Are you aware that over 2 billion people globally drink water contaminated with disease-causing microbes? Stanford University and SLAC National Accelerator Laboratory have developed a low-cost, recyclable powder that can kill thousands of waterborne bacteria per second when exposed to ordinary sunlight. This discovery could be a significant breakthrough for the nearly 30 percent of the world's population without access to safe drinking water. The results of their study are published in Nature Water.

Inhaler delivery systems have revolutionized the treatment of respiratory illnesses, making it easier for patients to receive the medicine they need to manage their symptoms. But how do these devices work, and what scientific principles underlie their design? At the heart of an inhaler is the aerosol, a fine mist of medication that is delivered directly to the lungs. To create this mist, inhalers use a propellant, which expands rapidly upon release, creating a burst of pressure that forces the medication out of the device and into the airways. One key challenge in designing inhalers is ensuring that the aerosol particles are small enough to be easily inhaled, yet large enough to deposit effectively in the lungs. This is where the science of aerodynamics comes into play, as researchers work to optimize the shape and size of the particles to achieve the ideal balance of delivery efficiency and patient comfort. Recent advancements in inhaler technology have led to the development of smart inhalers, which use sensors and digital connectivity to monitor patient use and provide personalized feedback and reminders. This innovation has the potential to improve patient adherence and outcomes, and is just one example of how inhaler delivery systems continue to evolve and improve. Leading academics in the field include Dr. Richard Costello, a respiratory physician and clinical scientist at the Royal College of Surgeons in Ireland, and Dr. Omar Usmani, a consultant physician in respiratory medicine at the Royal Brompton Hospital and professor of respiratory medicine at Imperial College London. These experts have contributed to important research on inhaler technology and the treatment of respiratory diseases, and continue to drive innovation in the field. Inhaler delivery systems have revolutionized the treatment of respiratory illnesses, allowing patients to manage their symptoms with greater ease and precision. By understanding the science behind aerosol medicine and the principles that underlie inhaler design, we can appreciate the incredible innovation that has made this possible.

Electronic waste is not just trash, it's a treasure trove of precious metals like gold! Researchers at the University of Cagliari and Imperial College London have found a way to extract gold from electronic waste and use it as a catalyst in making medicines. This not only prevents gold from being lost in landfills but also reduces our dependence on environmentally harmful mining practices.

This story of Harry Coover, a chemist during World War II, highlights the importance of persistence and creative thinking in academic pursuits. Coover and his team encountered challenges in their research, but instead of giving up, they looked for alternative uses for the materials they were working with. This led to the creation of super glue, which has saved countless lives in medical settings. This story shows that academic curiosity and perseverance can lead to unexpected discoveries with practical applications. By exploring academic topics through reading, reflection, and self-directed projects, students can develop the skills needed to tackle complex problems and make meaningful contributions to society.

Have you ever heard of the field of nanotechnology? It's a rapidly growing and exciting field that is revolutionizing the way we live, work, and play. Nanotechnology is the study and manipulation of materials on a molecular or atomic scale, and it has the potential to transform everything from medicine to electronics. Imagine creating tiny robots that can swim through your bloodstream and target cancer cells, or developing ultra-light and ultra-strong materials for airplanes and cars. These are just a few examples of the amazing possibilities that nanotechnology offers. As a nanotechnologist, you would work with these tiny materials to create new products and technologies. You might design and develop new materials, work on improving existing ones, or create entirely new devices and systems. You could work in a variety of fields, from medicine to electronics to energy. Typical duties in nanotechnology might include conducting experiments, analyzing data, designing and building prototypes, and collaborating with other scientists and engineers. There are also many areas of specialization within nanotechnology, such as nanoelectronics, nanobiotechnology, and nanomaterials. To get started in this field, you'll need a strong background in science and engineering. Many nanotechnologists have degrees in materials science, chemistry, physics, or electrical engineering. Some popular undergraduate programs and majors include nanotechnology engineering, materials science and engineering, and chemical engineering. In addition to technical skills, there are certain personal attributes that can be helpful in this field. These might include a strong attention to detail, excellent problem-solving skills, and a creative and innovative mindset. The job prospects for nanotechnologists are excellent, with many exciting opportunities available in both the public and private sectors. Some notable employers in this field include IBM, Intel, and Samsung, as well as government agencies such as NASA and the National Institutes of Health. So if you're looking for a career that is both challenging and rewarding, consider exploring the field of nanotechnology. Who knows what amazing discoveries and inventions you might be a part of in the future!

From toxic leaks to microplastic pollution, scientists are exploring how pollutants affect human health. Exposomics is a new field that aims to understand our exposure to chemicals and their impact. Carmen Marsit, a molecular epidemiologist, is leading the charge to measure our exposure to chemicals and their breakdown products in blood. Learn how scientists are using gas chromatography, liquid chromatography, and mass spectrometry to identify the chemicals we are exposed to and the potential health risks associated with chronic exposure.

Chemotherapy is a type of cancer treatment that uses drugs to kill rapidly dividing cancer cells in the body. The drugs are delivered through pills and injections and are toxic to all cells in the body, including healthy ones. However, cancer cells are more susceptible to the effects of chemotherapy because they multiply rapidly. Chemotherapy drugs can damage hair follicles, cells of the mouth, gastrointestinal lining, reproductive system, and bone marrow, which can cause side effects such as hair loss, fatigue, infertility, nausea, and vomiting. Despite these side effects, chemotherapy has greatly improved the outlook for many cancer patients. Advances in treatment have led to up to 95% survival rates for testicular cancer and 60% remission rates for acute myeloid leukemia. Researchers are still developing more precise interventions to target cancer cells while minimizing harm to healthy tissues. Learning about chemotherapy can help high school students understand the science behind cancer treatment and the importance of ongoing research to improve outcomes for patients.

Stanford researchers have developed a smart bandage that painlessly falls away from the skin and tracks signs of recovery and infection. It even responds with electrical stimulation to hasten healing. The bandage resulted in 25% faster healing, greater blood flow to injured tissue, and less scarring in animal studies. The bandage is just one example of how Stanford researchers combine organic chemistry and novel materials to reimagine medical devices in more powerful, personal, and unobtrusive ways.

Electricity is a fundamental part of modern life, but could too much of it be harmful? Understanding the movement of electric charges and resulting electromagnetic radiation is key to answering this question. While some radiation, like UV light and X-rays, can be dangerous, most of the radiation emitted by human technology, such as mobile phones and household appliances, is harmless. However, some studies have suggested possible long-term harm from constant exposure to weak electromagnetic radiation. The debate surrounding this issue highlights the importance of reliable scientific studies and responsible communication of findings. Learning about the effects of electromagnetic radiation can help students make informed decisions about their technology use and contribute to ongoing scientific research.

Scientists have developed a simple and low-cost method to break down almost a dozen types of "forever chemicals" known as PFAS, which have contaminated virtually every drop of water on the planet and are associated with certain cancers and thyroid diseases. By using a chemical guillotine and common solvents and reagents, they severed the molecular bonds in PFAS, gradually nibbling away at the molecule until it was gone, leaving behind only safe byproducts. This breakthrough could eventually make it easier for water treatment plants to remove PFAS from drinking water.

Tardigrades, also known as water bears, can survive extreme environments by entering a state of suspended animation and revitalizing decades later, and a UCLA chemist used this mechanism to develop a polymer called pTrMA that stabilizes drugs at high temperatures and over extended periods. This innovation could improve drug access, reduce waste, and save lives.

Think cold weather is only dangerous in extreme conditions? Think again. Research from the University of South Wales shows that even mild temperatures like 10°C can have a profound impact on the heart, lungs, and brain. Explore the science behind cold environments and their effects on the body in this eye-opening experiment.

Chemistry is an exciting field that involves the study of the composition, structure, and properties of matter. It is a field that explores the science behind everyday materials and phenomena. If you have an interest in science, problem-solving, and innovation, then a career in chemistry may be perfect for you! In a chemistry career, you could work in a variety of industries, including pharmaceuticals, food and drink, cosmetics, energy, and materials science. For example, you could work in drug development, designing new materials for use in batteries or electronic devices, or developing new food products with unique flavors and textures. You could also work in research, where you might study the properties of new materials or develop new chemical processes. Typical duties in a chemistry career include conducting laboratory experiments, analyzing data, writing reports, and presenting findings to colleagues. There are also many areas of specialization within chemistry, including analytical chemistry, organic chemistry, physical chemistry, and biochemistry. Other related fields include chemical engineering, environmental science, and materials science. To become a chemist, you typically need a bachelor's degree in chemistry or a related field. Popular undergraduate programs and majors include chemistry, biochemistry, and chemical engineering. Additionally, graduate education is often necessary for advanced positions in research and development. Helpful personal attributes for a chemistry career include a strong aptitude for math and science, attention to detail, and problem-solving skills. It's also important to have excellent communication and teamwork skills, as well as a passion for learning and a commitment to ongoing education. Job prospects for chemists are strong, with many opportunities available in both the public and private sectors. Notable potential employers include companies such as Pfizer, Dow Chemical, and DuPont, as well as government agencies such as the Environmental Protection Agency and the National Institutes of Health.

Plastics have become ubiquitous in our daily lives, but few of us know the history behind this versatile material. The first plastic was created in 1863 by an American named John Wesley Hyatt, who invented celluloid, made from cellulose found in wood and straw. This discovery led to a cascade of new plastics, including bakelite, polystyrene, polyvinyl chloride, acrylics, and nylon. Plastics have replaced other materials like wood, glass, and fabric in furniture, clothing, and packaging. While plastics have brought convenience and cost-effectiveness, they have also created staggering environmental problems. Many plastics are made of nonrenewable resources, and plastic packaging was designed to be single-use, but some plastics take centuries to decompose, creating a huge buildup of waste. By learning about plastics, students can understand how science and innovation have shaped our world, and they can explore ways to address the environmental problems associated with plastic use.

New research has identified gold-based compounds that could treat multidrug-resistant "superbugs", with some effectiveness against several bacteria. Antibiotic resistance is a global public health threat, and the development of new antibiotics has stalled. Gold metalloantibiotics, compounds with a gold ion at their core, could be a promising new approach. Dr. Sara M. Soto Gonzalez and colleagues studied the activity of 19 gold complexes against a range of multidrug-resistant bacteria isolated from patients. The gold compounds were effective against at least one bacterial species studied, with some displaying potent activity against several multidrug-resistant bacteria.

Are you interested in learning about a new antimicrobial coating material that can effectively kill bacteria and viruses, including MRSA and Covid-19? Researchers at the University of Nottingham's School of Pharmacy have used a common disinfectant and antiseptic to create this new material that could be used as an effective antimicrobial coating on a range of plastic products. This new study, published in Nano Select, offers an effective way to prevent the spread of pathogenic microorganisms and address the ever-increasing threat of antimicrobial resistance. Read more to find out how this material was created and how it can help in hospital settings.

Sharks may have a key to the future of soft robotics and medical implants. Physicists have discovered how sharks' spiral-shaped intestines work, which led them to 3D print models of the structures to study their fluid dynamics. They found that the soft, elastic materials led to faster fluid flow in one direction, contrary to a basic physics theorem. This discovery could inspire the development of soft robots and medical devices that can deform in different ways, just like an octopus.

Did you know that the oldest glue in the world is over 8,000 years old and comes from a cave near the Dead Sea? Ancient people used this glue, made from a mixture of animal bone and plant materials, to waterproof baskets and construct utensils. Today, we have enough types of tape and glue to build and repair almost anything. But have you ever wondered what gives glue and tape their stickiness? Adhesives can be made from synthetic molecules or natural proteins and carbohydrates. In order to work, glue and tape need both adhesive bonds and cohesive bonds. Glue is stronger than tape in terms of absolute strength of adhesive bonds, but no single adhesive works well in all circumstances. Engineers weigh similar factors all the time. Choosing the right glue to withstand the heat inside an engine is a matter of life and death. And though the strength of duct tape's adhesive bonds can't compete with those of epoxy glues, tape does have the advantage of instantaneous stickiness in an emergency. Learning about adhesives can help you understand how things are constructed and repaired, and can even save lives in certain situations.

Plastics are everywhere, and most of them never biologically degrade. This is a major problem for our environment, as plastic waste pollutes natural ecosystems for centuries. Fortunately, there are microbes that may be able to help us solve this growing problem. Scientists have discovered bacteria, also known as plastivores, that contain enzymes capable of breaking down PET polymers, a common type of plastic. However, we still need ways to biologically degrade all the other types of plastic, including abundant PEs and PPs. Researchers are looking for more heat-tolerant plastivores in the planet's most hostile environments and engineering better plastivorous enzymes in the lab. As students, you have the opportunity to learn about this important issue and contribute to finding solutions. By exploring the science behind plastic degradation, you can gain a deeper understanding of how to protect our environment and create a more sustainable future.

Nanotechnology is a fascinating field of study that explores the science of the very small. Imagine being able to manipulate and control matter at the atomic and molecular level! This is the world of nanotechnology. It is a highly interdisciplinary field that combines physics, chemistry, biology, and engineering to create new materials, devices, and systems that have the potential to revolutionize our world. One of the most exciting aspects of nanotechnology is the potential for new and innovative products that can improve our lives in countless ways. For example, scientists are currently researching how to use nanotechnology to develop new drug delivery systems, create more efficient solar panels, and even build tiny robots that can be used for medical purposes. Some of the most inspiring academic discourse in nanotechnology has come from researchers like Richard Smalley, who won the Nobel Prize in Chemistry for his work on carbon nanotubes, and Sumio Iijima, who discovered the first carbon nanotubes. Their groundbreaking research has paved the way for countless other scientists to explore the possibilities of nanotechnology. If you're interested in studying nanotechnology at the undergraduate level, you can expect to take courses in subjects like nanomaterials, nanoelectronics, and nanobiotechnology. You'll also have the opportunity to specialize in areas like nanomedicine or nanophotonics, depending on your interests. The potential career paths for someone with a degree in nanotechnology are vast and varied. You could work in industries like electronics, energy, or healthcare, developing new products and technologies that could change the world. Some specific examples of potential employers include Intel, IBM, and General Electric. To succeed in the field of nanotechnology, you'll need a strong background in science and math, as well as excellent critical thinking and problem-solving skills. You'll also need to be creative and innovative, as the field is constantly evolving and new discoveries are being made all the time. If you're interested in exploring the world of nanotechnology further, there's no better time to start than now. With so much potential for innovation and discovery, it's an exciting field that is sure to inspire and challenge you for years to come.