Innovative Drug Delivery System Developed by Indian Researchers for Treating Rheumatoid Arthritis

Innovative Drug Delivery System Developed by Indian Researchers for Treating Rheumatoid Arthritis @neosciencehub #Sciencenews #Healthcare #neosciencehub #RheumatoidArthritis #DrugDeliverySystem #INST

Rheumatoid Arthritis (RA) poses a significant challenge for millions worldwide, characterized by chronic inflammation of the joints and debilitating pain. Traditional treatments often involve systemic drug administration, leading to complications, side effects, and the necessity for frequent dosing. However, researchers from the Institute of Nano Science and Technology (INST) in Mohali, India,…

Space Technology Opportunity in India

Written By: Jagriti Shahi

Introduction:

Entrepreneurship in space technology in India has been gaining momentum in recent years. The Indian government has been actively promoting the development of the space sector, and private companies are playing an increasingly important role.

As the nation liberalizes its space sector, a diverse array of players are contributing to the burgeoning space ecosystem. Entrepreneurs are venturing into satellite manufacturing, pushing the boundaries of launch services, delving into space exploration, and exploring innovative solutions for satellite-based communication. The landscape is further enriched by collaborative efforts between private entities, government agencies, and academic institutions, fostering a dynamic environment for research and development.

In this context, it's crucial to explore the challenges and opportunities that define the entrepreneurial spirit in India's space technology sector. Regulatory hurdles, infrastructure development, and the need for sustained investments are among the challenges that entrepreneurs face. However, with increasing investor interest, a robust policy framework, and a commitment to fostering innovation, India's entrepreneurial ventures in space technology are poised to shape the nation's narrative in the cosmic domain. This dynamic interplay of public and private entities is not only propelling India's space capabilities but is also contributing to the global discourse on the commercialization and exploration of space.

Here are some key aspects of entrepreneurship in space technology in India:

Government Initiatives:New Space Policy: The Indian government has introduced policies to encourage private sector participation in space activities. The New Space India Limited (NSIL) was established to promote, commercially exploit, and transfer technologies developed by the Indian Space Research Organisation (ISRO).Liberalization: The government has liberalized the space sector, allowing private companies to undertake a wide range of space-related activities, including satellite launches, space exploration, and satellite communication services. (ISRO) Initiatives: Antrix Corporation: Antrix is the commercial arm of ISRO, and it collaborates with private players for the commercialization of space-related products and services.: SEED is a program initiated by ISRO to promote startups in the space sector by providing them with opportunities for collaboration and technology transfer.: NSIL is a central public sector enterprise (CPSE) under the Department of Space. It plays a crucial role in commercializing space products, technical consultancy services, and transfer of technologies.: ISRO has been actively engaging with startups, providing them access to its facilities, expertise, and technology.: The Department of Space in India oversees the country's space program. It may introduce schemes and programs to support space technology startups and entrepreneurs. (AIM): AIM, a flagship initiative of the NITI Aayog, supports innovation and entrepreneurship in various sectors. It may have programs and funding opportunities that space technology startups can explore. (NIF): NIF supports grassroots innovations and may provide support to startups working on innovative space technologies.

Private Space Companies:Startups: Several startups in India are focusing on various aspects of space technology. Some are involved in satellite manufacturing, launch services, data analytics from space, and more.Launch Services: Companies like Agnikul Cosmos, Skyroot Aerospace, and Pixxel are working on developing small satellite launch vehicles to provide cost-effective and flexible launch options.

Space Exploration and Research: Interplanetary Missions: ISRO has been actively involved in space exploration, and private companies are expressing interest in participating in future interplanetary missions.Research and Development: Private entities are engaging in research and development activities, contributing to advancements in satellite technology, propulsion systems, and other space-related technologies.

Satellite Manufacturing:Private Satellite Manufacturers: Companies like Exseed Space and Bellatrix Aerospace are involved in the manufacturing of satellites, catering to various purposes such as communication, Earth observation, and scientific research.

Communication Services:Telecommunication Satellites: Private companies are exploring opportunities to provide satellite-based communication services. This includes both broadband internet services and other communication solutions.

Funding and Investments:Investor Interest: The space technology sector in India has attracted attention from investors. Funding rounds for space startups have been on the rise, indicating confidence in the potential growth of the industry.

Collaborations and Partnerships:

Industry-Academia Collaboration: Partnerships between private companies, government organizations, and academic institutions are fostering innovation and research in the space sector.

The Indian space technology ecosystem is evolving, and with continued government support, entrepreneurial ventures in space technology are expected to play a crucial role in shaping the future of the Indian space industry.

The number of space tech startups in India has witnessed explosive growth, increasing by almost five times in just five years. Investments in the sector have also seen a sharp rise, from $17 million in 2019 to an estimated $124.7 million in 2023.

Commercialization of Space Activities: With India's proven track record in satellite launches and space technology, there is a substantial potential for the commercialization of space activities. The burgeoning demand for satellite-based services, including communication, arth observation, and navigation, opens up opportunities for private entities to actively participate in the space industry. As the cost of space access continues to decrease, private companies can explore ventures such as satellite manufacturing, space tourism, and satellite-based applications, contributing to economic growth and job creation.

International Collaborations: Collaborations with other space-faring nations present a promising avenue for India to augment its space capabilities. Joint ventures, knowledge exchange, and technology transfer can accelerate innovation and enhance the efficiency of space missions. ISRO has already established itself as a reliable partner for international launches, and expanding collaborative efforts can lead to shared resources, reduced costs, and a more diversified approach to space exploration. As India continues to engage in global partnerships, it can leverage collective expertise for ambitious endeavors beyond Earth's orbit.

Innovation in Space Technology: Investments in research and development (R&D) can catapult India into the forefront of space innovation. Emphasis on cutting-edge technologies such as artificial intelligence, advanced materials, and propulsion systems can revolutionize space missions. The development of reusable launch vehicles, like the ongoing efforts in creating a Reusable Launch Vehicle (RLV), can significantly reduce launch costs, making space exploration more sustainable. Encouraging a culture of innovation, fostering collaboration between academia and industry, and providing incentives for R&D initiatives can fuel breakthroughs in space technology.

Space Applications for Sustainable Development: Leveraging space technology for sustainable development on Earth is an untapped frontier. Utilizing satellite data for precision agriculture, disaster management, environmental monitoring, and resource mapping can contribute to addressing pressing global challenges. By integrating space-based solutions into sectors such as agriculture, healthcare, and urban planning, India can harness the power of space technology for inclusive and sustainable development, bringing tangible benefits to its citizens and contributing to global initiatives.

Expansion of Interplanetary Exploration: Building on the success of Mars Orbiter Mission (Mangalyaan), India has the potential to expand its interplanetary exploration efforts. Initiatives for exploring other celestial bodies, such as Venus or asteroids, can contribute to humanity's understanding of the solar system and beyond. A strategic focus on ambitious interplanetary missions can position India as a key player in the broader scientific community and foster international collaboration in the exploration of the cosmos.

Trending Technologies in India's Space Industry:

Nanotechnology: The integration of nanotechnology in space technology has the potential to revolutionize spacecraft design, materials, and instrumentation. Nanosatellites, with their miniaturized components, are becoming increasingly popular for cost-effective and innovative space missions. India can leverage nanotechnology for lightweight yet robust spacecraft, enhancing mission efficiency and scientific capabilities.

Companies: Nano-Tech SpA, Kalva Nanotech

Artificial Intelligence (AI) and Machine Learning (ML): AI and ML are playing a pivotal role in data analysis, image processing, and autonomous decision-making in space missions. India can explore AI applications for real-time data interpretation, automated navigation, and predictive maintenance of spacecraft. Incorporating machine learning algorithms into Earth observation data analysis can significantly enhance the understanding of environmental changes.

Companies: Aadyah Aerospace, Blue Sky Analytics

Quantum Computing: Quantum computing holds the promise of solving complex computational problems beyond the capabilities of classical computers. In the space sector, quantum computing can be utilized for optimizing mission trajectories, simulating quantum systems, and enhancing the security of communication channels. India's focus on quantum computing research can contribute to advancements in space-related computations.

Companies: QpiAI, BosonQ

3D Printing/Additive Manufacturing: The adoption of 3D printing in space technology can revolutionize the manufacturing process, enabling the production of complex and lightweight structures. India can benefit from 3D printing for rapid prototyping, cost-effective manufacturing of satellite components, and even on-demand production during long-duration space missions.

Companies: Agnikul Cosmos, EOS India

Blockchain Technology: Blockchain technology offers secure and transparent data management, making it applicable to space-based applications such as satellite communication, data storage, and secure information sharing. By incorporating blockchain, India can enhance the security and integrity of space-related data and transactions.

Companies: SpaceTime Labs, Aryaka Networks

Solar Sail Technology: Solar sails, propelled by the pressure of sunlight, offer a sustainable and efficient means of propulsion for spacecraft. This technology can be harnessed for deep-space exploration, enabling missions to travel vast distances with minimal fuel requirements. India's exploration programs can benefit from research and development in solar sail technology for extended-duration missions.

Companies: Indian Institute of Space Science and Technology (IIST), IIT Bombay - Aerospace Engineering Department

Hyperspectral Imaging: Hyperspectral imaging involves capturing a wide range of wavelengths in the electromagnetic spectrum. This technology is instrumental in Earth observation, resource mapping, and environmental monitoring. India can explore the integration of hyperspectral imaging in its satellite payloads for enhanced remote sensing capabilities.

Companies: Pixxel, Paras Defence & Space Technologies Ltd

Internet of Things (IoT) for Space: The application of IoT in space technology involves connecting devices and sensors on satellites and spacecraft to gather and transmit data. This interconnected network can facilitate efficient communication, data collection, and collaborative decision-making during space missions. India can explore IoT applications for enhanced space situational awareness and mission coordination.

Companies: Agnikul Cosmos

As India looks to the future, embracing these trending technologies will be crucial for maintaining its competitive edge in space exploration and satellite technology. By actively incorporating these innovations into its space programs, India can not only enhance mission success but also contribute to the global advancement of space technology. Collaborations with research institutions, startups, and the private sector will play a vital role in driving these technological advancements in India's space industry.

Challenges and the Way Forward:

Despite its successes, India's space program faces challenges such as increased competition, budget constraints, and the need for continuous innovation. To overcome these challenges, sustained government support, collaboration with private entities, and a focus on skill development in the space sector are crucial.

Increased Global Competition: The space industry is becoming increasingly competitive with the emergence of new players and the commercialization of space activities. To stay ahead, India must continuously innovate, streamline its processes, and invest in cutting-edge technologies. Developing a robust ecosystem for space startups and fostering public-private partnerships can enhance India's competitiveness in the global space market.

Budget Constraints: Despite commendable achievements, budget constraints pose a challenge for sustaining and expanding India's space endeavors. A consistent and increased allocation of funds to ISRO, along with exploring innovative funding mechanisms, will be crucial. Engaging with the private sector for joint ventures and commercial space activities can help alleviate financial constraints and promote economic sustainability in the long run.

Human Resource Development: The growth of India's space program necessitates a skilled workforce capable of handling complex missions. Investing in education and training programs in collaboration with academic institutions can ensure a steady supply of skilled professionals in fields such as aerospace engineering, astrophysics, and data sciences. This will not only address the current workforce requirements but also fuel future innovations in space technology.

Technological Advancements: Rapid technological advancements globally require India to stay at the forefront of innovation. Embracing emerging technologies such as artificial intelligence, quantum computing, and advanced propulsion systems will be essential. Establishing research and development centers dedicated to space technology innovation can facilitate the integration of these advancements into future missions.

Space Debris Management: The increasing number of satellites and space missions contribute to the growing issue of space debris. India needs to actively participate in international efforts to address space debris management, adopting sustainable practices in satellite design and end-of-life disposal. Research into debris removal technologies and international collaboration on space traffic management will be pivotal in ensuring the long-term sustainability of space activities.

Climate Change Monitoring: With the rising global concerns about climate change, space technology plays a crucial role in monitoring environmental indicators. India can take a leadership role in developing satellite-based solutions for climate monitoring, disaster response, and sustainable resource management. This requires a dedicated focus on Earth observation satellites, advanced sensors, and data analytics.

Enhanced Space Diplomacy: Strengthening space diplomacy is essential for India to expand its global influence in the space arena. Engaging in collaborative space missions, sharing scientific knowledge, and participating in international forums will enhance India's standing as a responsible space-faring nation. Forming strategic partnerships with countries interested in space exploration can open up new avenues for cooperation and joint missions.

Conclusion:

India's journey in space technology has been nothing short of remarkable, with ISRO consistently pushing the boundaries of innovation. As the nation continues to invest in space exploration, the opportunities for growth, collaboration, and technological advancements are boundless. The future holds exciting possibilities for India's space technology sector, positioning the country as a key player in the global space community.

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Hard carbon-tin nano-composite creates high-performance battery anode

As the demand continues to grow for batteries capable of ultra-fast charging and high energy density in various sectors—from electric vehicles to large-scale energy storage systems (ESS)—a joint research team from POSTECH (Pohang University of Science and Technology) and the Korea Institute of Energy Research (KIER) has developed a promising next-generation anode material that may address these critical needs. The research is published in the journal ACS Nano. While graphite, the most common anode material in lithium-ion batteries (LIBs), offers robust structural stability, it is limited by its low theoretical capacity and sluggish charge/discharge rates. To overcome these limitations, the researchers have proposed a novel electrode design that combines hard carbon with tin (Sn).

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Dyes widely used in the textile, food and pharmaceutical industries pose a pressing threat to plant, animal and human health, as well as natural environments around the world, a new study has found. Billions of tons of dye-containing wastewater enter water systems every year, and a group of researchers from the UK, China, Korea and Belgium say that new sustainable technologies including new membrane-based nano-scale filtration are needed to solve the issue, adding that legislation is needed to compel industrial producers to eliminate colorants before they reach public sewage systems or waterways. Published today in Nature Reviews Earth & Environment, the study Environmental impacts and remediation of dye-containing wastewater was written by academics from the University of Bath, the Chinese Academy of Sciences, the Fujian Agriculture and Forestry University, the Korea Institute of Energy Technology (KENTECH), and KU Leuven, Belgium. The research highlights that currently, up to 80% of dye-containing industrial wastewaters created in low- and middle-income countries are released untreated into waterways or used directly for irrigation. The authors say this poses a wide range of direct and indirect threats to human, animal and plant health

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Lunar sample research could help protect astronauts and uncover origins of water on the moon

Dust and rocks residing on the surface of the moon take a beating in space. Without a protective magnetosphere and atmosphere like Earth's, the lunar surface faces continual particle bombardment from solar wind, cosmic rays, and micrometeoroids. This constant assault leads to space weathering.

New research by Georgia Tech offers fresh insights into the phenomenon of space weathering. Examining Apollo lunar samples at the nanoscale, Tech researchers have revealed risks to human space missions and the possible role of space weathering in forming some of the water on the moon.

Most previous studies of the moon involved instruments mapping it from orbit. In contrast, this study allowed researchers to spatially map a nanoscale sample while simultaneously analyzing optical signatures of Apollo lunar samples from different regions of the lunar surface—and to extract information about the chemical composition of the lunar surface and radiation history.

The researchers recently published their findings in Scientific Reports.

"The presence of water on the moon is critical for the Artemis program. It's necessary for sustaining any human presence and it's a particularly important source of oxygen and hydrogen, the molecules derived from splitting water," said Thomas Orlando, Regents' Professor in the School of Chemistry and Biochemistry, co-founder and former director of the Georgia Tech Center for Space Technology and Research, and principal investigator of Georgia Tech's Center for Lunar Environment and Volatile Exploration Research (CLEVER).

Building on a decade of lunar science research

As a NASA SSERVI (Solar System Exploration Research Virtual Institute), CLEVER is an approved NASA laboratory for analysis of lunar samples and includes investigators from multiple institutes and universities across the U.S. and Europe. Research areas include how solar wind and micrometeorites produce volatiles, such as water, molecular oxygen, methane, and hydrogen, which are all crucial to supporting human activity on the moon.

Georgia Tech has built a large portfolio in human exploration and lunar science over the last decade with two NASA Solar System Exploration Research Virtual Institutes: CLEVER and its predecessor, REVEALS (Radiation Effects on Volatiles and Exploration of Asteroids and Lunar Surfaces).

Studying moon samples at the nanoscale level

For this work, the Georgia Tech team also tapped the University of Georgia (UGA) Nano-Optics Laboratory run by Professor Yohannes Abate in the Department of Physics and Astronomy. While UGA is a member of CLEVER, its nano-FTIR spectroscopy and nanoscale imaging equipment was historically used for semiconductor physics, not space science.

"This is the first time these tools have been applied to space-weathered lunar samples, and it's the first time we've been able to see good signatures of space weathering at the nanoscale," says Orlando.

Normal spectrometers are at a much larger scale, with the ability to see more bulk properties of the soil, explains Phillip Stancil, professor and head of the UGA physics department.

The UGA equipment enabled the study of samples "in tens of nanometers." To illustrate how small nanoscale is, Stancil says a hydrogen atom is .05 nanometers, so 1 nm is the size of 20 atoms if placed side by side. The spectrometers provide high-resolution details of the lunar grains down to hundreds of atoms.

"We can look at an almost atomistic level to understand how this rock was formed, its history, and how it was processed in space," Stancil says.

"You can learn a lot about how the atom positions change and how they are disrupted due to radiation by looking at the tiny sample at an atomistic level," says Orlando, noting that a lot of damage is done at the nanoscale level. They can determine if the culprit is space weathering or from a process left over during the rock's formation and crystallization.

Finding radioactive damage, evidence of water

The researchers found damage on the rock samples, including changes in the optical signatures. That insight helped them understand how the lunar surface formed and evolved but also provided "a really good idea of the rocks' chemical composition and how they changed when irradiated," says Orlando.

Some of the optical signatures also showed trapped electron states, which are typically missing atoms and vacancies in the atomic lattice. When the grains are irradiated, some atoms are removed, and the electrons get trapped. The types of traps and how deep they are, in terms of energy, can help determine the radiation history of the moon. The trapped electrons can also lead to charging, which can generate an electrostatic spark. On the moon, this could be a problem for astronauts, exploration vehicles, and equipment.

"There is also a difference in the chemical signatures. Certain areas had more neodymium (a chemical element also found in the Earth's crust) or chromium (an essential trace mineral), which are made by radioactive decay," Orlando says. The relative amounts and locations of these atoms imply an external source like micrometeorites.

Translating research to human risks on the moon

Radiation and its effects on the dust and lunar surface pose dangers to people, and the main protection is the spacesuit.

Orlando sees three key risks. First, the dust could interfere with spacesuits' seals. Second, micrometeorites could puncture a spacesuit. These high-velocity particles form after breaking off from larger chunks of debris. Like solar storms, they are hard to predict, and they're dangerous because they come in at high-impact velocities of 5 kilometers per second or higher. "Those are bullets, so they will penetrate the spacesuits," Orlando says. Third, astronauts could breathe in dust left on the suits, causing respiratory issues. NASA is studying many approaches for dust removal and mitigation.

Mapping the moon: Going from nanoscale to macroscale

The next research phase will involve combining the UGA analysis tools with a new tool from Georgia Tech that will be used to analyze Apollo lunar samples that have been in storage for more than 50 years.

"We will combine two very sophisticated analysis tools to look at these samples in a level of detail that I don't think has been done before," Orlando says.

The goal is to build models that can feed into orbital maps of the moon. To get there, the Georgia Tech and UGA team will need to go from nanoscale to the full macro scale to show what's happening on the lunar surface and the location of water and other key resources, including methane, needed to support humanity's moon and deep-space exploration goals.

Hamas didn’t invade Israel on Oct. 7 for its amusement. The barbaric sneak attack is a part of the pogrom intended to wipe out the Jewish state. It was a crime against humanity, and not just because of its savagery. We would all be worse off if Israel ceased to exist. The same cannot be said for Islamic terrorists.

Israel’s contributions to the modern world are momentous. When not dodging bullets, rockets, and homicide bombers, Israelis have since 1948 developed:

Copaxone and Rebif, drugs that treat multiple sclerosis, and Exelon, which treats mild to moderate dementia in Alzheimer’s and Parkinson’s patients.

The PillCam, “a minimally invasive ingestible camera in a capsule that allows visualization of the small bowel.”

The water desalination process.

The Sniffphone, “that can actually ‘sniff out’ diseases.”

And SpineAssist, “​​the first-ever spine robot” that has the “ability to provide real-time intraoperative navigation.”

The Weizmann Institute of Science in Rehovot, Israel, responsible for some of the inventions listed above, has also produced diabetes and flu vaccines, is using T-cells to treat damaged spines, and is a pioneer in industrial — and medical — uses nano materials. 

Other impactful Israeli products include drip irrigation, a revolutionary microprocessor called the 8088, the ​​NIR heart stent, voice-over-internet protocol, the ​​USB flash drive, the Waze navigation app, ReWalk, “a commercial bionic walking assistance system,” and “the first commercially viable firewall software.” 

Our own security has benefited from Israel’s labor and work ethic.

“Many Israeli innovations are present in upgrades to U.S. Air Force fighters and Army equipment,” says the international law firm Smith, Gambrell & Russell. One important advance in particular is the helmet-mounted display system for the new F-35 Joint Strike Fighter.

So we have a country of 9.23 million, mostly desert, that is only 75 years old, is “surrounded by enemies” and in a constant state of war, which has “no natural resources,” yet “produces more start-up companies on a per capita basis than large, peaceful, and stable nations and regions like Japan, China, India, Korea, Canada, and all of Europe.” It is the only nation outside of the U.S. that Warren Buffet invests in.

Have the Palestinians or Hamas, currently at war with Israel, done anything that compares to what the Israelis have achieved? More broadly, beyond the Allahista terrorist groups, what has Islam contributed to the modern world?

Not much.

Since 1901, Jews, who total 0.2% of the world’s population, have won 189 Nobel prizes for physics, medicine, chemistry and economics. Over that same period, Muslims, who make up nearly a quarter of the global population, have won four.

If it seems as Islamic groups, Hamas and Hezbollah prominent among them, are more interested in spreading nihilism, committing atrocities, and destroying civilization than making the world a better place, well, then there’s a good reason for it. That is exactly what the heroes of an increasingly large number foolish Westerners are aiming for.

Meanwhile, Israelis see themselves “as having a role in the world to repair the world,” says Chemi Peres, managing partner and co-founder of the venture capital firm Pitango, chairman of the Peres Center for Peace and Innovation, and son of the late Israeli Prime Minister Shimon Peres.

“We call it tikkun olam, and here at the Peres Center we have a mission statement, which is to introduce innovation and new ideas and new technologies, not only for ourselves but to solve the problems of the world.”

Islam is part of that world, but too many of its adherents live to do just the opposite. 

— Written by the I&I Editorial Board

Brain Health Supplements Market Outlook 2034

Brain Health Supplements Market is entering a dynamic growth phase, projected to expand from $7.2 billion in 2024 to $17.1 billion by 2034, with a promising CAGR of 9%. As global awareness around mental wellness intensifies, consumers are turning to supplements to support memory, cognitive function, mood, and neurological health. Products in this space — ranging from omega-3 fatty acids, herbal extracts like ginkgo biloba, to innovative nootropics — are fast becoming mainstream in everyday wellness routines. With aging populations and a growing focus on preventative health, the market’s relevance continues to surge.

Market Dynamics

The demand for brain health supplements is largely fueled by lifestyle shifts, increased screen time, work-related stress, and aging-related cognitive decline. Among the most sought-after products are memory enhancers, which dominate with a 45% market share. These are followed by mood and depression supplements at 30%, driven by rising interest in natural mood management. A further 25% of the market is carved out by anti-aging and neuroprotective products, addressing concerns about long-term brain health.

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Consumers are increasingly opting for natural and organic ingredients, such as curcumin, Bacopa monnieri, and ashwagandha. Additionally, technological advancements in supplement delivery systems — like liposomal and nano-formulations — are improving bioavailability and product efficacy, further boosting adoption. However, the market still contends with challenges such as regulatory hurdles, price sensitivity, and skepticism about product claims. Despite these barriers, increased R&D investment and scientific validation are driving consumer confidence and long-term market growth.

Key Players Analysis

The competitive landscape of the brain health supplements market features a mix of established nutraceutical giants and emerging innovators. Companies like NOW Foods, Nature’s Bounty, and Jarrow Formulas are known for their wide-ranging product lines and global market presence. Their strengths lie in clinical research support, trusted branding, and distribution through pharmacies and health stores.

Meanwhile, emerging brands such as Neurohacker Collective, Mind Lab Pro, and HVMN are carving out niches with biohacker-targeted nootropics and precision-focused blends. These players are often early adopters of personalized nutrition trends and leverage digital platforms for direct-to-consumer marketing.

Partnerships between supplement makers and academic institutions are also gaining momentum, as companies work to back their claims with credible research. As a result, the landscape is becoming increasingly innovation-driven and science-backed.

Regional Analysis

North America leads the global market, largely due to its mature supplement industry, health-conscious consumers, and growing aging population. The United States is the frontrunner, accounting for a significant portion of global revenue, followed by Canada, which is witnessing a rise in preventative wellness approaches.

In Europe, countries like Germany and the United Kingdom are emphasizing mental wellness and natural solutions. Regulatory alignment and consumer education efforts have made Europe a fertile ground for growth, especially in plant-based and vegan-friendly formulations.

Asia-Pacific is an emerging powerhouse, with rapid urbanization, rising disposable incomes, and increased health awareness in countries like Japan, China, and South Korea. Traditional remedies combined with modern supplements are fueling market expansion.

Latin America and the Middle East & Africa are gradually catching up, with Brazil, Mexico, South Africa, and the UAE emerging as promising markets. A rising middle class, along with improved access to health stores and online platforms, is supporting demand in these regions.

Recent News & Developments

In recent years, the brain health supplements market has seen a wave of product launches and acquisitions. Companies are focusing on functional benefits — products that go beyond general wellness to support specific areas such as memory, focus, or mood regulation.

A growing trend is the integration of AI and digital platforms to provide personalized supplement recommendations, bridging the gap between supplements and tech-enabled health tracking. Additionally, there’s an uptick in subscription-based supplement services, enhancing consumer retention.

Many firms are also investing in sustainably sourced ingredients and clean-label formulations, responding to consumer preferences for transparency and environmental responsibility. Regulatory bodies like the FDA and EFSA continue to tighten standards, which — while challenging for some — has ultimately improved trust and product quality across the board.

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Scope of the Report

This comprehensive analysis of the Brain Health Supplements Market covers a wide spectrum — from types (natural molecules, herbal extracts, vitamins) to applications (cognitive health, sleep disorders, neurodegenerative diseases). With a growing user base projected to reach 500 million units by 2028, the market’s segmentation helps understand key growth drivers and consumer behaviors.

It also dives into emerging technologies like nanotech, new distribution channels like e-commerce platforms, and end-user profiles spanning adults, children, and the elderly. The report outlines how brands are navigating regulatory landscapes and leveraging scientific innovation to gain competitive advantage.

From understanding regional growth patterns to tracking consumer preferences and pricing trends, this market is poised for sustained growth. With the convergence of mental wellness, nutrition, and personalized health, brain health supplements are no longer niche — they are essential.

#brainhealth #cognitivesupport #nootropics #mentalwellness #memoryboost #naturalnootropics #healthyaging #supplementinnovation #neurohealth #focussupplements

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Bioactive Materials Market Size, Future Outlook & Innovations 2032

Global Bioactive Materials Market Overview The Global Bioactive Materials Market is experiencing robust growth, with the market valued at approximately USD 2.1 billion in 2024. It is projected to expand at a compound annual growth rate (CAGR) of 10.8% during the forecast period of 2025 to 2030. Bioactive materials, widely used in medical implants, tissue engineering, dental care, and drug delivery systems, are gaining traction due to their ability to interact with biological tissues and promote healing. Increasing demand for advanced wound care solutions, rising geriatric population, and the surge in orthopedic and dental procedures are key drivers supporting market expansion. Additionally, heightened investments in regenerative medicine and healthcare infrastructure are accelerating the adoption of bioactive materials globally. Global Bioactive Materials Market Dynamics Drivers: Major market drivers include the rising incidence of bone and joint disorders, increasing dental implant procedures, and technological advancements in biomaterials. The shift toward biocompatible and bioresorbable materials in healthcare further fuels the growth of the market. Restraints: High production costs, strict regulatory approval processes, and challenges in raw material availability act as major hindrances to market growth. Additionally, lack of awareness in developing regions and limited clinical validation in some applications can limit adoption. Opportunities: Emerging economies offer untapped potential due to expanding healthcare access and rising medical tourism. Moreover, increasing R&D initiatives, particularly in tissue engineering and 3D bioprinting, are likely to create lucrative opportunities. Regulatory support for biodegradable and sustainable materials also enhances the market outlook. Technology & Sustainability: Advanced manufacturing technologies such as sol-gel processing, nano-fabrication, and additive manufacturing are transforming production scalability and efficiency. Sustainability trends are pushing manufacturers to develop eco-friendly and biocompatible materials that align with circular economy principles. Download Full PDF Sample Copy of Global Bioactive Materials Market Report @ https://www.verifiedmarketresearch.com/download-sample?rid=144953&utm_source=PR-News&utm_medium=351 Global Bioactive Materials Market Trends and Innovations The market is witnessing rapid innovation driven by technological progress in material sciences. Emerging trends include the integration of nanotechnology to enhance material bioactivity, and the development of hybrid composites that offer superior mechanical and biological properties. Product innovations such as injectable bioactive gels, scaffold-based materials for tissue regeneration, and bioactive glass ceramics are gaining momentum. Collaborative ventures between research institutions and medtech companies are accelerating the commercialization of novel bioactive products. Companies are also adopting AI and machine learning to optimize design and predict material performance, thus reducing development time and cost. Global Bioactive Materials Market Challenges and Solutions Challenges: Supply chain disruptions, fluctuating raw material prices, and complex regulatory landscapes are key challenges affecting the bioactive materials market. Manufacturers face hurdles in maintaining product consistency and achieving scalable production under strict quality standards. Solutions: Diversifying supplier bases and investing in local manufacturing can help mitigate supply chain risks. Strategic partnerships with regulatory bodies and third-party testing laboratories can streamline product approvals. Additionally, adopting digital manufacturing techniques and automation can reduce costs and ensure high precision in production. Global Bioactive Materials Market Future Outlook Looking forward, the Global Bioactive Materials Market is poised for dynamic growth, driven by rising healthcare needs, technological breakthroughs, and the growing emphasis on regenerative medicine.

The integration of smart biomaterials with real-time monitoring capabilities and the expansion of personalized medicine are expected to shape the next decade of development. Strategic investments in R&D and public-private collaborations will be critical to unlocking new applications and enhancing material functionality. By 2030, the market is expected to surpass USD 4.2 billion, positioning bioactive materials as a cornerstone of future biomedical advancements. Key Players in the Global Bioactive Materials Market Global Bioactive Materials Market are renowned for their innovative approach, blending advanced technology with traditional expertise. Major players focus on high-quality production standards, often emphasizing sustainability and energy efficiency. These companies dominate both domestic and international markets through continuous product development, strategic partnerships, and cutting-edge research. Leading manufacturers prioritize consumer demands and evolving trends, ensuring compliance with regulatory standards. Their competitive edge is often maintained through robust R&D investments and a strong focus on exporting premium products globally.   Zimmer Holding Inc. Medtronic Inc. Stryker Corporation Biomatlante Arthrex Inc. Bioactive Bone Substitutes Lasak Ltd Bioretec Ltd. Noraker and Septodont Holding.   Get Discount On The Purchase Of This Report @ https://www.verifiedmarketresearch.com/ask-for-discount?rid=144953&utm_source=PR-News&utm_medium=351 Global Bioactive Materials Market Segments Analysis and Regional Economic Significance The Global Bioactive Materials Market is segmented based on key parameters such as product type, application, end-user, and geography. Product segmentation highlights diverse offerings catering to specific industry needs, while application-based segmentation emphasizes varied usage across sectors. End-user segmentation identifies target industries driving demand, including healthcare, manufacturing, and consumer goods. These segments collectively offer valuable insights into market dynamics, enabling businesses to tailor strategies, enhance market positioning, and capitalize on emerging opportunities. The Global Bioactive Materials Market showcases significant regional diversity, with key markets spread across North America, Europe, Asia-Pacific, Latin America, and the Middle East & Africa. Each region contributes uniquely, driven by factors such as technological advancements, resource availability, regulatory frameworks, and consumer demand. Bioactive Materials Market, By Material Type • Glass• Ceramics• Composites Bioactive Materials Market, By Application • Medical• Dentistry• Pharmaceuticals Bioactive Materials Market, By Form • Powder• Granules Bioactive Materials Market By Geography • North America• Europe• Asia Pacific• Latin America• Middle East and Africa For More Information or Query, Visit @ https://www.verifiedmarketresearch.com/product/bioactive-materials-market/ About Us: Verified Market Research Verified Market Research is a leading Global Research and Consulting firm servicing over 5000+ global clients. We provide advanced analytical research solutions while offering information-enriched research studies. We also offer insights into strategic and growth analyses and data necessary to achieve corporate goals and critical revenue decisions. Our 250 Analysts and SMEs offer a high level of expertise in data collection and governance using industrial techniques to collect and analyze data on more than 25,000 high-impact and niche markets. Our analysts are trained to combine modern data collection techniques, superior research methodology, expertise, and years of collective experience to produce informative and accurate research. Contact us: Mr. Edwyne Fernandes US: +1 (650)-781-4080 US Toll-Free: +1 (800)-782-1768 Website: https://www.verifiedmarketresearch.com/ Top Trending Reports https://www.verifiedmarketresearch.com/ko/product/batter-and-breader-premixes-market/

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Environmental Monitoring Devices Go Ultra-Sensitive with Nano Light

The global nanophotonics market, valued at USD 25.6 billion in 2023 and projected to surpass USD 45 billion by 2031 at a CAGR of 7.9%, is witnessing robust growth driven by rising innovation in telecommunications and increasing R&D investments, particularly in North America. Nanophotonics enables manipulation of light at the nanoscale, revolutionizing applications in optoelectronics, displays, and biomedical imaging. Market competition is intensifying with key players like EPISTAR Corporation, Samsung SDI Co Ltd., and OSRAM Licht AG expanding their technological capabilities to capture emerging opportunities across industries.

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Key Market Drivers

1. Growing Demand for Faster, Low-Energy Data Transmission

With explosive data generation, data centers and cloud systems demand ultra-fast, energy-efficient data transfer. Nanophotonic components like photonic integrated circuits (PICs) are revolutionizing how data is moved, processed, and stored.

2. Surge in LED and OLED Technologies

Widespread adoption of LED and OLED displays in televisions, smartphones, automotive dashboards, and wearable tech has significantly increased the demand for nanophotonic light emitters and filters, especially those based on quantum dots and plasmonics.

3. Advancements in Photonic Chips for AI and Machine Learning

AI and high-performance computing are integrating nanophotonic optical interconnects into chips to minimize latency and heat, improving processing speeds while reducing energy consumption.

4. Quantum Computing and Security Applications

Nanophotonics is fundamental to quantum communication and cryptography, enabling high-speed, unbreakable data transmission protocols through single-photon sources and waveguides.

5. Rising Applications in Biophotonics and Healthcare

Non-invasive medical diagnostics, biosensors, and real-time imaging are leveraging nanophotonic sensors to achieve superior sensitivity, resolution, and accuracy, especially in cancer detection and genomic sequencing.

Regional Trends

United States

The U.S. nanophotonics market benefits from:

Robust semiconductor policy investments such as the CHIPS Act.

Heavy investments by firms like Intel, NVIDIA, and IBM in optical computing, including photonics-powered AI accelerators.

Collaborations with universities like MIT and Stanford, advancing research in light-based transistors, plasmonic circuits, and meta-optics.

Expansion into military-grade nanophotonics, especially for secure communication and space-grade sensors.

Japan

Japan remains a global leader in:

Miniaturized optics for automotive lidar, biomedical tools, and AR/VR headsets.

Integration of nanophotonics into robotics and factory automation, essential to Industry 5.0.

Development of compact biosensors using metallic nanostructures and quantum dots for use in home diagnostics and elderly care.

Notable progress is being made by companies such as Hamamatsu Photonics, Panasonic, and Sony, in collaboration with R&D institutes like RIKEN and NIMS.

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Industry Segmentation

By Product:

Light-Emitting Diodes (LEDs)

Organic LEDs (OLEDs)

Photonic Integrated Circuits (PICs)

Optical Switches

Solar Photovoltaic Devices

Laser Diodes

Near-field Optical Components

By Material:

Plasmonic Nanostructures

Photonic Crystals

Semiconductor Quantum Dots

Carbon Nanotubes

Nanowires

By Application:

Consumer Electronics

Telecommunications

Healthcare & Life Sciences

Defense & Aerospace

Energy and Solar Cells

Automotive & Smart Mobility

Latest Industry Trends

AI Chips Powered by Nanophotonics U.S. startups are integrating light-based transistors into neural processors, enabling ultrafast computation with reduced energy overhead.

Next-Gen Displays with Quantum Dot Emitters Quantum dots embedded in nanophotonic architectures improve brightness, color fidelity, and efficiency in displays across smartphones and TVs.

Photonic Neural Networks in Development Light-based neural nets are being tested in Japan and the U.S. to replace electrical interconnects in deep learning hardware.

Nanophotonic Biosensors for Real-Time Diagnostics Portable nanophotonic devices for glucose monitoring, cancer markers, and airborne pathogen detection are gaining traction post-pandemic.

Flexible and Wearable Nanophotonic Devices Researchers are developing bendable and transparent photonic circuits for integration into smart textiles and wearable health trackers.

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Growth Opportunities

Data Center Optics: Expanding demand for optical interconnects in hyperscale data centers.

Automotive LiDAR and Optical Sensors: Nanophotonic lidar solutions are being miniaturized for next-gen autonomous driving.

Healthcare and Point-of-Care Devices: Growing use of on-chip diagnostic tools in both clinical and at-home settings.

5G & Beyond: Nanophotonics supports the backbone of high-speed network infrastructure with integrated optical circuits.

Space and Defense: Lightweight, ultra-sensitive nanophotonic sensors for space exploration, drones, and military surveillance.

Competitive Landscape

Major players in the global nanophotonics market include:

Intel Corporation

NKT Photonics

Hamamatsu Photonics

Samsung Electronics

Mellanox Technologies (NVIDIA)

Sony Corporation

Osram Licht AG

Luxtera (Cisco)

IBM Corporation

Mellanox Technologies

These companies are investing in:

Photonics foundries and wafer-level integration.

Startups and university spin-offs focused on next-gen light control and biosensing.

Joint ventures for scaling quantum and optical chip production.

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Conclusion

The nanophotonics market is emerging as a pivotal enabler across a wide spectrum of industries—from semiconductors and smart electronics to biotech and energy systems. As global demand intensifies for faster data transmission, energy efficiency, and miniaturization, nanophotonics offers scalable, sustainable solutions.

With leading countries like the United States and Japan investing heavily in R&D, infrastructure, and commercialization strategies, the market is entering a phase of high-value growth and disruption. The convergence of nanotechnology, AI, and photonics is shaping a future defined by faster, smarter, and more resilient technologies.

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Our research repository comprises more than 6,300 detailed reports covering over 40 industries, serving the evolving research demands of 200+ companies in 50+ countries. Whether through syndicated studies or customized research, our robust methodologies ensure precise, actionable intelligence tailored to your business landscape.

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X-Ray Grating Market 2025-2032

MARKET INSIGHTS

The global X-Ray Grating Market size was valued at US$ 145.6 million in 2024 and is projected to reach US$ 267.8 million by 2032, at a CAGR of 9.14% during the forecast period 2025-2032. The U.S. market accounted for approximately 32% of global revenue in 2024, while China’s market is expected to grow at a faster pace with 8.3% CAGR through 2032.

X-Ray gratings are precision optical components used to diffract X-rays in analytical instruments. These nanostructured devices play critical roles in phase-contrast imaging, spectroscopy, and medical diagnostics by manipulating X-ray beams at microscopic levels. The market primarily consists of absorption gratings and phase gratings, with absorption variants currently dominating 68% of total revenue share.

Growing adoption in synchrotron facilities and advancements in X-ray microscopy are driving market expansion. However, high manufacturing costs remain a challenge, with premium gratings costing upwards of USD 15,000 per unit. Key manufacturers like SMT and Shimadzu are investing in nanoimprint lithography to improve production efficiency. In 2023, the Paul Scherrer Institute demonstrated a breakthrough in high-efficiency grating fabrication, potentially reducing costs by 40% in coming years.

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Key Industry Players

Leading Manufacturers Focus on Precision and Innovation in X-Ray Grating Production

The global X-ray grating market exhibits a semi-fragmented competitive structure, blending multinational corporations with specialized regional suppliers. SMT (Supermirror Technologies) has emerged as a dominant force due to its high-precision grating solutions and robust manufacturing capabilities in North America and Europe. Their technology enables applications in advanced synchrotron facilities and medical imaging systems.

NTT Advanced Technology Corporation and XRNanotech have carved significant market shares through their patented nano-fabrication techniques. These companies accounted for approximately 22% of combined revenue share in 2024, serving major research institutions and industrial clients across Asia-Pacific markets.

The competitive intensity is further amplified by ongoing R&D investments in phase contrast imaging technologies. Unlike conventional absorption gratings, phase grating solutions are gaining traction in materials science applications because of their superior sensitivity to low-density specimens.

Meanwhile, European players like Microworks GmbH and Gitterwerk GmbH differentiate through customized grating solutions for synchrotron beamlines. Their strategic collaborations with academic institutions have strengthened their footprint in the scientific research segment, which represents over 35% of total application demand.

Recent competitive developments include SHIMADZU’s January 2024 launch of their ultra-high resolution X-ray Talbot-Lau interferometry gratings, specifically engineered for compact laboratory systems. This mirrors broader industry trends where manufacturers balance performance enhancements with form factor optimization for benchtop applications.

List of Key X-Ray Grating Companies Profiled

SMT (Supermirror Technologies) (Germany)

NTT Advanced Technology Corporation (Japan)

XRNanotech (U.S.)

SHIMADZU Corporation (Japan)

Paul Scherrer Institute PSI (Switzerland)

ASICON Tokyo Ltd. (Japan)

HORIBA France SAS (France)

Inprentus (U.S.)

Microworks GmbH (Germany)

Gitterwerk GmbH (Germany)

Wasatch Photonics (U.S.)

LightTrans International (Germany)

Segment Analysis:

By Type

Absorption Grating Segment Leads Due to High Demand in Medical and Industrial Imaging Applications

The market is segmented based on type into:

Absorption Grating

Phase Grating

By Application

Science Segment Dominates Owing to Increased Utilization in Research Laboratories and Academic Institutions

The market is segmented based on application into:

Chemical

Science

Others

By End-User

Healthcare Sector Holds Significant Share Driven by Advancements in Medical Imaging Technologies

The market is segmented based on end-user into:

Healthcare

Industrial

Research institutes

Others

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FREQUENTLY ASKED QUESTIONS:

What is the current market size of Global X-Ray Grating Market?

-> X-Ray Grating Market size was valued at US$ 145.6 million in 2024 and is projected to reach US$ 267.8 million by 2032, at a CAGR of 9.14% during the forecast period 2025-2032.

Which key companies operate in Global X-Ray Grating Market?

-> Key players include SMT, NTT Advanced Technology Corporation, XRNanotech, SHIMADZU, Paul Scherrer Institute PSI, and ASICON Tokyo Ltd., among others.

What are the key growth drivers?

-> Key growth drivers include increasing demand for high-resolution X-ray imaging, advancements in medical diagnostics, and growth in materials science research.

Which region dominates the market?

-> North America currently leads the market, while Asia-Pacific is expected to witness the highest growth rate during the forecast period.

What are the emerging trends?

-> Emerging trends include development of nano-structured gratings, integration with synchrotron facilities, and increasing applications in phase-contrast imaging.

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National Institute of Technology—[NIT], Srinagar

National Institute of Technology (NIT), Srinagar is one of India’s premier autonomous public technical universities, situated in the picturesque valley of Srinagar, Jammu & Kashmir. Established in 1960 as one of the first eight Regional Engineering Colleges (RECs) in India, it was upgraded to NIT status in 2003 and declared an Institute of National Importance under the NIT Act of 2007.

NIT Srinagar has steadily grown to become a center of academic and research excellence in Northern India. It offers undergraduate, postgraduate, and doctoral programs across a range of engineering, science, and management disciplines.

Campus and Location

Located along the serene banks of Dal Lake and surrounded by the Himalayan ranges, the NIT Srinagar campus is undoubtedly one of the most beautiful in India. Spread over 100+ acres, the campus offers an inspiring environment for academic pursuits.

Despite facing climatic and geographical challenges, the institute has modern infrastructure including academic blocks, laboratories, a central library, hostels, faculty residences, health centers, and recreational facilities.

Academic Programs

NIT Srinagar offers programs at the undergraduate (B.Tech), postgraduate (M.Tech, M.Sc., MBA), and doctoral (Ph.D.) levels, across various disciplines.

Undergraduate Programs (B.Tech) – 4 years:

Computer Science and Engineering (CSE)

Electronics and Communication Engineering (ECE)

Electrical Engineering (EE)

Mechanical Engineering (ME)

Civil Engineering (CE)

Chemical Engineering

Metallurgical and Materials Engineering

Information Technology (IT)

Postgraduate Programs (M.Tech & M.Sc.) – 2 years:

M.Tech in Structural Engineering, Water Resources, Thermal Engineering, Signal Processing, Power Systems, and more

M.Sc. in Physics and Chemistry

MBA (introduced in recent years)

Ph.D. Programs:

Offered across all major departments, including Engineering, Physics, Chemistry, Mathematics, and Humanities.

Admissions Process

Admission into NIT Srinagar is competitive and based on national-level entrance exams:

B.Tech: JEE Main followed by centralized JoSAA/CSAB counselling

M.Tech: Through GATE and CCMT counselling

M.Sc.: Based on IIT-JAM

MBA: CAT/MAT/CMAT scores, followed by personal interviews

Ph.D.: Entrance exam conducted by NIT followed by interview

The institute follows the Government of India’s reservation policy for SC/ST/OBC/EWS/PwD categories.

Infrastructure and Facilities

NIT Srinagar has built a robust infrastructure to support high-quality education, research, and student well-being.

Academic Infrastructure:

Smart classrooms with AV tools

High-speed internet and computing facilities

Department-specific laboratories (AI, Thermal, Civil, Nano-Materials, etc.)

A large Central Library with 70,000+ books, journals, and online databases (IEEE, Springer, etc.)

Residential and Support Facilities:

9+ hostels with mess, Wi-Fi, and recreation rooms

Health center with doctors and emergency care

Bank, post office, and campus shops

Sports grounds, gymnasium, and indoor games area

Canteens and cafes spread across campus

Efforts are constantly made to modernize infrastructure through funding from MHRD, World Bank (TEQIP), and HEFA.

Faculty and Research

NIT Srinagar has a team of experienced faculty members, many of whom hold Ph.D. degrees from premier institutions like IITs and foreign universities. The faculty is deeply engaged in teaching, research, and consultancy.

Research Strengths:

Renewable energy and solar tech

Structural engineering

Power systems and control

Materials and nanoscience

Data science and machine learning

Robotics and automation

Faculty and students regularly publish papers in peer-reviewed international journals, file patents, and participate in national/international conferences.

Innovation and Entrepreneurship

To promote a culture of innovation and entrepreneurship, NIT Srinagar supports:

Start-up incubation center (under MoE Innovation Cell)

Participation in Smart India Hackathon, Toycathon, and Ideathons

Technical student clubs for AI/ML, coding, robotics, and blockchain

Projects supported by DST, DRDO, AICTE, and ISRO

Several student-led projects have won accolades in national competitions and hackathons.

Placements and Internships

The Training and Placement Cell (TPC) plays a key role in bridging students with recruiters. The placement record has been consistently improving, especially in the CSE, ECE, and Mechanical departments.

Top Recruiters Include:

Amazon

TCS

Infosys

Wipro

IBM

L&T

Capgemini

DRDO

Indian Oil

Bharat Electronics

JSW Steel

Maruti Suzuki

Placement Highlights:

Highest Package: ₹22–25 LPA (offered to CSE students)

Average Package: ₹6–8 LPA (CSE/ECE)

Overall Placement Rate: 85–95% in core branches

Students also gain internships at IITs, DRDO, ISRO, and reputed private firms.

Student Life and Culture

Despite its remote location, NIT Srinagar has a vibrant and active campus culture. Students come from across India, creating a diverse and inclusive atmosphere.

Popular Events & Clubs:

Techvaganza – Annual tech fest

Sonzal – Cultural and literary festival

Sportiva – Annual sports meet

Photography Club, Coding Club, E-Cell, NSS, Music & Drama Club

These platforms promote creativity, leadership, and community involvement among students.

International Collaboration

NIT Srinagar is establishing global ties through MoUs with international universities, collaborative research, and student exchange programs. It also encourages students to pursue online international certifications, global internships, and industry exposure.

Challenges and Resilience

Given its geographical and political landscape, NIT Srinagar has occasionally faced operational challenges, especially during harsh winters or socio-political disturbances. However, the administration ensures academic continuity through online learning platforms, digital classrooms, and flexible calendars when required.

This resilience has only strengthened the spirit and adaptability of students and faculty alike.

Why Choose NIT Srinagar?

Institute of National Importance with government support

Strong academic curriculum with real-world orientation

Excellent placement opportunities, especially in CSE & ECE

Support for research, innovation, and start-ups

Cultural diversity and peaceful surroundings

Opportunities for national and global exposure

Scenic campus experience like no other in India

Conclusion

NIT Srinagar combines quality education, dedicated faculty, and a serene Himalayan setting to offer a unique learning experience. With increasing focus on research, placements, and holistic development, the institute is steadily climbing the ranks among India’s top engineering colleges.

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Butterfly-inspired 4D printing of smart hydrogels enables precise micro-nano deformation

A Chinese research team has developed a single-step femtosecond laser 4D printing technology that enables rapid and precise micro-scale deformation of smart hydrogels. This innovation, inspired by the hierarchical structure of butterfly wings, holds significant promise for applications in flexible electronics and minimally invasive medicine. The findings were published online in ACS Materials Letters on February 17. Led by Prof. Liu Lianqing from the Shenyang Institute of Automation of the Chinese Academy of Sciences and Prof. Li Wenjung from the City University of Hong Kong, the researchers drew inspiration from the wing structure of Papilio maackii, a butterfly species known for its remarkable balance of lightness and toughness.

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A research team led by Dr. Ho Sang Jung of the Department of Nano-Bio Convergence at the Korea Institute of Materials Science (KIMS), a research institute under the Ministry of Science and ICT, in collaboration with the KOTITI Testing & Research Institute, has developed the world's first technology to rapidly and highly sensitively detect microplastics (MPs), which can cause human and genetic toxicity through environmental pollution and the food chain. The research results were published on 10 September in Advanced Functional Materials.

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X-Ray Grating Market: Key Players and Regional Insights

MARKET INSIGHTS

The global X-Ray Grating Market size was valued at US$ 145.6 million in 2024 and is projected to reach US$ 267.8 million by 2032, at a CAGR of 9.14% during the forecast period 2025-2032. The U.S. market accounted for approximately 32% of global revenue in 2024, while China’s market is expected to grow at a faster pace with 8.3% CAGR through 2032.

X-Ray gratings are precision optical components used to diffract X-rays in analytical instruments. These nanostructured devices play critical roles in phase-contrast imaging, spectroscopy, and medical diagnostics by manipulating X-ray beams at microscopic levels. The market primarily consists of absorption gratings and phase gratings, with absorption variants currently dominating 68% of total revenue share.

Growing adoption in synchrotron facilities and advancements in X-ray microscopy are driving market expansion. However, high manufacturing costs remain a challenge, with premium gratings costing upwards of USD 15,000 per unit. Key manufacturers like SMT and Shimadzu are investing in nanoimprint lithography to improve production efficiency. In 2023, the Paul Scherrer Institute demonstrated a breakthrough in high-efficiency grating fabrication, potentially reducing costs by 40% in coming years.

MARKET DYNAMICS

MARKET DRIVERS

Expanding Medical Imaging Applications Accelerate X-Ray Grating Demand

The global healthcare sector’s accelerating adoption of advanced X-ray imaging technologies is significantly boosting the X-ray grating market. Phase-contrast imaging techniques using X-ray gratings now enable early detection of soft tissue abnormalities with up to 100 times greater sensitivity than conventional radiography. This breakthrough is particularly transformative for mammography and pulmonary diagnostics, where current systems achieve resolutions below 50 micrometers. The technology’s ability to differentiate between tumor types without contrast agents is revolutionizing diagnostic pathways while reducing patient exposure to ionizing radiation by approximately 30-40% compared to traditional CT scans.

Materials Science Breakthroughs Create New Industrial Applications

Beyond healthcare, X-ray gratings are becoming indispensable tools in materials characterization across aerospace, semiconductor, and renewable energy sectors. Recent developments in nano-fabrication techniques allow gratings with periodicities below 100nm, enabling non-destructive testing of advanced composites and battery materials. The automotive industry’s shift toward lightweight materials has driven grating adoption for weld integrity testing, with some manufacturers reporting 25-35% reductions in quality control cycle times. Semiconductor producers increasingly rely on phase-shift gratings for sub-10nm chip defect detection, creating sustained demand from this high-value sector.

Synchrotron Facility Expansion Creates Specialist Demand

The synchronized global expansion of fourth-generation synchrotron facilities presents specialized opportunities for high-performance grating manufacturers. Next-generation light sources like the European XFEL and upgraded APS-U require gratings with dimensional stability below 1nm over meter-scale lengths. This technical challenge has spurred development of silicon carbide and monocrystalline tungsten gratings capable of withstanding 100W/mm² heat loads without deformation. With over 50 major synchrotron facilities operational worldwide and at least 12 upgrade projects underway, specialist grating providers are experiencing compound annual growth exceeding 9% in this niche segment.

MARKET RESTRAINTS

Precision Fabrication Challenges Limit Mass Production Capacity

Despite growing demand, X-ray grating adoption faces significant manufacturing bottlenecks. Producing grating structures with sub-micron periodicity requires specialized cleanroom facilities and e-beam lithography equipment costing upwards of $5 million per system. Even with advanced tools, typical production yields for high-performance gratings rarely exceed 70%, creating supply constraints. The industry’s reliance on small-batch manual alignment processes further exacerbates capacity limitations, with lead times for custom gratings frequently extending beyond six months.

Material Limitations Constrain Performance Parameters

Current grating materials struggle to simultaneously optimize three critical parameters: high diffraction efficiency, thermal stability, and radiation hardness. Silicon gratings offer excellent dimensional precision but degrade rapidly above 500W/mm² fluxes. Gold-coated gratings provide superior heat resistance but exhibit efficiency losses at high X-ray energies. These material limitations force difficult trade-offs in application-specific designs, particularly for emerging techniques like time-resolved X-ray diffraction that require both high flux tolerance and temporal resolution below 10 picoseconds.

MARKET CHALLENGES

Metrology Gaps Impede Quality Assurance Processes

The industry faces persistent challenges in verifying grating specifications after production. Conventional optical microscopy cannot resolve sub-100nm features, while atomic force microscopy throughput remains insufficient for production-quality inspections. This metrology gap creates uncertainties in performance validation, particularly for phase-shift gratings where structural errors as small as 5nm can degrade imaging contrast by 30% or more. Without standardized characterization methods, manufacturers and end-users frequently disagree on acceptance criteria, increasing project risks and warranty exposures.

Intellectual Property Barriers Slow Technology Transfer

Proprietary fabrication methods and overlapping patent claims create minefields for new market entrants. Several critical grating designs remain protected by university-held patents with complex licensing structures, while key processing techniques are closely guarded as trade secrets. This IP landscape discourages collaborative development and makes technology transfer between academic research and commercial production particularly challenging. The resulting innovation bottlenecks are evident in the gradual pace of manufacturing automation adoption across the sector.

MARKET OPPORTUNITIES

Compact Laboratory Sources Expand Addressable Market

The commercialization of benchtop X-ray sources with grating-compatible brilliance creates substantial growth potential. Modern laser-driven plasma sources now achieve spectral brightness exceeding 10¹⁰ photons/s/mm²/mrad² within laboratory footprints, eliminating the need for synchrotron access in many applications. Early adopters report successful grating-based phase contrast imaging implementations with these systems at 10-15% of traditional facility costs. As source technology matures, the total available market for X-ray gratings could expand by 40-60% into academic labs and industrial QA departments previously priced out of the technology.

Multi-layer Gratings Enable New Measurement Modalities

Emerging multi-layer grating architectures promise to unlock novel characterization techniques. Stacked grating designs combining absorption and phase components can simultaneously extract attenuation-, phase-, and dark-field contrast from single exposures – a capability already demonstrated in prototype mammography systems. Similarly, tunable grating systems incorporating MEMS actuators enable adjustable energy filtering, potentially replacing multiple fixed gratings in clinical CT scanners. These innovations could drive grating content per system upwards while creating technical differentiation opportunities for advanced manufacturers.

Additive Manufacturing Opens New Design Possibilities

Advances in nanoscale 3D printing present intriguing possibilities for next-generation grating production. Two-photon polymerization systems now achieve <100nm feature resolution suitable for certain grating applications, while electron beam melting shows promise for direct metal grating fabrication. Although current additive methods cannot yet match lithography-based approaches for critical parameters, they enable previously impossible geometries like tapered grating profiles and integrated mounting structures. Several research groups have demonstrated prototypes with 10-15% efficiency gains from these unconventional designs, suggesting a disruptive potential that warrants industry attention.

X-RAY GRATING MARKET TRENDS

Technological Advancements in X-Ray Imaging Driving Market Expansion

The X-Ray grating market is experiencing significant growth due to rapid advancements in X-ray imaging technologies, particularly in medical diagnostics and material science applications. The shift toward high-resolution phase-contrast imaging systems has created substantial demand for precision X-ray gratings. Recent developments include novel fabrication techniques using deep reactive ion etching (DRIE) and nanoimprint lithography, enabling production of gratings with sub-micron feature sizes. These innovations are critical for next-generation X-ray interferometry applications, where the global market is projected to grow at a CAGR of 8-10% through 2032. Furthermore, the integration of artificial intelligence in X-ray image reconstruction algorithms is enhancing the performance demands placed on grating components.

Other Trends

Expansion of Synchrotron and Laboratory-Based Applications

While medical imaging remains the dominant application segment, synchrotron facilities and laboratory X-ray systems are emerging as key growth areas. There are currently over 50 synchrotron light sources operational worldwide, with several new facilities under construction across Asia and Europe. These large-scale research installations require advanced grating systems for high-precision X-ray analysis techniques such as X-ray fluorescence and small-angle X-ray scattering. The market for laboratory X-ray instruments incorporating grating optics is estimated to reach $200-250 million annually by 2027, driven by increasing adoption in pharmaceutical research and nanotechnology characterization.

Materials Innovation and Manufacturing Challenges

The industry faces both opportunities and constraints in materials development. Silicon remains the predominant material for X-ray gratings, accounting for approximately 65-70% of all gratings produced. However, emerging materials such as diamond and high-Z metals are gaining traction for specialized applications requiring extreme durability or high-energy X-ray performance. The transition to these advanced materials presents manufacturing challenges, with yields for high-quality diamond gratings currently below 40% in most production facilities. Nevertheless, ongoing process optimization efforts are expected to improve both quality and cost-effectiveness as the technology matures.

The competitive landscape continues to evolve, with established players investing in large-area grating fabrication capabilities to meet the needs of whole-body phase-contrast medical imaging systems. Meanwhile, startup companies are pioneering novel approaches to grating design, including adaptive and tunable grating solutions that could revolutionize X-ray analysis methodologies in the coming decade.

COMPETITIVE LANDSCAPE

Key Industry Players

Leading Manufacturers Focus on Precision and Innovation in X-Ray Grating Production

The global X-ray grating market exhibits a semi-fragmented competitive structure, blending multinational corporations with specialized regional suppliers. SMT (Supermirror Technologies) has emerged as a dominant force due to its high-precision grating solutions and robust manufacturing capabilities in North America and Europe. Their technology enables applications in advanced synchrotron facilities and medical imaging systems.

NTT Advanced Technology Corporation and XRNanotech have carved significant market shares through their patented nano-fabrication techniques. These companies accounted for approximately 22% of combined revenue share in 2024, serving major research institutions and industrial clients across Asia-Pacific markets.

The competitive intensity is further amplified by ongoing R&D investments in phase contrast imaging technologies. Unlike conventional absorption gratings, phase grating solutions are gaining traction in materials science applications because of their superior sensitivity to low-density specimens.

Meanwhile, European players like Microworks GmbH and Gitterwerk GmbH differentiate through customized grating solutions for synchrotron beamlines. Their strategic collaborations with academic institutions have strengthened their footprint in the scientific research segment, which represents over 35% of total application demand.

Recent competitive developments include SHIMADZU’s January 2024 launch of their ultra-high resolution X-ray Talbot-Lau interferometry gratings, specifically engineered for compact laboratory systems. This mirrors broader industry trends where manufacturers balance performance enhancements with form factor optimization for benchtop applications.

List of Key X-Ray Grating Companies Profiled

SMT (Supermirror Technologies) (Germany)

NTT Advanced Technology Corporation (Japan)

XRNanotech (U.S.)

SHIMADZU Corporation (Japan)

Paul Scherrer Institute PSI (Switzerland)

ASICON Tokyo Ltd. (Japan)

HORIBA France SAS (France)

Inprentus (U.S.)

Microworks GmbH (Germany)

Gitterwerk GmbH (Germany)

Wasatch Photonics (U.S.)

LightTrans International (Germany)

Segment Analysis:

By Type

Absorption Grating Segment Leads Due to High Demand in Medical and Industrial Imaging Applications

The market is segmented based on type into:

Absorption Grating

Phase Grating

By Application

Science Segment Dominates Owing to Increased Utilization in Research Laboratories and Academic Institutions

The market is segmented based on application into:

Chemical

Science

Others

By End-User

Healthcare Sector Holds Significant Share Driven by Advancements in Medical Imaging Technologies

The market is segmented based on end-user into:

Healthcare

Industrial

Research institutes

Others

Regional Analysis: X-Ray Grating Market

North America The North American X-ray grating market is driven by robust healthcare expenditure and strong research & development activities in medical imaging technologies. The U.S. leads the region with a market size estimated at $ million in 2024, supported by advanced diagnostic infrastructure in hospitals and research institutions. Major players like SMT and Wasatch Photonics maintain strong market positions, catering to both medical and industrial applications. Phase gratings are gaining traction due to their superior resolution capabilities in synchrotron facilities, though absorption gratings remain dominant in conventional X-ray equipment. Challenges include high production costs and stringent FDA approval processes for medical-grade components.

Europe Europe’s market thrives on cutting-edge scientific research and precision engineering capabilities. Germany and France collectively account for over 40% of regional demand, with institutes like Paul Scherrer Institute PSI driving innovation in phase contrast imaging. The market benefits from cross-border academic collaborations and EU-funded research projects in nanotechnology. However, the fragmentation of standards across countries creates compliance complexities for manufacturers. Recent developments include the adoption of high-efficiency gratings in airport security scanners and automotive NDT applications. Environmental regulations on material usage (particularly lead-based components) are reshaping product specifications across the region.

Asia-Pacific Asia-Pacific exhibits the highest growth potential, projected to reach $ million by 2032 primarily due to China’s expanding healthcare infrastructure. Local manufacturers like XRNanotech and Top-Unistar Science & Technology are capturing market share through cost-competitive solutions, though Japanese firms (SHIMADZU, ASICON Tokyo) dominate premium segments. Two distinct trends emerge: budget-conscious hospitals opt for conventional absorption gratings, while research centers invest in advanced phase gratings for materials science applications. India’s market grows at 8% CAGR, fueled by public-private partnerships in medical imaging and government initiatives like Make in India. However, inconsistent quality standards and intellectual property concerns remain key challenges.

South America The region shows moderate growth, with Brazil accounting for 60% of market activity. Limited local manufacturing capabilities create dependence on imports from North America and Europe, particularly for specialized applications in oil & gas pipeline inspection. Economic instability in Argentina and Venezuela hinders market expansion, though Colombia and Chile demonstrate steady demand from mining and petrochemical industries. Market opportunities exist in upgrading aging hospital imaging equipment, but currency fluctuations and complex import procedures delay procurement cycles. The lack of regional technical expertise in grating maintenance also impacts aftermarket services.

Middle East & Africa This emerging market centers around GCC countries, where healthcare modernization projects and oilfield inspection needs drive demand. The UAE and Saudi Arabia collectively invest over $500 million annually in medical imaging equipment, creating opportunities for grating suppliers. However, the absence of local production facilities results in complete import reliance at premium prices. Key restraints include limited awareness of advanced grating technologies and budget prioritization toward complete imaging systems rather than components. South Africa shows potential in mining applications, though political and economic uncertainties curb sustained market growth.

Report Scope

This market research report provides a comprehensive analysis of the global and regional X-Ray Grating markets, covering the forecast period 2025–2032. It offers detailed insights into market dynamics, technological advancements, competitive landscape, and key trends shaping the industry.

Key focus areas of the report include:

Market Size & Forecast: Historical data and future projections for revenue, unit shipments, and market value across major regions and segments. The Global X-Ray Grating market was valued at USD 220.8 million in 2024 and is projected to reach USD 340.6 million by 2032.

Segmentation Analysis: Detailed breakdown by product type (Absorption Grating, Phase Grating), application (Chemical, Science, Others), and end-user industry to identify high-growth segments and investment opportunities. The Absorption Grating segment is expected to reach USD 198.2 million by 2032.

Regional Outlook: Insights into market performance across North America, Europe, Asia-Pacific, Latin America, and the Middle East & Africa, including country-level analysis. The U.S. market size is estimated at USD 78.4 million in 2024, while China is projected to reach USD 92.1 million by 2032.

Competitive Landscape: Profiles of leading market participants including SMT, NTT Advanced Technology Corporation, XRNanotech, and SHIMADZU, covering their product offerings, R&D focus, manufacturing capacity, pricing strategies, and recent developments.

Technology Trends & Innovation: Assessment of emerging technologies in X-ray optics, nano-fabrication techniques, and evolving industry standards for grating-based X-ray imaging.

Market Drivers & Restraints: Evaluation of factors driving market growth along with challenges such as high manufacturing costs and technical complexities in grating fabrication.

Stakeholder Analysis: Insights for component suppliers, OEMs, system integrators, investors, and policymakers regarding the evolving X-ray grating ecosystem and strategic opportunities.

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