatment for obstructive sleep apnoea is sleeping with a machine that blows air through a face mask to keep the airways open. Unfortunately, many people find these machines hard to use over the long term, so there is a need to find alternative treatments.” The researchers conducted a randomised controlled trial of almost 300 obstructive sleep apnoea patients in Belgium, the Czech Republic, France, Germany and Spain who did not use the Cpap machines. They were divided into four groups and given one of three strengths of sulthiame or a placebo. © 2024 Guardian News & Media Limited
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29474 - Posted: 09.11.2024
By Kevin Loria When you have obstructive sleep apnea, addressing it is key. Left untreated, sleep apnea is linked to daytime sleepiness and an increased risk of anxiety, diabetes, hypertension and stroke. With OSA, your breathing pauses during sleep because your tongue or relaxed throat muscles block your airway, explains Richard Schwab, chief of the division of sleep medicine at the University of Pennsylvania Perelman School of Medicine in Philadelphia. Losing weight, quitting smoking and limiting alcohol can all help ease obstructive sleep apnea symptoms such as snoring, says Ana Krieger, medical director of the Center for Sleep Medicine at Weill Cornell Medicine in New York City. Sleep apnea’s severity is determined by something called your apnea-hypopnea index (AHI): the number of times per hour you fully or partially stop breathing for 10 seconds or longer. The primary treatment for people with moderate (15 to 29 AHI) or severe (30 AHI and higher) obstructive sleep apnea is a continuous positive airway pressure (CPAP) machine, which keeps your airway open by pumping air through a mask you wear over your mouth and/or nose when you sleep. Many people have difficulty tolerating a CPAP and don’t stick with it, however. The good news is CPAP machines have become smaller and quieter, with more comfortable options available. And for some people with mild (5 to 14 AHI) or even moderate OSA, less-invasive alternatives to a CPAP may be worth considering. A dental device designed to move the jaw so that the tongue shifts toward the front of the mouth can help keep the airway open. It’s one of the primary alternatives to a CPAP, Schwab says, and can also be used with a CPAP to help make severe obstructive sleep apnea milder.
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29460 - Posted: 09.04.2024
Tobi Thomas People who “catch up” on missed sleep at the weekend may have up to a 20% lower risk of heart disease compared with those who do not, according to a study. The findings, presented at a meeting of the European Society of Cardiology, looked at data from 90,903 adults taking part in the UK Biobank project, a database that holds medical and lifestyle records of 500,000 people in the UK. Of these, 19,816 met the criteria for being sleep-deprived, and over a follow-up period of 14 years the researchers found that the people who had the most extra sleep during the weekends were 19% less likely to develop heart disease than those who had the least amount of sleep at the weekends. Sleep deprivation in the study has been defined as those who self-reported having had less than seven hours of sleep per night. The video player is currently playing an ad. Those who got extra sleep at weekends ranged from an additional 1.28 hours to 16.06 hours, and those with the least sleep were losing 16.05 hours to 0.26 hours over the weekend. The study also looked at a sub-group of people with daily sleep deprivation and found that those who had the most compensatory sleep at the weekend had a 20% lower risk of developing heart disease than those with the least. Although the rest of the participants included in the study may have experienced inadequate sleep, on average their daily hours of sleep did not meet the criteria for being sleep deprived. Prof Yanjun Song, the study’s author, of China’s National Centre for Cardiovascular Disease in Beijing, said: “Sufficient compensatory sleep is linked to a lower risk of heart disease. The association becomes even more pronounced among individuals who regularly experience inadequate sleep on weekdays.” © 2024 Guardian News & Media Limited
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29455 - Posted: 08.31.2024
Linda Geddes Imagine a world in which you could solve problems, create art or music or even improve your tennis serve in your sleep. If scientists working in the field of lucid dreams succeed, that world could become a reality sooner than we realise. Researchers are developing techniques that could enable more people to experience lucid dreams – a state of consciousness where a person is aware they are dreaming and can recognise their thoughts and emotions while doing so – and transfer the content of these dreams into their waking lives. They have shown in recent months that it is possible to transfer the rhythm of dream music, switch on a real-life kettle and control a virtual car on a computer screen from inside a lucid dream. “Sooner or later there will be methods or tools that will allow anybody to experience lucid dreams easily or relatively easily, we are searching for ways to connect these two worlds together,” said Michael Raduga, the founder and CEO of REMspace Inc, a sleep research company in Redwood City, California who led the studies. “Even for people who don’t think they are smart, their subconscious is enormous, and we hope to be able to transfer all of this information into reality.” The video player is currently playing an ad. Although not everyone can do it, roughly half of the population have experienced at least one lucid dream in their lifetimes and around a fifth experience them once a month or more. An international group of researchers published a paper in Current Biology several years ago that suggested it was possible to ask people questions, either vocally or using morse code delivered via flashing lights, while they were in a lucid dream – including basic mathematical calculations – and for the dreamers to answer using eye movements or by contracting facial muscles to convey yes/no or numerical answers. © 2024 Guardian News & Media Limited
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29439 - Posted: 08.19.2024
By Catherine Offord Lack of sleep wreaks havoc on the brain, making us worse learners and disrupting our memory, among other insults. Now, a study in mice suggests some of these effects could stem from changes in how brain cells are connected to one another. In a paper published today in Current Biology, researchers show that just hours of sleep deprivation reduce how many different types of synapses—the places where neurons meet—there are in brain regions associated with learning and memory. The findings hint at a novel way sleep might help keep us sharp, the team says. The study “is a technical tour de force,” says Marcos Frank, a neuroscientist at Washington State University who was not involved in the work. Still, he and others caution it’s not yet clear whether this result explains sleep deprivation’s unpleasant side effects. Nerve cells meet and communicate via chemicals across synapses, allowing signals to travel through the nervous system. There are trillions such connections in the human brain, forming and rearranging circuits of neurons that capture and store information. Various theories have tried to invoke these connections to explain the relationship between sleep and memory. One well-known idea from the early 2000s holds that the strength of synapses in the brain decreases when we sleep, and that this is important for conserving energy and prepping the brain for encoding new information the following day. But such theories often treat synapses as relatively uniform, says Seth Grant, a neuroscientist at the University of Edinburgh. In the past few years, his team and others have found that synapses are surprisingly diverse. They differ not only in the types of chemical, or neurotransmitter, they use to send signals, but in structure and in the composition of proteins present in the neurons surrounding them.
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29422 - Posted: 08.03.2024
Oscar Allan The sluggish start to the day, the struggle to concentrate on everyday tasks and the lethargy that comes with just a few hours sleep, these are the symptoms that will be familiar to anyone who suffers with insomnia. But according to research, not all sleepless nights are the same. Brain scans have revealed evidence for distinct forms of insomnia, each with an associated pattern of neural wiring. And while the clinical distinction may mean little to those whose days are blighted by sleep deprivation, the discovery does raise the prospect of tailored interventions for people with different kinds of insomnia, which could lead to better treatments. Researchers at the Netherlands Institute for Neuroscience in Amsterdam analysed MRI scans from more than 200 insomniacs and dozens of sound sleepers and spotted structural changes that distinguished sleepers from the sleepless and five separate forms of insomnia. “If these subtypes differ in their biological mechanism, then patients in each subtype might benefit from different focused treatments,” said Tom Bresser, a neuroscientist and first author on the study. Insomnia is broadly defined as poor sleep, generally due to difficulties falling or staying asleep, which negatively affects daytime functioning. About a third of adults in western countries have sleep problems at least once a week, with up to 10% qualifying for a formal insomnia diagnosis. Chronic insomnia is diagnosed if someone suffers sleep problems on at least three nights a week for three months or more. The condition is nearly twice as common in women than men. © 2024 Guardian News & Media Limited
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29401 - Posted: 07.23.2024
By Dana G. Smith Getting too little sleep later in life is associated with an increased risk for Alzheimer’s disease. But paradoxically, so is getting too much sleep. While scientists are confident that a connection between sleep and dementia exists, the nature of that connection is complicated. It could be that poor sleep triggers changes in the brain that cause dementia. Or people’s sleep might be disrupted because of an underlying health issue that also affects brain health. And changes in sleep patterns can be an early sign of dementia itself. Here’s how experts think about these various connections and how to gauge your risk based on your own sleep habits. Too Little Sleep Sleep acts like a nightly shower for the brain, washing away the cellular waste that accumulates during the day. During this process, the fluid that surrounds brain cells flushes out molecular garbage and transfers it into the bloodstream, where it’s then filtered by the liver and kidneys and expelled from the body. That trash includes the protein amyloid, which is thought to play a key role in Alzheimer’s disease. Everyone’s brain produces amyloid during the day, but problems can arise when the protein accumulates into sticky clumps, called plaques. The longer someone is awake, the more amyloid builds up and the less time the brain has to remove it. Scientists don’t know whether regularly getting too little sleep — typically considered six hours or less a night — is enough to trigger the accumulation of amyloid on its own. But research has found that among adults aged 65 to 85 who already have plaques in their brains, the less sleep they got, the more amyloid was present and the worse their cognition. “Is lack of sleep sufficient to cause dementia? Probably not by itself alone,” said Dr. Sudha Seshadri, the founding director of the Glenn Biggs Institute for Alzheimer’s and Neurodegenerative Diseases at the University of Texas Health Science Center at San Antonio. “But it seems to definitely be a risk factor for increasing the risk of dementia, and perhaps also the speed of decline.” © 2024 The New York Times Company
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming; Chapter 7: Life-Span Development of the Brain and Behavior
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep; Chapter 13: Memory and Learning
Link ID: 29400 - Posted: 07.23.2024
Jon Hamilton About 170 billion cells are in the brain, and as they go about their regular tasks, they produce waste — a lot of it. To stay healthy, the brain needs to wash away all that debris. But how exactly it does this has remained a mystery. Now, two teams of scientists have published three papers that offer a detailed description of the brain's waste-removal system. Their insights could help researchers better understand, treat and perhaps prevent a broad range of brain disorders. The papers, all published in the journal Nature, suggest that during sleep, slow electrical waves push the fluid around cells from deep in the brain to its surface. There, a sophisticated interface allows the waste products in that fluid to be absorbed into the bloodstream, which takes them to the liver and kidneys to be removed from the body. One of the waste products carried away is amyloid, the substance that forms sticky plaques in the brains of patients with Alzheimer's disease. This illustration demonstrates how the thin film of sensors could be applied to the brain during surgery. There's growing evidence that in Alzheimer's disease, the brain's waste-removal system is impaired, says Jeffrey Iliff, who studies neurodegenerative diseases at the University of Washington but was not a part of the new studies. The new findings should help researchers understand precisely where the problem is and perhaps fix it, Iliff says. "If we restore drainage, can we prevent the development of Alzheimer's disease?" he asks. The new studies come more than a decade after Iliff and Dr. Maiken Nedergaard, a Danish scientist, first proposed that the clear fluids in and around the brain are part of a system to wash away waste products. The scientists named it the glymphatic system, a nod to the body's lymphatic system, which helps fight infection, maintain fluid levels and filter out waste products and abnormal cells. © 2024 npr
Related chapters from BN: Chapter 2: Functional Neuroanatomy: The Cells and Structure of the Nervous System; Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 2: Neurophysiology: The Generation, Transmission, and Integration of Neural Signals; Chapter 10: Biological Rhythms and Sleep
Link ID: 29369 - Posted: 06.26.2024
By Francine Russo Desperate for sleep, you go to a sleep clinic, where your head is fitted with electrodes to record your brain waves through various sleep stages. In the morning, you report that you barely slept at all. Yet according to the test—polysomnography, the gold standard for sleep measurement—you slept all night. You’re not the classic example of a person with insomnia who waits for sleep to come, maybe checks the clock, paces, reads and waits for morning. What you have has been called subjective insomnia, paradoxical insomnia or sleep misperception. Scientists have doggedly attacked this stubborn puzzle for decades without result—until now. Now they say that you have not been misrepresenting your sleep; they have been mismeasuring it. The most recent studies, using far more enhanced measurement, have found that many people with subjective insomnia show different brain activity from good sleepers—throughout the night. Neuroscientist Aurélie Stephan and colleagues at the Netherlands Institute for Neuroscience (NIN) realized that something unusual was going on after they asked people in their study to put onto their head a net of 256 electrodes rather than the typical six to 20 used in sleep clinics. In one series of experiments, the researchers woke sleepers about 26 times on average during the night. The participants were asked whether they’d been asleep or awake and what they’d been thinking about. The most remarkable finding, Stephan says, is that these people showed pockets of arousal in the form of fast brain waves during rapid eye movement (REM) sleep. REM is the stage in normal sleep when your brain should completely disconnect from the systems that keep you aware and vigilant, Stephan says. © 2024 SCIENTIFIC AMERICAN
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29348 - Posted: 06.08.2024
By Andrea Muraski I had a nightmare last night. It began like many of my dreams do – I was on vacation with my extended family. This time, we were in Australia, visiting family friends in a big house. Things took a turn when — in some way that I can’t quite explain — I got mixed up in this Australian family’s jewelry theft and smuggling operation. And I lied about it in front of my relatives, to protect myself and my co-conspirators. Before I woke up, I was terrified I’d be sent to prison. The dream seems bizarre, but when I pick the narrative apart, there are clear connections to my waking life. For instance, I recently listened to a podcast where a pair of fancy hairpins suspiciously go missing during a family gathering. Moreover, I’m moving tomorrow and still have packing to do. When the movers arrive in the morning, if I haven't finished packing, I'll face the consequences of my lack of preparedness – a crime, at least to my subconscious. Dr. Rahul Jandial, neurosurgeon, neuroscientist and author of This is Why You Dream: What Your Sleeping Brain Reveals About Your Waking Life, says the major themes and images of vivid dreams like these are worth paying attention to, and trying to derive meaning from. (For me, I decided that the next time I have to move, I’m taking the day before off!) I spoke with Dr. Jandial about what else we can learn from our dreams, including some of modern science’s most remarkable findings, and theories, about the dreaming brain. 1. Dreams are not random From dream diaries recorded in ancient Egypt and China to reports from anthropologists in the Amazon, to surveys of modern Americans, evidence shows our dreams have a lot in common. For example, being chased and falling are pretty consistent. “Reports of nightmares and erotic dreams are nearly universal,” Jandial says, while people rarely report dreaming about math. Jandial says the lack of math makes sense because the part of your brain primarily responsible for logic — the prefrontal cortex — is typically not involved in dreaming. © 2024 npr
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29340 - Posted: 06.04.2024
By Elissa Welle A new study suggests that the brain clears less waste during sleep and under anesthesia than while in other states—directly contradicting prior results that suggest sleep initiates that process. The findings are stirring fresh debate on social media and elsewhere over the glymphatic system hypothesis, which contends that convective flow of cerebrospinal fluid clears the sleeping brain of toxins. The new work, published 13 May in Nature Neuroscience, proposes that fluid diffusion is responsible for moving waste throughout the brain. It uses a different method than the earlier studies—injecting tracers into mouse brain tissue instead of cerebrospinal fluid—which is likely a more reliable way to understand how the fluid moves through densely packed neurons, says Jason Rihel, professor of behavioral genetics at University College London, who was not involved in any of the studies on brain clearance. The findings have prompted some sleep researchers, including Rihel, to question the existence of a glymphatic system and whether brain clearance is tied to sleep-wake states, he says. But leading proponents of the sleep-induced clearance theory are pushing back against the study’s techniques. The new study is “misleading” and “extremely poorly done,” says Maiken Nedergaard, professor of neurology at the University of Rochester Medical Center, whose 2013 study on brain clearance led to the hypothesis of a glymphatic system. She says she plans to challenge the work in a proposed Matters Arising commentary for Nature Neuroscience. Inserting needles into the brain damages the tissue, and injecting fluid, as the team behind the new work did, increases intracranial pressure, says Jonathan Kipnis, professor of pathology and immunology at Washington University School of Medicine in St. Louis. Kipnis and his colleagues published a study in February in support of the glymphatic system hypothesis that suggests neural activity facilitates brain clearance. “You disturb the system when you inject into the brain,” Kipnis says, “and that’s why we were always injecting in the CSF.” © 2024 Simons Foundation
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming; Chapter 2: Functional Neuroanatomy: The Cells and Structure of the Nervous System
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep; Chapter 2: Neurophysiology: The Generation, Transmission, and Integration of Neural Signals
Link ID: 29327 - Posted: 05.25.2024
By Erin Blakemore More than three-quarters of sudden infant deaths involved multiple unsafe sleep practices, including co-sleeping, a recent analysis suggests. A study published in the journal Pediatrics looked at 7,595 sudden infant death cases in a Centers for Disease Control and Prevention registry between 2011 and 2020. The majority of deaths occurred in babies less than 3 months old. The statistics revealed that 59.5 percent of the infants who died suddenly were sharing a sleep surface at the time of death, and 75.9 percent were in an adult bed when they died. Though some demographic factors such as sex and length of gestation were not clinically significant, the researchers found that the babies sharing a sleep surface were more likely to be Black and publicly insured than those who didn’t share sleep surfaces. Soft bedding was common among all the infants who died, and 76 percent of the cases involved multiple unsafe practices. The analysis mirrors known risk factors for sudden infant death. Current recommendations direct parents and other caretakers to provide infants with firm, flat, level sleep surfaces that contain nothing but a fitted sheet. Though room sharing reduces the risk of sudden infant death, CDC officials discourage parents from sharing a sleep surface with their child. Exposure to cigarette smoke during pregnancy was more common among infants who shared surfaces when they died. Though most infants were supervised by an adult when they died, the supervisor was more likely to be impaired by drug and alcohol use among those who shared a sleeping surface.
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29230 - Posted: 04.02.2024
By Charles Digges My default mode for writing term papers during my student days was the all-night slog, and I recall the giddy, slap-happy feeling that would steal over me as the sun rose. There was a quality of alert focus that came with it, as well as a gregariousness that would fuel bonding sessions with my other all-night companions. After we’d turned in the products of our midnight oil to our professors, we would all head out for pancakes. Then I’d go home and sleep the magic off. For years, I’d wondered if there was any basis for this temporary euphoria that I—though certainly not all my classmates—experienced after those sleepless nights. That I should feel so expansive and goofy after skipping sleep while many of them turned into drowsy grouches seemed to defy logic. Going without sleep isn’t supposed to be a good thing, especially for folks who experience depression, as I have. But it turns out this paradox has been the subject of inquiry for at least two centuries. In 1818, University of Leipzig psychiatrist Johann Christian August Heinroth was reportedly the first to suggest that partial or total sleep deprivation could be temporarily effective against “melancholia,” as depression was called in those days. He found this to be true only in a certain subset of patients—around 60 percent. More than a hundred years later, in the 1970s, evidence emerged that a “resynchronization” of disturbed circadian rhythms could be responsible for the improved moods of depressed patients after a night without sleep. And more recently, researchers have found that a neurotransmitter involved in reward known as dopamine may play a role in this effect, as may neuroplasticity—the nervous system’s ability to rearrange itself in response to stimuli. But the precise neural mechanisms responsible have remained unclear. © 2024 NautilusNext Inc.,
Related chapters from BN: Chapter 16: Psychopathology: Biological Basis of Behavior Disorders; Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 12: Psychopathology: The Biology of Behavioral Disorders; Chapter 10: Biological Rhythms and Sleep
Link ID: 29220 - Posted: 03.28.2024
Ian Sample Science editor Two nights of broken sleep are enough to make people feel years older, according to researchers, who said consistent, restful slumber was a key factor in helping to stave off feeling one’s true age. Psychologists in Sweden found that, on average, volunteers felt more than four years older when they were restricted to only four hours of sleep for two consecutive nights, with some claiming the sleepiness made them feel decades older. The opposite was seen when people were allowed to stay in bed for nine hours, though the effect was more modest, with participants in the study claiming to feel on average three months younger than their real age after ample rest. “Sleep has a major impact on how old you feel and it’s not only your long-term sleep patterns,” said Dr Leonie Balter, a psychoneuroimmunologist at the Karolinska Institute in Stockholm and first author on the study. “Even when you only sleep less for two nights that has a real impact on how you feel.” Beyond simply feeling more decrepit, the perception of being many years older may affect people’s health, Balter said, by encouraging unhealthy eating, reducing physical exercise, and making people less willing to socialise and engage in new experiences. The researchers ran two studies. In the first, 429 people aged 18 to 70 answered questions about how old they felt and on how many nights, if any, they had slept badly in the past month. Their sleepiness was also rated according to a standard scale used in psychology research. For each day of poor sleep the volunteers felt on average three months older, the scientists found, while those who reported no bad nights in the preceding month felt on average nearly six years younger than their true age. It was unclear, however, whether bad sleep made people feel older or vice versa. © 2024 Guardian News & Media Limited
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29219 - Posted: 03.28.2024
By Maria Popova I once dreamed a kiss that hadn’t yet happened. I dreamed the angle at which our heads tilted, the fit of my fingers behind her ear, the exact pressure exerted on the lips by this transfer of trust and tenderness. Freud, who catalyzed the study of dreams with his foundational 1899 treatise, would have discounted this as a mere chimera of the wishful unconscious. But what we have since discovered about the mind — particularly about the dream-rich sleep state of rapid-eye movement, or REM, unknown in Freud’s day — suggests another possibility for the adaptive function of these parallel lives in the night. One cold morning not long after the kiss dream, I watched a young night heron sleep on a naked branch over the pond in Brooklyn Bridge Park, head folded into chest, and found myself wondering whether birds dream. The recognition that nonhuman animals dream dates at least as far back as the days of Aristotle, who watched a sleeping dog bark and deemed it unambiguous evidence of mental life. But by the time Descartes catalyzed the Enlightenment in the 17th century, he had reduced other animals to mere automatons, tainting centuries of science with the assumption that anything unlike us is inherently inferior. In the 19th century, when the German naturalist Ludwig Edinger performed the first anatomical studies of the bird brain and discovered the absence of a neocortex — the more evolutionarily nascent outer layer of the brain, responsible for complex cognition and creative problem-solving — he dismissed birds as little more than Cartesian puppets of reflex. This view was reinforced in the 20th century by the deviation, led by B.F. Skinner and his pigeons, into behaviorism — a school of thought that considered behavior a Rube Goldberg machine of stimulus and response governed by reflex, disregarding interior mental states and emotional response. © 2024 The New York Times Company
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming; Chapter 6: Evolution of the Brain and Behavior
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29216 - Posted: 03.26.2024
By Meghan Bartels No matter how much trouble your pet gets into when they’re awake, few sights are as peaceful as a dog curled up in their bed or a cat stretched out in the sun, snoring away. But their experience of sleep can feel impenetrable. What fills the dreams of a dog or cat? That’s a tricky question to answer. Snowball isn’t keeping a dream journal, and there’s no technology yet that can translate the brain activity of even a sleeping human into a secondhand experience of their dream world, much less a sleeping animal. “No one has done research on the content of animals’ dreams,” says Deirdre Barrett, a dream researcher at Harvard University and author of the book The Committee of Sleep. But Rover’s dreamscape isn’t entirely impenetrable, at least to educated guesses. First of all, Barrett says, only your furrier friends appear to dream. Fish, for example, don’t seem to display rapid eye movement (REM), the phase of sleep during which dreams are most common in humans. “I think it’s a really good guess that they don’t have dreams in the sense of anything like the cognitive activity that we call dreams,” she says. Whether birds experience REM sleep is less clear, Barrett says. And some marine mammals always keep one side of their brain awake even while the other sleeps, with no or very strange REM sleep involved. That means seals and dolphins likely don’t dream in anything like the way humans do. But the mammals we keep as pets are solidly REM sleepers. “I think it’s a very safe, strong guess that they are having some kind of cognitive brain activity that is as much like our dreams as their waking perceptions are like ours,” she says. That doesn’t mean that cats and dogs experience humanlike dreams. “It would be a mistake to assume that other animals dream in the same way that we do, just in their nonhuman minds and bodies,” says David Peña-Guzmán, a philosopher at San Francisco State University and author of the book When Animals Dream. For example, humans rarely report scents when recounting dreams; however, we should expect dogs to dream in smells, he says, given that olfaction is so central to their waking experience of the world. © 2024 SCIENTIFIC AMERICAN
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming; Chapter 18: Attention and Higher Cognition
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep; Chapter 14: Attention and Higher Cognition
Link ID: 29176 - Posted: 03.05.2024
By Carolyn Todd Any sleep tracker will show you that slumber is far from a passive affair. And no stage of sleep demonstrates that better than rapid eye movement, or REM, commonly called dream sleep. “It’s also called paradoxical sleep or active sleep, because REM sleep is actually very close to being awake,” said Dr. Rajkumar Dasgupta, a sleep medicine and pulmonary specialist at the Keck School of Medicine of the University of Southern California. Before scientists discovered REM sleep in the 1950s, it wasn’t clear that much of anything was happening in the brain at night. Researchers today, however, understand sleep as a highly active process composed of very different types of rest — including REM, which in some ways doesn’t seem like rest at all. While the body typically remains “off” during REM sleep, the brain is very much “on.” It’s generating vivid dreams, as well as synthesizing memories and knowledge. Scientists are still working to unravel exactly how this strange state of consciousness works. “It is fair to say that there is a lot left to learn about REM sleep,” Dr. Dasgupta said. But from what researchers do understand, REM is critical to our emotional health and brain function — and potentially even our longevity. Where does REM sleep fall in the sleep cycle? Throughout the night, “We’re going in and out of this rhythmic, symphonic pattern of the various stages of sleep: non-REM 1, 2, 3 and REM,” said Rebecca Robbins, an instructor in medicine at Harvard Medical School and an associate scientist in the division of sleep and circadian disorders at Brigham and Women’s Hospital. © 2024 The New York Times Company
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming; Chapter 15: Emotions, Aggression, and Stress
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep; Chapter 11: Emotions, Aggression, and Stress
Link ID: 29128 - Posted: 02.03.2024
Ashley Montgomery In December 1963, a military family named the Gardners had just moved to San Diego, Calif. The oldest son, 17-year-old Randy Gardner, was a self-proclaimed "science nerd." His family had moved every two years, and in every town they lived in, Gardner made sure to enter the science fair. He was determined to make a splash in the 10th Annual Greater San Diego Science Fair. When researching potential topics, Gardner heard about a radio deejay in Honolulu, Hawaii, who avoided sleep for 260 hours. So Gardner and his two friends, Bruce McAllister and Joe Marciano, set out to beat this record. Randy Gardner spoke to NPR's Hidden Brain host Shankar Vedantam in 2017. When asked about his interest in breaking a sleep deprivation record, Gardner said, "I'm a very determined person, and when I get things under my craw, I can't let it go until there's some kind of a solution." Of his scientific trio, Randy lost the coin toss: He would be the test subject who would deprive himself of sleep. His two friends would take turns monitoring his mental and physical reaction times as well as making sure Gardner didn't fall asleep. The experiment began during their school's winter break on Dec. 28, 1963. Three days into sleeplessness, Gardner said, he experienced nausea and had trouble remembering things. Speaking to NPR in 2017, Gardner said: "I was really nauseous. And this went on for just about the entire rest of the experiment. And it just kept going downhill. I mean, it was crazy where you couldn't remember things. It was almost like an early Alzheimer's thing brought on by lack of sleep." But Gardner stayed awake. The experiment gained the attention of local reporters, which, in Gardner's opinion, was good for the experiment "because that kept me awake," he said. "You know, you're dealing with these people and their cameras and their questions." The news made its way to Stanford, Calif., where a young Stanford sleep researcher named William C. Dement was so intrigued that he drove to San Diego to meet Gardner. © 2024 npr
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep
Link ID: 29120 - Posted: 01.31.2024
By Sara Reardon Lustful male marsupials sacrifice their sleep for weeks to make more time for mating1. The antechinus, an Australian marsupial roughly the size of a gerbil, is a rare example of a mammal that mates during a certain season and never again. Roughly every August, male antechinus enter a three-week breeding frenzy in which they mate with every female they can and then die en masse. “It’s very short, very intense,” says zoologist Erika Zaid at La Trobe University in Melbourne, Australia. Males generally live for only one year; females can live for at least a year longer and produce more than one litter. To find out how males make enough time for sex in their short lives, Zaid and her colleagues trapped ten male and five female dusky antechinus (Antechinus swainsonii) and kept them in separate enclosures so they couldn’t mate. They attached activity monitors to the animals’ collars and collected blood samples to measure biomarkers. The researchers found that captive males, but not females, moved around much more and slept less during breeding season than they did the rest of the year. On average, the males’ sleep time per day was around 20% lower during the breeding season than during the non-breeding season ― and one male’s sleep time per day was more than 50% lower. At the end of breeding season, two of the males died within a few hours of one another. The other eight became sterile. To determine whether sleep loss occurs in the wild, Zaid and her colleagues trapped 38 animals from a related species called agile antechinus (A. agilis) before and during breeding season and measured the animals’ oxalic acid, a chemical in the blood whose levels drop when an animal is short on sleep. Males’ oxalic acid levels fell sharply during the breeding season. Unlike the captive females, wild females showed drops as well, suggesting that males were waking them up for shenanigans. Mysterious death © 2024 Springer Nature Limited
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming; Chapter 12: Sex: Evolutionary, Hormonal, and Neural Bases
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep; Chapter 8: Hormones and Sex
Link ID: 29113 - Posted: 01.27.2024
By Lauren Peace Tampa Bay Times Nina Shand couldn’t stay awake. She had taken afternoon naps since she was a teenager to accommodate her “work hard, play hard” attitude, but when she was in her mid-20s the sleepiness became more severe. Menial computer tasks put her to sleep, and a 20-minute drive across her city, St. Petersburg, Florida, brought on a drowsiness so intense that her eyelids would flutter, forcing her to pull over. She knew something was really wrong when she no longer felt safe behind the wheel. In 2021, she received a diagnosis: narcolepsy, a rare disorder that causes excessive daytime sleepiness. Her doctor prescribed her Adderall, the brand-name version of the amphetamine-powered medication commonly known for treating attention-deficit/hyperactivity disorder. It worked. For the first time in years, Shand, now 28, felt energized. She was no longer struggling at work, sneaking naps, or downing coffees to trick her body into staying awake. She felt hope. But by 2022, a national Adderall shortage meant pharmacies were no longer able to fill her prescription. Shand and countless others across the country were being turned away, left to piece together a new — and often less effective — treatment plan with doctors scrambling to meet their needs. More than a year later, the shortage continues. In October, Democrats in the U.S. House of Representatives implored the FDA and Drug Enforcement Administration to work with drug manufacturers to ensure better supply. “We cannot allow this to be the continuing reality for Americans,” read their letter, led by Rep. Abigail Spanberger (D-Va.). But for now, it is.
Related chapters from BN: Chapter 14: Biological Rhythms, Sleep, and Dreaming; Chapter 4: The Chemistry of Behavior: Neurotransmitters and Neuropharmacology
Related chapters from MM:Chapter 10: Biological Rhythms and Sleep; Chapter 4: Development of the Brain
Link ID: 29102 - Posted: 01.16.2024