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Exenatide as a potential drug Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link A common diabetes drug treating Parkinson’s disease 05/04/26, 14:28 Last updated: Published: 24/01/24, 21:15 Exenatide as a potential drug Disclaimer: the results from the February 2025 Phase 3 Exenatide-PD3 trial shows that exanetide did not outperform the placebo, and did not slow the progression of Parkinson's disease. Parkinson's (PD) is the second most common neurodegenerative disorder. The connection between type 2 diabetes (T2DM) and PD was discovered in 1993, when PD patients with co-existing T2DM had worse motor symptoms and response to therapy. Dopaminergic neurons promote eating behaviour in hypoglycaemic states, mediated via insulin receptors in the substantia nigra, because dopaminergic neuronal loss affects glycaemic control. Thus, T2DM patients are more likely to acquire PD than people without diabetes. Excess glucose in the brain, as found in uncontrolled T2DM, may interact randomly with surrounding proteins and interfere with their function. These interactions also result in toxic end products promoting inflammation and α-synuclein clustering, both of which are PD characteristics. Over a 12-year period, retrospective data (N=8,190,323) showed that T2DM responders had considerably greater PD rates when compared to those without diabetes. The rise was significantly more pronounced among individuals with complex T2DM and those aged 25-44. Exenatide: Overview and Mechanism of Action Exenatide is a synthetic form of exendin-4, a naturally occurring protein identified in the saliva of the Gila monster (poisonous lizard endemic to the Southwest US) by Dr. Eng in the early 1990s. In humans, the chemical is produced after a meal to increase insulin production, decreasing blood sugar. GLP-1 degrades fast in humans, and its benefits are short-lived. However, investigations have shown effects of exendin-4 continue longer in people. This finally led to FDA clearance in 2005, when the product was sold as Byetta TM . Its current indications are for the treatment of balancing glucose levels in T2DM with or without additional oral hypoglycemic medications. This glycaemic control is an analogue of human GLP-1, used in T2DM treatment, either alone or in conjunction with other antidiabetic medications. Exendin-4's neuroprotective characteristics may aid in rescuing degenerating cells and neuron protection. Because T2DM and PD are linked, researchers want to explore its effectiveness as a PD therapy. Patients treated with exenatide for one year (in addition to standard medication) experienced less deterioration in motor symptoms when tested without medication compared to the control group. Research on Exenatide as a Potential Parkinson's Disease Therapy 21 patients with intermediate PD were assessed over a 14-month period, and their progress was compared to 24 other people with Parkinson's who served as controls. Exenatide was well accepted by participants, albeit some individuals complained about weight loss. Significantly, exenatide-treated participants improved their PD movement symptoms, while the control patients continued to deteriorate. The researchers investigate exenatide, a possible PD therapy, in an upcoming clinical study, lending support to the repurposing of diabetes drugs for Parkinson's patients. This research adds to the evidence for a phase 3 clinical trial of exenatide for PD patients. Data on 100,288 T2DM revealed that people using two types of diabetic medications, GLP-1 agonists and DPP4-inhibitors, were less likely to be diagnosed with Parkinson's up to 3.3 years follow-up. Those who used GLP-1 agonists were 60% less likely to acquire PD than those who did not. The results revealed that T2DM had a higher risk of Parkinson's than those without diabetes, although routinely given medicines, GLP-1 agonists, and DPP4-inhibitors seemed to reverse the association. Furthermore, a 2-year follow-up research indicated individuals previously exposed to exenatide displayed a substantial improvement in their motor characteristics 12 months after they ceased taking the medication. However, this experiment was an open-label research so the gains may be explained by a placebo effect. The research adds to the evidence that exenatide may assist to prevent or treat PD, perhaps by altering the course of the illness rather than just lowering symptoms. Other risk factors for PD should be considered by clinicians when prescribing T2DM drugs, although further study is required to clarify clinical significance. Findings from Clinical Trials and Studies Based on these findings, the UCL team broadened their investigation and conducted a more extensive, double-blind, placebo-controlled experiment. The findings establish the groundwork for a new generation of PD medicines, but they also confirm the repurposing of a commercially existing therapy for this illness. Patients were randomly randomised (1:1) to receive exenatide 2 mg or placebo subcutaneous injections once weekly in addition to their current medication for 48 weeks, followed by a 12-week washout period. Web-based randomisation was used, with a two-stratum block design depending on illness severity. Treatment allocation was concealed from both patients and investigators. The main outcome was the adjusted difference in the motor subscale of the Movement Disorders Society Unified Parkinson's Disease Rating Scale after 60 weeks in the realistically defined off-medication condition. Six major adverse events occurred in the exenatide group and two in the placebo group, but none were deemed to be connected to the research treatments in either group. It is unclear if exenatide alters the underlying illness mechanism or causes long-term clinical consequences. Implications and Future Directions Indeed, the UCL study showed that exenatide decreases deterioration compared to a placebo. However, participants reported no change in their quality of life. The study team would broaden their study to include a broader sample of people from several locations. Because PD proceeds slowly, longer-term trials might provide a better understanding of how exenatide works in these responders. Overall, findings suggest that gathering data on this class of medications should be the topic of additional inquiry to evaluate their potential. Exenatide is also being studied to see whether it might postpone the onset of levodopa-induced problems (e.g., dyskinesias). Furthermore, if exenatide works for Parkinson's, why not for other neurodegenerative illnesses (Alzheimer's, amyotrophic lateral sclerosis, Huntington's disease, multiple sclerosis) or neurological diseases (including cerebrovascular disorders, traumatic brain injury...)? Exenatide has been FDA-approved for diabetes for many years and has a good track record, but it does have some adverse side effects in Parkinson's patients, namely gastrointestinal difficulties (nausea, constipation). Exenatide as a prospective PD therapy is an example of medication repurposing or repositioning, an essential method for bringing novel therapies to patients in a timely and cost-effectively. However, further research is required, so it will be many years before a new therapy is licenced and available. Drug repurposing, or using authorised medicines for one ailment to treat another, opens up new paths for Parkinson's therapeutic development. Conclusion Exenatide shows potential as a therapy for Parkinson's disease (PD). Studies have shown that exenatide may help improve motor symptoms and slow down the progression of PD. However, further research and clinical trials are needed to fully understand its effectiveness and long-term effects. The findings also suggest that repurposing existing medications, like exenatide, could provide new avenues for developing PD therapies. While exenatide shows promise, it will likely be many years before it is licensed and widely available as a PD treatment. PROJECT GALLERY IMAGES DESCRIPTION Figure 1- The use of GLP-1 is beyond diabetes treatment. Nineteen clinical studies found that GLP-1 agonists can improve motor scores in Parkinson's Disease, improve glucose metabolism in Alzheimer's, and improve quality of. They can also treat chemical dependency, improve lipotoxicity, and reduce insulin resistance. However, adverse effects are primarily gastrointestinal. Thus, GLP-1 analogues may be beneficial for other conditions beyond diabetes and obesity. Figure 2- Potent GLP-1 agonists suppress appetite through a variety of mechanisms, including delayed gastric emptying, increased glucose-dependent insulin secretion, decreased glucagon levels, and decreased food ingestion via central nervous system effects. Short-acting agents, including exenatide, primarily function by impeding gastric evacuation, thereby leading to a decrease in postprandial glucose levels. On the contrary, extended-release exenatide and other long-acting agonists (e.g., albiglutide, dulaglutide) exert a more pronounced impact on fasting glucose levels reduction via their mechanism of action involving the release of insulin and glucagon. The ineffectiveness of long-acting GLP-1 receptor agonists on gastric evacuation can be attributed to the development of tolerance to GLP-1 effects, which is regulated by parasympathetic tone alterations. Figure 3- Illustrated is the cross-communication with insulin receptor signalling pathways and downstream effectors . Biomarkers can be derived from the formation and origin of extracellular vesicles, which indicate the initial inward budding of the plasma membrane. An early endosome is formed when this membrane fuses; it subsequently accumulates cytoplasmic molecules. As a consequence, multivesicular bodies are generated, which subsequently fuse with the plasma membrane and discharge their constituents into the extracellular milieu. Akt denotes protein kinase B; Bcl-2 signifies extracellular signal-related kinase; Bcl-2 antagonist of death; Bcl-2 extra large; Bcl-XL signifies Bcl-2; Bim signifies Bcl-2-like protein 11; cAMP signifies cyclic adenosine monophosphate; CREB signifies cAMP response element-binding protein; Erk1/2 signifies extracellular signal-related kinase IDE, insulin-degrading enzyme; IL-1α, interleukin 1α; IRS-1, insulin receptor signalling substrate 1; MAPK, mitogen-associated protein kinase; mTOR, mechanistic target of rapamycin; mTORC1, mTOR complex 1; mTORC2, mTOR complex 2; NF-kB, nuclear factor–κB; PI3-K, phosphoinositide 3-kinase; PKA, protein kinase; FoxO1/O3, forkhead box O1/O3, forkhead box O1/O3; GRB2, growth factor receptor-bound protein 2; GSK-3β, Written by Sara Maria Majernikova Related articles: Pre-diabetes / Will diabetes mellitus become an epidemic? / Parkinson's risk / Markers for Parkinsonism Project Gallery

Natural substances and their treatment potential Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Using Natural Substances to Tackle Infectious Diseases 05/04/26, 14:43 Last updated: Published: 06/06/23, 17:06 Natural substances and their treatment potential Introduction There is increased concern of antimicrobial resistance, especially when referring to bacteria with superbugs such as Methicillin-resistant Staphylococcus aureus (MRSA) and Carbapenem-resistant Enterobacteriaceae (CRE) as they impact lives globally, mainly through fatalities. Given this predicament, It seems that humanity is losing as a result of this pressing issue. However, it is possible for healthcare professionals to utilise more natural products, which are chemicals made by plants, animals and even microorganisms. This includes resources such as wood and cotton aside from food like milk and cacao. In the context of medicinal treatments, an important justification for using more natural products is because although synthetic or partially synthetic drugs are effective for treating countless diseases, an article found that 8% of hospital admissions in the United States and approximately 100,000 fatalities per year were due to people experiencing unfortunate side effects from these drugs. This article explores three specific natural products, where each have similar and unique health properties that can be harnessed to tackle infectious diseases and its subsequent consequences when left sufficiently unaddressed (i.e. antimicrobial resistance). Honey One of the most famous natural products that has been referenced in various areas of research and has been a food and remedial source for thousands of years is honey. It has properties ranging from antibacterial to antioxidant, suggesting that when honey is applied clinically, it has the potential to stop pathogenic bacteria. For example, honey can protect the gastrointestinal system against Helicobacter pylori , which causes stomach ulcers. In disc diffusion assays, the inhibitive properties of honey were shown when honey samples were evaluated holistically as opposed to its individual ingredients. This implies that the macromolecules in honey (carbohydrates, proteins and lipids) work in unison with other biomolecules, illustrating that honey is a distinctive remedy for preventing bacterial growth. For tackling infectious diseases, particularly against wound infections among others, honey’s medicinal properties provide a lot of applications and because it is a natural product, honey would not present any drastic side effects to a patient upon its administration. Garlic Another natural product that can be effective against microorganisms is garlic because similar to honey, it has antimicrobial and antioxidative compounds. A study judged different garlic phenotypes originating from Greece and discovered that they were beneficial against Proteus mirabilis and Escherichia coli aside from inhibiting Candida albicans and C. kruzei . As for fresh garlic juice (FGJ), it increases the zone of inhibition in various pathogens at 10% and more along with it displaying minimum inhibitory concentrations (MICs) in the 4-16% range. Therefore, garlic in solid or liquid form does show potential as a natural antimicrobial agent, especially against pathogenic bacteria and fungi. With this in mind, it too has multiple applications like honey and should be further studied to best isolate the chemical compounds that could be involved in fighting infectious diseases. Turmeric Curcuma longa (also known as turmeric) is one other natural product with unique properties like garlic and honey, making it a suitable candidate against various microbes. One specific pigment that is part of the ginger family and found in turmeric is curcumin, which can tackle diverse microbes through numerous mechanisms illustrated below in Figure 2 . With this said, curcumin has drawbacks: it is highly hydrophobic, has low bioavailability and quickly breaks down. Although when paired with nanotechnology for delivery into the human body, its clinical applications can be advantageous and an additional observation about curcumin is that it can work collaboratively with other plant derived chemicals to stop antibiotic resistant bacteria. One specific bacterial strain that turmeric can attack is Clostridium difficile, a superbug that causes diarrhoea. A study had 27 strains to measure the MICs of turmeric constituents, particularly curcuminoids and curcumin. The results showed reduced C. difficile growth in the concentration range 4-32 μg/mL. Moreover, they had no negative impacts on the gut microbiome and curcumin had more efficacy in stopping C. difficile toxin production compared to fidaxomicin. Thus, turmeric is efficacious as a natural antimicrobial chemical and with further experimentation (same as honey and garlic), it can be harnessed to prevent infectious diseases besides their impact on human lives. Conclusion Considering the above examples of natural products in this article and others not mentioned, it is clear that they can be powerful in the battle against infectious diseases and the problems associated with them, mainly antimicrobial resistance. They are readily available to purchase in markets and shops at low cost, making them convenient. Moreover, populations in Eastern countries like China and India traditionally have used, and are still using these materials for curing pain and illness. In turn, manufacturing medicines from natural products on a larger scale has the prospect of preventing infectious diseases and even alleviating those that patients currently have. Written by Sam Jarada Related article: Mechanisms of pathogen evasion Project Gallery

An extensive collection of insightful reviews on the best STEM books available. Whether you're a student looking to deepen your knowledge or something to aid your revision and research, an educator seeking great resources for your classroom, or simply a curious mind passionate about science, technology, engineering, mathematics, medicine and more, you'll find something here to inspire and inform you.  Discover Your Next Great Read Deep Dive into STEM Books Here you can explore an extensive collection of insightful reviews on the best STEM books available. Whether you're a student looking to deepen your knowledge or something to aid or complement your revision and research, an educator seeking great resources for your classroom, or simply a curious mind passionate about science, technology, engineering, mathematics, medicine and more, you'll find something here to inspire and inform you. Our Curated Selections: Intern Blues by Robert Marion, M.D. The Emperor of All Maladies by Siddhartha Mukherjee The Molecule by Dr Rick Sax and Marta New

Scientia News is full of STEM blogs, articles and resources freely available across the globe for students. Browse all of our fascinating content written by students and professionals showing their passion in STEM and the other sciences. Log In Welcome to Scientia News DELIVERING INFORMATIVE CONTENT Scientia News is full of STEM blogs, articles and resources freely available across the globe for students. Browse all of our fascinating content written by students and professionals showing their passion in STEM and other sciences. We hope this platform helps you discover something that inspires your curiosity, and encourages you to learn more about important topics in STEM. Meet the Official Team NAVIGATE AND CLICK THE PHOTOS BELOW TO LEARN MORE ABOUT US! To play, press and hold the enter key. To stop, release the enter key. To play, press and hold the enter key. To stop, release the enter key. To play, press and hold the enter key. To stop, release the enter key. Latest Articles ecology Rock, paper, survival? View More chemistry Diels–Alder Reaction View More biology Addressing Health Inequalities View More chemistry Molecular blueprints: the synthesis of ibuprofen View More CONTACT CONTACT US Scientia News welcomes anyone who wants to share their ideas and write for our platform. If you are interested in realising your writing potential with us AND live in the UK; and/ or would like to give feedback: Email us at scientianewsorg@gmail.com or fill in our GET IN TOUCH form below and we'll be in contact... Follow us on our socials for the latest updates. Comment, like and share! Join our mailing list below for latest site content. You can also sign up to become a site member . SUBSCRIPTION Join our mailing list to receive alerts for new articles and other site content. Be sure to check your spam/ junk folders in case emails are sent there. Email Subscribe GET IN TOUCH First Name Last Name Email Message Send Thanks for submitting!

Elements, compounds, and mixtures make up the building blocks of materials that shape our world. Read on to uncover the latest contributions in chemistry, such as advances in mass spectrometry and quantum chemistry. Chemistry Articles Elements, compounds, and mixtures make up the building blocks of materials that shape our world. Read on to uncover the latest contributions in chemistry, such as advances in mass spectrometry and quantum chemistry. You may also like: Medicine , Pharmacology Advances in mass spectrometry Analytical chemistry Bioorthogonal chemistry Chemical reactions with high yields Polypharmacy Multiple medications Plastics and their environmental impact The same property that makes plastics so strong endangers the environment Quantum chemistry A relatively new field of chemistry Nanomedicine and targeted drug delivery An overview as to why nanoparticles are suitable for drug delivery Nanogels Smarter drug delivery The importance of symmetry in chemistry Symmetry in spectroscopy, reaction mechanisms and bonding Not all chemists wear white coats Computational organic chemistry Molecular blueprints: the art of synthetic planning Article #1 in a two-part series on retrosynthesis. Looking at the rare earth elements These comprise the lanthanide series as well as scandium (Sc) and yttrium (Y), and are characterised by the similarity of their chemical properties. Molecular blueprints: the synthesis of ibuprofen Article #2 in a two-part series on retrosynthesis. Diels-Alder reaction A reaction that shows the importance of symmetry in chemistry Previous

Psilocybin's active metabolite, psilocin, acts as a serotonin receptor agonist Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link The promising effects of magic mushrooms for depression Last updated: 05/04/26, 14:37 Published: 19/02/26, 08:00 Psilocybin's active metabolite, psilocin, acts as a serotonin receptor agonist This is Article 3 in a series on psychiatric disorders and the brain. Previous article: Inside out: the chemistry of depression . Next article coming soon. What is psilocybin? Psilocybin is a naturally occurring psychedelic tryptamine alkaloid found in over 200 species of mushrooms (Psilocybin mushrooms), commonly known as magic mushrooms or shrooms. Upon ingestion, the body converts psilocybin into its active metabolite, psilocin, which acts as a serotonin receptor agonist, primarily impacting 5-HT2A receptors. What is psilocybin useful for? In recent years, clinical research has shown that psilocybin-assisted therapy, can quickly and meaningfully reduce symptoms of depression, often within days rather than weeks, when given in a safe, controlled medical setting with psychological support. Importantly, these studies don’t just look at mood while someone is under the influence. They measure long-term changes weeks or months after treatment. Studies, such as Gukasyan et al. , 2022 and Goodwin et al. , 2022, have shown that 1-2 doses of psilocybin plus therapy have led to sustained reductions in depressive symptoms that last at least 8-12 weeks, and in some cases 12 months later. Research has also demonstrated potential benefits for individuals whose depression has not responded to conventional antidepressant treatments. A large phase II double-blinded trial, by Griffiths et al. , 2016, involving people with treatment-resistant depression found that those given a therapeutic dose (25 mg) of psilocybin had noticeably greater improvement in their depression scores compared with a very low dose (10 mg). Scientists, for example Daws et al. , 2022, believe psilocybin works differently from standard antidepressants. It appears to temporarily increase connections between different parts of the brain and may help break rigid patterns of negative thinking that are typical in depression. If psilocybin is effective, why is it not currently used in treatment for depression? Psilocybin remains classified as a Schedule I controlled substance under the United Nations 1971 Convention on Psychotropic Substances, meaning it is considered to have a high potential for abuse and no accepted medical use. For psilocybin to become an approved clinical treatment for depression, it must be rescheduled through formal regulatory review, a process that involves extensive clinical testing and bureaucratic steps. In many countries, including the United States, rescheduling controlled substances can be slow and complex. For example, in 2022-2023, the U.S. government reviewed the scheduling of marijuana (cannabis) after presidential direction to federal agencies, but a final rescheduling decision was still pending as of late 2025. According to the U.S. Drug Enforcement Administration, Schedule III drugs are defined as substances with moderate to low potential for physical and psychological dependence, whereas Schedule I substances are defined as having no currently accepted medical use and a high potential for abuse. Because psilocybin is still Schedule I in most jurisdictions, it cannot yet be prescribed as a mainstream treatment for depression, despite promising clinical trial results. Written by Chloe Kam Related article: What does depression do to your brain? Project Gallery

Study the plethora of interactions between drug and target with these articles focusing on antibiotic resistance, analgesics, and drug treatments for diseases with presently no cure. Pharmacology Articles Study the plethora of interactions between drug and target with these articles focusing on antibiotic resistance, analgesics, and drug treatments for diseases with presently no cure. You may also like: Chemistry , Medicine Effect of heat on medicine When medication is exposed to extreme heat, what happens? Antibiotic resistance Its rising threat Exploring ibuprofen Ibuprofen is a painkiller A treatment for Parkinson's disease By using a common diabetes drug mRNA vaccines What they are, and how they are different to traditional (live, attenuated, or viral-vectored) vaccines Anthrax toxin Using bacterial toxins to treat pain 'The Molecule': an upcoming biotech thriller A book review Psilocybin mushrooms and effect on depression Can this type of mushroom be used to treat the world's most common mental health disorder?

How chemistry plays a part Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link The role of chemistry in space exploration 04/04/26, 16:17 Last updated: Published: 05/08/23, 09:41 How chemistry plays a part Background Space exploration is without a doubt one of the most intriguing areas of science. As humans, we have a natural tendency to investigate everything around us – with space, the main question we want to answer is if there is life beyond us on Earth. Astronomers use advanced telescopes to help look for celestial objects and therefore study their structures, to get closer in finding a solution to this question. However, astronomers do have to communicate with other scientists in doing so. After all, the field of science is all about collaboration. One example is theoretical physicists studying observed data and, as the name suggests, come up with theories using computational methods for other scientists to examine experimentally. In this article, we will acknowledge the importance of chemistry in space exploration, from not only studying celestial bodies but also to life support technology for astronauts and more. Examples of chemistry applications 1) Portable life support systems To survive in space requires advanced and well-designed life support systems due to being exposed to extreme temperatures and conditions. Portable life support systems (PLSS) are devices connected to an astronaut’s spacesuit that supplies oxygen as well as removal of carbon dioxide (CO2). The famous apollo lunar landing missions had clever PLSS – they utilised lithium hydroxide to remove CO2 and liquid cooling garments, which used any water to remove heat from breathing air. However, these systems are large and quite bulky, so hopefully we can see chemistry help us design even more smart PLSS in the future. 2) Solid rocket propulsion systems Chemical propellants in rockets eject reaction mass at high velocities and pressure using a source of fuel and oxidiser, causing thrust in the engine. Simply put, thrust is a strong force that causes an object to move – in this case, a rocket launching into space. Advancements in propellant chemistry has allowed greater space exploration to take place due to more efficient and reliable systems. 3) Absorption spectroscopy Electromagnetic radiation is energy travelling at the speed of light (approx. 3.0 x 108 m/s!) that can interact with matter. This radiation consists of different wavelengths and frequencies, with longer wavelengths possessing shorter frequencies and vice versa. Each molecule has unique absorption wavelength(s) – this means that if specific wavelengths of radiation ‘hits’ a substance, electrons in the ground state will become excited and can jump up to higher energy states. A line appears in the absorption spectrum for every excited electron (see Figure 1 ). Raman spectroscopy is also used. As a result, spectroscopic analysis of newly discovered planets or moons can give us information on the different elements that are present. It should also be noted that the excited electrons will relax back down to the ground state and emit a photon, allowing us to observe emission spectra as well. In the emission spectra, the lines would be in the exact same place as those in the absorption, but coloured in a black background (see Figure 2 ). Fun fact: There are six essential elements needed for life – carbon, hydrogen, nitrogen, oxygen, phosphorus and sulfur. In 2023, scientists concluded that Saturn’s moon Enceladus has all these which indicates that life could be present here! 1) Space medicine Whilst many people are fascinated by the idea of going to space, it is definitely not an easy task as the body undergoes more stress and changes than one can imagine. For example, barotrauma is when tissues filled with air space due to differences in pressure between the body and ambient atmosphere becomes injured. Another example is weakening of the immune system, as researchers has been found that pre-existing T cells in the body were not able to fight off infection well. However, the field of space medicine is growing and making sure discomforts like those above are prevented where possible. Space medicine researchers have developed ‘countermeasures’ for astronauts to follow, such as special exercises that maintain bone/muscle mass as well as diets. Being in space is isolating which can cause mental health problems, so early-on counselling and therapy is also being provided to prevent this. To conclude Overall, chemistry plays a vital role in the field of space exploration. It allows us to go beyond just analysis of celestial objects as demonstrated in this article. Typically, when we hear the word ‘chemistry’ we often just think of its applications in the medical field or environment, but its versatility should be celebrated more often. Written by Harsimran Kaur Related articles: AI in space / The role of chemistry in medicine / Astronauts in space Project Gallery

And a hope for a more sustainable future Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Green Chemistry 04/04/26, 17:32 Last updated: Published: 29/06/23, 10:33 And a hope for a more sustainable future Green Chemistry is a branch of chemistry that takes into consideration the design of synthetic reactions to minimise the generation of hazardous by-products, their impact on humans and the environment. Often reactions are designed to take place at low temperatures with short reaction times and increased yields. This is preferred as fewer materials are used and it is more energy efficient. When designing routes it is important to consider ‘How green is the process?’ in this way we are shifting focus to a more sustainable future where we are emitting fewer pollutants, using renewable feedstocks and energy sources with minimal waste. In 1998, Paul Anastas and John Warner devised the twelve principles of Green Chemistry. They serve as a framework for scientists to design innovative scientific solutions to existing and new synthetic routes. Scientists are looking into environmentally friendly reaction schemes which can simplify production as well as being able to use greener resources. It is impossible to fulfil all twelve principles at the same time but making attempts to apply as many principles as possible when designing a protocol is just as good. The twelve principles are: Prevention: waste should be prevented rather than treating waste after it has been created. Atom Economy: designing processes where you are maximising the incorporation of all materials so all reagents are in the final product. Less Hazardous Chemical Synthesis : synthetic methods should be designed to be safe and the hazards of all the substances should be reviewed. Designing Safer Chemicals: designed to eliminate chemicals which are carcinogenic, neurotoxic, etc. essentially safe to the Earth. Safer Solvents and Auxiliaries: using auxiliary substances and minimising usage of solvents to reduce waste created. Design for Energy Efficiency: designing synthetic methods where reactions can be conducted at ambient temperature and pressure. Use of Renewable Feedstock: raw materials used for reactions should be renewable rather than depleting. Reduce Derivatives: reducing the steps required in a reaction by using catalysts/ enzymes and adding protecting or deprotecting groups or temporary modification of functionality. Extra steps require more reagents and generate a lot of waste. Catalysis: catalysts lower energy consumption and increase reaction rates. They allow for decreased use of harmful and toxic chemicals. Design for Degradation: chemical products should be designed so that they can break down and have no harmful effects on the environment. Real-time analysis for Pollution Prevention: analytical techniques required to allow monitoring of the formation of hazardous substances. Inherently Safer Chemistry for Accident Prevention: involves using safer chemical alternatives to prevent the occurrence of an accident e.g. fires; explosions. Some examples of areas where Green Chemistry is implemented: Computer Chips: the use of supercritical carbon dioxide as a step for the preparation of a chip. This has reduced the quantities of chemicals, water and energy required to produce chips. Medicine: developing more efficient ways of synthesising pharmaceuticals e.g. chemotherapy drug Taxol. Green Chemistry is widely being implemented in academic labs as a way to reduce the environmental impact and high costs. In 2026, green chemistry has evolved from a niche sustainability goal into a $1 trillion global industry. This branch in Chemistry is still fairly new and will likely be one of the most important fields in the future. Written by Khushleen Kaur Related article: The challenges in modern day chemistry Project Gallery

And can we overcome them? Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link The Challenges in Modern Day Chemistry 04/04/26, 16:39 Last updated: Published: 24/02/24, 22:09 And can we overcome them? Chemistry is often called the "central science" because it connects everything in the natural world. It is the foundation for how we understand life and is essential for solving the massive problems facing humanity today. In recent years, chemistry has changed significantly as top researchers push the boundaries of technology. However, this progress is met with a series of complex, overlapping challenges that require creative and completely new solutions. This article explores the most difficult hurdles currently facing the world of modern chemistry. Sustainability and the Imperative of Green Chemistry The biggest challenge for modern chemistry is the urgent need for environmental sustainability. For a long time, the chemical industry has been a major contributor to pollution and the loss of natural resources. Because of this, there is a desperate need to create "greener" and safer chemical processes. Green chemistry is a leading movement focused on designing products that avoid using or creating hazardous materials. Researchers in this field are working hard to find non-toxic alternatives and energy-efficient methods to reduce the damage caused by chemical work. Energy Storage and Conversion at the Frontier As the world demands more renewable energy, like solar and wind power, the need for better ways to store and convert that energy has become incredibly urgent. Chemistry is at the heart of developing advanced batteries, fuel cells, and supercapacitors. However, scientists are still struggling with how to make batteries hold more power, last longer, and cost less to produce. To solve this, a massive effort is underway to find brand-new materials and invent better ways to manage the chemical reactions that store electricity. Drug Resistance as a Crescendoing Predicament The rise of "superbugs"—bacteria that antibiotics can no longer kill—is a growing crisis in medicine. As germs continue to evolve, chemists face the massive task of constantly inventing new antibiotics and antiviral drugs. At the same time, the move toward "personalized medicine" requires new ways to design drugs that are tailored to a specific person’s body. The ultimate goal is to find a way to stop drug resistance while also getting rid of dangerous side effects, which is one of the most difficult puzzles in chemistry today. Ethical Conundrums and the Regulatory Labyrinth As chemistry continues to move forward, the ethical and legal questions surrounding it become more complicated. Issues like who owns a discovery, how to innovate responsibly, and how to prevent chemical knowledge from being used for harm require careful thought and strict ethical rules. Finding the right balance between pushing for scientific breakthroughs and being a responsible protector of those discoveries is a constant challenge for the chemistry community. In conclusion... Modern chemistry is a fast-moving field that drives innovation in almost every industry while tackling global problems. However, it must overcome its own obstacles, from environmental responsibility and drug resistance to complex ethical dilemmas. Success will require experts from different fields to work together, use their imaginations, and commit to using their power for good. As we continue to learn more about the world of atoms and molecules, solving these problems is the only way to ensure a sustainable and successful future for everyone. Written by Navnidhi Sharma Related article: Green Chemistry Project Gallery