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Explore artificial intelligence, a technology that has taken the world by storm. Learn how it is used in fields like agriculture, drug discovery, and outer space. Elsewhere, get to grips with semi-conductor manufacturing, quantum computing, and biotechnology. Technology Articles Explore artificial intelligence, a technology that has taken the world by storm. Learn how it is used in fields like agriculture, drug discovery, and outer space. Elsewhere, get to grips with semi-conductor manufacturing, quantum computing, and biotechnology. You may also like: Maths , Physics , Engineering Fake science websites Ways fake science websites misinform and misguide readers The evolution of artificial intelligence And its greater role in natural language processor technologies Medical biotechnology Technology in the medical sciences Quantum computing What are its applications? Improving agriculture Revolutionising sustainable agriculture through AI AI in drug discovery Using this technology in drug research Digital disinformation With the use of IT cells Digital innovation in rural farming What are the benefits? AI in space What is artificial intelligence used for in outer space? Radiation therapy to treat cancer Revolutionising patient setup in cancer treatment AI: the good, the bad, and the future A Scientia News Biology group collaboration Photonic integration In semiconductor manufacturing Nanomedicine Tiny solutions for big health problems NHS clinical computer scientist Exploring the day-to-day routine in this new field in healthcare Semi-conductor laser technology The recent advancements Code to cure How bioinformatics and technology helped to develop a vaccine for COVID-19 Virtual reality in healthcare Its potential Mauritius's rise as African leader of mobile networks An in-depth look at the rollout of 5G on the island, and the factors enabling this

In today's fast-paced and often overwhelming world, taking care of our mental well-being is more crucial than ever. In this article, we will explore practical strategies that can easily be incorporated into our day-to-day lives, allowing us to establish a solid foundation for our mental well-being and sustain it in the long run. Go Back Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Empowering your mental health journey with practical strategies Last updated: 22/05/25 Published: 18/05/23 In today's fast-paced and often overwhelming world, taking care of our mental well-being is more crucial than ever. In this article, we will explore practical strategies that can easily be incorporated into our day-to-day lives, allowing us to establish a solid foundation for our mental well-being and sustain it in the long run. 1. Embracing mindfulness Mindfulness is a powerful practice that helps us stay present, cultivate awareness, and manage stress. Imagine starting your day by dedicating a few minutes to mindful breathing or meditation, allowing yourself to set a calm and focused tone for the day. Engage in activities with a mindful mindset, whether it's taking a peaceful walk in nature, relishing a cup of tea, or fully immersing yourself in the present moment. 2. Exercise Physical activity is another essential self-care strategy that not only benefits our physical health but also plays a profound role in nurturing our mental well-being. Find an exercise routine that that brings you joy and that easily fits into your life. Whether it's walking, jogging, yoga, or any other form of movement that resonates with you, the key is to find something you enjoy and can stick to. Even small bursts of exercise throughout the day, like a short walk during your lunch break or opting for the stairs instead of the elevator, can make a significant difference in your overall well-being. 3. Sleep Hygiene Adequate sleep is vital for mental and emotional wellbeing. Establishing good sleep hygiene is crucial. Maintain a consistent sleep schedule by going to bed and waking up at the same time each day. Create a relaxing bedtime routine that signals to your body that it's time to unwind. Consider reading a book, taking a warm bath, or practicing gentle stretches to prepare your mind and body for restful sleep. Ensure your bedroom provides an optimal sleep environment by keeping it dark, quiet, and cool, and minimize exposure to screens before bed. 4. Online mental health platforms In our digital age, online mental health platforms have become invaluable resources for supporting our mental well-being. Platforms like Headspace , Better Help , and Calm offer a range of services, including meditation exercises, therapy sessions with licensed professionals, and stress reduction tools. Exploring these platforms can provide the support and guidance needed on your mental health journey. Self-care apps that can be installed on phones Prioritising self-care is essential for maintaining good mental health. By incorporating these practices into your daily routine, you can nurture your mind, body, and soul. By investing time and energy into yourself, you are fostering a stronger foundation for a happier and healthier life. Written by Viviana Greco Related articles: Physical and mental health / Imposter syndrome in STEM / Mental health in the South Asian community

Conservation, diseases, animal behaviour, adaptation and survival. Expand your knowledge on the incredible diversity of life on Earth with these articles. Zoology Articles Conservation, diseases, animal behaviour, adaptation and survival. Expand your knowledge on the incredible diversity of life on Earth with these articles. You may also like: Biology , and Ecology Deception by African birds The species Dicrurus adsimilis uses deception by flexible alarm mimicry to target and carry out food-theft attempts An experiment on ochre stars Investigating the relative fitness of the species Pisaster ocharceus Orcinus orca A species report Rare zoonotic diseases We all know about COVID-19. But what about the other zoonotic diseases? Article #1 in a series on Rare diseases. Marine iguanas Their conservation The cost of coats 55 years of vicuna conservation in South America. Article #1 in a series on animal conservation around the world. Conserving the California condor These birds live on the west coast of North America. Article #2 in a series on animal conservation around the world. Emperor penguins Kings of ice. Article #6 in a series on animal conservation around the world. Protecting rock-wallabies in Australia A group of 25 animal species, and subspecies related to kangaroos. Article #7 in a series on animal conservation around the world. Do other animals get periods? Looking at menstruation in non-human animals e.g. monkeys, bats Same-sex attraction in non-human animals SSSB in birds, mammals, and invertebrates Changing sex in fish Why some fish change sex during their lifetimes

Rock-wallabies are adapted to occupy specific rocky habitats, like outcrops, cliffs and caves Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Protecting rock-wallabies in Australia Last updated: 06/11/25, 11:54 Published: 29/05/25, 07:00 Rock-wallabies are adapted to occupy specific rocky habitats, like outcrops, cliffs and caves This is the final article (article no. 7) in a series on animal conservation. Previous article: Emperor penguins, kings of ice . First article: 55 years of vicuna conservation . Australia is home to many unique mammals because they have evolved in geographic isolation for millennia. Over 200 years ago, European colonists brought their own mammals to Australia, devastating this unique wildlife in ways that can still be seen today. One example is the rock-wallabies ( Petrogale spp. ), a group of 25 animal species and subspecies related to kangaroos. Australian scientists are monitoring rock-wallaby populations to ensure they remain safe from natural and human-caused threats. This article will describe those threats and how rock wallabies are being conserved. Rock-wallaby habitat As their name suggests, rock-wallabies are adapted to occupy specific rocky habitats, including outcrops, cliffs and caves. Since they are primarily nocturnal, these habitats provide shelter in the daytime. Rock-wallabies have modified foot pads to grip tricky surfaces and access places their predators cannot. Recent research found that for two rock-wallaby species, their abundance is associated with more complex and rocky habitats. Because their habitat type is so niche and they rarely migrate, one small disturbance could wipe out an entire rock-wallaby population. This is reflected by their protections under Australian law: five types of rock-wallaby are classified as ‘vulnerable’, six as ‘endangered’, and one as ‘critically endangered’. Thus, the complex habitat of rock-wallabies is both a blessing and a curse. Threats to rock-wallabies Rock-wallabies are vulnerable or endangered mainly because of invasive predators such as foxes, cats, and goats. After being introduced from Europe during colonisation, these predators have eaten many wallabies and scared the rest into foraging elsewhere. If predators live between two rock-wallaby populations, there will be less migration and interbreeding, reducing overall genetic health ( Figure 1 ). In addition, rock-wallabies will not forage if predators are in an area, so they have limited food sources under high pressure ( Figure 1 ). Combined with these indirect reasons, direct predation by invasive mammals is the biggest threat to rock-wallaby survival. Invasive predators are not the only threats to rock-wallaby populations. Wildfires kill the plants that wallabies rely on for food and shelter, such as rock figs. For example, one wildfire in the 2019/2020 season destroyed about 38% of brush-tailed rock-wallaby habitat. The already dwindling rock-wallaby populations may disappear if the climate crisis makes wildfires less predictable and more severe. Native herbivores like the euro and invasive herbivores like goats may also compete with rock-wallabies for food. There is evidence that euros out-compete rock-wallabies when food supplies are limited, but no evidence for goats yet. Thus, fires and competition combine with invasive predators to endanger rock-wallabies. Translocation and monitoring Monitoring existing rock-wallaby populations and creating new ones by translocation are reducing the threats of predation, fire, and competition. Brush-tailed rock-wallabies were translocated to Grampians National Park in 2008, but most animals died by 2013. Scientists thought manually handling wallabies might make them stressed and more vulnerable to predators. From 2014 onwards, non-invasive monitoring procedures like cameras and faecal DNA monitoring reduced predation and increased the survival rate of young rock-wallabies. Meanwhile, black-flanked rock-wallabies were being translocated from four different source populations to Kalbarri National Park, hoping they would interbreed and create a new genetically diverse population. The project was successful, as microsatellite genotyping found that the translocated population had more heterozygotes and more alleles per locus than the source populations ( Figure 2 ). This population is predicted to grow until at least 2028 because it is diverse enough to avoid the inbreeding mentioned earlier. The Grampians and Kalbarri translocations show the importance of careful monitoring and genetic considerations for conserving rock-wallabies. Conclusion After invasive mammalian predators have decimated rock-wallaby populations throughout Australia for over 200 years, wildfires and herbivore competition make survival even more difficult. Conservation efforts are made harder by the specific and limited habitats that rock-wallabies need. However, translocation efforts which consider genetic diversity and the stress of manual handling keep rock-wallaby populations afloat. Written by Simran Patel Related article: Wildlife corridors REFERENCES Campbell, I. & Woods, S. (2013) Wildlife of Australia . Princeton, UNITED STATES: Princeton University Press. Kleemann, S., Sandow, D., Stevens, M., Schultz, D.J., Taggart, D.A. & Croxford, A. (2022) Non-invasive monitoring and reintroduction biology of the brush-tailed rock-wallaby (Petrogale penicillata) in the Grampians National Park, Australia. Australian Journal of Zoology . 69 (2): 41–54. Available from: https://www.publish.csiro.au/zo/ZO21009 (Accessed 10th December 2024). Lavery, T.H., Eldridge, M., Legge, S., Pearson, D., Southwell, D., Woinarski, J.C.Z., Woolley, L.-A. & Lindenmayer, D. (2021) Threats to Australia’s rock-wallabies (Petrogale spp.) with key directions for effective monitoring. Biodiversity and Conservation . 30 (14): 4137–4161. Available from: https://doi.org/10.1007/s10531-021-02315-3 (Accessed 9th December 2024). Morris, S.D., Johnson, C.N. & Brook, B.W. (2020) Roughing it: terrain is crucial in identifying novel translocation sites for the vulnerable brush-tailed rock-wallaby (Petrogale pencillata). Royal Society Open Science . 7 (12): 201603. Available from: https://royalsocietypublishing.org/doi/full/10.1098/rsos.201603 (Accessed 10th December 2024). Nilsson, K., Pearson, D., Paxman, M., Desmond, A., Kennington, J., Byrne, M. & Ottewell, K. (2023) Translocations restore a population of a threatened rock-wallaby and bolster its genetic diversity. Conservation Genetics . 24 (5): 547–561. Available from: https://doi.org/10.1007/s10592-023-01520-7 (Accessed 9th December 2024). Silcock, J.L., Gynther, I.C., Horsup, A., Molyneux, J., Wattz, T.L., Fairfax, R.J., Healy, A.J., Murphy, D. & McRae, P.D. (2024) Half a century of survey data reveal population recovery but persistent threats for the Vulnerable yellow-footed rock-wallaby in Queensland, Australia. Oryx . 1–13. Available from: https://www.cambridge.org/core/journals/oryx/article/half-a-century-of-survey-data-reveal-population-recovery-but-persistent-threats-for-the-vulnerable-yellowfooted-rockwallaby-in-queensland-australia/D976E61ABE458B9FADA059372117382E (Accessed 10th December 2024). Project Gallery

How diseases start and spread, the body’s defence system, vaccines, policies, and public opinion: unravel the maze of infection and immunity with these articles. Immunology Articles How diseases start and spread, the body’s defence system, vaccines, policies, and public opinion: unravel the maze of infection and immunity with these articles. You may also like: Biology , Medicine , Neuroscience , Chemistry COVID-19 misconceptions Common misconceptions during the COVID-19 pandemic Glossary of COVID-19 terms Key terms used during the COVID-19 pandemic A vaccine for malaria? A new hope for a vaccine for malaria The world vs. the next pandemic Can we see it coming? What steps do we need to take? Are pandemics becoming more severe? Arguments for and against Natural substances And how they can tackle infectious diseases A treatment for HIV? Can the CRISPR-Cas9 system be used as a potential treatment? The mast cell Key cells in the immune system Origins of COVID -19 How COVID-19 caused a pandemic Mechanisms of pathogen invasion How pathogens avoid detection by the immune system Astronauts in space How does little gravity affect the immune system? Ageing and immunity Ageing and its association with immune decline The impacts of global warming on dengue fever Dengue fever is a mosquito-borne Neglected Tropical Disease (NTD) Is the immune system 'selfish'? 'Selfish' genes from a Dawkins perspective, and the Modern Evolutionary Synthesis

Jennifer Doudna and Emmanuelle Charpentier were jointly awarded the Nobel Prize in Chemistry in the year 2020, for their major contributions in reducing the number of components in the CRISPR-Cas9 system. An outline of their discovery CRISPR-Cas9 (clustered regularly interspaced short palindromic repeats) can be used, by removing, adding, or altering particular DNA sequences and may edit specific parts of the genome. Go Back Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Who were the winners of the Nobel Prize in Chemistry in 2020? Last updated: 26/04/26 Published: 02/02/23 Jennifer Doudna and Emmanuelle Charpentier were jointly awarded the Nobel Prize in Chemistry in the year 2020, for their major contributions in assembling and demonstrating Cas9 gene editing capabilities in vitro. An outline of their discovery Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR-Cas9) can be used, by removing, adding, or altering particular DNA sequences and may edit specific parts of the genome. A four-part mechanism called the Cas9 endonuclease consists of two small molecules. Charpentier discovered the tracrRNA, which, when combined with the crRNA (discovered in 2007 by a different group), they could assemble and demonstrate Cas9 gene editing capabilities in vitro. The two types of sequences were later combined to the now well-known "single-guide RNA" (sgRNA)- done in collaboration with Doudna in 2012. By combining these two RNA molecules into a sgRNA, the Cas9 endonuclease was redesigned into a more manageable two-component system that could locate and cut the DNA target defined by the guide RNA- CRISPR/Cas9 ‘genetic scissors’. It can silence or activate genes as well as add or remove others. The Nobel Prize in Chemistry was awarded in 2020 in recognition of this contribution. Some advantages of this technology: quick easy adaptable innovative, unique Disadvantages: distribution challenges extremely conservative ethical issues some off-target effects some negative outcomes Significance of this discovery This discovery is important in preventing disease and is such a revolutionary tool. It does not just help humans but also animals, plants and even bacteria. CRISPR has already been applied to various disorders, such as cancer and infectious diseases. By making it possible to make changes to the target cells' genomes, which were previously challenging to do, the procedure offers a new perspective on biological treatment and demonstrates how important this tool is. But since this technology is still recent, scientists must develop straightforward processes and techniques to monitor and test its progress, performance, and outcomes. Jennifer Doudna Hailing from Washington DC., USA, Jennifer Doudna was born in 1964. As a professor of biochemistry, biophysics, and structural biology, Doudna’s main research focus is on RNA, and its variety of structures and functions. It was her research lab’s work that led to the discovery of CRISPR-Cas9 as an extraordinarily powerful tool to cut and edit the human genome to treat disease. This remarkable discovery was a decade ago in 2012, when Doudna and others were able to copy a bacterial system to create molecular scissors, in order to edit the genetic code. In October 2020, at the time of her being awarded the Nobel Prize in Chemistry, Doudna was affiliated to the University of Berkeley, in California. Emmanuelle Charpentier Coming from a French background, Emmanuelle Charpentier is a professor and researcher in microbiology, genetics, and biochemistry. Born in 1968, researcher Charpentier has made tremendous progress in her respective field. From being the director at the Berlin Max Planck Institute for Infection Biology in 2015, to founding her own independent research institute- the Max Planck Unit for the Science of Pathogens in the year 2018, and of course being jointly awarded the Nobel Prize in Chemistry in 2020; it is true that Charpentier has added new, valuable research in her work and has come a long way in her career. Why the CRISPR/ Cas9 system fascinates us We find CRISPR fascinating because as biological science students, we know this tool is vital for genetics and can help cure present incurable diseases such as sickle cell disease as well as cancer, showing what a revolutionary tool this is. It does not just help humans but also animals, plants and even bacteria showing how broad biology is and different fields can be linked to one another. Researchers are constantly coming up with new ways to use CRISPR-Cas9 gene editing technology to solve problems in the real world, such as epigenome editing, new cell and gene therapies, infectious disease research, and the conservation of endangered species. The advantages of this technology are that it is quick, easy and adaptable, but its disadvantages include distribution challenges, extremely conservative ethical issues, some off-target effects, and some negative outcomes. By making it possible to make changes to the target cells' genomes, which were previously challenging to do, the procedure offers a new perspective on biological treatment and demonstrates how important this tool is. Written by Jeevana Thavarajah, and Manisha Halkhoree Scientia News Founder and Managing Director Related articles: Female Nobel prize winners in Chemistry and in Physics

Looking at modern society in terms of the food being consumed and the amount of exercise undertaken collectively, it is entirely inevitable that diabetes will become an epidemic. Now before delving into the above statement further, diabetes mellitus (from Greek ‘siphon’ and Latin ‘sweet’) is a non-communicable disease that occurs when blood sugar levels in the body are so high, that the pancreas is unable to produce adequate insulin in order to manage this problem. Go back Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Will diabetes mellitus become an epidemic? Last updated: 25/02/26 Published: 18/05/23 Defining diabetes and its causes Looking at modern society in terms of the food being consumed and the amount of exercise undertaken collectively, it is entirely inevitable that diabetes will become an epidemic. Now before delving into the above statement further, diabetes mellitus (from Greek ‘siphon’ and Latin ‘sweet’) is a non-communicable disease that occurs when blood sugar levels in the body are so high, that the pancreas is unable to produce adequate insulin in order to manage this problem. Also, diabetes can be categorised into various types, but the most common are types 1 and 2 as well as gestational (which happens during pregnancy). There is also diabetes insipidus (from Latin ‘lacking taste’), and this is where the kidneys are unable to conserve water. The causes of diabetes mellitus can be divided based on the type. Since type 1 can be caused by the body’s immune system attacking the pancreas, this means that the beta cells are unable to make enough insulin because they are damaged. Not only can type 1 diabetes arise this way, it is possible that environmental factors such as diet and viral infections lead to the disease. As for type 2, it primarily comes from insulin resistance, meaning that the body does not respond to the hormone effectively compared to a person without diabetes. This in turn impacts insulin mediated glycogen synthesis and glycolysis leading to hyperglycemia as seen in figure 1. There are many reasons why diabetes is likely to become an epidemic. Firstly, there is a clear connection between obesity and type 2 diabetes which cannot be ignored; this is because an article found that people with both conditions are exacerbated perhaps due to increased non esterified fatty acids (NEFAs) and glycerol among other linked biochemicals. On the other hand, this same article stated that people with type 1 diabetes are not usually obese. Nevertheless, it is vital that in order to prevent the incidence of type 2 diabetes in later life, it is important to implement strategies such as regular exercise and lowering carbohydrate intake in the diet. Alluding to the previous paragraph, one of the major factors to the increase in obesity and type 2 diabetes diagnoses is the sedentary lifestyle or decreased mobility through sitting. A meta-analysis evaluated 10 studies with over 500,000 volunteers and concluded that there was a 112% cumulative increase in type 2 diabetes risk linked to watching TV. Additionally, a study showed that more sedentary time had raised body and trunk fat percentage while there was reduced appendicular skeletal muscle mass. Taking into account these findings among others, it is evident that exercise does play a role in reducing the risk of type 2 diabetes. Counteracting the previous paragraphs, it is equally plausible that diabetes will not be epidemic because there are current pharmaceutical drugs taken orally like sulfonylureas and meglitinides that cause the pancreas to release insulin aside from injection based ones such as amylin mimetics, which maintains blood glucose concentration, which are used for type 2 diabetes. As for those afflicted with type 1 diabetes, they mainly take insulin because they are in deficit of the hormone or they can have a pancreatic transplant, which has more than 96% and 83% survival rates after 1 and 5 years of the operations respectively, although it does have a major complication of rejection like any other type of operation. With regards to future treatments, a review discussed how newer drugs for decreasing blood glucose such as dipeptidyl peptidase-4 (DPP-4) inhibitors have been re-evaluated for cardiovascular outcome trials by showing patients experiencing a decrease in other non-communicable diseases like myocardial infarction and albuminuria, indicating that they can be useful for heart and kidney diseases associated with type 2 diabetes. Furthermore, there are other potential therapies such as probiotics and prebiotics that can be used along with faecal transplants to change the gut microbiome for type 2 diabetes patients. (New NICE guidance recommends that most people should now be offered metformin along with an SGLT-2 inhibitor from the start). It is uncertain that diabetes will/won’t become an epidemic From a more neutral perspective, there is not enough certainty that diabetes will or will not become an epidemic simply because accurately predicting the future 100% of the time is impossible. As such, the future interventions for treating diabetes may not actually get to exist, perhaps due to prospective factors like politics and societal values with respect to science as well as taking into account the difficulty for a therapeutic method to be put onto the market for the patients to consider. Another point to address is the fact that the human body is so incredibly complex that it took humans thousands of years to truly discover all of the current facts known in relation to its anatomy and physiology along with having some level of understanding of them. Not only that, there are still observations about the human body that are still unclear to scientists today and so the drugs for treating diabetes may or may not be effective depending on who is receiving the therapy because each person is genetically unique. Conclusion Referring to all of the arguments made, it is evident that diabetes is a huge burden for modern and future societies because of its links to obesity or sedentary lifestyle and consuming foods high in carbohydrates. Yet, this issue may be prevented by exploring future therapies, exploiting current ones and implementing non-clinical interventions such as increased regular exercise and reducing carbohydrate intake. Therefore, it is the responsibility of each patient and health organisation to manage diabetes before it becomes even worse. Written by Sam Jarada Related articles: Pre-diabetes / Diabetes drug to treat Parkinson's / The world vs the next pandemic REFERENCES Diabetes UK. Types of diabetes. Diabetes UK. 2022. Paschou SA, Papadopoulou-Marketou N, Chrousos GP, Kanaka-Gantenbein C. On type 1 diabetes mellitus pathogenesis. Endocrine Connections. 2018 Jan;7(1):R38–46. Cersosimo E, Triplitt C, Solis-Herrera C, Mandarino LJ, DeFronzo RA. Pathogenesis of Type 2 Diabetes Mellitus. Nih.gov. MDText.com, Inc.; 2018. Algoblan A, Alalfi M, Khan M. Mechanism linking diabetes mellitus and obesity. Diabetes, Metabolic Syndrome and Obesity: Targets and Therapy. 2014 Dec;7(587–591):587. Barnes AS. The epidemic of obesity and diabetes: trends and treatments. Texas Heart Institute journal. 2011;38(2):142–4. Hamilton MT, Hamilton DG, Zderic TW. Sedentary Behavior as a Mediator of Type 2 Diabetes. Medicine and Sport Science. 2014;60:11–26. Li D, Yang Y, Gao Z, Zhao L, Yang X, Xu F, et al. Sedentary lifestyle and body composition in type 2 diabetes. Diabetology & Metabolic Syndrome. 2022 Jan 15;14(1). Mayo Clinic. Diabetes treatment: Medications for type 2 diabetes. Mayo Clinic. 2018. Bahar SG, Devulapally P. Pancreas Transplantation. PubMed. Treasure Island (FL): StatPearls Publishing; 2022. Bailey CJ, Day C. The future of new drugs for diabetes management. Diabetes Research and Clinical Practice. 2019 Sep;155:107785. Bailey CJ, Day C. Treatment of type 2 diabetes: future approaches. British Medical Bulletin. 2018 Jun 1;126(1):123–37.

Antifreeze proteins and frozen foods Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link The Survival Secrets of the Arctic Springtail 04/07/25, 12:59 Last updated: Published: 21/09/24, 16:09 Antifreeze proteins and frozen foods Introduction Approximately 450 million years ago, during the Ordovician period, the Earth was characterised by a hot and humid globe. The sea was teeming with life, with early squids, eel-like fish, and sea worms hunting smaller animals. However, there was no sign of movement above ground as the animals had not yet crawled ashore. This period of warmth created ideal living conditions for wildlife, but it was about to change dramatically. Shortly after, the land masses began to freeze, and an ice cap started to spread. The once warm and accommodating waters turned cold and inhospitable, leading to the second-worst mass extinction in the history of the planet. Many species succumbed to the harsh conditions, but one animal survived - the springtail. The springtail, a small insect-like animal, had developed a special strategy to combat the cold. Its cells started producing proteins that could protect them from freezing. This discovery challenges the previous belief that animals did not develop antifreeze proteins until much later. Research from Aarhus University has shown that the springtail might have been the first animal to develop such proteins. Applications in the Food Industry Since then, scientists have found antifreeze proteins in various animals, plants, and microorganisms. These proteins have also found applications in different industries. One of the industries utilising antifreeze proteins is the food industry, especially in producing frozen foods. Frozen foods often suffer from changes in taste and texture due to the formation of ice crystals. However, by incorporating antifreeze proteins, these undesirable effects can be prevented. Industrial yeast cell cultures have been engineered to produce antifreeze proteins derived from fish genes. These proteins can then be added to different foods, including ice cream, to improve texture and prevent the formation of ice crystals. Exploring Arctic Fish Aside from their contribution to the food industry, springtails have also fascinated scientists due to their ability to survive in extremely cold regions. The discovery of antifreeze proteins explained how arctic fish could swim in icy seawater. The proteins prevent ice from forming in the cells and blood of the fish, allowing them to survive in freezing conditions. Martin Holmstrup, a researcher at Aarhus University, oversees colonies of springtails in his laboratory. These small animals require minimal space and can be easily maintained in Petri dishes with a base of moist plaster and a feed of dry yeast. Researchers have determined that springtails developed these proteins long before other animals by studying the DNA sequences responsible for building antifreeze proteins. The discovery of antifreeze proteins in springtails opens up possibilities for various applications, including in the food industry. These proteins have been found to prevent ice crystal formation, which can affect the taste and texture of frozen foods. The genes responsible for their production have been copied into industrial yeast cell cultures to utilise these proteins. This allows the yeast to produce the antifreeze proteins, which can then be added to different foods. One example is the use of these proteins in ice cream, where they help create a delightful texture and allow the ice cream to be thawed and refrozen without compromising its quality. Conclusion The discovery of antifreeze proteins in springtails has revolutionised various industries, particularly the food industry. These proteins have been found to prevent ice crystal formation, improving the taste and texture of frozen foods. Incorporating antifreeze proteins derived from fish genes into yeast cell cultures can produce and add these proteins to different foods, such as ice cream, ensuring a delightful texture and the ability to thaw and refreeze without compromising quality. This remarkable adaptation of springtails has provided insight into their survival in extremely cold regions and opened up possibilities for further applications of antifreeze proteins in various fields. Written by Sara Maria Majernikova Related articles: p53 protein / Zinc finger proteins / Emperor penguins, kings of ice Project Gallery

A type of anaemia Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Iron deficiency anaemia 09/05/26, 13:47 Last updated: Published: 27/06/23, 17:10 A type of anaemia This article is no. 2 of the anaemia series. Next article: anaemia of chronic disease . Previous article: Anaemia . Aetiology Iron deficiency anaemia (IDA) is the most frequent in children due to rapid growth (adolescence) and poor diets (infants), and in peri and post -menopausal women due to rapid growth (pregnancy) and underlying conditions. Anaemia typically presents in around 50% of cases, as headache, lethargy and pallor, depending on the severity. Less common side effects include organomegaly and Pica, which occur in patients with zinc and iron deficiency, and is defined by the eating of things with little to no nutritional value. Pathophysiology Iron is primarily sourced through diet, as haem (Fe2+) and non-haem iron (Fe3+). Fe2+ is sourced through meat, fish, and other animal-based products, Fe2+ can be absorbed directly through the enterocyte via the haem carrier protein1 (HCP1). Fe3+ is less easily absorbed and is mostly found in plant-based products. Fe3+ must be reduced and transported through the duodenum by the enzyme duodenal cytochrome B (DcytB) and the divalent metal transporter 1 (DMT1), respectively. Diagnosis As with any diagnosis, the first test to run would be a full blood count and this will occur with all the anaemias. In suspected cases of anaemia, the haemoglobin (Hb) levels would be lower than 130 in males and 120 in females. The mean cell volume (MCV) is a starting point for pinpointing the type of anaemia. For microcytic anaemias, you would expect to see an MCV < 80. Iron studies are best for diagnosing anaemias. For IDA, you would expect most of the results to be low. A patient with IDA has little to no available iron so the body would halt the mechanism’s for storing iron. As ferratin is directly related to storage, low ferratin can be a lone diagnostic of IDA. Total iron-binding capacity (TIBC) would be expected to be raised, as transferrin transports iron throughout the body. The higher TIBC is, the more iron it would be capable of binding to. Elliptocytes (tear drop) are elongated RBC, often described as pencil-like in structure, and are regularly seen in IDA and other anaemias. Typically, one would see hypochromic RBC as they contain less Hb than normal cells; the Hb is what gives red cells their pigment. It’s not uncommon to see other changes in RBC such as target cells, given their name due to the bulls-eye appearance. Target cells are frequently seen in cases with blood loss. Summary IDA is the most frequent anaemia affecting patients of all age ranges, and usually presents with lethargy and headaches. Dietary iron from animal derivatives are the most efficient source of iron uptake. Diagnosis of IDA is through iron studies, red cell morphological investigations alongside clinical presentation, to rule out other causes. Written by Lauren Kelly Project Gallery

Manufacturing doubt is another strategy where facts are intentionally changed to promote an agenda. It is used in the tobacco industry and against the climate crisis. Meaning articles can maintain the façade of using scientific methods by referencing sources that are difficult to interpret whilst research supported by sound evidence is labelled and downplayed. Go back Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link How fake science websites hijack our trust in experts to misinform and confuse Last updated: 07/11/24 Published: 29/12/22 In science, all research is peer-reviewed by experts. Now, fake science websites are mimicking these disciplines. These websites capitalise on our trust in experts. In some cases, these websites are paid to publish fake science. This is becoming more common. In a recent global survey, almost 50% of respondents said they see false or misleading information online daily. By understanding the methods these sites use we can prevent their influence. Hyperlinking is a technique used to convince website users. They reassure the user that the content is credible, but most people don’t have experience in analytical techniques and so these links aren’t questioned. Repetition is used to increase the visibility of fake science content but also saturate search engines. This content can be repeated and spread across different sites. Users of “lateral reading” get multiple websites that corroborate the fake science from the initial source. Many of these sites only choose articles that agree with their perspective and depend on the audience not taking time to follow up. Manufacturing doubt is another strategy where facts are intentionally changed to promote an agenda. It is used in the tobacco industry and against the climate crisis. Meaning articles can maintain the façade of using scientific methods by referencing sources that are difficult to interpret whilst research supported by sound evidence is labelled and downplayed. On fake science websites first, check the hyperlinked articles. These websites will use sites with repeated content from disreputable sites. Next, look at the number of reposts a website has. Legitimate science posts are on credible websites. Some websites investigate websites that feature fake science. Ultimately, these websites thrive on users not having the time or skills to look deeper into the evidence, so doing so will help expose the fake websites. Written by Antonio Rodrigues Related articles: Digital disinformation / COVID-19 misconceptions