UK-based researchers have developed a new method for rapid and scalable preparation of uniform anisotropic polymer nanoparticles, achieving a breakthrough in precision nanomaterials. This method allows for high-throughput production of precision polymer nanomaterials, significantly reducing processing time from a week to just minutes. This enables the production of high-quality nanostructures at a scale previously unattainable. The method integrates seed preparation and living CDSA in a continuous flow setup, achieving end-to-end production of nanostructures in just three minutes. The authors believe this breakthrough has far-reaching implications for the fields of drug delivery, disease treatment, and programmable material design, and could potentially lead to improved treatments for diseases like cancer.

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The International Electrotechnical Commission (IEC) has approved a new standard for nanotechnology, specifically for luminous nanomaterials used in lighting and display applications. The standard, based on the IEC Technical Working Group 113 series, provides a detailed specification for luminous nanomaterials without assigning values. This standard allows customers to specify requirements and verify the properties of luminous nanomaterials through standardized methods.

Iran has made significant progress in nanotechnology, ranking fourth in the world in nanotechnology publications, according to the nanotechnology research website StatNano. International entities have recognized Iranian contributions to the field, including a scholarly article published by the American Institute of Physics on the use of nanomaterials for cancer treatment by Iranian scientists.

Iran’s nanotechnology products are diversified, with 42% related to construction, 17% to petroleum, and 13% to automobile manufacturing. Key accomplishments in nanotechnology can be seen across various sectors, including engineering, energy, and medicine. The development of this standard meets the needs of the nano research and industrial sectors, enabling customers to specify requirements and verify the properties of luminous nanomaterials in standardized ways.

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The Nanomaterials Market report provides a comprehensive analysis of the global market, projecting a valuation of USD 98.3 billion by 2035, growing at a CAGR of 14.30% between 2024 and 2035. The report covers material types, including carbon-based, metal-based, and polymeric nanomaterials, as well as nanoparticles, nanotubes, nanofibers, and nanocomposites. The market is segmented into various applications, such as electronics and semiconductors, energy and power, healthcare, and life sciences, and aerospace and defense.

The report includes an analysis of regional markets, including North America, Europe, Asia Pacific, Latin America, and the Middle East and Africa. Major companies in the market are BASF SE, Nanophase Technologies Corporation, NanoSys, Inc., and others. The report offers insights into the key drivers, restraints, and opportunities in the market, as well as company profiles, and is available for purchase on the Metatech Insights website.

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The nanotechnology market is experiencing rapid growth, driven by the unique properties of nanomaterials, which have the potential to transform industries such as medicine, electronics, and energy. The market size is expected to grow at a CAGR of 41.01% from 2023 to 2033, reaching $7.32 billion in 2023. Key opportunities in nanomaterials include targeted drug delivery, diagnostic imaging, and tissue engineering in healthcare, and next-generation semiconductors, flexible displays, and energy storage devices in electronics. However, the industry faces challenges such as toxicity and environmental impact, scalability and manufacturing, characterization and standardization, regulatory frameworks, and public perception. To overcome these challenges, solutions such as a safe-by-design approach, advanced manufacturing techniques, standardized characterization methods, and risk assessment and management are crucial. Evolve Business Intelligence offers market research reports and advisory services to help businesses navigate the nanotechnology market and identify opportunities for growth.

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The content is a collection of scientific articles and studies related to cancer research, with a focus on immunotherapy, targeted delivery, and nanotechnology. The articles discuss various aspects of cancer treatment, including the use of immunotherapies such as checkpoint inhibitors, the role of the tumor microenvironment, and the development of targeted therapies.

The articles also explore the use of nanotechnology, including nanoparticles and liposomes, for delivering cancer treatments and improving their efficacy. The importance of tumor targeting, lymph node targeting, and intratumoral delivery is highlighted. The role of pH-responsive polymers and ATP-activated decrosslinking vectors in cancer therapy is also discussed.

The content also touches on the importance of precision medicine, as well as the development of personalized cancer therapies. The use of antibodies, antibody drug conjugates, and bispecific antibodies for cancer treatment is also explored.

Overall, the content provides an in-depth look at the latest research in the field of cancer treatment, with a focus on immunotherapy, targeted delivery, and nanotechnology. It highlights the importance of these areas in advancing cancer research and developing effective treatments for cancer patients.

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The provider of Azthena answers uses only edited and approved content. However, there is a possibility that the responses may be incorrect. Therefore, it is advised to confirm any data provided with the original suppliers or authors. Additionally, the provider does not offer medical advice, and if you search for medical information, you must consult a medical professional before taking any action.

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The global nanotechnology drug delivery market is expected to reach USD 167.47 billion by 2030, growing at a CAGR of 8.9% from 2023 to 20230. The market is driven by the increasing demand for targeted therapies, advancements in nanomaterials, and collaborations between pharmaceutical companies and nanotechnology firms. However, regulatory challenges, cost barriers, and safety concerns pose obstacles for market players.

The report highlights key trends, including nanoparticle-based therapeutics, personalized medicine, and nanoformulations for cancer treatment. It also covers emerging areas such as biodegradable nanomaterials, intranasal drug delivery, and disease-specific treatments. The market is segmented by technology (nanocrystals, nanoparticles, liposomes, micelles, and others), application (neurology, oncology, cardiovascular, and others), and region (North America, Europe, Asia Pacific, Latin America, and Middle East & Africa).

The report provides insights into the competitive landscape, including top companies such as Merck, Bayer, Amgen, Pfizer, and Novartis. It also addresses challenges, opportunities, and outlook for the market. The report is a comprehensive analysis of the Nanotechnology Drug Delivery Market, offering valuable insights for businesses, investors, and researchers.

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The European Commission’s Joint Research Centre (JRC) has released two new certified reference materials (CRMs) for testing nanomaterials, titanium dioxide (ERM-FD104) and barium sulfate (ERM-FD105) powders. These CRMs will enable laboratories to accurately identify nanomaterials, a crucial step in implementing the European Union’s regulatory framework for nanomaterials. The EU has established a framework that requires manufacturers and importers to provide detailed information on material properties, including particle size, to ensure safe use of nanomaterials. The particle size is a key factor in determining toxicity, bioavailability, and environmental fate of nanomaterials, making accurate characterization essential. The CRMs will allow laboratories to validate their testing methods and measure the particle size and size distribution of powders containing nanoparticles and small particles. The release of these CRMs is a significant milestone in supporting the implementation of the EU’s nanomaterial regulatory framework and promoting the development of innovative and safe products based on nanomaterials. The CRMs are available for purchase through the JRC’s online reference materials catalogue.

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The global Carbon Nanotubes And Nanomaterials market is expected to experience significant growth from 2025 to 2032, driven by technological advancements, increasing consumer demand, and supportive regulatory policies. The market is driven by the rising acceptance of CNTs and nanomaterials across sectors such as electronics, aerospace, automotive, and healthcare. The need for light-weight, high-performance materials in energy storage devices is a key driver of market expansion. Additionally, the integration of digital technologies, such as AI and IoT, is optimizing operational workflows and enhancing product capabilities. The market faces challenges such as high initial investment costs, regulatory complexities, and supply chain disruptions. However, emerging trends such as sustainability, personalization, and customization are reshaping industry dynamics. Businesses that prioritize innovation, agility, and strategic planning are better positioned to adapt to these changes and sustain long-term growth in the evolving Carbon Nanotubes And Nanomaterials market.

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Researchers at the University of Toronto have developed a new nanomaterial lattice that is both the lightest and strongest material of its kind. The material, created through a process called pyrolysis, has a strength-to-weight ratio that is unmatched by any other nanomaterial, with the ability to support over a million times its own mass. The material is also delicate enough to sit on top of a soap bubble, making it a significant advancement in the field of nanotechnology. The researchers claim that this material has a wide range of potential uses, including in aircraft, solar energy systems, and armor. They also see this as a key advancement for generative AI modeling in mechanics, as the algorithm used to design the material can create structures that would be difficult for humans to envision through conventional methods. While there are still challenges to overcome before the material can be mass-produced and sold, the researchers are optimistic about its potential to revolutionize various industries.

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A team of researchers in Canada has created ultrahigh-strength carbon nanolattices using machine learning. The material is as strong as carbon steel, but only as dense as Styrofoam, making it a potentially game-changing breakthrough in nanomaterials. The team used a machine learning algorithm to predict the best lattice geometries for enhancing stress distribution and improving the strength-to-weight ratio. They then used a two-photon polymerization 3D printer to create a precise nanoscale prototype. The resulting nanolattice withstood five times the amount of stress that titanium can, making it suitable for aerospace applications, such as replacing titanium components on planes. The potential fuel savings are estimated to be 80 liters per year for every kilogram of material replaced. The team plans to continue developing even stronger and less dense materials, as well as finding cost-effective ways to manufacture components with these designs.

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The article review is focused on biomimetics, which is the process of developing technology inspired by nature. The authors of the listed papers discuss various aspects of biomimetics, including the development of biomimetic intelligence and robotics, as well as the application of biomimetic principles to the design of advanced materials and devices.

The review highlights the importance of nature in inspiring innovation, as well as the potential of biomimetic approaches to solve complex problems in fields such as medicine, energy, and the environment. The papers also explore the use of diatoms, a type of microscopic algae, as a model system for the development of advanced materials and devices.

The review also covers various topics, including photonic crystals, which are materials that exhibit unusual optical properties. The authors discuss the potential of photonic crystals to create advanced optical devices, such as sensors and lasers.

The authors also review various mathematical and computational methods, including data analysis and machine learning, which are used to understand and model complex biological systems. Overall, the review highlights the importance of interdisciplinary approaches to address complex problems, and the potential of biomimetics to inspire new and innovative solutions in various fields.

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A team of researchers has developed a nanomaterial that can deliver lidocaine, a common anesthetic, in a more effective and sustainable way. The nanomaterial, called Methyl-PEG2000-DSPE-PVP-LDC, has the ability to encapsulate lidocaine and release it slowly, providing prolonged anesthetic effects. This could potentially address the limitations of traditional lidocaine, which only lasts for a few hours and can be toxic in high doses. The nanomaterial also has anti-inflammatory and anti-cancer properties, making it a promising candidate for treating various diseases, including cancer, chronic wounds, and inflammatory skin diseases. The researchers hope to continue studying the nanomaterial to improve its biodegradability, drug release profile, tissue distribution, and to accelerate its transition to clinical and therapeutic applications. The potential applications of this nanomaterial are vast, with the possibility of it being used to improve lidocaine safety and efficacy in medical procedures.

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A team of researchers at the University of Toronto, led by engineer Tobin Filleter, has developed a new nanomaterial that is incredibly strong and lightweight. The material, which is made of pyrolytic carbon, was designed using an AI algorithm that was trained to recognize the best geometric structure for a given material. The resulting nanolattice is incredibly strong, able to support over a million times its own mass, yet is as light as Styrofoam. This means it could have a wide range of applications, including in medical equipment, such as prosthetics, and in aerospace, where it could be used to create lighter vehicles that require less fuel. The team also notes that the material could be used in “aerospace, ballistics absorption, ultrafast response for optics, and many other contemporary design applications.” The researchers were able to scale up the production of the material, which is typically a challenge with nanomaterials, and they believe it has the potential to revolutionize the field of materials design. While it may not be as mythical as vibranium, this new material has impressive strength-to-weight ratio, making it a promising development for a variety of industries.

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The text discusses the effect of nanomaterials (NS and CNTs) on the uniaxial compression properties of Engineered Cementitious Composites (ECCs). The compressive strength and peak compressive strain of ECC specimens were tested with different nanomaterial concentrations. The results show that the addition of nanomaterials improves the compressive strength and peak compressive strain of ECC. The compressive strength and peak compressive strain of the NS series exhibit an initial increase, followed by a decrease as the concentration of nanomaterials increases, with the ideal NS content being 2%. In contrast, the CNTs series shows a more consistent increase in compressive strength and peak compressive strain with the ideal content being 0.15%.

The study also investigates the effect of nanomaterials on the microstructure of ECC. The results show that the incorporation of NS enhances the density of the matrix, improves the structure of the interfacial transition zone, and reduces the number of cracks. The XRD analysis shows that the addition of NS consumes more CH crystals, generating an increased quantity of C-S-H gels, which enhances the mechanical characteristics of the ECCs. The SEM analysis reveals that NS particles can act as nuclei, accelerating the crystallization process of the matrix material, leading to a denser and more homogeneous structure.

In conclusion, the two types of nanomaterials (NS and CNTs) demonstrate different effects on the compressive properties of ECC. NS performs better in enhancing compressive strength, while CNTs perform better in enhancing compressive strain. The study highlights the potential of nanomaterials to improve the mechanical properties of ECC and demonstrates the importance of understanding the microstructure of the material to optimize its performance.

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The paper provides a bibliometric analysis of research on watermelon and its relationship with graphene oxide. It highlights the increasing interest in the use of graphene oxide in plant biotechnology, plant cell biology, and plant pathology. The study notes that graphene oxide has been shown to enhance the growth and development of various plant species, including watermelon, and has potential applications in plant breeding and genetic transformation. The paper also discuss the toxic effects of graphene oxide on algae and bacteria, as well as its use as a potential carrier for gene silencing and immunotherapy. The study also notes the potential of graphene oxide in the development of new antimicrobial agents and in the treatment of certain diseases. Overall, the paper provides a comprehensive overview of the current state of research on graphene oxide and its applications in plant biology and medicine.

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Researchers at the Indian Institute of Technology (IIT), Madras, have made a significant breakthrough in breast cancer treatment with a newly patented next-generation drug delivery system. This innovative system uses nanomaterials to target cancerous cells precisely, offering a safer and more effective alternative to traditional chemotherapy. Unlike conventional treatments, the nanocarriers are biocompatible, avoiding toxic side effects like hair loss and immune suppression. Lab tests have shown promising results, effectively halting tumor growth in breast cancer cells. The researchers aim to transition to animal model testing and collaborate with healthcare industries to bring this technology to clinical trials, potentially transforming cancer therapy globally. This advancement has the potential to enhance treatment efficacy and minimize the risks associated with traditional chemotherapy.

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In a breakthrough discovery, researchers have created two-faced graphene nanoribbons that could lead to the development of the first purely carbon-based ferromagnets. Ferromagnets are materials that are capable of being magnetized and are commonly used in products such as credit cards, magnetic hooks, and magnetic resonance imaging (MRI) machines. Traditional ferromagnets are typically made from metal alloys, but the new discovery could pave the way for the creation of ferromagnets made entirely from carbon.

The two-faced graphene nanoribbons were created by researchers at the University of California, Los Angeles (UCLA) and the University of Pennsylvania. The nanoribbons have a unique two-dimensional structure that allows them to have both ferromagnetic and antiferromagnetic properties, which is essential for the creation of ferromagnets. The researchers believe that the discovery could have significant implications for the development of new electronic devices and medical technologies.

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The articles reviewed in this collection focus on the effects of lead (Pb) on plants, including its toxicity, uptake, and detoxification. The studies discuss the impacts of Pb on plant growth, photosynthesis, and antioxidant enzymes, as well as the role of silicon (Si) in mitigating Pb toxicity. The articles also investigate the use of nano-silica and other nanoparticles to improve crop yield and reduce metal toxicity. Additionally, the collection includes research on the effects of Pb on human health and the environment, as well as the use of microorganisms to remediate contaminated soil.

Some of the key findings include:

* Pb can have detrimental effects on plant growth and development, including reduction of chlorophyll production and disruption of photosynthesis.
* Silicon can help to reduce Pb uptake and toxicity in plants by forming a physical barrier around the plant’s roots and improving antioxidant defenses.
* Nano-silica and other nanoparticles can be used to improve crop yield and reduce metal toxicity by increasing water absorption, reducing oxidative stress, and promoting nutrient uptake.
* Lead toxicity can also have negative effects on human health, including neurological and reproductive problems.
* Microorganisms can be used to remediate contaminated soil by breaking down heavy metals and improving soil structure.

Overall, the collection highlights the importance of understanding the effects of Pb on plants and the environment, as well as the potential benefits of using silicon and other materials to mitigate its toxicity.

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Researchers at the University of Toronto’s Faculty of Applied Science & Engineering have developed a new type of nanomaterial that combines the strength of carbon steel with the lightness of Styrofoam. By using machine learning, the team created nanomaterials with unprecedented strength, weight, and customizability. The material is composed of tiny building blocks measuring just a few hundred nanometers, making it incredibly strong and lightweight.

The team used a machine learning algorithm to optimize the geometry of the nanomaterials, predicting optimal designs and improving the strength-to-weight ratio. This process was accelerated, requiring only 400 data points compared to traditional methods which may require 20,000 or more. The team was surprised by the improvements, which went beyond the training data, allowing them to predict entirely new lattice geometries.

The potential applications of these materials are vast, including aerospace and automotive industries. The researchers envision using these materials to create ultra-lightweight components for planes, helicopters, and spacecraft, potentially reducing carbon footprint and energy consumption.

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Scientists have designed a new type of nanomaterial with the strength of carbon steel and the lightness of styrofoam using artificial intelligence (AI) and a 3D printer. The material, created by researchers at the University of Toronto and Caltech, is stronger than existing designs and has the potential to be used in the development of lighter, more fuel-efficient components for airplanes and cars. The material’s strength is thanks to a machine learning algorithm that simulated various geometries and predicted the best shapes to evenly distribute applied stresses. The resulting nanolattices have a strength-to-weight ratio of 2.03 megapascals for every cubic meter per kilogram, five times higher than titanium. The researchers aim to scale up the materials and continue to improve their designs to create even lighter and stronger components in the future. The potential applications of this material could include reducing fuel consumption in aviation, with estimates suggesting that replacing titanium components with this new material could save up to 80 liters of fuel per year per kilogram of material replaced.

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Researchers at IIT Guwahati have developed a cost-effective method for detecting harmful metals like mercury in human cells and the environment. Led by Prof Saikat Bhaumik, the team used perovskite nanocrystals to identify toxic metals with high sensitivity and accuracy. This innovation could revolutionize disease diagnostics and environmental monitoring by improving the detection and management of metal toxicity. The perovskite nanocrystals have a narrow emission linewidth, which allows for sharper and more detailed imaging, overcoming limitations of traditional imaging methods. This breakthrough has potential applications beyond mercury detection, including identifying other toxic metals in biological systems and real-time monitoring of treatment efficacy. The nanocrystals could also be adapted for drug delivery, enabling real-time monitoring of treatment efficacy. This research has the potential to transform medical and biological research, and could lead to new treatments and diagnostic tools.

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Researchers at IIT Guwahati have developed a new method to detect harmful metals in living cells and the environment using perovskite nanocrystals. These nanocrystals, one-lakhth smaller than a human hair, are highly responsive to light and can interact with it in significant ways, making them ideal for detecting metal ions. Previously, their quick degradation in water had limited their applications, but encapsulating them in silica and polymer coatings has enhanced their stability and luminescent intensity. The enhanced nanocrystals emit a bright green light under specific wavelengths, enabling precise detection of mercury ions, which are hazardous even in minute concentrations. The detection sensitivity is remarkable, able to detect mercury levels as low as a few nanomolar concentrations. Moreover, the nanocrystals were found to be non-toxic and preserved cell function while monitoring mercury ions in live mammalian cells. The potential applications of this research extend beyond mercury detection, with possibilities for identifying other toxic metals and adapting them for drug delivery.

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A new type of coarse-grained model, called MetaParticles (MP), has been developed to simulate the behavior of flexible nanoparticles. This model allows for tuning of the particles’ properties, such as flexibility, surface heterogeneity, and anisotropy, by adjusting the connections between beads that make up the particles. The MP model has been used to study the behavior of nanoparticles with various sizes and symmetries under external stress, and has been found to produce elastomer-like responses with varying degrees of flexibility and rigidity. The researchers have also discovered that the particles’ deformation pathways depend on size, which could lead to the development of tunable nanomaterials with specific properties. The ultimate goal is to use the MP model to improve the performance of nanoparticles in biomedical applications, such as drug delivery and imaging, by better understanding their interactions with cellular membranes. The researchers plan to further develop the MP model by incorporating details gained from atomistic simulations and experiments, with the aim of creating more accurate and relevant simulations of flexible nanoparticles. This research has significant implications for the development of nanoparticles with improved performance in biomedical applications.

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Scientists are exploring the use of nanomaterials to mechanically kill bacteria, which can resist traditional antibiotics. The team, led by Cristina Flors, aims to understand how to effectively deliver force to bacterial cells to kill them. They used atomic force microscopy to study the interaction between bacteria and mechano-bactericidal nanomaterials, which are sharp nanoparticles or features that can damage bacterial cell walls. The research found that killing bacteria requires a force of a few nano-newtons (nN) to a few tens of nN, which is much less than previously thought. However, the way this force is applied is crucial, as it needs to be focused on the bacterial cell wall to cause damage.

The team is now working to develop better mechano-bactericidal materials, which could be used in medical devices, water filtration systems, and even food packaging. The goal is to provide an alternative to antibiotics, which are facing the threat of resistance. The research highlights the importance of understanding cell-material interactions to develop effective antimicrobial strategies. Flors and her team believe that their work could lead to the development of more effective antimicrobial materials, which could have a significant impact on public health.

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The global nanomaterials market is expected to grow at a CAGR of 14.4% from 2024 to 2031, reaching a market value of US$31.3 billion. The growth is driven by increasing demand for high-performance materials in various industries such as electronics, healthcare, energy, and environmental sectors. Factors such as technological advancements, regulatory issues, and high production costs are challenges facing the market. However, trends like the development of advanced nanomaterials, nanomaterial-based coatings, and 3D printing are expected to accelerate market growth. The nanomaterials market can be segmented by material type (nanotubes, nanoparticles, nanowires, graphene, and nanocomposites) and application (electronics, healthcare, energy, environmental, automotive, and aerospace). The North American region dominates the market, followed by Europe and the Asia-Pacific region. The report highlights key players such as BASF SE, Evonik Industries AG, and Nanocyl SA, among others. The future outlook for the nanomaterials market is positive, with increasing adoption across industries and decreasing production costs driving growth.

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The global nano-biotechnology market is expected to grow at a CAGR of 9.3% from 2023 to 2034, reaching a value of over $421.5 billion by 2034. The market is driven by the need for targeted and effective healthcare solutions, such as personalized medicine and advanced diagnostic tools. Key segments driving growth include drug delivery systems, diagnostic imaging, gene delivery, and tissue engineering. Brands like Thermo Fisher Scientific, Sigma-Aldrich, Nanobiotix, Cambridge Nanotherm, and Nanosyn are major players in the market.

The market is expanding beyond healthcare, with applications in agriculture, energy, and environmental sustainability. Recent advancements in nano-based gene delivery systems and diagnostic tools are enabling more accurate and early disease detection. Key trends in the market include targeted drug delivery systems, personalized medicine and diagnostics, gene therapy advancements, wearable nano devices, and sustainable technologies.

The impact of nano-biotechnology is transforming the healthcare industry, introducing new diagnostic and therapeutic options that are safer, more precise, and effective. As awareness grows, demand for nano-enabled medical devices and personalized treatments will rise, driving further market expansion.

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Xeriant, Inc. has appointed Mark Sternberg to its Advisory Board, effective immediately. Sternberg brings extensive expertise in manufacturing operations, quality control, and licensing, particularly in the field of nano-coatings. He has a strong background in developing and commercializing nanomaterial products, including nanodiamonds. Sternberg has worked with several technology companies as an innovator and senior executive, and has patented nanomaterial products and manufacturing techniques. He is expected to contribute to the rollout of NEXBOARD, an eco-friendly, patent-pending composite green construction panel made from plastic and fiber waste. Xeriant’s CEO, Keith Duffy, stated that Sternberg’s business accomplishments in the nanomaterials space will ensure the successful introduction of NEXBOARD into the green construction materials marketplace. Sternberg is excited to contribute to the rollout of NEXBOARD, which he believes has the potential to save lives and reduce property damage.

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A six-day online faculty development program (FDP) on “Nano materials for real-time biomedical applications” is being held at JSS Science and Technology University in Mysuru, India. The program, organized by the department of electronics and communication engineering, aims to empower academicians, researchers, and students to advance nanotechnology’s role in healthcare. The FDP provides a platform for knowledge exchange and collaboration, with a focus on the latest advancements in nano materials for biomedical use, including theranostics, bioimaging, and nanovaccine technologies. The program concluded on January 11, with a chief guest speech by NH Siddalinga Swamy, adviser-II of the All India Council for Technical Education (AICTE). Other dignitaries present included AN Santosh Kumar, vice-chancellor of JSS Science and Technology University, and C Nataraju, principal of SJCE and dean (E&T) of JSS STU.

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This review article focuses on the synthesis methods and applications of rhenium-based nanomaterials (ReNPs) for sustainable purposes. The article highlights the development of electrochemical sensors, catalytic organic reactions, surface-enhanced Raman spectroscopy (SERS), and biomedical applications. The authors discuss the excellent stability, adaptability, affordability, safety, and biocompatibility of ReNPs, which make them suitable for various fields, including biology, chemistry, optics, and sensing.

The article summarizes the preparation procedures and applications of ReNPs in catalysis, SERS, supercapacitors, photocatalysis, biology, and biomedical applications. Additionally, the authors discuss the potent anti-microbial and anti-cancer activities of ReNPs. The review also touches on the challenges and future opportunities associated with Re nanomaterials. The article is published in Coordination Chemistry Reviews, Elsevier Publications, and aims to provide a comprehensive overview of the current state of Re-based nanomaterials and their potential applications.

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The article discusses the role of crop protection in sustainable potato production to alleviate global starvation problems. It highlights the importance of integrated pest management (IPM) strategies that combine physical, cultural, biological, and chemical controls to minimize the use of chemical pesticides. The article also reviews the bioefficacy of farnesol, a common sesquiterpene, on the survival, growth, and development of Spodoptera littoralis, a major pest of potato crops.

The article also discusses the use of nanoparticles, such as zinc oxide and selenium, as a potential alternative to chemical pesticides. It highlights the benefits of nanoparticles, including their ability to target specific pests and reduce environmental pollution. The article also reviews the use of biological control agents, such as Trichoderma spp., to control pests and diseases in potato crops.

Additionally, the article discusses the importance of sustainable agriculture practices, such as organic farming and permaculture, to promote soil health and biodiversity. It highlights the need for a holistic approach to crop protection that considers the ecological and environmental impacts of pest management strategies.

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Scientists have discovered a new method to sculpt diamonds by controlling the reactions of carbon atoms in a furnace at a temperature similar to a lit match (500-700°C). The initial goal was to purify diamonds through air oxidation, but the researchers found that the uneven oxidation of carbon atoms could be used to shape diamonds into various forms. By controlling the time and temperature, they were able to create specific shapes, such as spheres, pyramids, and porous crystals, in large batches. This method can produce up to 500 million diamonds measuring 1-2 micrometers in diameter in less than a day. The unique shapes and properties of these diamonds could be used in security applications, such as verifying authenticity, and the researchers hope to refine the technique to create diamonds with specific optical and quantum properties.

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A team of researchers at Columbia Engineering and Lawrence Berkeley National Lab have developed a new type of force sensor that can measure piconewton to micronewton forces with high sensitivity and spatial resolution. The nanoscale sensors, called “all-optical nanosensors,” use luminescent nanocrystals that emit light when pushed or pulled. This allows for remote read-outs and eliminates the need for wires or connections. The sensors have an unprecedented dynamic range, spanning four orders of magnitude in force, and are 100 times more sensitive than existing nanoparticles.

The team used the photon-avalanching effect, where a single photon absorbed by a nanocrystal triggers the emission of many photons, to create the sensors. They also designed new nanosensors that change their luminescence color or intensity in response to applied forces. The sensors can operate in previously inaccessible environments, such as subsurface or interfacial sites, and have potential applications in robotics, cellular biophysics, medicine, and space travel. The researchers believe the new sensors will revolutionize the field of sensing, enabling the study of forces in a wide range of systems, from the subcellular to the whole-system level.

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The article “Accelerating innovative water treatment in Latin America” highlights the need for innovative solutions to treat water pollution in Latin America. The article reviews recent advances in chemical oxygen demand (COD) determination methods, including non-electrochemical and electrochemical approaches. Electrochemical methods have gained popularity due to their high sensitivity and selectivity. The review covers the use of boron-doped diamond (BDD) electrodes, titanium dioxide (TiO2), and other semiconductor materials in COD determination.

The article also discusses the use of advanced oxidation processes (AOPs) and photocatalysis in water treatment. AOPs are chemical processes that use oxidizing agents to break down pollutants, while photocatalysis uses light to accelerate chemical reactions. The article highlights the use of BDD electrodes and TiO2 in AOPs and photocatalysis applications.

The authors also review the use of renewable energy sources, such as solar and wind power, to drive electrochemical water treatment processes. The article concludes by highlighting the need for further research on innovative water treatment technologies, including electrochemical and AOP approaches, to address the global water pollution challenge.

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