Did you know that selecting the embryo with the lowest risk for a given disease can cut the risk for that disease by almost half? This is particularly true for disorders such as schizophrenia and Crohn’s disease. However, the selection process may not lead to significant improvements in non-disease traits such as intelligence. Moreover, the use of preimplantation genetic screening (PES) raises concerns about psychological well-being, social values, and ethics. Learn more about the potential benefits and risks of PES, and how it may impact our society and individuality.

In "The Neuroscientist Who Lost Her Mind," author Lipska takes readers on a journey through her own brain, as she battles metastatic melanoma and experiences symptoms of mental disorders such as schizophrenia. With her scientific knowledge, Lipska is able to identify the changes in her brain during treatment, providing a unique perspective on the intersection of neuroscience and cancer. Her memoir is a testament to the power of strength, courage, and a supportive network in the face of illness. Recommended for those interested in neuroscience, cancer research, and mental health, "The Neuroscientist Who Lost Her Mind" offers a unique perspective on the impact of cancer on the brain. Lipska's personal experience highlights the importance of a strong support system and the resilience of the human brain. This memoir will be particularly relevant to those in the medical field, as well as patients and caregivers dealing with cancer and its effects on the mind and body.

HIV, the virus that causes AIDS, is a master of disguise. It can change its outer coat of proteins frequently, making it hard for the immune system to recognise and destroy it. HIV targets Helper T cells, which act as the air traffic controllers of the immune system, coordinating the efforts of other immune cells. If Helper T cells disappear, the whole immune system would have trouble fighting not just HIV but many other illnesses as well. Boosting the immune system against HIV requires getting the Helper T cells back in control. Learning about the immune system and how it works can help you understand how HIV affects the body and how to boost your immune system against it. By exploring this topic through reading, reflection, writing and self-directed projects, you can gain a deeper understanding of the immune system and how to protect yourself from harmful intruders like viruses and bacteria.

UCLA scientists have identified how immune cells detect and respond to cancer cells, leading to better personalized immunotherapies for patients who do not respond to treatment. Checkpoint inhibitors improve T cells' ability to recognize and attack cancer cells, and the study showed that when immunotherapy is effective, it directs a diverse repertoire of T cells against a small group of selected mutations in a tumor. The researchers adapted advanced gene-editing technology to make unprecedented observations about immune responses in patients with metastatic melanoma receiving anti-PD-1 "checkpoint inhibitor" immunotherapy.

A groundbreaking study by the University of Oxford as part of the UK's 100,000 Genomes Project has defined five new subgroups of chronic lymphocytic leukaemia (CLL) and linked these to clinical outcomes, paving the way for more personalized patient care. This is the first study to analyze all the relevant changes in DNA across the entire cancer genome!

As we grow older, our bodies undergo many changes, including changes in our metabolism. Metabolism refers to the chemical processes that occur in our bodies to maintain life. These processes are essential for providing energy, building and repairing tissues, and eliminating waste products. As we age, our metabolic pathways can become altered, leading to various age-related diseases and conditions. One example of a metabolic pathway that is affected by aging is the mitochondrial electron transport chain (ETC). The ETC is responsible for producing ATP, the primary source of energy for our cells. As we age, the function of the ETC can become impaired, leading to a decrease in ATP production and an increase in oxidative stress. This can contribute to age-related diseases such as Alzheimer's disease, Parkinson's disease, and diabetes. Another example is the mTOR (mechanistic target of rapamycin) pathway, which regulates cellular growth and metabolism. Studies have shown that inhibiting the mTOR pathway can increase lifespan in various model organisms, including mice. This has led to increased interest in developing drugs that target this pathway as a potential anti-aging strategy. One of the leading academics in this field is Dr. David Sinclair, a Professor of Genetics at Harvard Medical School. Dr. Sinclair's research has focused on the role of metabolism in aging and age-related diseases, and he has made significant contributions to the field. For example, his research has shown that supplementing with NAD+, a molecule involved in energy metabolism, can improve various aspects of aging in mice. Another leading academic in this field is Dr. Valter Longo, a Professor of Gerontology and Biological Science at the University of Southern California. Dr. Longo's research has focused on the role of fasting and caloric restriction in aging and age-related diseases. His work has shown that periodic fasting can have a range of health benefits, including improving insulin sensitivity and reducing inflammation. In conclusion, the study of metabolic pathways in aging is a fascinating and rapidly growing field. By understanding the complex interplay between metabolism and aging, we can better understand the underlying causes of age-related diseases and conditions. Students who are interested in this topic can continue to explore it through reading and research, or by pursuing their own experiments and projects. With the right tools and resources, they can make meaningful contributions to this exciting field and help improve our understanding of aging and metabolic pathways.

Childhood cancer is a devastating disease that affects thousands of children every year. However, as cancer is more likely to occur in adults rather than children, research on childhood cancer is often underfunded, leading to fewer treatment options and lower survival rates. One of the biggest challenges in treating childhood cancer is the risk of long-term side effects from chemotherapy and radiation. These treatments can cause developmental delays, learning disabilities, and even secondary cancers later in life. As a result, new treatment strategies are being developed to minimize these risks. One of the most promising new approaches is immunotherapy, a type of treatment that harnesses the power of the immune system to attack cancer cells. CAR T-cell therapy, in which T-cells are genetically engineered to recognize and attack cancer cells, has shown particularly promising results in clinical trials. Another challenge in treating childhood cancer is the lack of targeted therapies. Unlike adult cancers, childhood cancers often have no known driver mutations that can be targeted with precision medicine. Researchers are working to identify new drug targets and develop new treatments that can attack cancer cells while sparing healthy cells. Dr. Kimberly Stegmaier, an oncologist and researcher at the Dana-Farber Cancer Institute, is one of the leading experts in childhood cancer research. She and her team are working to identify new drug targets and develop targeted therapies for childhood cancers. They are also studying the genetic and molecular characteristics of childhood cancers to better understand how they develop and how they can be treated. In conclusion, childhood cancer presents unique challenges that require innovative solutions. While underfunded research and the lack of targeted therapies have made progress difficult, recent developments in immunotherapy, such as CAR T-cell therapy, show promising results. As we continue to fight for a cure, let us also remember the children and families affected by this disease and strive to support them in any way we can.

Organ transplants are a life-saving medical breakthrough that have revolutionized the field of medicine. Kidneys are essential organs that filter waste material from the blood and process it into urine. A typical dialysis patient has a poorer life expectancy than many cancers. Removing one kidney should not affect someone's lifespan or quality of life. A kidney from a living donor in general will have a much better quality because it comes from a healthy and tested person. Kidneys are expected to survive up to twice as long on average in the recipient. Currently, it's not allowed to donate a kidney under any form of payment. However, incentivizing people to donate more is actually a way to starve black markets. It's not to recreate them, it's to undermine them. If you reward a person amply for the sacrifice they've made, something they go into with their eyes open and well informed, that's not exploitation. Organ donation is an incredible gift that can save someone's life so palpably, and everyone should consider donating.

Scientists have developed a groundbreaking treatment for blood cancer using off-the-shelf T-cells. The CALM clinical trial evaluated the potential of UCART19, an "off-the-shelf" CAR-T cell product, against adult patients with B-ALL. The results were recently published in The Lancet Haematology and Cancer Research Communications, showing that 48% of treated patients achieved complete remission lasting an average of 7.4 months. This new approach offers a more efficient and effective alternative to traditional CAR-T cell therapy, providing hope for patients with relapsed or treatment-resistant blood cancers.

Are you interested in pursuing a career that enables you to make a difference in people's lives while helping them? The field of surgery may be the ideal fit for you! Surgeons are highly skilled medical professionals responsible for performing operations to cure and treat a wide range of diseases and injuries. Let's delve deeper into what it takes to build a career in surgery. As a surgeon, your primary responsibility is to perform surgeries and other medical procedures to diagnose and treat various ailments and conditions. You'll be working with patients of all ages, from infants to the elderly, in several specializations, including neurosurgery, orthopedic surgery, plastic surgery, cardiothoracic surgery, and more. One of the most compelling aspects of a career in surgery is the chance to have a significant and long-lasting impact on people's lives. For example, as a neurosurgeon, you can perform life-saving brain surgeries, while as a plastic surgeon, you can help boost someone's confidence and self-esteem by fixing their physical defects. To become a surgeon, you'll need to earn a medical degree, complete a residency program, and get a state license. The entire process of education and training may take up to 14 years, including undergraduate studies in biology, chemistry, or pre-med. Excellent manual dexterity, communication and interpersonal skills, and the ability to work under pressure are essential qualities for success in this field. Attention to detail, critical thinking, and problem-solving skills are equally vital. The job prospects and long-term outlook for surgeons are favorable, with an expected job growth of 4% over the next decade. Surgeons are in high demand worldwide, with hospitals, private clinics, research institutions, and government agencies being some of the potential employers. Numerous top-notch organizations are looking for talented surgeons to join their teams, including the Mayo Clinic, Johns Hopkins Hospital, Cleveland Clinic in the USA, the Royal London Hospital in the UK, and St. Vincent's Hospital in Australia. In conclusion, if you're looking for a fulfilling and exciting career that allows you to make a difference in people's lives while working in a challenging and rewarding field, surgery may be the perfect career path for you. Take the time to explore this field further and see if it's the right choice for you!

Cancer is a mysterious and deadly disease that claims the lives of 1500 Americans every day. But why is it so common, and why does treatment often fail? In "Cancer: The Evolutionary Legacy", leading researcher Mel Greaves offers clear and convincing answers to these questions by looking at cancer through a Darwinian lens. Greaves argues that human development has trapped us in a nature-nurture mismatch, causing cancer to thrive. With compelling examples from history and modern research, this fascinating book sheds light on the evolutionary context of cancer and its implications for prevention and treatment. Recommended for biology students, medical professionals, and anyone interested in the evolutionary origins of disease, "Cancer: The Evolutionary Legacy" offers a fresh perspective on this complex and elusive disease. With its lucid and engaging style, this book is accessible to readers of all backgrounds and provides a comprehensive overview of cancer research and treatment. Additionally, those interested in the history of medicine and public health will find the compelling examples from history, including the epidemic of scrotal skin cancer in 18th-century chimney sweeps, to be particularly interesting.

Get ready to revolutionize the way we treat cancer and age-related diseases! A new company, GlioQuell, co-founded by Dr. Kambiz Alavian from the Department of Brain Sciences, is developing a cutting-edge approach to target the powerhouses of cancer cells - the mitochondria. By reducing the efficiency of these structures, GlioQuell aims to turn off the cancer cells' energy supply and treat one of the most aggressive forms of cancer - glioblastoma.

Medical research is a fascinating field of study that explores the complexities of the human body and its many diseases. It's an exciting area of research that is constantly evolving, with new discoveries and innovations being made every day. One of the most appealing aspects of medical research is the potential to make a real difference in people's lives. Researchers in this field are at the forefront of developing new treatments and therapies for a wide range of illnesses, from cancer to Alzheimer's disease. One example of groundbreaking research in this field is the development of immunotherapy, a treatment that harnesses the power of the immune system to fight cancer. This innovative approach has already helped to save countless lives and is just one example of the many exciting breakthroughs being made in medical research. At the undergraduate level, students can expect to take a variety of modules that cover topics such as genetics, molecular biology, and epidemiology. These modules provide a solid foundation in the basic principles of medical research and prepare students for further specialisation in areas such as cancer research or infectious diseases. Potential future jobs and roles in medical research include positions as research scientists, clinical trial coordinators, and medical writers. There are also many opportunities to work in public health or in the pharmaceutical industry, with notable employers including the National Institutes of Health, Pfizer, and GlaxoSmithKline. To succeed in this field of study, students should have a strong interest in science and a passion for helping others. They should also possess excellent analytical and critical thinking skills, as well as the ability to work independently and as part of a team. Overall, the study of medical research is an exciting and rewarding field that offers endless possibilities for those who are passionate about making a difference in the world of healthcare.

Genome-edited CAR T-cells treated a young patient's incurable T-cell leukaemia, leading to complete remission after just 28 days. Designed and developed by researchers at UCL and GOSH, the treatment represents a cutting-edge approach that paves the way for other new treatments and ultimately better futures for sick children.

Genetic sequencing has revolutionized healthcare but the genomic gap, where over 86% of data is from white Europeans, is exacerbating healthcare inequalities. Discover how this gap leads to adverse drug reactions and inaccurate genetic tests for ethnic minority groups. Explore the urgent need for reinvestment to narrow the gap and provide accurate genomic information for all.

Vaccines are likely the most important public health intervention of the last 100 years, having saved over a billion lives. They have led to a massive reduction in child mortality in sub-Saharan Africa and can even prevent cancer. A world without vaccines would be unimaginable, with outbreaks of disease regularly all over the world. Vaccines are the only public health intervention that can bring equality, as they protect not only oneself but also one's family and community. While anti-vaccination fears have been around for over a century, it's important to engage with people where they are and understand their context, concerns, and experiences with health and vaccines. Taking a vaccine is not just a personal choice, but a moral choice that affects other people. Vaccines are fundamental to the privileges we have in the modern world and make it a safe place for most of us to be.

Have you ever heard of the placebo effect? It's a fascinating phenomenon that can make you feel better, even if you're not taking any real medication. The placebo effect is the power of the mind to influence the body's physical and emotional responses. It has been the subject of much research and debate in the medical community, and its potential applications are vast and varied. One of the most well-known examples of the placebo effect is in the field of pain relief. Studies have shown that even when patients are given a sugar pill instead of a painkiller, they can still experience significant pain reduction. In fact, one study found that the placebo effect can be just as powerful as morphine! The placebo effect is not just limited to pain relief, however. It has been shown to be effective in treating a wide range of conditions, from depression and anxiety to Parkinson's disease and even irritable bowel syndrome. And it's not just limited to humans - animals can also experience the placebo effect! So how does the placebo effect work? One theory is that it activates the body's natural healing mechanisms, such as the release of endorphins and other feel-good chemicals. Another theory is that it creates a sense of expectation and anticipation, which can influence the way we perceive and interpret pain and other symptoms. Some leading academics in the field of placebo research include Harvard professor Ted Kaptchuk, who has conducted extensive studies on the placebo effect in pain management, and Dr. Fabrizio Benedetti, a neurophysiologist at the University of Turin in Italy, who has explored the neurobiological mechanisms underlying the placebo effect. The placebo effect is a fascinating and complex topic that offers a wealth of opportunities for exploration and discovery. Whether you're interested in psychology, neuroscience, medicine, or culture, there's something for everyone in the world of placebo research!

If you're looking for a field of study that is both fascinating and essential to our everyday lives, then look no further than Microbiology! Microbiology is the study of microscopic organisms such as bacteria, viruses, fungi, and algae. It is a field that has a significant impact on our health, food, environment, and much more. One of the most appealing aspects of Microbiology is that it has a direct impact on our daily lives. For example, microbiologists play a critical role in developing vaccines, antibiotics, and other treatments for infectious diseases. They also work to ensure the safety of our food supply by monitoring for harmful bacteria and other microorganisms. In terms of research and innovation, Microbiology is a field that is constantly evolving. There are always new discoveries being made, such as the recent development of CRISPR-Cas9 gene editing technology. Microbiology also has a rich history, with notable figures such as Louis Pasteur and Robert Koch making groundbreaking contributions to the field. At the undergraduate level, students can expect to take courses in areas such as microbial genetics, immunology, and virology. There are also opportunities for further specialization, such as studying environmental microbiology or medical microbiology. Real-life examples of exciting careers in Microbiology include working as a clinical microbiologist, a food microbiologist, or a research scientist. There are a range of potential future jobs and roles that this field of study might be directly helpful for, including working in public health, biotechnology, pharmaceuticals, and more. Notable employers in the field include the Centers for Disease Control and Prevention (CDC), the World Health Organization (WHO), and pharmaceutical companies such as Pfizer and Merck. To succeed in Microbiology, students should have a strong interest in science and a natural curiosity about the world around them. They should also be detail-oriented, analytical, and have excellent problem-solving skills. Overall, studying Microbiology is an exciting and rewarding experience that has the potential to make a real difference in the world. So if you're interested in a field that combines cutting-edge research with practical applications, then Microbiology might just be the perfect fit for you!

Have you ever considered a career that involves helping people regain their independence and improve their quality of life? If so, then studying Occupational Therapy at university undergraduate level might be the perfect fit for you! Occupational Therapy is a field of study that focuses on helping individuals of all ages who are experiencing physical, mental, or developmental challenges. Whether it's helping a stroke victim regain their mobility or assisting a child with autism to develop their social skills, Occupational Therapists play a vital role in helping people live their lives to the fullest. One of the most appealing aspects of studying Occupational Therapy is the wide range of meaningful and rewarding career opportunities available to graduates. From working in hospitals and rehabilitation centers to schools and private practices, the possibilities are endless. And with an increasing demand for Occupational Therapists in both the public and private sectors, the job outlook is excellent. At the undergraduate level, students typically take courses in anatomy, physiology, psychology, and kinesiology, as well as specialized courses in Occupational Therapy theory and practice. Students also have the opportunity to gain hands-on experience through clinical placements and internships. Innovative research in Occupational Therapy is constantly pushing the boundaries of what is possible. For example, researchers are exploring the use of virtual reality technology to help patients with physical and cognitive impairments regain their skills and independence. And with the increasing focus on mental health and wellness, Occupational Therapists are playing an important role in helping people cope with stress, anxiety, and other mental health challenges. To succeed in this field, it's important to have strong communication and interpersonal skills, as well as a passion for helping others. A background in science, psychology, or social sciences can also be helpful. Some potential employers for Occupational Therapists include hospitals, rehabilitation centers, schools, and private practices. Notable employers include the National Health Service (NHS) in the UK, the Mayo Clinic in the US, and the Royal Children's Hospital in Australia. So, if you're looking for a career that is both challenging and rewarding, consider studying Occupational Therapy at university undergraduate level. It could be the start of a fulfilling and meaningful career helping others.