made minos prime out of gmo e. coli

12,500 Years Later Dire Wolves Reborn : Return of the Ice Age Predator

Colossal Biosciences has produced three dire wolf pups—two males and one female—using gene editing, cloning, and ancient DNA from fossils dated 13,000 to 72,000 years old. By editing 14 genes in gray wolf cells to match dire wolf traits like thick fur, stronger jaws, and broader skulls, scientists recreated the dire wolf phenotype. The embryos were implanted into domestic dogs.

The pups, born in late 2024 and early 2025, now live on a secure 2,000-acre site under strict oversight. While the animals are about 99.9% gray wolf, Colossal claims this is the first real proof of de-extinction in practice and a step toward reviving species like the mammoth and dodo. #direwolves #extinctanimals #sciencenews #biology #genetics #wildlife #conservation #DeExtinctionProject #animalscience #futureofscience #DireWolfDeExtinction #colossalbiosciences #geneticengineering #ExtinctSpeciesRevival #ancientdna #crisproducciones #DeExtinctionTechnology #wildlifeconservation #PleistoceneFauna #ResurrectionScience #bioengineering

Be Thankful

Glazed in beguiling dark humor, this taxidermy sculpture has a serious message that rings even more true today than it did when I originally made the piece ten years ago. As most of you likely have heard, the population of Earth just reached 8 billion. In the span of a mere decade since this sculpture was created, an additional billion humans now live on the planet. Below is the statement that accompanied this sculpture the first time it was exhibited in 2014 in a themed exhibition titled Fruitful and Multiplying – The Overpopulation Exhibit. So much for progress.

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TITLE: Turducken à la Monsanto MATERIALS: Domestic duck, turkey, and rooster skins

“This piece is a commentary on the absurdity and entitlement of gourmet foods, the privilege of being able to allocate food for the purpose of art, and the disconcerting technology of interspecies grafting performed by the bioengineering industry. The strain on our planet's resources has become immense as the population of Earth crests 7 billion. With a tipping point looming, genetic engineers are creating hybrid species of livestock and crops designed to produce the highest yield possible while using the least amount of resources. The reality is many developing countries do not have the means to utilize this controversial technology and only an elite portion of the Earth's population will profit from these so-called advances. We live in a country rich in all resources. It enables us to use food towards a myriad of frivolous ends, including our entertainment. We create designer cuisine that is more about status than it is about sustenance, and we feed human quality food to our pets. While we enjoy our luxury foods, for much of the world just having food is a luxury.” ~

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I recently culled a number of works from my personal collection to offer for sale. This sculpture is among a handful of others that are now available. Link here for price list

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Soft optical fibers block pain while moving and stretching with the body

The fibers could help with testing treatments for nerve-related pain.

Jennifer Chu | MIT News

Scientists have a new tool to precisely illuminate the roots of nerve pain.

Engineers at MIT have developed soft and implantable fibers that can deliver light to major nerves through the body. When these nerves are genetically manipulated to respond to light, the fibers can send pulses of light to the nerves to inhibit pain. The optical fibers are flexible and stretch with the body.

The new fibers are meant as an experimental tool that can be used by scientists to explore the causes and potential treatments for peripheral nerve disorders in animal models. Peripheral nerve pain can occur when nerves outside the brain and spinal cord are damaged, resulting in tingling, numbness, and pain in affected limbs. Peripheral neuropathy is estimated to affect more than 20 million people in the United States.

“Current devices used to study nerve disorders are made of stiff materials that constrain movement, so that we can’t really study spinal cord injury and recovery if pain is involved,” says Siyuan Rao, assistant professor of biomedical engineering at the University of Massachusetts at Amherst, who carried out part of the work as a postdoc at MIT. “Our fibers can adapt to natural motion and do their work while not limiting the motion of the subject. That can give us more precise information.”

“Now, people have a tool to study the diseases related to the peripheral nervous system, in very dynamic, natural, and unconstrained conditions,” adds Xinyue Liu PhD ’22, who is now an assistant professor at Michigan State University (MSU).

Details of their team’s new fibers are reported today in a study appearing in Nature Methods. Rao’s and Liu’s MIT co-authors include Atharva Sahasrabudhe, a graduate student in chemistry; Xuanhe Zhao, professor of mechanical engineering and civil and environmental engineering; and Polina Anikeeva, professor of materials science and engineering, along with others at MSU, UMass-Amherst, Harvard Medical School, and the National Institutes of Health.

Keep reading.

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Living Intelligence: The Fusion of AI, Biotechnology, and Sensors

How AI, Biotechnology, and Sensors Create Adaptive Living Systems

Introduction: A New Frontier in Living Intelligence Technology

In today’s era of rapid technological breakthroughs, the convergence of artificial intelligence (AI), biotechnology, and advanced sensor technology is giving rise to an extraordinary new paradigm known as Living Intelligence. This innovative fusion blurs the lines between biological systems and machines, creating adaptive, self-regulating systems that exhibit characteristics of living organisms.

Living intelligence systems have the potential to transform numerous fields from health monitoring and personalized medicine to environmental sensing and smart cities. By mimicking natural processes such as learning, adaptation, and self-healing, these technologies open doors to solutions that were previously unimaginable.

As this field evolves, it is poised to revolutionize how humans interact with technology, enabling smarter ecosystems that respond dynamically to their environment. For those interested in exploring the cutting edge of science and technology, living intelligence represents a thrilling frontier with vast potential.

To learn more about the intersection of biology and AI, explore research initiatives at the MIT Media Lab.

Understanding Living Intelligence: The Fusion of AI, Biotechnology, and Sensors

Living intelligence represents a cutting-edge integration of artificial intelligence (AI), biotechnology, and advanced sensor technologies to create dynamic, responsive systems capable of perceiving, learning, and adapting in real time. Unlike traditional machines or static software programs, living intelligence systems embody characteristics commonly found in biological organisms including self-organization, evolutionary adaptation, and environmental responsiveness.

At the heart of living intelligence lies a powerful synergy between three core components:

AI’s data processing and machine learning capabilities: These enable the system to analyze vast amounts of data, identify patterns, and make informed decisions autonomously.

Biotechnology’s expertise in biological processes: This allows for the manipulation and integration of living cells or biomaterials into technological systems, enabling functionalities such as self-repair and growth.

Advanced sensor technology: High-precision sensors collect real-time data from the environment or living organisms, feeding information continuously to AI algorithms for rapid response.

This triad facilitates a seamless flow of information between biological and artificial elements, resulting in adaptive, efficient, and often autonomous systems that can operate in complex, dynamic environments. These systems have promising applications across healthcare, environmental monitoring, robotics, and beyond.

For an in-depth look at how living intelligence is shaping future technologies, check out this insightful overview from Nature Biotechnology.

The Role of AI in Living Intelligence: The Cognitive Engine of Adaptive Systems

Artificial Intelligence (AI) serves as the cognitive engine powering living intelligence systems. Leveraging advances in deep learning, neural networks, and machine learning algorithms, AI excels at pattern recognition, predictive analytics, and complex decision-making. When combined with biological inputs and continuous sensor data streams, AI can decode intricate biological signals and convert them into meaningful, actionable insights.

For instance, in healthcare technology, AI algorithms analyze data from wearable biosensors that track vital signs such as heart rate variability, glucose levels, or brain activity. This enables early detection of illnesses, stress markers, or other physiological changes, empowering proactive health management and personalized medicine.

In the field of precision agriculture, AI integrated with biosensors can monitor plant health at a molecular or cellular level, optimizing irrigation, nutrient delivery, and pest control to enhance crop yield while minimizing resource use promoting sustainable farming practices.

Beyond analysis, AI also drives continuous learning and adaptive behavior in living intelligence systems. These systems evolve in response to new environmental conditions and feedback, improving their performance autonomously over time mirroring the self-improving nature of living organisms.

For more on how AI transforms living intelligence and bio-integrated systems, explore resources from MIT Technology Review’s AI section.

Biotechnology: Bridging the Biological and Digital Worlds in Living Intelligence

Biotechnology serves as the critical bridge between biological systems and digital technologies, providing the tools and scientific understanding necessary to interface with living organisms at the molecular and cellular levels. Recent breakthroughs in synthetic biology, gene editing technologies like CRISPR-Cas9, and advanced bioengineering have unlocked unprecedented opportunities to design and manipulate biological components that seamlessly communicate with AI systems and sensor networks.

A particularly exciting frontier is the emergence of biohybrid systems, innovative integrations of living cells or tissues with electronic circuits and robotic platforms. These biohybrids can perform sophisticated functions such as environmental sensing, biomedical diagnostics, and targeted drug delivery. For example, engineered bacteria equipped with nanoscale biosensors can detect pollutants or toxins in water sources and transmit real-time data through AI-driven networks. This capability facilitates rapid, precise environmental remediation and monitoring, crucial for addressing global ecological challenges.

Moreover, biotechnology enables the creation of advanced biosensors, which utilize biological molecules to detect a wide range of chemical, physical, and even emotional signals. These devices can continuously monitor critical health biomarkers, identify pathogens, and assess physiological states by analyzing hormone levels or other biochemical markers. The rich data collected by biosensors feed directly into AI algorithms, enhancing the ability to provide personalized healthcare, early disease detection, and adaptive treatment strategies.

For a deeper dive into how biotechnology is revolutionizing living intelligence and healthcare, check out the latest updates at the National Institutes of Health (NIH) Biotechnology Resources.

Sensors: The Eyes and Ears of Living Intelligence

Sensors play a pivotal role as the critical interface between biological systems and artificial intelligence, acting as the “eyes and ears” that capture detailed, real-time information about both the environment and internal biological states. Recent advances in sensor technology have led to the development of miniaturized, highly sensitive devices capable of detecting an extensive range of physical, chemical, and biological signals with exceptional accuracy and speed.

In the realm of healthcare, wearable sensors have revolutionized personalized medicine by continuously tracking vital signs such as heart rate, blood oxygen levels, body temperature, and even biochemical markers like glucose or hormone levels. This continuous data stream enables proactive health monitoring and early disease detection, improving patient outcomes and reducing hospital visits.

Environmental sensors also play a crucial role in living intelligence systems. These devices monitor parameters such as air quality, soil moisture, temperature, and pollutant levels, providing vital data for environmental conservation and sustainable agriculture. By integrating sensor data with AI analytics, stakeholders can make informed decisions that protect ecosystems and optimize resource management.

What sets sensors in living intelligence apart is their ability to participate in real-time feedback loops. Instead of merely collecting data, these sensors work in tandem with AI algorithms to create autonomous systems that dynamically respond to changes. For example, in smart agricultural setups, sensors detecting dry soil can trigger AI-driven irrigation systems to activate precisely when needed, conserving water and maximizing crop yield. Similarly, in healthcare, sensor data can prompt AI systems to adjust medication dosages or alert medical professionals to potential emergencies immediately.

Together, these advanced sensors and AI create living intelligence systems capable of self-regulation, adaptation, and continuous learning bringing us closer to a future where technology and biology co-evolve harmoniously.

For more insights into cutting-edge sensor technologies, explore the resources provided by the IEEE Sensors Council.

Applications and Impact of Living Intelligence

The convergence of artificial intelligence (AI), biotechnology, and advanced sensor technology in living intelligence is already revolutionizing a wide array of industries. This innovative fusion is driving transformative change by enabling smarter, adaptive systems that closely mimic biological processes and enhance human capabilities.

Healthcare: Personalized and Predictive Medicine

Living intelligence is accelerating the shift toward personalized medicine, where treatments are tailored to individual patients’ unique biological profiles. Implantable biosensors combined with AI algorithms continuously monitor vital health metrics and biochemical markers, enabling early detection of diseases such as diabetes, cardiovascular conditions, and even cancer. These systems facilitate real-time medication adjustments and proactive management of chronic illnesses, reducing hospital visits and improving quality of life. For example, AI-powered glucose monitors can automatically regulate insulin delivery, empowering diabetic patients with better control. Learn more about AI in healthcare at NIH’s Artificial Intelligence in Medicine.

Environmental Management: Smart and Sustainable Ecosystems

Living intelligence is reshaping environmental monitoring and management by creating smart ecosystems. Biosensors deployed in natural habitats detect pollutants, chemical changes, and climate variations, feeding real-time data to AI models that analyze trends and predict ecological risks. Automated bioremediation systems and adaptive irrigation solutions respond dynamically to environmental cues, enhancing sustainability and reducing human intervention. This approach helps combat pollution, conserve water, and protect biodiversity in an increasingly fragile environment. Discover innovations in environmental sensing at the Environmental Protection Agency (EPA).

Agriculture: Precision Farming and Resource Optimization

Precision agriculture leverages living intelligence to maximize crop yields while minimizing environmental impact. By integrating soil biosensors, climate data, and AI-driven analytics, farmers can optimize water usage, fertilization, and pest control with pinpoint accuracy. This results in healthier crops, reduced chemical runoff, and more efficient use of natural resources. For instance, AI-powered drones equipped with sensors monitor plant health at the molecular level, allowing targeted interventions that save costs and boost productivity. Explore advancements in smart farming at FAO - Precision Agriculture.

Wearable Technology: Beyond Fitness Tracking

Wearable devices enhanced by living intelligence go far beyond step counting and heart rate monitoring. These advanced wearables assess mental health indicators, stress responses, and neurological conditions through continuous biometric sensing and AI analysis. This opens new frontiers in early diagnosis, personalized therapy, and wellness optimization. For example, AI-driven wearables can detect signs of anxiety or depression by analyzing hormone fluctuations and physiological patterns, enabling timely interventions. Check out the latest in wearable health tech from Wearable Technologies.

Robotics and Biohybrids: Adaptive and Responsive Machines

Living intelligence is paving the way for biohybrid robots machines integrated with living cells or bioengineered tissues. These robots combine the flexibility and self-healing properties of biological material with the precision of robotics, enabling them to perform delicate medical procedures, intricate manufacturing tasks, or exploration in unpredictable environments. Such systems adapt dynamically to changes, enhancing efficiency and safety in sectors like surgery, pharmaceuticals, and space missions. Learn about biohybrid robotics at MIT’s Biohybrid Robotics Lab.

Ethical and Social Considerations in Living Intelligence

As living intelligence technologies increasingly merge biological systems with artificial intelligence and sensor networks, they raise profound ethical and social questions that demand careful reflection. This emerging frontier blurs the boundaries between living organisms and machines, requiring a responsible approach to development and deployment.

Manipulation of Biological Materials

Advances in synthetic biology, gene editing (such as CRISPR), and biohybrid systems enable unprecedented manipulation of living cells and tissues. While these innovations hold tremendous promise, they also provoke concerns about unintended consequences, such as ecological disruption or irreversible genetic changes. Ethical frameworks must guide the use of biotechnology to prevent misuse and ensure safety. Learn about gene editing ethics from the National Human Genome Research Institute.

Data Privacy and Genetic Information Security

Living intelligence systems often rely on vast amounts of biometric data and genetic information, raising critical questions about data privacy and consent. Protecting sensitive health data from breaches or misuse is paramount, especially as AI-driven analytics become more powerful. Regulatory compliance with standards like HIPAA and GDPR is essential, alongside transparent data governance policies. Public trust hinges on safeguarding individual rights while enabling technological progress. Explore data privacy regulations at the European Data Protection Board.

Environmental and Ecological Impact

The integration of living intelligence into ecosystems carries risks of ecological imbalance. Introducing engineered organisms or biohybrid devices into natural environments may have unpredictable effects on biodiversity and ecosystem health. Continuous environmental monitoring and impact assessments are necessary to mitigate potential harm and ensure sustainability. See more on ecological risk management at the United Nations Environment Programme.

Transparency, Regulation, and Public Engagement

Responsible innovation in living intelligence requires transparent communication about the technology’s capabilities, risks, and benefits. Governments, industry stakeholders, and researchers must collaborate to establish clear regulatory frameworks that promote ethical standards and accountability. Equally important is engaging the public in meaningful dialogue to address societal concerns, build trust, and guide policymaking. For insights into ethical AI governance, visit the AI Ethics Guidelines by OECD.

By proactively addressing these ethical and social dimensions, society can harness the transformative power of living intelligence while safeguarding human dignity, privacy, and the environment. This balanced approach is essential for building a future where technology and biology coexist harmoniously and ethically.

The Road Ahead: Toward a Symbiotic Future

Living intelligence opens the door to a symbiotic future where humans, machines, and biological systems do more than just coexist; they collaborate seamlessly to address some of the world’s most pressing challenges. This emerging paradigm holds the promise of revolutionizing fields such as personalized healthcare, by enabling continuous health monitoring and adaptive treatments tailored to individual needs. It also paves the way for environmental resilience, with biohybrid sensors and AI-driven ecosystems working in tandem to monitor and protect our planet in real time.

Innovative applications will extend into agriculture, smart cities, and robotics, creating technologies that not only perform tasks but also learn, evolve, and respond to their environments autonomously. However, realizing this transformative potential hinges on sustained interdisciplinary research, development of robust ethical guidelines, and ensuring equitable access to these advanced technologies across communities and countries.

As AI, biotechnology, and sensor technologies become ever more intertwined, living intelligence will redefine how we interact with the natural and digital worlds, unlocking new potentials that once belonged only in the realm of science fiction.

Conclusion: Embracing the Future of Living Intelligence

The fusion of artificial intelligence, biotechnology, and sensor technologies marks the beginning of an exciting new era, one where the boundaries between living organisms and machines blur to create intelligent, adaptive systems. Living intelligence promises to improve healthcare, enhance environmental stewardship, and drive technological innovation that benefits all of humanity.

To navigate this future responsibly, it is essential to balance innovation with ethical considerations, transparency, and collaboration among researchers, policymakers, and society at large. By doing so, we can ensure that living intelligence becomes a force for good, empowering individuals and communities worldwide.

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FAQs

What is Living Intelligence in technology? Living Intelligence refers to systems where artificial intelligence (AI), biotechnology, and sensors merge to create responsive, adaptive, and autonomous environments. These systems behave almost like living organisms collecting biological data, analyzing it in real-time, and making decisions or adjustments without human input. Examples include smart implants that adjust medication doses, bio-hybrid robots that respond to environmental stimuli, or AI-driven ecosystems monitoring human health. The goal is to mimic natural intelligence using technology that senses, thinks, and evolves enabling next-generation applications in healthcare, agriculture, environmental science, and more.

How do AI, biotechnology, and sensors work together in Living Intelligence? In Living Intelligence, sensors collect biological or environmental data (like heart rate, chemical levels, or temperature). This data is sent to AI algorithms that analyze it instantly, recognizing patterns or abnormalities. Biotechnology then acts on these insights, often in the form of engineered biological systems, implants, or drug delivery systems. For example, a biosensor may detect dehydration, the AI recommended fluid intake, and a biotech implant responds accordingly. This fusion enables systems to adapt, learn, and respond in ways that closely resemble living organisms bringing a dynamic edge to digital health and bioengineering.

What are real-world examples of Living Intelligence? Examples include smart insulin pumps that monitor blood glucose and adjust doses automatically, AI-enhanced prosthetics that respond to muscle signals, and biosensors embedded in clothing to track health metrics. In agriculture, Living Intelligence powers systems that detect soil nutrient levels and deploy micro-doses of fertilizer. In environmental monitoring, bio-sensing drones track pollution levels and AI predicts ecological shifts. These innovations blur the line between machine and organism, offering intelligent, autonomous responses to biological or environmental conditions often improving speed, precision, and personalization in critical fields.

What role does biotechnology play in Living Intelligence? Biotechnology serves as the biological interface in Living Intelligence. It enables machines and sensors to interact with living tissues, cells, and molecules. From genetically engineered cells that react to pollutants to biocompatible implants that communicate with neural pathways, biotechnology helps translate biological signals into data AI can process and vice versa. This allows for precision treatments, early disease detection, and real-time bodily monitoring. In essence, biotechnology enables machines to "speak the language" of life, forming the bridge between human biology and machine intelligence.

Are Living Intelligence systems safe for human use? When properly developed, Living Intelligence systems can be safe and even enhance health and safety. Regulatory oversight, clinical testing, and ethical review are essential before human deployment. Implants or biotech sensors must be biocompatible, AI must avoid bias or misinterpretation, and data must be securely encrypted. Most systems are designed with safety protocols like auto-shutdown, alert escalation, or user override. However, because these technologies are still evolving, long-term effects and ethical considerations (like autonomy, data privacy, and human enhancement) continue to be actively explored.

How is Living Intelligence transforming healthcare? Living Intelligence is revolutionizing healthcare by making it predictive, personalized, and proactive. Wearable biosensors track vitals in real time, AI analyzes this data to detect early signs of illness, and biotech systems deliver treatments exactly when and where needed. This reduces hospital visits, speeds up diagnosis, and enables preventative care. For example, cancer detection can happen earlier through bio-integrated diagnostics, while chronic illnesses like diabetes or heart disease can be managed more effectively with adaptive, AI-guided interventions. The result: longer lifespans, better quality of life, and lower healthcare costs.

Can Living Intelligence be used outside of healthcare? Yes, Living Intelligence extends far beyond healthcare. In agriculture, it enables smart farming with biosensors that detect soil health and AI that regulates water or nutrient delivery. In environmental science, it’s used in biohybrid sensors to monitor air or water pollution. In wearable tech, it powers personalized fitness and stress management tools. Even in space exploration, researchers are exploring AI-biotech hybrids for autonomous life support. Wherever biology meets decision-making, Living Intelligence can optimize systems by mimicking the adaptability and efficiency of living organisms.

How do biosensors contribute to Living Intelligence? Biosensors are the input channels for Living Intelligence. These tiny devices detect biological signals such as glucose levels, hormone changes, or toxins and convert them into digital data. Advanced biosensors can operate inside the body or in wearable devices, often transmitting data continuously. AI then interprets these signals, and biotech components act accordingly (e.g., drug release, alerting doctors, or environmental controls). Biosensors allow for non-invasive, real-time monitoring and make it possible for machines to understand and react to living systems with remarkable precision.

What are the ethical concerns surrounding Living Intelligence? Key ethical concerns include data privacy, human autonomy, and biological manipulation. When AI monitors health or biology, who owns the data? Can systems make decisions that override human will like stopping medication or triggering an alert? Additionally, biotech integration raises concerns about altering natural biology or creating bioengineered entities. Transparency, informed consent, and regulation are vital to ensure these technologies serve humanity without exploitation. As Living Intelligence evolves, policymakers and technologists must collaborate to align innovation with ethical standards.

What does the future hold for Living Intelligence? The future of Living Intelligence is incredibly promising. We’ll likely see cyborg-like medical devices, fully autonomous bio-monitoring ecosystems, and AI-driven drug synthesis tailored to your DNA. Smart cities may use biosensors in public spaces to track environmental health. Even brain-computer interfaces could become more common, powered by AI and biological sensors. Over time, machines won’t just compute, they'll sense, adapt, and evolve, making technology indistinguishable from life itself. The challenge ahead is not just building these systems but ensuring they remain ethical, secure, and beneficial for all.

🇧🇷 PORTUGUÊS 🚨 MARCO HISTÓRICO: 3.000 INSCRITOS NO VI CDNB! 🎉

A meta foi SUPERADA, mas as portas ainda estão abertas até 08/06/2025!

👉 Quem diria? Nem o Dr. Luciano Paulino da Silva (mentor intelectual do evento e inscrição # 0001 💡) imaginaria que, após testar o sistema, veríamos não apenas 4 dígitos... mas TRÊS MIL mentes brilhantes reunidas!

Aos que duvidaram: lamentamos informar que falharam. Aos que fazem parte: vocês são a revolução da Nano&Bio mundial!

🔥 NÃO É TARDE PARA SE JUNTAR A ESTE MARCO: ✅ Inscreva-se AGORA (100% GRATUITO): https://www.even3.com.br/vicdnb/?lang=pt ✅ Seja Embaixador CDNB: forms.gle/T4cHTEi9GnziRwok9 ✅ Cadastre seu Laboratório: forms.gle/jkMrjxbceaZMKhUJ7

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🇬🇧 ENGLISH 🚨 HISTORIC MILESTONE: 3,000 REGISTERED FOR 6TH CDNB! 🎉

Goal CRUSHED, but registrations remain open until June 8, 2025!

👉 Who would’ve guessed? Not even Dr. Luciano Paulino da Silva (event mentor and registration # 0001 💡) imagined that after testing the system, we’d hit not 4 digits... but THREE THOUSAND brilliant minds!

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Embrapa Embrapa Recursos Genéticos e Biotecnologia

Job Opportunity: Technician Biotechnology Platform (2 Posts) at the University of Zimbabwe! - March 2025

The University of Zimbabwe’s Faculty of Veterinary Sciences, Department of Veterinary Biosciences, is seeking two skilled Technicians to run their Biotechnology Platform laboratories! If you have a background in chemistry, biochemistry, biological sciences, or biotechnology, and a passion for molecular diagnostics and bioengineering, this is a great opportunity for you. About the Role: As a…

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manufacturer of industrial fermenter bioreactor for biotech and biopharmaceuticals industries

Scientists Develop Synthetic Cyborg Cells: First step in future of Synthetic Biology | Researchatory.AI |Aakash Khurana

Breaking barriers in biology! Scientists have created synthetic cyborg cells, paving the way for groundbreaking medical advancements and environmental solutions. #cyborgcells #syntheticbiology #biotechnology #science #innovation #futureofmedicine #environmentalprotection #CyborgCells #CellBiology #Bioengineering #MedicalTechnology #Nanotechnology #ScienceNews #Breakthrough #Discoveries

Scientists have indeed developed synthetic cyborg cells. These hybrid organisms, a blend of biological and synthetic components, hold immense potential for various applications, from medicine to environmental cleanup.

Key characteristics of cyborg cells:

* Combination of living and non-living: They incorporate synthetic materials into living cells, enhancing their capabilities.

* Programmable: Scientists can customize their functions to perform specific tasks.

* Non-replicating: This ensures controlled growth and prevents unintended consequences.

* Enhanced resilience: Cyborg cells often exhibit increased resistance to stressors like extreme temperatures or chemicals.

Potential applications:

* **Medicine:**

 * Targeted drug delivery

 * Cancer treatment

 * Tissue regeneration

* **Environmental cleanup:**

 * Bioremediation of pollutants

 * Detection of contaminants

* **Materials science:**

 * Creation of novel materials with unique properties

Recent advancements:

* Researchers at the University of California, Davis, have created cyborg bacteria that can invade cancer cells.

* Other studies have explored the use of cyborg cells for producing therapeutic compounds and cleaning up toxic waste.

Challenges and future directions:

While cyborg cells offer exciting possibilities, there are still challenges to overcome. These include ensuring their safety, addressing ethical concerns, and developing scalable production methods. As research continues, we can expect to see even more innovative applications of these remarkable hybrid organisms.

for more info:

Polyurethane: A Versatile Scaffold for Biomedical Applications_Crimson Publishers

Abstract:

Polyurethanes (PUs) are one of the most versatile and explored polymeric materials in which the urethane groups are the major repeating unit and can be synthesized by reacting di or polyisocyanates (hard segments) with di or polyols (soft segments) via catalyzed polymerization process [1]. A broad range of PU with variety of physical and mechanical properties can be tuned just by changing the ratio of soft and hard segments [2]. Thus, it consists of two phase structure in which the hard segments are embedded into the soft segments. Using different ratios of hard/soft segments, it can be fabricated according to their need of applications in rubber, fibers, films, paints, coatings, elastomers, foams, gels etc. [3] These many forms of PUs available to date are simple improvements of the invention of Dr. Otto Bayer and his coworkers in the 1930s [4]. The continuous improvements in the polyurethane made them a suitable and promising material for the incorporation in widespread applications. For the decades, it has been used in the field of biomedical due to their well-known properties such as good durability, high tensile strength, fatigue resistance, excellent biodegradability and biocompatibility [5]. Among the polymers like, silicone, polyvinyl chloride (PVC), polyethylene and poly tetra fluoro ethylene (PTFE), PUs are widely used in medical application due to their superior bio and hemo compatibility. On account of this very characteristic property, they have extensively been used in catheters, heart valves, vascular grafts, prostheses and blood coagulating devices [6].

It has also been noticed that PUs are best suitable candidates for the scaffolds in tissue engineering, hydro gels, shape memory devices, nontoxic implants, various cardiovascular repair, wound healing and bone regenerations [7]. On account of this, the present review summarizes the chemistry of polyurethane, their historical background and considering factors for biomedical application. Moreover, their biomedical application in the field of tissue engineering and drug delivery has also been discussed.

Read More About this Article: https://crimsonpublishers.com/sbb/fulltext/SBB.000536.php

Read More Articles: https://crimsonpublishers.com/sbb/

Artificial Eater🧬🍽️

By:

Exploring the Growing Wetware Computers Market: Merging Biology with Technology

Introduction to Wetware Computers

In the realm of futuristic technology, wetware computers represent a fascinating frontier where biology and technology converge. These cutting-edge devices utilize living neural tissue, bioengineered components, and neural interfaces to create powerful computing systems. As the field of biotechnology advances, wetware computers are poised to revolutionize various industries and reshape our relationship with technology.

The Evolution of Wetware Technology

Wetware computers have evolved significantly since their inception, with advancements in bioengineering, neural interfaces, and computational neuroscience driving innovation. Initially conceptualized as experimental prototypes, these systems have matured into sophisticated platforms capable of interfacing with the human brain at unprecedented levels of precision and efficiency.

Applications Across Industries

The potential applications of wetware computers span a wide range of industries, from healthcare and medicine to gaming and entertainment. In healthcare, these devices hold promise for diagnosing and treating neurological disorders, enhancing prosthetic control, and even augmenting cognitive abilities. In the gaming industry, wetware interfaces offer immersive experiences that blur the lines between reality and virtual worlds, creating new opportunities for interactive entertainment.

Challenges and Ethical Considerations

Despite their immense potential, wetware computers also pose significant challenges and ethical considerations. Issues such as data privacy, informed consent, and the potential for misuse raise important questions about the responsible development and deployment of these technologies. As wetware technology continues to advance, it will be crucial to address these challenges proactively to ensure that its benefits are realized ethically and equitably.

Future Outlook and Growth Prospects

Looking ahead, the wetware computers market is poised for continued growth and innovation. As research in biotechnology and neurotechnology accelerates, we can expect to see increasingly sophisticated wetware systems with enhanced capabilities and applications. From medical breakthroughs to new forms of human-computer interaction, the future of wetware technology holds boundless possibilities.

Conclusion

In conclusion, wetware computers represent a groundbreaking fusion of biology and technology that has the potential to revolutionize various industries and aspects of human life. As researchers and innovators continue to push the boundaries of what is possible, the wetware computers market is set to experience exponential growth, offering new opportunities for scientific discovery, technological innovation, and human enhancement. However, it is essential to approach the development and deployment of these technologies with caution, ensuring that they are used responsibly and ethically to maximize their benefits for society as a whole.

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🇬🇧 ENGLISH Can you turn science into art? 🎨✨ 👉 Already registered? Submit your Scientific Illustration by 05/30/2025! 👉 Not registered yet? Secure your 6th CDNB spot, then submit your work! 🔗 Register NOW: even3.com.br/vicdnb/?lang=en

Why join? ✅ FREE and digital! ✅ Expert-judged + public voting! ✅ Win global visibility! 🔗 Submission link: https://forms.gle/C5qpSFJ4MxLswmZ98

⚠️ Heads up! Abstract submissions close 05/02/2025 (150 slots only). Don’t miss out! Creativity is science’s universal language. Shine bright! 🌟 #6thCDNB#ScientificIllustration#Creativity#Nanobiotechnology#Bioengineering

🇪🇸 ESPAÑOL ¿Tienes habilidades para convertir ciencia en arte? 🎨✨ 👉 ¿Ya estás inscrito? Envía tu Ilustración Científica antes del 30/05/2025! 👉 ¿Aún no te has registrado? Asegura tu lugar en el VI CDNB y luego envía tu obra. 🔗 Inscríbete AHORA: even3.com.br/vicdnb/?lang=es

¿Por qué participar? ✅ ¡GRATUITO y en línea! ✅ ¡Evaluada por expertos + votación pública! ✅ ¡Gana visibilidad global! 🔗 Enlace de envío: https://forms.gle/C5qpSFJ4MxLswmZ98

⚠️ ¡Atención! La convocatoria de resúmenes cierra el 02/05/2025 (solo 150 plazas). ¡No te quedes fuera! La creatividad es el lenguaje universal de la ciencia. ¡Brilla! 🌟 #VICDNB#IlustraciónCientífica#Creatividad#Nanobiotecnología#Bioingeniería

Unnatural Amino Acids: Beyond the Basics - Unlocking New Research Frontiers

Unnatural amino acids are revolutionizing research and bioengineering. Explore their applications in protein engineering, biomaterial design, and drug discovery. Discover the top players in the market and the exciting future of unnatural amino acids

The Unnatural Amino Acids Market: Pushing Boundaries in Bioengineering The unnatural amino acids market is a rapidly evolving field with vast potential in various scientific and technological applications. Unnatural amino acids are molecules structurally similar to the 20 naturally occurring amino acids that form the building blocks of proteins. However, unnatural amino acids possess unique…

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Job Opportunity: Technician Biotechnology Platform (2 Posts) at the University of Zimbabwe! - March 2025

The University of Zimbabwe’s Faculty of Veterinary Sciences, Department of Veterinary Biosciences, is seeking two skilled Technicians to run their Biotechnology Platform laboratories! If you have a background in chemistry, biochemistry, biological sciences, or biotechnology, and a passion for molecular diagnostics and bioengineering, this is a great opportunity for you. About the Role: As a…