Join Imperial College London, France's National Centre for Scientific Research (CNRS), and the University of Lille in discovering new ways to tackle metabolic diseases, such as diabetes, hypertension, and obesity. The Integrative Metabolism International Research Project (IRP) will utilize artificial intelligence and machine learning to develop new drugs and treatments. The team aims to create a 'Google Earth' of metabolism and predict disease trajectories, advancing precision medicine. Led by Professor Mark Thursz at Imperial and Professor Marc-Emmanuel Dumas at the University of Lille's and CNRS's European Genomic Institute for Diabetes (EGID), this interdisciplinary project will deepen our understanding of metabolism's role in the body and revolutionize treatment for millions of people worldwide.

A new AI system that can diagnose dementia after a single brain scan is being tested. This system may also be able to predict the progression of the disease, improving patient outcomes and potentially avoiding further damage.

Uncover the Divine Power of Artificial Intelligence: Meet Sybil, the new AI tool for predicting lung cancer risk developed by researchers at MIT, Mass General Cancer Center and Chang Gung Memorial Hospital.

Did you know that every time you visit the doctor or take a medication, you are contributing to the vast amounts of health data that are collected and analyzed? Thanks to advances in technology and the rise of big data, these massive amounts of information are now being used to revolutionize the field of medicine, and the results are nothing short of incredible. Data-driven medicine is the practice of using vast amounts of health-related data to improve patient outcomes and healthcare delivery. By analyzing large amounts of patient information, healthcare providers can identify patterns and trends that would be impossible to detect otherwise. This information can be used to develop personalized treatment plans, predict disease outbreaks, and even prevent illnesses before they occur. One area where data-driven medicine has already made a significant impact is in cancer treatment. Thanks to the analysis of genetic data, doctors can now tailor treatments to individual patients based on their specific genetic profile, resulting in better outcomes and fewer side effects. In fact, the use of data-driven medicine in cancer treatment has already led to a 30% reduction in mortality rates. But data-driven medicine isn't just about treating disease. It's also about preventing it. By analyzing patient data, healthcare providers can identify risk factors for certain diseases and take steps to prevent them from developing. For example, doctors can use patient data to identify individuals who are at high risk for heart disease and develop personalized prevention plans that include exercise, diet changes, and medication. Leading academics in the field of data-driven medicine include Dr. Atul Butte, a professor of pediatrics and biomedical informatics at Stanford University, and Dr. Eric Topol, a professor of molecular medicine and the executive vice-president of Scripps Research. Both researchers have made significant contributions to the field, including the development of innovative data-driven tools and techniques that are transforming the way we approach healthcare. Remember, the key to success in exploring academic topics is to be curious, ask questions, and be willing to learn. With data-driven medicine, the possibilities are endless, and the potential to make a real difference in people's lives is huge.

Are you fascinated by the inner workings of the human body? Do you have a passion for technology and problem-solving? If so, a career as a Radiologic Technologist might just be the perfect fit for you! Radiologic Technologists are healthcare professionals who use imaging equipment to capture images of the body's internal structures. These images are then used by physicians to diagnose and treat a wide range of medical conditions. As a Radiologic Technologist, you'll have the opportunity to work with patients of all ages and backgrounds, making a real difference in their lives. One of the most appealing aspects of this field is the variety of specializations available. From diagnostic imaging to radiation therapy, Radiologic Technologists can choose to focus on a specific area of interest. This means that there's always something new to learn and explore! To become a Radiologic Technologist, you'll typically need to complete a two-year associate's degree program in Radiologic Technology. Many colleges and universities also offer four-year bachelor's degree programs in Radiologic Sciences, which can lead to more advanced positions in the field. In addition to formal education and training, there are several personal attributes that can help you succeed as a Radiologic Technologist. These include strong communication skills, attention to detail, and the ability to work well under pressure. Job prospects for Radiologic Technologists are excellent, with the field expected to grow by 9% over the next decade. This means that there will be plenty of opportunities for graduates to find rewarding and challenging positions in a variety of settings, including hospitals, clinics, and imaging centers. Some of the most notable and attractive potential employers in the field include the Mayo Clinic, Cleveland Clinic, and Johns Hopkins Hospital. These institutions are known for their commitment to innovation and excellence, and offer Radiologic Technologists the chance to work with some of the most advanced imaging equipment in the world. So if you're looking for a career that combines technology, healthcare, and problem-solving, consider becoming a Radiologic Technologist. With its many specializations, excellent job prospects, and potential for growth and advancement, it's a field that offers something for everyone!

Artificial Intelligence (AI) is transforming the healthcare industry in ways we never imagined. AI has the potential to revolutionize the way we diagnose, treat, and prevent diseases. With the help of AI, medical professionals can now analyze large amounts of data in seconds, making the process of diagnosing and treating patients much more efficient. Leading academics such as Dr. Eric Topol, a cardiologist and digital health pioneer, have been working on incorporating AI into healthcare for years. For example, Dr. Topol has been working on developing AI algorithms that can help diagnose diseases from scans and images, reducing the need for invasive procedures. He has also been studying the use of AI in personalized medicine, where AI can help predict the best treatment for a patient based on their specific genetic makeup. Statistics show that AI is already having a positive impact on healthcare. In 2019, researchers used AI to diagnose skin cancer with accuracy comparable to human dermatologists. Another study found that AI could help detect breast cancer up to five years before a traditional mammogram. These are just a few examples of how AI is changing the face of healthcare. AI is also helping healthcare professionals work more efficiently. For example, AI algorithms can quickly analyze medical records and help doctors identify patients who need immediate attention. This saves time and reduces the risk of missing critical information.

Florence Nightingale, known as the "lady with the lamp" for her work as a nurse during the Crimean War, was also a trained statistician who believed that statistics were "God's work." She used her knowledge of statistics to revolutionize the way hospitals were run by collecting data and showing that changes in diet and sanitation could bring the death rate down. Florence's work laid the groundwork for things we now take for granted, like being able to compare hospitals' performance and the fact that hospitals are clean. By following evidence instead of gut instinct, prejudice, or tradition, Florence showed what could be achieved. She turned data into pictures, making it impossible for MPs and civil servants to ignore. Florence would love the way big data makes all this possible but would hate some of the ways that data are abused. By learning about statistics and data, students can follow in Florence's footsteps to make the world a better place and shine a little more light on us all.

Stanford University researchers, in collaboration with other institutions, have developed a molecule that prevents the spike protein of the SARS-CoV-2 virus from twisting and infecting cells, including those with new variants. This new type of antiviral therapeutic, called the longHR2\_42 inhibitor, may be delivered via inhaler to treat early infections and prevent severe illness. The team's detailed understanding of the twisted structure of the virus's spike protein allowed them to create a longer molecule that is more effective than previous attempts to block the virus. Their groundbreaking research may lead to a promising solution to combat COVID-19.

Are you interested in science and making a difference in people's lives? A career in pharmaceutical research might be just what you're looking for! Pharmaceutical research is an exciting field that involves discovering and developing new drugs and therapies to treat and cure diseases. As a pharmaceutical researcher, you will have the opportunity to work on cutting-edge research projects that could change the lives of millions of people. For example, did you know that the development of the COVID-19 vaccines is a result of years of pharmaceutical research? You could be part of the next breakthrough in medicine! In this field, your typical duties will include conducting laboratory experiments, analyzing data, developing new drugs, and testing their safety and effectiveness. You may also specialize in a particular area, such as drug design, pharmacology, or clinical research. To become a pharmaceutical researcher, you will need to pursue a degree in a relevant field, such as chemistry, biology, or pharmacology. Popular undergraduate programs and majors include Biochemistry, Pharmaceutical Sciences, and Medicinal Chemistry. A graduate degree in pharmaceutical research is also highly desirable and may be required for some positions. Helpful personal attributes for this field include strong critical thinking skills, attention to detail, and excellent communication skills. A passion for science and a desire to make a difference in the world are also important. The job prospects for pharmaceutical researchers are promising. With the aging population and increasing demand for new drugs and therapies, the demand for skilled researchers is expected to grow. Notable and attractive potential employers in this field include pharmaceutical companies such as Pfizer, Merck, and Novartis, as well as government agencies such as the National Institutes of Health (NIH) and the Food and Drug Administration (FDA).

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.

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.

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.

Ballet dancers can perform pirouettes without feeling dizzy. Researchers found that years of training enable dancers to suppress signals from the balance organs in the inner ear. This discovery could help improve treatment for patients with chronic dizziness. The study also revealed differences in brain structure between dancers and non-dancers. Discover the secrets of dancers' brains and how it could lead to better treatment for chronic dizziness.

NYU Wagner researchers are using a massive dataset to uncover how policies and social conditions affect the health of New Yorkers. The unique access they have to Medicaid-related information has allowed them to make groundbreaking findings, including the negative health impacts of living under La Guardia Airport's takeoff paths and the positive effects of universal pre-kindergarten programs on children's vision. Their work also sheds light on the health impacts of evictions and incarceration, and the potential benefits of paid sick leave policies. With "virtually limitless" potential, the Medicaid Data Initiative promises to offer important insights for policy makers and researchers alike.

An interdisciplinary UCLA research team has developed a tiny implantable device called SymphNode, which has been shown to be able to drive tumours into remission, eliminate metastasis, and prevent the growth of new tumours, resulting in longer survival in mice. This groundbreaking technology may decrease the risk of cancer returning, making it a potential addition to chemotherapy or other first-step treatments for a variety of cancers.

Want to know the secret to successful and sustainable weight loss? According to a recent study by Stanford Medicine researchers, it's all about the bacteria in your gut and the biomarkers in your body! The study found that certain gut microbiome ecologies and amounts of proteins can predict whether you will be successful at losing weight and keeping it off. So, are you ready to unlock the power of your gut and biomarkers for weight loss success?

Have you ever wondered what it takes to be a heart doctor? Well, look no further because we've got the inside scoop on the exciting and rewarding field of cardiology! As a cardiologist, you'll be responsible for diagnosing and treating heart conditions, helping patients live longer, healthier lives. From heart attacks to arrhythmias, you'll have the knowledge and skills to provide life-saving care to those in need. But being a cardiologist isn't just about saving lives, it's also about preventing heart disease. You'll work with patients to develop healthy habits and manage risk factors, like high blood pressure and high cholesterol. And the best part? The field of cardiology is constantly evolving, with new treatments and technologies being developed all the time. You'll have the opportunity to stay at the forefront of medical advancements and make a real difference in the lives of your patients. Typical duties of a cardiologist include performing diagnostic tests, like electrocardiograms and echocardiograms, prescribing medication and lifestyle changes, and performing procedures like angioplasty and stenting. There are also many areas of specialisation within the field, such as electrophysiology and interventional cardiology. To become a cardiologist, you'll need to complete extensive education and training. This typically includes a bachelor's degree in a relevant field, such as biology or chemistry, followed by medical school and a residency in internal medicine. After that, you'll complete a fellowship in cardiology, where you'll gain specialised knowledge and skills. Helpful personal attributes for a career in cardiology include strong communication skills, attention to detail, and a passion for helping others. You'll also need to be able to work well under pressure and make quick decisions in life-or-death situations. Job prospects for cardiologists are excellent, with a growing demand for heart specialists around the world. Some notable potential employers include the Mayo Clinic, Cleveland Clinic, and Johns Hopkins Hospital, among many others. So, if you're looking for a challenging and rewarding career that allows you to make a real difference in the lives of others, consider becoming a cardiologist. Your heart (and your patients' hearts) will thank you!

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.

Get ready for a game-changing medical innovation! Engineers from MIT have developed a biocompatible tissue glue inspired by barnacles that can quickly stop bleeding and seal wounds in a matter of seconds. This new paste could revolutionize the way we treat traumatic injuries and control bleeding during surgeries.

Have you ever had a moment of inspiration that led to a groundbreaking invention? In 1816, a doctor named René Laennec had just that moment while walking through Paris. He observed children using a long piece of wood to amplify sound and later used this concept to create the stethoscope. By placing a rolled-up sheet of paper to a young woman's chest, he was able to hear her heartbeat with clarity. Laennec spent three years perfecting his invention, which eventually became the forerunner to the stethoscopes we still use today. Learning about the development of the stethoscope not only expands your knowledge of medical history but also inspires you to think creatively and use everyday observations to solve complex problems.