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creativeera · 19 days

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Advancing Precision Diagnostics: Technology, Applications, and Future Insights

Adequate diagnosis is the use of advanced technologies to accurately analyze biological markers in patients. This emerging field allows for more targeted diagnosis and treatment compared to traditional one-size-fits-all approaches. By developing a deep understanding of disease at the molecular level, adequate diagnosis can enable truly personalized care for each unique patient. Advanced Technology Enabling Precision

Major technological advances are fueling the rise of adequate Precision Diagnostics. Next-generation sequencing has dramatically reduced the cost and increased the speed of obtaining genetic information from patients. This genomic data provides crucial biomarkers that can indicate disease risk, identify molecular subgroups, and predict treatment responses. Advanced imaging techniques now allow visualization of organs and tissues at microscopic resolution. Combining molecular analysis with diagnostic imaging creates a multi-dimensional overview of a patient's condition. Computer algorithms also play an important role by synthesizing huge amounts of biomarker and clinical data to derive diagnostic and prognostic insights. Together, these technologies empower clinicians with the tools for pinpoint targeting and tracking of diseases. Insights for a Variety of Precision Diagnostics

Cancer is one area that has benefited greatly from adequate diagnosis approaches. Genomic profiling of tumor samples routinely identifies disease-driving genetic alterations that can be targeted with specific therapies. For example, detection of Epidermal Growth Factor Receptor (EGFR) mutations in lung cancer guides treatment decisions for EGFR inhibitor drugs. Similar molecular characterization is available for other cancer types like melanoma, leukemia, and breast cancer. Cardiovascular diseases are also embracing precision, with new genetic risk scores to predict heart attack or stroke likelihood. Biomarkers in blood can detect early signs of conditions like heart failure and help monitor responses to therapies over time. In neurology, biomarkers hold promise for improving Alzheimer's and Parkinson's disease diagnoses which currently rely on clinical assessments. Molecular subtyping of lung diseases, infections and autoimmune conditions may also enable personalized management strategies in the future. Challenges in Implementing Adequate diagnosis

While the opportunities presented by adequate diagnosis are exciting, challenges remain in fully realizing this vision in clinical practice. One major hurdle is the complexity of analyzing, securely storing and interpreting vast amounts of multi-dimensional patient data. Turning raw biomarkers into actionable medical insights requires advanced data analytics capabilities that will continue advancing. Regulatory bodies must also establish standards and oversight procedures for precision diagnostic tests to ensure accuracy, efficacy and safety. Reimbursement policies need revising to account for the development costs of precision technologies and ongoing monitoring of patients. Building an adequately skilled clinical workforce is equally important, as physicians need training to proficiently collect and interpret different biomarkers alongside traditional examinations. Over time, large real-world outcomes studies will further validate the clinical utility and cost-effectiveness of precision approaches on diverse patient populations and health systems. With dedication to addressing these obstacles, adequate diagnosis show tremendous long-term potential to transform healthcare delivery. Get more insights on Precision Diagnostics

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About Author:

Money Singh is a seasoned content writer with over four years of experience in the market research sector. Her expertise spans various industries, including food and beverages, biotechnology, chemical and materials, defense and aerospace, consumer goods, etc. (https://www.linkedin.com/in/money-singh-590844163)

#Precision Diagnostics #Diagnostic Testing #Personalized Medicine #Molecular Diagnostics #Precision Medicine #Genetic Testing #Biomarker Analysis

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innonurse · 3 months

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Genomics: Tempus goes public

- By InnoNurse Staff -

Tempus, a genomic testing and data analysis company founded by Eric Lefkofsky, debuted on Nasdaq last Friday with a 15% rise, raising nearly $411 million at a valuation over $6 billion despite previous higher valuations, and aims to become cash-flow positive by 2025 while positioning itself as an AI company.

Read more at TechCrunch

#genomics #ai #tempus #medtech #health informatics #health tech #nasdaq #ipo #diagnostics #precision medicine

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cbccindia · 6 months

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Transforming Cancer Care with Precision Oncology

Cancer Immunotherapy stands as a source of encouragement in the landscape of cancer treatment, offering novel approaches that harness the body’s immune system to combat cancer cells. As conventional treatments like Chemotherapy have limitations and can often cause significant side effects, the emergence of Immunotherapy has sparked a new era in oncology, transforming the way we perceive and manage cancer. Let us delve into the intricacies of Cancer Immunotherapy, exploring its mechanisms, efficacy, and impact on cancer treatment, alongside the invaluable contributions of CBCC India in advancing patient care and wellbeing.

#Precision oncology treatment #Targeted cancer therapy #Personalized oncology care #Molecular diagnostics in oncology #Genomic profiling cancer #Biomarker-driven cancer treatment #Precision medicine for cancer #Oncogenomics and cancer #Cancer genomics analysis

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market-insider · 8 months

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Unraveling the Intricacies of the Molecular Diagnostics Market and its Future Prospects

The global molecular diagnostics market size is expected to reach USD 17.97 billion by 2030, and expanding at a CAGR of 4.5% from 2024 to 2030, according to a recent study by Grand View Research, Inc. The contraction in the market will be due to the decline in demand for molecular testing for COVID-19. However, factors such as the rising geriatric population and increasing demand for technologies such as NGS is expected to drive market growth.

Molecular Diagnostics Market Report Highlights

The reagents segment dominated the market and accounted for a share of 62.2% of the global revenue in 2023. It is expected to maintain its dominance throughout the forecast years owing to its wide application scope in research & clinical settings and increasing adoption of novel tests.

The polymerase chain reaction technology segment accounted for the largest revenue share in 2023. This is attributed to its use in detecting COVID-19 and other infectious diseases.

The infectious diseases segment accounted for the largest revenue share in 2023. The increased usage of molecular, particularly PCR tests, for diagnosing COVID-19 has increased the segment share significantly.

The central laboratories segment dominated the industry in 2023 owing to high procedure volumes for COVID testing and other healthcare indications in central laboratories.

North America dominated the market and accounted for a 39.3% share in 2023. This is attributed to the rising epidemiology of infectious as well as chronic diseases, thus, encouraging companies to introduce novel molecular diagnostic tests, thereby boosting market growth.

Asia Pacific is anticipated to exhibit significant growth from 2024 to 2030 owing to increased market penetration, initiatives of local market players to increase the adoption of novel diagnostic technologies, and high unmet market needs.

For More Details or Sample Copy please visit link @: Molecular Diagnostics Market Report

Molecular diagnostics plays an important role in infectious disease testing as they can yield effective and fast results. Hence, the increasing prevalence of hospital-acquired infections & infectious diseases is projected to drive the market over the forecast period. Increasing incidence and awareness regarding genetic disorders is further anticipated to accelerate market growth. The miniaturization of three basic molecular assays-nanobiotechnology, biochips, and microfluidics are expected to increase the accuracy and specificity of diagnostic outcomes, and hence, increase the demand for molecular diagnostic products. These improvements are expected to enhance the availability of PoC molecular diagnostic tests to yield quick and effective test results.

Companies are expanding their product portfolios with the acquisition of smaller companies. For instance, in March 2021, Hologic announced the acquisition of Diagenode-a molecular diagnostic company with a wide range of PCR instruments, facilitating the detection of over 30 bacteria-for USD 159 million. Similarly, in April 2021, F. Hoffmann-La Roche Ltd. acquired GenMark Diagnostics, Inc. at a price of USD 24.05 per share in cash, and it holds around 82.89% of total shares of GenMark Diagnostics. GenMark Diagnostics, Inc. has proprietary technologies, such as eSensor XT-8 and ePlex, which can be utilized in developing tests for infectious diseases, including bloodstream infections.

#MolecularDiagnostics #PrecisionMedicine #HealthcareInnovation #GenomicTesting #DiagnosticsTechnology #Biotechnology #PersonalizedMedicine #DiagnosticRevolution #NGS #BiomarkerDiscovery #InfectiousDiseaseDiagnosis #CancerDetection #Theranostics #Bioinformatics #MolecularBiology #DiagnosticTrends #MedicalTechnology #LaboratoryTesting #PointofCareDiagnostics #HealthTechInnovation

#Molecular Diagnostics #Precision Medicine #Healthcare Innovation #Genomic Testing #Diagnostics Technology #Biotechnology #Personalized Medicine #Diagnostic Revolution #NGS #Next Generation Sequencing #Biomarker Discovery #Infectious Disease Diagnosis #Cancer Detection #Theranostics #Bioinformatics #Molecular Biology

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asrarblog · 1 year

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Understanding Precision Medicine – Asrar Qureshi’s Blog Post #821

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#Adverse Events #Asrar Qureshi #Blogpost821 #Diagnostic Tools #Genome Testing #Personalized Medicine #Pharma Industry #Pharma Veterans #Precision Medicine #Targeted Therapy

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jesse-pinkman123 · 2 years

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The request analysis report speaks about the growth rate of Precision Medicine Diagnostics Market till 2028 manufacturing process, crucial factors driving this request with deals, profit, and price analysis of top manufacturers of request, distributors, dealers and dealers of Precision Medicine Diagnostics Market.

#Precision Medicine Diagnostics Market Share #Precision Medicine Diagnostics Market Analysis

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jackiequick · 10 months

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TOP GUN OCs Part 3 ✈️

-> Click here to see the other parts

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Nurse Jordana "Echo" Walker 🩺

Callsign: Echo

Age: 38

Relationship status: Divorced, Single

Background: Jordana, known as "Echo," is a skilled medical doctor in the squadron. She earned her callsign due to her exceptional diagnostic skills and the ability to provide vital medical support during missions. Her father was a renowned military surgeon, which inspired her to pursue a career in medicine.

Personality: Compassionate, charming, level-headed, and dedicated to her patients' well-being.

Lifestyle: Echo leads a fulfilling life, both personally and professionally, and is committed to her role as a doctor.

Nicknames: Her colleagues often refer to her as "Jor” or “Jordan”

Extra information: What she loves the most is getting get nails dirty and behind the wheel of a car or plane, ever since she was a child she was fancied by the way Navy pilots took the skies and feel like nothing even better once they’re above the clouds. That feeling of watching the world spin around while your frozen to your seat in the air and the adrenaline you get afterwards.

She was flying for a while in the late 90s—early 2000s, when she saw plenty of pilots become jet washed and she didn’t like it one bit, hearing stories about plenty being injured on the job and not a lot of staff on board, so that resulted in her taking up a medical exam. A few short months later, she started working alongside nurses and doctors to help nurse pilots back to health. Which is where she met Captain Maverick Mitchell, as he was injured after flight testing and sent to the medical wing of the North Islands to get check up, he was charming and thanked her for cleaning up his wounds.

With a smile Jor told Mav, “You gotta be more careful next time, Captain.” Maverick just grinned and nodding, saying he’ll try to best more cautious even though sometimes tells him, he will be back in this medical wing a few short months later. And he was right, meeting Jor again as she was sewing his wounds near his eyebrow. That time, he brought a friend who got hurt with him. Wraith. So she had two patients to nurse back to health, thankfully they weren’t that badly affected from the crash. Just a few cuts, bumps and bruises.

It didn’t take long for Jor to meet the rest of the 86 crew members, as Hollywood, Wolfman and Slider would make appearances at the hospital along with their friends Iceman, Buzz, Valkyrie, Sunset and others. Sometimes it was for checkups, other times to see some of their friends at the clinic but sometimes they just liked hanging out with the staff. Mainly because they were good people.

Captain Apollo "Mack" McCleary🔐

Callsign: Mack

Age: 42

Background: Mack, known simply as "Mack," is a control room operator. He earned his callsign due to his impeccable skills in managing communications and mission coordination. His precision and reliability make him an essential part of the squadron.

Personality: Analytical, total sweetheart, humorous, reliable, and a natural problem-solver.

Lifestyle: Mack has a steady and disciplined lifestyle, often working long hours in the control room.

Relationship Status: Mack is married to his high school sweetheart.

Nicknames: His colleagues affectionately call him "Mac."

Extra information: Apollo has been in the multiple square areas and has been working ever since he started back in 2005 in the Navy, wanting to be apart of Blue Angels and be behind the controls. He has always been one to have honest honor and respect towards everyone around him, putting his trust and thoughts into pilots he believes who can take the heat as he navigates them from the operations center. Such as Iceman, he would give all his attention and follow his leadership, as he stands back in the frontline of the control room sending up to the skies.

But it also gets him into a lot of trouble, due to him listening to Maverick during the Darkstar Project for Mach 10! Apollo knew it was supposed to be canceled that day, but a part of him though they gone so far into the process of making a jet that can go hypersonic it was worth a final flight according to Maverick. So Mack and his team got to quick work setting everything up in the control room launching Maverick into the air as he commuted with him from the ground reaching Mach 10–but it cost him and Hondo in some trouble with Admiral Cain afterwards. Even though, Apollo got into some trouble he was secretly grinning due to the fact that they achieved that purpose for the project, running home to his high school sweetheart to tell them to the good news.

Afterwards, Hondo gave him a call telling Mack he would be sent to Top Gun to help manage communication and mission coordinations. He was humorous about the fact that he would be returning back to North Island. But he always knew that he would never have a bad reputation there, since one of his friends/lieutenants Fanboy Garcia and Payback Fitch would be sent out the same mission too. So let’s just say things got interesting when he saw how The Dagger Squad decided to challenge Maverick, because Mack was waiting for every single one of them for their push-ups with a smirk.

Mack had his arms crossed and said, “It was all shits and giggles, huh? Drop down and start giving me 10 then we’ll raise it to 20.” All the Daggers glared at him, dropping down giving him 20 push ups as Hondo grinned counting them.

Naomi "Nova" Reynolds🍻

Callsign: Nova

Age: 28

Relationship Status: Single

Background: Naomi, known as "Nova," is a bartender who owns a popular bar near the naval base. Her callsign reflects her vibrant and outgoing personality, which lights up the atmosphere in her establishment. She serves as a source of support and encouragement for the Navy personnel and fighter pilots who frequent her bar.

Personality: Charismatic, welcoming, and known for her sense of humor.

Lifestyle: Nova enjoys a social and active lifestyle, always looking to bring joy to those around her. But she also sassy, knowledgeable due to being a bartender so she knows secrets, and loves karaoke.

Nicknames: She's often referred to as "No" by her regular customers. The women know the rules for the bar set by Penny Benjamin, so she doesn’t have a problem telling people “No”, or “No roughhousing, take it outside.”

Extra information: Naomi never really knew what she wanted to do in (still doesn’t to be honest), as she always has dreams and aspirations for things but as time files so quickly it feels like those ideals weren’t coming as fast as she wanted. As Naomi always said she wanted to be a writer, a musician of some kind finding herself making stories and music, then posting them on social media for some sort of attraction. One afternoon, at The Hard Deck she decided to take a chance singing on the small stage with her old guitar and caught a few eyes.

Penny, the owner of the bar saw how nice of an impression she made on the crowd and offered her a chance to sing whenever she wants. She even asked if she was open to working at the bar as well, Naomi didn’t mind it at all and agreed to Penny’s offer. Training under her and practicing bartending. And to be honest, Naomi loved it!

Working at The Hard Deck made her smile, let her have some fixable schedules since she had an active lifestyle and socialize with brand new people everyday. It resulted in her meeting some friends such as Lucky Kenner, who she already met before she started working there, and the rest of the Daggers. Anyone who walks into the bar, she’s always the first one to greet them at the counter with a smile pouring drinks and taking orders. They would say she’s a sight for sore eyes with an encouraging enough smile.

Jeremy "Renegade" Turner 🗃

Callsign: Renegade

Age: 47

Background: Jeremy, known as "Renegade," grew up in a family with a military tradition. His father was a Navy pilot, and he followed in his footsteps. His callsign reflects his tendency to sometimes push boundaries and sometimes take unconventional approaches during missions, often against orders. Makes sense how he ended up with Maverick as a friend.

Personality: Adventurous, sarcastic and snarky, witty, a bit rebellious, and unafraid to take risks depending on the situation.

Lifestyle: Renegade is a single pilot who leads an adventurous and sometimes unpredictable life, as he’s always sent on missionary work to go undercover and investigate tasks for the Navy. Sometimes it makes him question his line of work and wonder when’s retirement for him again.

Relationship Status: Single

Nicknames: His fellow aviators often call him "Ren" for short.

Extra information: Due to him messing around with Maverick and his gang so much, it makes wonder if he needs new friends, then he remembers Iceman and Wraith are there then he feels a little better. He thinks he’s sarcastic, stubborn as hell and snarky until he met Iceman’s wife Daredevil also known as Hazel, who nicknames him Hawkeye as a joke.

Ren has been working on and off duty for years, everytime he thinks he’s off the hook or thinking retirement is on his way—BAM! He’s given new duties to watch over new records and recruits for TOP GUN, which in his opinion ain’t so bad. He actually liked the new fresh faced students at TOP GUN, being so young and spirited in the way they fly. Some are way cocky for their own good where they get in trouble with their superior officers meanwhile others are trying to keep an low profile and just learn from their own actions.

Ren being well..Ren, always try to get under their skin and see what they’re made of, in small manners. Like let’s say he’s talking to another person and a student is running in the halls, he tells them to not do that but they won’t listen. So in result, Ren would lean a foot outwards causing the student to trip and learn to not run in the hallway. “Oops..i said watch where your going!” Ren said with a little smirk.

Sometimes Ren gets dragged into the craziness of Maverick Mitchell and the others plan. Such as when he was given the role to return to Top Gun as an independent counsel with Hondo and Hazel, having to watch over the team of returning recruits for the highly competitive mission. A few of them, he trained himself being their co-instructor years back, being Payback, Phoenix, Yale and Harvard. Even met Halo once during her classes.

Ren was in charge of being the one up in the far skies and taking notes of the crews flying skills, measuring their speeding length as they went along. Having everything ready for pre and landing as well! Like said beforehand, Ren has a tendency to not always follow orders and end up regularly regretting it later depending on what it is, pushing a few boundaries when it came to Admirals. So in result, he was the one to open the hard deck without Admiral Cyclone’s permission for Maverick to fly and even a few other things.

—

Thanks for reading! Who are your favorites of the 4? Let me know in the comments below

Remember to like, share and reblog for more like this

Tags: @gaminggirlsstuff @starkleila @halesfavoriteharlot @missstrawbs2001 @gcthvile @mandylove1000 @rooster-84 @mallowbee4 @degenbrat @hardballoonlove @queenslandlover-93 @djs8891 @theloveoftoms @topgun-imagines @simplyscorpio @roostersforevergirl and etc

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hypocrite-human · 10 months

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AI & IT'S IMPACT

Unleashing the Power: The Impact of AI Across Industries and Future Frontiers

Artificial Intelligence (AI), once confined to the realm of science fiction, has rapidly become a transformative force across diverse industries. Its influence is reshaping the landscape of how businesses operate, innovate, and interact with their stakeholders. As we navigate the current impact of AI and peer into the future, it's evident that the capabilities of this technology are poised to reach unprecedented heights.

1. Healthcare:

In the healthcare sector, AI is a game-changer, revolutionizing diagnostics, treatment plans, and patient care. Machine learning algorithms analyze vast datasets to identify patterns, aiding in early disease detection. AI-driven robotic surgery is enhancing precision, reducing recovery times, and minimizing risks. Personalized medicine, powered by AI, tailors treatments based on an individual's genetic makeup, optimizing therapeutic outcomes.

2. Finance:

AI is reshaping the financial industry by enhancing efficiency, risk management, and customer experiences. Algorithms analyze market trends, enabling quicker and more accurate investment decisions. Chatbots and virtual assistants powered by AI streamline customer interactions, providing real-time assistance. Fraud detection algorithms work tirelessly to identify suspicious activities, bolstering security measures in online transactions.

3. Manufacturing:

In manufacturing, AI is optimizing production processes through predictive maintenance and quality control. Smart factories leverage AI to monitor equipment health, reducing downtime by predicting potential failures. Robots and autonomous systems, guided by AI, enhance precision and efficiency in tasks ranging from assembly lines to logistics. This not only increases productivity but also contributes to safer working environments.

4. Education:

AI is reshaping the educational landscape by personalizing learning experiences. Adaptive learning platforms use AI algorithms to tailor educational content to individual student needs, fostering better comprehension and engagement. AI-driven tools also assist educators in grading, administrative tasks, and provide insights into student performance, allowing for more effective teaching strategies.

5. Retail:

In the retail sector, AI is transforming customer experiences through personalized recommendations and efficient supply chain management. Recommendation engines analyze customer preferences, providing targeted product suggestions. AI-powered chatbots handle customer queries, offering real-time assistance. Inventory management is optimized through predictive analytics, reducing waste and ensuring products are readily available.

6. Future Frontiers:

A. Autonomous Vehicles: The future of transportation lies in AI-driven autonomous vehicles. From self-driving cars to automated drones, AI algorithms navigate and respond to dynamic environments, ensuring safer and more efficient transportation. This technology holds the promise of reducing accidents, alleviating traffic congestion, and redefining mobility.

B. Quantum Computing: As AI algorithms become more complex, the need for advanced computing capabilities grows. Quantucm omputing, with its ability to process vast amounts of data at unprecedented speeds, holds the potential to revolutionize AI. This synergy could unlock new possibilities in solving complex problems, ranging from drug discovery to climate modeling.

C. AI in Creativity: AI is not limited to data-driven tasks; it's also making inroads into the realm of creativity. AI-generated art, music, and content are gaining recognition. Future developments may see AI collaborating with human creators, pushing the boundaries of what is possible in fields traditionally associated with human ingenuity.

In conclusion, the impact of AI across industries is profound and multifaceted. From enhancing efficiency and precision to revolutionizing how we approach complex challenges, AI is at the forefront of innovation. The future capabilities of AI hold the promise of even greater advancements, ushering in an era where the boundaries of what is achievable continue to expand. As businesses and industries continue to embrace and adapt to these transformative technologies, the synergy between human intelligence and artificial intelligence will undoubtedly shape a future defined by unprecedented possibilities.

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covid-safer-hotties · 1 day

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COVID-19: examining the effectiveness of non-pharmaceutical interventions - Published Aug 2023 (PDF)

The license is available at: creativecommons.org/licenses/by/4.0

Executive summary

Introduction

The purpose of this report from the Royal Society is to assess what has been learnt about the effectiveness of the application of non-pharmaceutical interventions (NPIs) during the COVID-19 pandemic of 2020 – 2023 by assembling and examining evidence from researchers around the world. These NPIs were a set of measures (described in Box 1) aimed at reducing the person-to-person transmission of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the virus that caused the pandemic. Six groups of researchers were commissioned to assemble evidence reviews for this report, examining the effectiveness of a range of NPIs that were applied with the aim of reducing the transmission of SARS-CoV-2. Researchers were tasked with documenting what has been learnt, identifying gaps in knowledge and considering how these might be filled in the future. This report summarises these evidence reviews and interprets them alongside national case studies. It pays particular attention to the context and the constraints on the types of research that could be and were performed during the pandemic. The report is non-judgemental on the timing and manner in which NPIs were applied in different regions and countries around the world. It focuses on understanding the impact of NPIs on SARS-CoV-2 transmission and makes no assessment of the economic or other societal impacts of the different NPIs. Assessing these other impacts are important tasks for the many different COVID-19 inquiries that are underway around the world.

From the start of the pandemic, rapidly growing scientific information was deployed continuously to help to control its spread. The genome of the causative virus, SARS-CoV-2, was sequenced from some of the very earliest samples available from infected humans in China. This sequence information enabled the development of precise molecular diagnostic tests that could be used for diagnosis and mass testing of populations, the development of vaccines and continuous monitoring of the evolution of the virus. The development of tests led to the widespread implementation of ‘test, trace and isolate’ interventions early in the pandemic. COVID-19 was the first pandemic in which it was feasible to conduct prophylactic and therapeutic drug trials and to create novel vaccines during the course of the pandemic, saving lives and modifying the outcomes. However, despite extraordinary scientific capabilities, for most of the first year of the pandemic the only measures available to slow the transmission of the novel virus were NPIs. For those that were infected and seriously ill, there were no specific treatments or preventative measures in the form of drugs or vaccines. The supportive measures of modern medicine, such as oxygen supplementation, pulmonary ventilation and other forms of advanced life support, saved many lives, but did nothing to slow transmission.

What are NPIs? The principles behind NPIs are firmly grounded in prior knowledge about the epidemiology and biology of infectious diseases. In essence, the transmission of an infection from one human to another can be prevented if the transmission pathway can be blocked effectively. For an airborne virus such as SARSCoV-2, effective measures reduce exposure to virus that has been exhaled by infected people (by breathing, talking, coughing or sneezing). Measures that can assist, in theory, include the wearing of face masks, enhanced ventilation and social distancing. Where infectious virus survives on surfaces (furniture, clothes or hands), cleaning regimes including enhanced handwashing can help. Personal protection equipment (PPE), common in healthcare environments (including gloves, visors, gowns and masks) potentially offers protection against exposure.

Early clinical studies of COVID-19 strongly suggested that the primary routes for acquiring infection were likely to be by direct inhalation or exposure of the mucosal surfaces of the nose and mouth to virus suspended in airborne droplets or, as was realised some months into the pandemic, in aerosols. Early evidence of fomites (contaminated surfaces), extensively contaminated with SARS-CoV-2 viral nucleic acid shed from infected people, pointed to the possibility that hand-to-face contact might also transmit the infection. This view was informed by prior knowledge of the transmission mechanisms of other respiratory viruses, such as influenza, respiratory syncytial virus (RSV) and the coronavirus (now named SARS-CoV-1) that caused the SARS outbreak in several countries around the world in 2003.

Use of NPIs for infectious disease control Considering the incomplete knowledge about this new viral infection and prior knowledge, many governments around the world implemented measures similar to those used just over a century earlier during the 1918 influenza pandemic. Some countries in Asia implemented measures based on their more recent experience of outbreaks of SARS and Middle East Respiratory Syndrome (MERS). NPIs included the wearing of masks and enhanced personal hygiene measures, including enhanced surface cleaning and handwashing. Social distancing was introduced and enforced to variable extents. Social distancing measures included closures of schools and workplaces, as well as entertainment, leisure and sporting venues. These closures were often augmented by stayat-home orders for all but essential workers.

Border controls and closures were put in place in many countries with the aim of reducing the movement of cases across national borders. The precise measures, and the ways they were implemented, varied between countries according to their social and political-economic contexts and prior experiences. In most of the world, NPIs remained the dominant mechanism for control of the pandemic until well into its second year. The UK was the first country to approve the use of vaccines against SARS-CoV-2, approving three vaccines during December 2020 and January 2021. By July 2021, approximately half of the UK’s population had received two doses of vaccine. However, it took until January 2022 for half of the global population to have had two doses – and a year later in January 2023 the global figure had risen to approximately 63%.

The challenge for governments around the world facing a pandemic is how to minimise the harms to their populations. The harms of a pandemic are the morbidity and mortality from the viral infection, coupled with the social disruption and harms that follow from the direct and indirect consequences of that morbidity and mortality. The latter can be exceptionally severe if the extent of illness and social response to the illness disrupts the healthcare systems, infrastructure, goods and services on which the health, wellbeing, resilience and security of the population depend.

What are non-pharmaceutical interventions (NPIs)? NPIs include any measure that is implemented during an infectious disease outbreak to attempt to reduce transmission that is not a vaccine or drug. NPIs can be behavioural, social, physical, or regulatory in nature. Their uptake and use can be encouraged through a variety of approaches, escalating from advice and guidance through to regulation. NPIs are therefore the first line of defence in the effort to contain outbreaks and to limit the impacts on affected populations before biological interventions become available. They have also been used alongside vaccines and drugs, especially where these interventions fail to prevent transmission. The precise ways in which NPIs were implemented during the COVID-19 pandemic varied between different countries and contexts.

The programme of work described in this report covered six broad categories of NPIs and the evidence available concerning= their effectiveness at reducing transmission of SARS-CoV-2. The six categories are as follows:

Masks and face coverings Masks act as barriers to virus particles in air being inhaled and/or exhaled through the nose or mouth. Virus-carrying droplets (larger, heavier particles) or aerosols (smaller, lighter articles) captured on the inside or outside of the mask can no longer spread via the air. The materials and features of masks affect the size of the particles that are filtered out, and their resulting effectiveness. How well the mask fits the face of the wearer is also key. N95 masks (also known as respirators), when worn correctly, are highly effective barriers.

Social distancing and ‘lockdowns’ Respiratory diseases are transmitted by infectious material carried by exhalations (eg. breathing, talking, coughing or sneezing) from one individual to another. Increasing physical distance between individuals can reduce the amount of infectious material being carried to others in droplets and aerosols, although aerosols typically transmit over longer distances than droplets. A commonly recommended minimum distance of separation between individuals during the COVID-19 pandemic was two metres. Interventions on populations and communities included closures of schools, workplaces, places of worship and entertainment venues, as well as ‘stay-at-home’ orders (‘lockdowns’) that prevented most people from coming into contact with anyone outside their own homes.

Test, trace and isolate SARS-CoV-2 is transmitted when infected individuals are in close proximity to others. A strategy employed to break the chain of transmission is to identify infectious people (‘test’), determine with whom they have come into physical contact (‘trace’) and encourage or enforce both infected individuals and their contacts to stay at home and avoid physical contact with others until the risk of being infectious has subsided (‘isolate’).

Travel restrictions and controls across international borders During a pandemic, where an infectious disease is spreading across international borders, restricting the ability of people to move between countries can be used to try to prevent the global movement of the pathogen. Border controls applied during the pandemic varied in stringency and took the form of complete or partial bans targeted at international travellers from particular regions perceived as being at higher risk. Often border controls were accompanied by requirements for international travellers to test and/or quarantine at the border of departure and/or arrival to enable some travel.

Environmental controls Particles carrying infectious material vary in size from droplets that settle on surfaces close to the point of exhalation through to very fine aerosols which can linger in the air and travel further. Certain elements of building design and management can be implemented with the intention of restricting the spread of respiratory pathogens. These include enhancing ventilation systems to replace air carrying infectious aerosols with outside air, and filtering or treating air inside buildings to reduce infectious virus. Screens made of a variety of materials and reduced occupancy limits for rooms or buildings can also be used. Environmental controls also include cleaning of surfaces to remove droplets carrying infectious material and enhanced handwashing.

Communications Effective communication about any of thephysical, social or behavioural interventions is essential if people are to understand and be convinced of the reason for their use, as well as being willing to adopt and maintain the practices, and to do so correctly, so as to maximise effectiveness.

#mask up #covid #pandemic #covid 19 #wear a mask #public health #coronavirus #sars cov 2 #still coviding #wear a respirator

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hedwig-dordt · 1 year

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The Ig Nobel Prize, for scientific research that makes people laugh and then makes them think. This year's winners!

CHEMISTRY and GEOLOGY PRIZE [POLAND, UK] Jan Zalasiewicz, for explaining why many scientists like to lick rocks. REFERENCE: “Eating Fossils,” Jan Zalasiewicz, The Paleontological Association Newsletter, no. 96, November 2017. Eating fossils | The Palaeontological Association (palass.org) WHO TOOK PART IN THE CEREMONY: Jan Zalasiewicz

LITERATURE PRIZE [FRANCE, UK, MALAYSIA, FINLAND] Chris Moulin, Nicole Bell, Merita Turunen, Arina Baharin, and Akira O’Connor for studying the sensations people feel when they repeat a single word many, many, many, many, many, many, many times. REFERENCE: “The The The The Induction of Jamais Vu in the Laboratory: Word Alienation and Semantic Satiation,” Chris J. A. Moulin, Nicole Bell, Merita Turunen, Arina Baharin, and Akira R. O’Connor, Memory, vol. 29, no. 7, 2021, pp. 933-942. doi.org/10.1080/09658211.2020.1727519 WHO TOOK PART IN THE CEREMONY: Chris Moulin, Akira O’Connor

MECHANICAL ENGINEERING PRIZE [INDIA, CHINA, MALAYSIA, USA] Te Faye Yap, Zhen Liu, Anoop Rajappan, Trevor Shimokusu, and Daniel Preston, for re-animating dead spiders to use as mechanical gripping tools. REFERENCE: “Necrobotics: Biotic Materials as Ready-to-Use Actuators,” Te Faye Yap, Zhen Liu, Anoop Rajappan, Trevor J. Shimokusu, and Daniel J. Preston, Advanced Science, vol. 9, no. 29, 2022, article 2201174. doi.org/10.1002/advs.202201174 WHO TOOK PART IN THE CEREMONY: Te Faye Yap and Daniel Preston

PUBLIC HEALTH PRIZE [SOUTH KOREA, USA] Seung-min Park, for inventing the Stanford Toilet, a device that uses a variety of technologies — including a urinalysis dipstick test strip, a computer vision system for defecation analysis, an anal-print sensor paired with an identification camera, and a telecommunications link — to monitor and quickly analyze the substances that humans excrete. REFERENCE: “A Mountable Toilet System for Personalized Health Monitoring via the Analysis of Excreta,” Seung-min Park, Daeyoun D. Won, Brian J. Lee, Diego Escobedo, Andre Esteva, Amin Aalipour, T. Jessie Ge, et al., Nature Biomedical Engineering, vol. 4, no. 6, 2020, pp. 624-635. doi.org/10.1038/s41551-020-0534-9 REFERENCE: “Digital Biomarkers in Human Excreta,” Seung-min Park, T. Jessie Ge, Daeyoun D. Won, Jong Kyun Lee, and Joseph C. Liao, Nature Reviews Gastroenterology and Hepatology, vol. 18, no. 8, 2021, pp. 521-522. doi.org/10.1038/s41575-021-00462-0 REFERENCE: “Smart Toilets for Monitoring COVID-19 Surges: Passive Diagnostics and Public Health,” T. Jessie Ge, Carmel T. Chan, Brian J. Lee, Joseph C. Liao, and Seung-min Park, NPJ Digital Medicine, vol. 5, no. 1, 2022, article 39. doi.org/10.1038/s41746-022-00582-0 REFERENCE: “Passive Monitoring by Smart Toilets for Precision Health,” T. Jessie Ge, Vasiliki Nataly Rahimzadeh, Kevin Mintz, Walter G. Park, Nicole Martinez-Martin, Joseph C. Liao, and Seung-min Park, Science Translational Medicine, vol. 15, no. 681, 2023, article eabk3489. doi.org/10.1126/scitranslmed.abk3489 WHO TOOK PART IN THE CEREMONY: Seung-min Park

COMMUNICATION PRIZE [ARGENTINA, SPAIN, COLOMBIA, CHILE, CHINA, USA] María José Torres-Prioris, Diana López-Barroso, Estela Càmara, Sol Fittipaldi, Lucas Sedeño, Agustín Ibáñez, Marcelo Berthier, and Adolfo García, for studying the mental activities of people who are expert at speaking backward. REFERENCE: “Neurocognitive Signatures of Phonemic Sequencing in Expert Backward Speakers,” María José Torres-Prioris, Diana López-Barroso, Estela Càmara, Sol Fittipaldi, Lucas Sedeño, Agustín Ibáñez, Marcelo L. Berthier, and Adolfo M. García, Scientific Reports, vol. 10, no. 10621, 2020. doi.org/10.1038/s41598-020-67551-z WHO TOOK PART IN THE CEREMONY: María José Torres-Prioris, Adolfo García

MEDICINE PRIZE [USA, CANADA, MACEDONIA, IRAN, VIETNAM] Christine Pham, Bobak Hedayati, Kiana Hashemi, Ella Csuka, Tiana Mamaghani, Margit Juhasz, Jamie Wikenheiser, and Natasha Mesinkovska, for using cadavers to explore whether there is an equal number of hairs in each of a person’s two nostrils. REFERENCE: “The Quantification and Measurement of Nasal Hairs in a Cadaveric Population,” Christine Pham, Bobak Hedayati, Kiana Hashemi, Ella Csuka, Margit Juhasz, and Natasha Atanaskova Mesinkovska, Journal of The American Academy of Dermatology, vol. 83, no. 6, 2020, pp. AB202-AB202. doi.org/10.1016/j.jaad.2020.06.902 WHO TOOK PART IN THE CEREMONY: Christine Pham, Natasha Mesinkovska, Margit Juhasz, Kiana Hashemi, Tiana Mamaghani

NUTRITION PRIZE [JAPAN] Homei Miyashita and Hiromi Nakamura, for experiments to determine how electrified chopsticks and drinking straws can change the taste of food. REFERENCE: “Augmented Gustation Using Electricity,” Hiromi Nakamura and Homei Miyashita, Proceedings of the 2nd Augmented Human International Conference, March 2011, article 34. doi.org/10.1145/1959826.1959860 WHO TOOK PART IN THE CEREMONY: Homei Miyashita, Hiromi Nakamura

EDUCATION PRIZE [CHINA, CANADA, UK, THE NETHERLANDS, IRELAND, USA, JAPAN] Katy Tam, Cyanea Poon, Victoria Hui, Wijnand van Tilburg, Christy Wong, Vivian Kwong, Gigi Yuen, and Christian Chan, for methodically studying the boredom of teachers and students. REFERENCE: “Boredom Begets Boredom: An Experience Sampling Study on the Impact of Teacher Boredom on Student Boredom and Motivation,” Katy Y.Y. Tam, Cyanea Y. S. Poon, Victoria K.Y. Hui, Christy Y. F. Wong, Vivian W.Y. Kwong, Gigi W.C. Yuen, Christian S. Chan, British Journal of Educational Psychology, vol. 90, no. S1, June 2020, pp. 124-137. doi.org/10.1111/bjep.12549 REFERENCE: “Whatever Will Bore, Will Bore: The Mere Anticipation of Boredom Exacerbates its Occurrence in Lectures,” Katy Y.Y. Tam, Wijnand A.P. Van Tilburg, Christian S. Chan, British Journal of Educational Psychology, epub 2022. doi.org/10.1111/bjep.12549 WHO TOOK PART IN THE CEREMONY: Christian Chan, Katy Y.Y. Tam, Wijnand A.P. Van Tilburg

PSYCHOLOGY PRIZE [USA] Stanley Milgram, Leonard Bickman, and Lawrence Berkowitz for experiments on a city street to see how many passersby stop to look upward when they see strangers looking upward REFERENCE: “Note on the Drawing Power of Crowds of Different Size,” Stanley Milgram, Leonard Bickman, and Lawrence Berkowitz, Journal of Personality and Social Psychology, vol. 13, no. 2, 1969, pp. 79-82. psycnet.apa.org/doi/10.1037/h0028070 WHO TOOK PART IN THE CEREMONY: Len Bickman

PHYSICS PRIZE [SPAIN, GALICIA, SWITZERLAND, FRANCE, UK] Bieito Fernández Castro, Marian Peña, Enrique Nogueira, Miguel Gilcoto, Esperanza Broullón, Antonio Comesaña, Damien Bouffard, Alberto C. Naveira Garabato, and Beatriz Mouriño-Carballido, for measuring the extent to which ocean-water mixing is affected by the sexual activity of anchovies. REFERENCE: “Intense Upper Ocean Mixing Due to Large Aggregations of Spawning Fish,” Bieito Fernández Castro, Marian Peña, Enrique Nogueira, Miguel Gilcoto, Esperanza Broullón, Antonio Comesaña, Damien Bouffard, Alberto C. Naveira Garabato, and Beatriz Mouriño-Carballido, Nature Geoscience, vol. 15, 2022, pp. 287–292. doi.org/10.1038/s41561-022-00916-3 WHO TOOK PART IN THE CEREMONY: Bieito Fernandez Castro, Beatriz Mouriño-Carballido, Alberto Naveira Garabato, Esperanza Broullon, Miguel Gil Coto

#science #ig nobel prize winners #ig nobel prize

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acorpsecalledcorva · 10 months

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Additional thoughts on diagnostic criteria (hopefully short thoughts because I forgot to take my sleep meds and it's 5am)

Something that is currently debated in psych circles (academic slap fights in the letters to the editor section of journals are hilarious but really really interesting btw, do check them out) is how identity alteration interacts with the impairment part of the "Causes clinical distress or impairment/dysfunction" criteria. Some argue that, by nature, identity alteration is a dysfunction. You're supposed to have one contiguous if not continuous identity and so the formation of an alter identity is therefore by definition an impairment of identity and meets the dysfunction criteria. I don't think I'm alone in disliking this notion.

First up, bold fuckin claim dude, making a lot of assumptions about how sure we are about what identity and consciousness are and how they are internally experienced globally aren't ya. Secondly, that's such a narrow view of even the multiplicity experiences. Is having blorbos in your head an alteration of identity? I mean sure there's passive influence and dissociative intrusions but those make a Venn Diagram not a circle. Even with blackout switching, not every system experiences that as an alteration of identity, they don't become someone else, they just go away and someone else takes over. It may externally appear to be an alteration of identity to an observer but who the fuck are they to define what it actually means to the person living it.

It really highlights how much of medicine and psychology is just a fucked up hogwarts sorting hat of normal and not normal with arbitrary boundaries that increasingly fall apart the more rigid you try to make them.

This is why I really appreciate the approach Eli Somer takes with Maladaptive Daydreaming. He's literally just like "Yo! That actually sounds so cool! Wish I could do that! Sorry you're struggling with it though let's see if we can work on that", defining the disorder by the experience of dysfunction as opposed to the observation of dysfunction and saying "Ew, mentally ill people are weird and make me uncomfortable"

It is all part of the process though, borders and boundaries are meant to be challenged, whittling them down like recursively dividing by two, never approaching zero but getting ever thinner, precise but fragile.

Ah beans I made it long again didn't I 🥹

#syscourse

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innonurse · 2 years

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US: According to a Carta Healthcare survey, a majority of patients supply duplicate health information

- By InnoNurse Staff -

According to a new Carta Healthcare survey, 80% of respondents stated healthcare workers spend more than half of their time during the visit staring at screens rather than at the patient in front of them. Patients were also dissatisfied that their health data was not being used to their benefit.