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.

Revolutionize cancer treatment with a new approach - turning cancer cells into cancer-killing vaccines! Researchers at Brigham and Women's Hospital and Harvard-affiliate are developing a cell therapy that eliminates tumours and trains the immune system to prevent future cancer outbreaks.

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.

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.

Are you interested in learning about the latest advancements in medical research? Then you won't want to miss the BBC's article on the world's biggest human imaging project! Over 60,000 UK volunteers, including the author of the article, have had their brains, bodies, and genomes scanned in order to help predict and prevent diseases like dementia, cancer, and heart disease. With researchers in over 90 countries using this database for health-related studies, the possibilities for new medical breakthroughs are endless. Don't miss out on this fascinating article!

Discover how human evolution has led to unique diseases like knee osteoarthritis, affecting millions worldwide. Professor Terence D. Capellini shares genetic research on the link between bipedalism and knee osteoarthritis, and how identifying high-risk patients at an early age can inform future therapies. Explore the Developmental and Evolutionary Genetics Lab's work and hypotheses published in his 2020 paper "Evolutionary Selection and Constraint on Human Knee Chondrocyte Regulation Impacts Osteoarthritis Risk." Join the Harvard Museums of Science & Culture's ongoing series to learn more.

China's updated regulations on gene editing in humans may not be enough to prevent regulatory negligence and ethical concerns, warns Dr Joy Zhang of Kent University. The regulations set requirements for ethical approval, supervision, and inspection, but experts worry they may not apply to the private sector. Gene editing is a controversial technique that could correct many inherited diseases, but raises the possibility of permanent changes to a person's genetic make-up. The world's leading scientists were stunned when a Chinese scientist claimed to have created the world's first gene-edited babies. This article explores the latest developments in the field of gene editing in China.

Cancer is one of the leading causes of death worldwide and has been the focus of countless scientific studies and research projects. In the field of biochemistry, scientists have made tremendous progress in understanding the underlying mechanisms of cancer and developing new treatments to fight it. One of the most exciting breakthroughs in the field of cancer research has been the discovery of targeted therapies. These treatments are designed to specifically target the genetic mutations that cause cancer, rather than simply killing all rapidly dividing cells, which can lead to side effects. For example, imatinib (brand name Gleevec) is a targeted therapy that was developed to treat chronic myeloid leukemia (CML), and has been incredibly successful in treating this form of cancer. Another area of biochemistry that is making a big impact in the fight against cancer is the study of cancer metabolism. Researchers have found that cancer cells have a unique metabolism that allows them to rapidly divide and grow. By targeting this unique metabolism, scientists are developing new treatments that can specifically target cancer cells, while leaving healthy cells unharmed. One of the leading scientists in the field of cancer metabolism is Dr. Lewis Cantley, a Professor of Cancer Biology at Weill Cornell Medicine. He has made numerous contributions to the field, including the discovery of the PI3K pathway, which is a key player in cancer cell metabolism. By targeting this pathway, scientists are developing new treatments that can effectively fight cancer. So, whether you're a student who is just starting to learn about biochemistry and cancer research, or you're an experienced researcher looking to make an impact in this field, there are countless exciting opportunities to get involved and make a difference. The battle against cancer is a journey through biochemistry that is waiting for you to join!

A team at Massachusetts General Hospital has developed an AI-powered method to detect Alzheimer's disease with 90% accuracy using routinely collected clinical brain images. The model is blind to features of the brain associated with age and can detect Alzheimer's regardless of other variables. The study made substantial steps toward performing this in real-world clinical settings, making a strong case for clinical use of this diagnostic technology.

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.

Cancer is a disease that affects millions of people worldwide and has been a subject of intense research for decades. Thanks to recent advances in cancer treatment, survival rates are on the rise, and more and more people are able to beat the disease. One of the key developments in cancer treatment has been the use of immunotherapy. This approach harnesses the power of the patient's own immune system to fight cancer cells. For example, the drug Keytruda, which was developed by three developers -- Hans van Eenennaam, John Dulos and Andrea van Elsas -- has been shown to be effective in treating several types of cancer, including melanoma and non-small cell lung cancer. Another exciting development in cancer treatment is the use of precision medicine. This approach uses genetic information to tailor treatments to individual patients, increasing their effectiveness and reducing side effects. For example, the drug Gleevec, which was developed by Dr. Brian Druker, has revolutionized the treatment of certain types of cancer (such as acute lymphoblastic leukaemia, chronic myeloid leukaemia, gastrointestinal stromal tumours, and myelodysplastic/myeloproliferative diseases), leading to high cure rates in patients with this disease. Additionally, advances in radiation therapy have also played a major role in the fight against cancer. Today, more precise and targeted radiation treatments are available, reducing side effects and improving outcomes for patients. For example, proton therapy, which was developed by Elekta, uses beams of protons to precisely target cancer cells, minimizing damage to healthy tissue.

Do you have a passion for science, medicine, and technology? Are you interested in exploring the cutting-edge world of biotechnology research? If so, then a career in biotechnology research may be just what you're looking for. Biotechnology research is a field that combines biology and technology to develop new products and processes that improve human health, agriculture, and the environment. This field has the potential to make a huge impact on the world, with applications in everything from gene therapy and personalized medicine to renewable energy and sustainable agriculture. As a biotechnology researcher, you would be responsible for conducting experiments and analyzing data to help develop new biotech products and processes. You might work in a lab, testing new drugs or studying the genetics of a particular disease. You could also work in a manufacturing setting, helping to develop new techniques for producing biofuels or other renewable resources. One exciting example of the impact of biotechnology research is the development of mRNA vaccines, which are currently being used to combat COVID-19. Researchers in this field have also made progress in developing gene therapies for conditions such as cystic fibrosis, sickle cell anemia, and certain types of cancer. There are many potential areas of specialization within biotechnology research, including genetics, microbiology, biochemistry, and molecular biology. You could also choose to focus on specific applications, such as developing new medical treatments, improving agricultural yields, or creating sustainable biofuels. To pursue a career in biotechnology research, you typically need a strong foundation in science and mathematics. Most entry-level positions require at least a bachelor's degree in a relevant field, such as biology, chemistry, or bioengineering. Popular undergraduate programs and majors include Biomedical Engineering, Biology, Biochemistry, and Molecular Biology. In addition to a strong academic background, successful biotechnology researchers typically possess certain personal attributes. These might include a curiosity and passion for science, critical thinking and problem-solving skills, creativity, and the ability to work well in a team. The job prospects for biotechnology researchers are excellent, with strong demand expected to continue in the coming years. There are a wide range of potential employers in both the public and private sectors, including pharmaceutical companies, biotech startups, government agencies, and research institutions. Some notable employers in this field include Pfizer, Moderna, Novartis, and the National Institutes of Health.

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.

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!

Do you have a passion for science and a desire to help people? If so, Optometry may be the perfect field of study for you. Optometry is a branch of medicine that focuses on the eyes and vision. It is a fascinating field that combines science, technology, and patient care to help people see clearly and live their best lives. Optometry is all about helping people to see the world around them. As an optometrist, you will use your knowledge of the eyes and vision to diagnose and treat a range of eye conditions, from simple refractive errors to more complex diseases such as glaucoma and cataracts. You will also help people to maintain their eye health and prevent vision problems from developing. One of the most exciting aspects of Optometry is the constant innovation and research that is taking place in the field. From new technologies that allow for more accurate diagnosis and treatment, to groundbreaking research into the causes and treatments of eye diseases, there is always something new and exciting happening in Optometry. At the undergraduate level, typical majors and modules include anatomy and physiology of the eye, optics, visual perception, and ocular disease. Students will also have the opportunity to gain practical experience through clinical placements and internships. After completing their undergraduate degree, students can go on to specialize in areas such as pediatric optometry, contact lenses, or vision therapy. With a degree in Optometry, there are a range of potential job opportunities available. Optometrists can work in private practice, hospitals, clinics, or for government agencies. Some notable employers in the field include Bausch + Lomb, Johnson & Johnson, and Essilor. To succeed in Optometry, students should have a strong background in science, particularly biology and chemistry. They should also possess excellent communication and interpersonal skills, as they will be working closely with patients on a daily basis. If you are passionate about science and helping people, a degree in Optometry may be the perfect choice for you.

Alzheimer's disease is a debilitating and progressive brain disorder that affects millions of people worldwide. It is a leading cause of dementia, which causes memory loss, difficulty in thinking, and other cognitive and behavioral problems. This write-up aims to provide high school students with a comprehensive overview of Alzheimer's, its global challenges, and innovations that can help us better understand and manage this disease. Alzheimer's disease affects approximately 50 million people worldwide, and this number is projected to triple by 2050. It is a significant health challenge that not only affects individuals but also their families and caregivers. Alzheimer's can lead to a reduced quality of life, an increased risk of mortality, and significant healthcare costs. However, innovative research is helping to unlock the mysteries of this disease, leading to promising treatments and interventions. One of the most exciting innovations in Alzheimer's research is the use of artificial intelligence and machine learning. These technologies can help identify individuals at high risk for Alzheimer's disease, predict disease progression, and develop personalized treatments. Researchers are also exploring the use of stem cells, gene editing, and immunotherapy to treat Alzheimer's disease. Many prominent researchers and academics have contributed significantly to Alzheimer's research. For example, Dr. Atri is a leading expert in the field of cognitive and memory disorders. His research focuses on identifying cognitive and biomarker changes that predict Alzheimer's disease progression. Dr. Bredesen is another prominent researcher who has developed a comprehensive program to prevent and reverse cognitive decline. Alzheimer's disease is a complex and challenging topic, but with innovative research and a commitment to learning, we can better understand and manage this disease. By exploring academic topics related to Alzheimer's, high school students can gain valuable knowledge and make a meaningful impact on this important issue.

Weight loss surgery decreases bile acids linked to higher appetite, but lifestyle changes could mimic the effect. Researchers from King's, the University of Nottingham, and Amsterdam University Medical Centre found that gut microbes play a key role in regulating bile acids and metabolism. The study's results have important implications for targeted interventions for metabolic disorders focused on the gut microbiome. Co-author Professor Tim Spector, the co-founder of personalised nutrition company ZOE, highlights the promise of gut microbiome testing in supporting metabolic health.

We all know how important it is to stay healthy and avoid getting sick. But have you ever wondered about the science behind vaccines? In this video clip, we learn about the key academic concept of how the immune system works to fight off infections and how scientists are working to develop a universal flu vaccine that could protect us against every strain of the flu, even ones that don't exist yet. Learning about this exciting field of research not only expands our knowledge of how vaccines work, but also helps us understand the importance of public health initiatives.

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.

A groundbreaking study from Weill Cornell Medicine has identified four distinct subtypes of autism based on brain activity and behavior. Machine learning was used to analyze neuroimaging data from 299 people with autism and 907 neurotypical individuals, revealing patterns of brain connections linked to behavioral traits. The study shows promise for personalized therapies and new approaches to diagnosis and treatment.