SJK Audio Edition

Read this article at: https://www.sciencejournalforkids.org/articles/how-does-your-brain-know-which-food-made-you-sick/ or watch at: https://youtu.be/y0ySCVZrZgMSummary: Scientists studied how the brain links new flavors with delayed sickness by replaying flavor memories in the amygdala.Abstract: Sometimes food makes you feel sick long after you eat it. But how does your brain know which food caused the problem? We wanted to find out. We studied this question in mice. First, we gave them a sweet drink with a flavor that was either new or familiar. Then, after a short delay, we caused mild sickness and looked at their brains. The amygdala, a brain area for memory, “replayed” the flavor signal when the stomach sent the sickness signal. This replay made the memory stronger. Mice then avoided the new flavor that made them sick, but not the familiar flavor that hadn’t made them sick in the past. This shows how the brain bridges the gap between eating and later feeling sick.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/whats-on-natures-secret-plant-list/ or watch at: https://youtu.be/MeXwRVLbOpMSummary: Scientists studied thousands of sites worldwide to discover that natural areas are missing many plant species that could live there, a hidden loss they call dark diversity.Abstract: Picture a meadow or forest full of plants. Did you know that even when it looks wild and healthy, there are many plants missing? Scientists call these “missing species” dark diversity. Our team studied more than 5,000 sites in 119 regions across the globe. Each site was about the size of a classroom. We counted the plants that actually grew there. Then we compared them with the plants that could live there. On average, only about one-quarter of the possible plants were present. The rest were gone, even in places that still look natural. Why? Human activities – like building roads, cities, and farms – make it hard for plants to survive or return. We found that the more people shape the land, the fewer plants remain from the full list of potential species. This hidden loss shows that Nature is emptier around us than it appears. That matters for protecting biodiversity.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at:   or watch at: https://youtu.be/XIl20eaK31USummary: Researchers wanted to know how fast COVID-19 science research reached decision-makers.Abstract: Do you remember the lockdowns during the COVID-19 pandemic? Leaders had to make fast choices. But how did they know what to do? We looked at the work of a team of scientists from Imperial College London. They helped by sharing reports, news stories, and science papers – fast. We looked at 620 reports they put out between 2020 and 2022. We were curious. What types of reports did they produce? How fast did they share their work? Who used it? What did they study?News stories reached leaders the fastest. About two months faster than normal science papers. That matters when people are getting sick! Reports and preprints were also created by the team. Governments from 41 different countries cited work from the team as they developed policy. The team also changed what they studied as the virus changed. This made their reports more useful for governments. Our study shows something important: sharing science quickly can help develop policy that keeps people safe.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/who-lives-in-the-rainforest-canopy/ or watch at: https://youtu.be/EkO0cYJbMOUSummary: Researchers developed a new eDNA collection system to look at biodiversity in tropical rainforests.Abstract: Can you list all the animals that live at the top of rainforest trees? You might have seen pictures of birds or monkeys living in the rainforest canopy. The tropical rainforest is very biodiverse. But researchers still don’t know about everything that lives there.We wanted to test a new way of finding out what lives in the rainforest canopy. We set up collectors that catch rainwater as it falls down from the trees. We studied environmental DNA from the water to look at biodiversity. We found that hundreds of different organisms live in the rainforest canopy. There is also more biodiversity in areas that are not disturbed by humans. So, the environmental DNA gathered in rainwash is very important. This method can help people learn more about the rainforest ecosystem and conserve its biodiversity.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at:   or watch at: https://youtu.be/GBkNur1E_BwSummary: Researchers identified four different camouflage hunting displays in wild broadclub cuttlefish.Abstract: Predators and prey are in conflict with each other. Predators try to catch prey, while prey try to avoid predators. Predators can blend into their surroundings and wait for prey to get close. Or predators can chase their prey. Some predators will even sneak up on their prey before chasing it. Camouflage can help these predators be more successful.One predator that uses camouflage is the cuttlefish. But we don’t know much about how they hunt in the wild. So, we observed broadclub cuttlefish on coral reefs in the Indo-Pacific. We saw four different hunting displays. We also saw individual cuttlefish using multiple displays in different moments. This information can help us better understand predator behavior on coral reefs.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/how-can-growing-seaweed-help-fight-climate-change/  or watch at: https://youtu.be/Av0AflIv6bYSummary: Researchers compared seaweed farming scenarios to see if seaweed farming could help reduce carbon emissions.Abstract: Why is seaweed important? If you ask a fish, they might say that seaweed helps them hide from predators. A sea lion might say that seaweed forests are great places to find fish to eat! And people all around the world like to eat seaweed.Recently, people have started to talk about seaweed farming as a way to help with the climate crisis. Why? Because farming seaweed doesn’t use very many resources. Growing it may even improve ocean health by providing habitat and food to sea creatures. Seaweed also absorbs carbon dioxide (CO2) as it grows, so it could even help with climate change by reducing the amount of CO2 in the atmosphere. But just because it could help doesn’t mean it will!We studied five different seaweed farming scenarios using a computer simulation. We found that growing and harvesting seaweed can help with climate change. The biggest impact would come from using seaweed products to replace common things that right now take a lot of carbon-intensive energy to make.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at:   or watch at: https://youtu.be/JKoJhxkvFYQSummary: Scientists wanted to find out how sea snails were adapting to new habitats in colder waters.Abstract: If you lived in sunny California, would you want to move north? Well, some sea snails are doing exactly that! We were curious about Kellet’s whelks, a type of sea snail. They usually live in the warm waters of Southern California and Mexico. Now, we’re finding them further north in colder water! We collected Kellet’s whelks from the California coast – some from the south and some from the north. We kept them in separate tanks with identical conditions. Then we compared the DNA of their babies.The northern snails had 2,770 genes that were working differently. These differences were so clear that we could tell if a baby snail’s parents came from the south or north just by looking at its DNA. We also found that the northern snails’ genes show some changes that help them survive in the colder water up north! Our findings are helping scientists understand how ocean animals are adapting to a changing climate.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/what-are-good-ways-to-track-melting-glaciers/  or watch at: https://youtu.be/BUo2SaeYdKoSummary: Researchers combined datasets to more accurately measure changes in glacier melt around the world.Abstract: Have you ever watched an ice cube melt on a hot day? Well, that’s happening to glaciers all over the world. Glaciers have important impacts on water resources, runoff, and sea level rise. Keeping track of how glaciers change is important to predict and plan for these downstream impacts. We wanted to create a more recent record of how glaciers have changed from 2000 to 2023. So we compared and combined data about glaciers collected using different methods. We found that glaciers worldwide lost about 5% of their mass in this period. In different regions glaciers lost between 2% and 39% of their mass. We saw slight differences between data collection methods that could add up over time. We expect glacier loss to continue, which will lead to some regions losing their glaciers by 2100. It’s important to use the most accurate and up-to-date information to make predictions about glacier loss in the future. You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/why-is-bird-flu-making-cows-sick/  or watch at: https://youtu.be/Hf7bk_O6LIASummary: Scientists tracked how the bird flu virus spread from birds to dairy cows and other animals.Abstract: Did you know bird flu can affect animals other than birds? Bird flu usually affects wild birds like geese and farm birds like chickens. But sometimes it can “jump” to other animals. This includes cats, cows, and even humans. We wanted to understand this process better.When cows started getting sick from bird flu and stopped producing milk, we examined how this happened. We looked at the amount of virus and where it was present in the cows. We sampled their milk and several other tissues. We found that the virus mainly infected the mammary glands, which produce milk. We studied the genetic changes in the virus’ genetic code. This helped us better understand how it spreads. We discovered that the bird flu virus moved between cows and from cows to other animals in the farms easily. We also learned that the virus moved between farms. It is important to track outbreaks and reduce activities that could spread the bird flu virus. This can help us prevent more animals and humans from getting sick.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/how-does-climate-change-affect-mental-health/  or watch at: https://youtu.be/Pr2AJ_6sm2ISummary: Researchers develop a way to determine the level of climate change anxiety a person experiences.Abstract: Did you know that climate change affects people’s mental health? Some people experience climate change anxiety. They have extreme worries and fears about the future because of climate change. We wanted to describe the levels of climate change anxiety that people experience more clearly. We used a survey called the Climate Change Anxiety Scale. We also used a survey about stress, anxiety, and depression. We used the results to determine cut-off scores. We found that a total score of 21 means a person has mild to moderate climate change anxiety symptoms. A total score of 23 means a person has severe climate change anxiety symptoms. We also found that many young people have climate change anxiety. Measuring climate change anxiety can help health care professionals provide support. It can also help governments make policies to reduce climate change. These policies should improve people’s mental health.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at:  https://www.sciencejournalforkids.org/articles/how-do-lizards-find-food-to-eat/ or watch at: https://youtu.be/WzUBIZ_qGjESummary: Scientists watched lizards navigate a maze to learn more about how lizards use their senses to find food.Abstract: What is your hide-and-seek strategy? Maybe you search one area at a time, look for signs of movement, or even listen to see if you can hear your friends. Wild animals use lots of different strategies when they search for food. Guatemalan beaded lizards come from a desert valley surrounded by rugged mountains. They like to eat bird and lizard eggs, as well as insects, baby birds and small mammals. These can be hard to find! We wanted to know what strategies these lizards use when they are hunting for their next meal. We designed a maze experiment to help us figure it out. We placed food in a maze and watched how the lizards navigated the maze. We found that they were good at remembering where they’d already looked. They did best when there was a scent trail for them to follow. They did not do as well when they had to detect airborne scent from a distance. These experiments help us know more about the strategies these lizards use in the wild!You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/what-do-egyptian-mummies-smell-like/  or watch at: https://youtu.be/whGBDdaNJS8Summary: Researchers smelled ancient Egyptian mummified bodies to learn more about mummification materials, decomposition, and preservation practices.Abstract: There are lots of things to see in museums. Some museums even have things you can touch or hear. But not many museums have things you can smell. Smells from museum artifacts can provide a lot of information. They can tell us what artifacts are made of, how they are preserved, and what condition they are in. We wanted to know what ancient Egyptian mummified bodies smelled like. We analyzed air samples from nine ancient Egyptian mummified bodies. We used trained volunteers and chemical analyses to identify smells. We found that mummified bodies smell “woody”, “spicy”, and “sweet”. Smells were more intense for mummified bodies in display cases. We also saw similarities between mummified bodies from the Late Period (664–332 BCE). We can use this technique to help us conserve and preserve museum artifacts in the future.You are one of half a million educators in the U.S. who use our articles and videos in class. All our content is FREE, no paywalls, no need to subscribe. But recent federal cuts have made it hard for us to win grants to fund our mission. We are a small non-profit, and without support, we may not make it.If you enjoy our content, please consider donating - https://www.sciencejournalforkids.org/support-us.html This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/how-can-rats-help-fight-tuberculosis/  or watch at: https://youtu.be/aQSq5wYeH_4Summary: Researchers compared the ability of African giant pouched rats to identify tuberculosis in adults and children to standard microscope smear tests.Abstract: Can you imagine a rat sniffing out a disease? The African giant pouched rat can! Scientists trained these rats to identify if a person has tuberculosis (TB). TB is a bacterial disease that most commonly affects the lungs. It spreads easily and can be dangerous if untreated. When rats smell samples of mucus a person coughs up, they can smell if it has TB bacteria. We wanted to know if rats are better at identifying cases of TB compared to a standard microscope test. We also wanted to know if rats can better identify TB in children than in adults. We found that rats can identify TB in samples that the microscope test said were negative. We also learned that the rats are more likely to identify TB in children – even when they have low levels of bacteria. Using rats can help more people receive treatment for TB and reduce the spread. This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/do-some-dog-breeds-have-a-better-sense-of-smell/  or watch at: https://youtu.be/ydH_4wytXJYSummary: Researchers compared the smelling abilities of dogs across different breeds to see which types of dogs might make the best searchers.Abstract: Have you ever seen a search dog? What breed of dog was it? Search dogs are specially trained to detect explosives, drugs, or diseases. To be good at this job, search dogs must have a sharp sense of smell and the ability to cooperate with humans. Common breeds of search dogs include German and Belgian shepherds, Labradors, and border collies. But are these dogs better at smelling than other breeds? Or is it their training and cooperation that make them good at the job? We wanted to find out whether some dogs are naturally better at smelling than others. So we used a test called the Natural Detection Task to compare how well dogs can find food using their nose without any previous training. We tested all the dogs with the same setup. We then compared specific breed groups and different breeds. We found that some breeds were better at smelling than others. But dog breeds that humans have selectively bred for their ability to smell were not always the better performers. This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/how-does-climate-change-impact-satellites/ or watch at: https://youtu.be/lh3fpn3sIQ8Summary: Researchers used climate scenarios to estimate the future number of satellites that could safely fit in low Earth orbit. Abstract: There are a lot of satellites in low Earth orbit. We use them for things like communication and weather forecasting. Climate change is actually cooling this region of our atmosphere. This changes the density of air there. Changes in climate could impact these satellites. We wanted to know how much.We used a model to estimate air density changes in low Earth orbit in the future. Then we calculated how many satellites the region could safely hold. We did this for three climate change scenarios. We found that by 2100, climate change could reduce the number of satellites low Earth orbit can hold by 50–66%. This means we need to develop strategies to make low Earth orbit a more sustainable resource for the future. This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/why-is-a-sense-of-community-so-important-for-our-well-being/  or watch at: https://youtu.be/isK_krpNqkcSummary: Researchers wanted to explore how your way of thinking about time might explain the link between feeling like you belong to a group and your mental health.Abstract: Anxiety, depression, and stress are becoming more common. Psychologists want to understand why. We were curious to find out how feeling like you belong to a group improves mental health. We wondered if how you think about time (past, present, and future) affects this. We asked 352 people to complete surveys. We asked about their stress, anxiety, and depression. We also asked about belonging and how they thought about time. People who felt connected to a group had lower depression, stress, and anxiety. We also found that this relationship was affected by a person's thoughts about time. This supports good mental health! This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/how-do-octopuses-coordinate-their-arms/  or watch at: https://youtu.be/TaEPrsglDkoSummary: Researchers explored the nervous system of octopuses to understand how they coordinate eight arms and hundreds of suckers.Abstract: Have you ever tried patting your head and rubbing your stomach simultaneously? Coordinating two arms at the same time can be difficult. So imagine if you had eight arms, like an octopus! The nervous system helps animals coordinate their movements. It also helps them sense and respond to their environment. Each type of animal has a nervous system that is organized differently. We wanted to know how the octopus's nervous system is organized. To find out, we looked at the nerves inside octopuses’ arms. We found that the main nerve cord in each octopus arm has segments. These segments can communicate with each other. They are also linked to individual suckers. This helps octopuses make large, smooth movements, like swimming. It also helps octopuses make tiny targeted movements, like moving a single sucker. So, the layout of the nerves in the arms tells us how octopuses make such complex movements! This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/how-can-there-be-oxygen-in-the-deep-sea-without-light/ or watch at: https://youtu.be/T1KXbjH6TY8Summary: Researchers explored how oxygen could be produced in the deep sea.Abstract: Have you ever wondered what goes on at the bottom of the ocean? We do! During experiments near the seafloor, we detected oxygen production. It did not make sense. Photosynthesis produces oxygen. But there is no light in the deep sea for photosynthesis! We wanted to know where the oxygen was coming from.So, we went back to do more experiments. We tested multiple hypotheses. We thought that we might have accidentally added oxygen to our experiments. Or that there were organisms in our samples producing the oxygen. We only found one hypothesis with good support. Metallic rocks on the seafloor seem to have produced the oxygen. We need to know a lot more about this process before we can understand how it happens and its impact on the deep ocean community. This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/what-can-you-do-with-a-microscopic-robot/  or watch at: https://youtu.be/Vl9UUr90ch0Summary: Scientists built a microscopic robot that can interact with light in useful ways.Abstract: Can you imagine a robot so small that you can’t even see it without a microscope? No, it’s not science fiction! Microscopic robots, or microbots, are tiny machines that are about the same size as a red blood cell. That’s only a few millionths of a meter across, about a tenth of a hair's diameter. Making a robot this small is hard. Controlling a microbot is especially challenging!We developed a new type of microbot that can be controlled remotely using an electromagnet. The basic shape of the robot is simple. They have two sides and bend in the middle like an inchworm. They are covered in special, super tiny magnets. By adjusting a magnetic field, we can make microbots walk, swim, and fold themselves up like origami!  Their tiny size even lets them change how light bounces off a surface. We think these microbots have a lot of potential! This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com

Read this article at: https://www.sciencejournalforkids.org/articles/how-many-legs-does-it-take-to-escape-a-predator/  or watch at: https://youtu.be/5orR9Vr5BBMSummary: Researchers wanted to learn whether using two legs instead of four helps jumping rodents escape their predatorsAbstract: Why do animals have such different shapes and sizes? Many animals are hunted by predators. Prey animals have features that help them escape these predators. For example, some animals like frogs have two powerful back legs to jump away from predators. Other animals, like deer, have four legs that help them run away to safety. Some rodents use two legs, while many other rodents use four legs. But which ones are better at avoiding predators? We compared the bipedal kangaroo rat with the pocket mouse, woodrat, and ground squirrel. We created fake predator attacks and measured how each rodent responded. We found that pocket mice and kangaroo rats jumped away the fastest. This might be because both are small and have strong back legs. Woodrats and ground squirrels jumped lower and slower. So, rodents jumping with two legs were better at reacting to attacks. This means using two legs may be an advantage for rodents when avoiding predators. This is a public episode. If you would like to discuss this with other subscribers or get access to bonus episodes, visit sciencejournalforkids.substack.com