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Decoding the Future of AI: From Disruption to Democratisation and Beyond
The global AI landscape has become a melting pot for innovation, with diverse thinking pushing the boundaries of what is possible. Its application extends beyond just technology, reshaping traditional business models and redefining how enterprises, governments, and societies operate. Advancements in model architectures, training techniques and the proliferation of open-source tools are lowering barriers to entry, enabling organisations of all sizes to develop competitive AI solutions with significantly fewer resources. As a result, the long-standing notion that AI leadership is reserved for entities with vast computational and financial resources is being challenged. This shift is also redrawing the global AI power balance, with a decentralised approach to AI where competition and collaboration coexist across different regions. As AI development becomes more distributed, investment strategies, enterprise innovation and global technological leadership are being reshaped. However, established AI powerhouses still wield significant leverage, driving an intense competitive cycle of rapid innovation. Amid this acceleration, it is critical to distinguish true technological breakthroughs from over-hyped narratives, adopting a measured, data-driven approach that balances innovation with demonstrable business value and robust ethical AI guardrails. Implications of the Evolving AI Landscape The democratisation of AI advancements, intensifying competitive pressures, the critical need for efficiency and sustainability, evolving geopolitical dynamics and the global race for skilled talent are all fuelling the development of AI worldwide. These dynamics are paving the way for a global balance of technological leadership. Democratisation of AI Potential The ability to develop competitive AI models at lower costs is not only broadening participation but also reshaping how AI is created, deployed and controlled. Open-source AI fosters innovation by enabling startups, researchers, and enterprises to collaborate and iterate rapidly, leading to diverse applications across industries. For example, xAI has made a significant move in the tech world by open sourcing its Grok AI chatbot model, potentially accelerating the democratisation of AI and fostering innovation. However, greater accessibility can also introduce challenges, including risks of misuse, uneven governance, and concerns over intellectual property. Additionally, as companies strategically leverage open-source AI to influence market dynamics, questions arise about the evolving balance between open innovation and proprietary control. Increased Competitive Pressure The AI industry is fuelled by a relentless drive to stay ahead of the competition, a pressure felt equally by Big Tech and startups. This is accelerating the release of new AI services, as companies strive to meet growing consumer demand for intelligent solutions. The risk of market disruption is significant; those who lag, face being eclipsed by more agile players. To survive and thrive, differentiation is paramount. Companies are laser-focused on developing unique AI capabilities and applications, creating a marketplace where constant adaptation and strategic innovation are crucial for success. Resource Optimisation and Sustainability The trend toward accessible AI necessitates resource optimisation, which means developing models with significantly less computational power, energy consumption and training data. This is not just about cost; it is crucial for sustainability. Training large AI models is energy-intensive; for example, training GPT-3, a 175-billion-parameter model, is believed to have consumed 1,287 MWh of electricity, equivalent to an average American household’s use over 120 years1. This drives innovation in model compression, transfer learning, and specialised hardware, like NVIDIA’s TensorRT. Small language models (SLMs) are a key development, offering comparable performance to larger models with drastically reduced resource needs. This makes them ideal for edge devices and resource-constrained environments, furthering both accessibility and sustainability across the AI lifecycle. Multifaceted Global AI Landscape The global AI landscape is increasingly defined by regional strengths and priorities. The US, with its strength in cloud infrastructure and software ecosystem, leads in “short-chain innovation”, rapidly translating AI research into commercial products. Meanwhile, China excels in “long-chain innovation”, deeply integrating AI into its extended manufacturing and industrial processes. Europe prioritises ethical, open and collaborative AI, while the APAC counterparts showcase a diversity of approaches. Underlying these regional variations is a shared trajectory for the evolution of AI, increasingly guided by principles of responsible AI: encompassing ethics, sustainability and open innovation, although the specific implementations and stages of advancement differ across regions. The Critical Talent Factor The evolving AI landscape necessitates a skilled workforce. Demand for professionals with expertise in AI and machine learning, data analysis, and related fields is rapidly increasing. This creates a talent gap that businesses must address through upskilling and reskilling initiatives. For example, Microsoft has launched an AI Skills Initiative, including free coursework and a grant program, to help individuals and organisations globally develop generative AI skills. What does this mean for today’s enterprise? New Business Horizons AI is no longer just an efficiency tool; it is a catalyst for entirely new business models. Enterprises that rethink their value propositions through AI-driven specialisation will unlock niche opportunities and reshape industries. In financial services, for example, AI is fundamentally transforming operations, risk management, customer interactions, and product development, leading to new levels of efficiency, personalisation and innovation. Navigating AI Integration and Adoption Integrating AI is not just about deployment; it is about ensuring enterprises are structurally prepared. Legacy IT architectures, fragmented data ecosystems and rigid workflows can hinder the full potential of AI. Organisations must invest in cloud scalability, intelligent automation and agile operating models to make AI a seamless extension of their business. Equally critical is ensuring workforce readiness, which involves strategically embedding AI literacy across all organisational functions and proactively reskilling talent to collaborate effectively with intelligent systems. Embracing Responsible AI Ethical considerations, data security and privacy are no longer afterthoughts but are becoming key differentiators. Organisations that embed responsible AI principles at the core of their strategy, rather than treating them as compliance check boxes, will build stronger customer trust and long-term resilience. This requires proactive bias mitigation, explainable AI frameworks, robust data governance and continuous monitoring for potential risks. Call to Action: Embracing a Balanced Approach The AI revolution is underway. It demands a balanced and proactive response. Enterprises must invest in their talent and reskilling initiatives to bridge the AI skills gap, modernise their infrastructure to support AI integration and scalability and embed responsible AI principles at the core of their strategy, ensuring fairness, transparency and accountability. Simultaneously, researchers must continue to push the boundaries of AI’s potential while prioritising energy efficiency and minimising environmental impact; policymakers must create frameworks that foster responsible innovation and sustainable growth. This necessitates combining innovative research with practical enterprise applications and a steadfast commitment to ethical and sustainable AI principles. The rapid evolution of AI presents both an imperative and an opportunity. The next chapter of AI will be defined by those who harness its potential responsibly while balancing technological progress with real-world impact. Resources Sudhir Pai: Executive Vice President and Chief Technology & Innovation Officer, Global Financial Services, Capgemini Professor Aleks Subic: Vice-Chancellor and Chief Executive, Aston University, Birmingham, UK Alexeis Garcia Perez: Professor of Digital Business & Society, Aston University, Birmingham, UK Gareth Wilson: Executive Vice President | Global Banking Industry Lead, Capgemini 1 https://www.datacenterdynamics.com/en/news/researchers-claim-they-can-cut-ai-training-energy-demands-by-75/?itm_source=Bibblio&itm_campaign=Bibblio-related&itm_medium=Bibblio-article-related
Aston University is leading a new £5.5 million EU research project Will focus on converting fibre-optic cables into sensors to detect natural hazards Could identify earthquakes and tsunamis and assess civil infrastructure. Aston University is leading a new £5.5 million EU research project to explore converting existing telecommunication fibre-optic cables into sensors which can detect natural hazards, such as earthquakes and tsunamis, and assess the condition of civil infrastructure. The project is called ECSTATIC (Engineering Combined Sensing and Telecommunications Architectures for Tectonic and Infrastructure Characterisation) and is part of the Horizon Europe Research and Innovation Action (RIA), which aims to tackle global challenges and boost the continent’s industrial competitiveness. Converting telecom fibres into sensors requires new digital signal processing to overcome the limited data storage and processing capabilities of existing communication networks. To address this the project will use localised, high performance digital processing that will integrate artificial intelligence and machine learning. The researchers’ goal is to minimise algorithms’ complexity while providing extremely accurate real-time sensing of events and network condition. The new laser interrogation and signal processing technologies will be tested using existing fibre optic networks, including those underwater, in cities, and along railway infrastructure to assess their potential. Delivered by a consortium of 14 partners across seven countries, from academic and non-academic sectors, the research will start in February 2025 and will last three and a half years. The Europe-wide team will be led by Professor David Webb who is based in the Aston Institute of Photonic Technologies (AIPT). Professor Webb said: “There are more than five billion kilometres of installed data communications optical fibre cable, which provides an opportunity to create a globe-spanning network of fibre sensors, without laying any new fibres. “These traverse the seas and oceans - where conventional sensors are practically non-existent - and major infrastructures, offering the potential for smart structural health monitoring.” Professor Webb will be joined by fellow researchers Professor Sergei Turitsyn, Dr Haris Alexakis and Dr Pedro Freire. For media inquiries in relation to this release, contact Nicola Jones, Press and Communications Manager, on (+44) 7825 342091 or email: n.jones6@aston.ac.uk
Aston University scientist to help make crop monitoring easier and cheaper
Photonics expert Dr Sergey Sergeyev to help make crop monitoring easier and cheaper with remote sensing The technology can be placed on drones and flown over crop fields to provide real-time information about crop health Remote sensing is an essential tool to provide real-time information about crops to estimate yields. An Aston University photonics expert has received a Royal Society Industry Fellowship grant to help make crop monitoring easier and cheaper with remote sensing technology. Dr Sergey Sergeyev of Aston Institute of Photonic Technologies (AIPT) has received £174,000 to improve polarimetric LIDAR, a technology that uses light to remotely observe plants. LiDAR, an acronym for Light Detection and Ranging, involves light sent from a transmitter which is reflected from objects. Devices with this technology can be placed on drones and flown over crop fields to provide real-time information about crop health to help farmers forecast the success of their crops. Polarimetric synthetic-aperture radars (SARs) and polarimetric LiDARs are the most advanced, cost-effective sensors for crop monitoring. They are often used onboard aircraft and satellites and have been in use for three decades. However, current polarimetric LIDAR systems have low spatial resolution, a slow measurement speed and use expensive components that limit their cost effectiveness. Dr Sergeyev will be working in collaboration with Salford-based digital and AI farming company Fotenix to meet farmers' need for a cost-effective solution to check if their plants are adequately watered and disease-free. The team will aim to advance recently patented AIPT technology of the polarimetric LIDAR, making it affordable for farmers in the UK and worldwide. The project, called POLIDAR, will run from 2024 to 2025. Dr Sergeyev said: “Aston University’s patented technique will be modified by using a laser emitting four time-delayed pulse trains with different states of polarisation. By comparing the input states of polarisation and states of polarisation of light reflected from plants, it will reveal information about the distance to plants and plants' leaf texture, such as water stress and pathogen infection. Unlike state-of-the-art solutions we suggest an all-fibre design with a minimum number of bulk components that reduces the footprint, cost and weight. Dr Sergeyev added: “My project's motivation is driven by the global and UK agenda on increased food production, requiring novel remote sensing approaches towards ICT farming. “As declared at the World Summit on Food Security in 2017, the growth in the world's population requires increased and more efficient agricultural production. “Remote sensing is an essential tool to systematically address the challenging task of enhanced agricultural efficiency by providing real-time information about crop traits for yield estimation.” The announcement coincides with UNESCO Day of Light which marks the role light plays in science, culture and art, education and sustainable development. It is held on 16 May every year, the anniversary of the first successful operation of a laser. ENDS World Summit on Food Security in 2017 The future of food and agriculture: Trends and challenges (fao.org) https://www.fao.org/3/i6583e/i6583e.pdf UNESCO Day of Light The International Day of Light is a global initiative that provides an annual focal point for the continued appreciation of light and the role it plays in science, culture and art, education, and sustainable development, and in fields as diverse as medicine, communications, and energy. The broad theme of light will allow many different sectors of society worldwide to participate in activities that demonstrates how science, technology, art and culture can help achieve the goals of UNESCO – education, equality, and peace. The International Day of Light is held on May 16th every year, the anniversary of the first successful operation of the laser in 1960 by physicist and engineer, Theodore Maiman. The laser is a perfect example of how a scientific discovery can yield revolutionary benefits to society in communications, healthcare and many other fields. About Aston University For over a century, Aston University’s enduring purpose has been to make our world a better place through education, research and innovation, by enabling our students to succeed in work and life, and by supporting our communities to thrive economically, socially and culturally. Aston University’s history has been intertwined with the history of Birmingham, a remarkable city that once was the heartland of the Industrial Revolution and the manufacturing powerhouse of the world. Born out of the First Industrial Revolution, Aston University has a proud and distinct heritage dating back to our formation as the School of Metallurgy in 1875, the first UK College of Technology in 1951, gaining university status by Royal Charter in 1966, and becoming The Guardian University of the Year in 2020. Building on our outstanding past, we are now defining our place and role in the Fourth Industrial Revolution (and beyond) within a rapidly changing world. For media inquiries in relation to this release, contact Nicola Jones, Press and Communications Manager, on (+44) 7825 342091 or email: n.jones6@aston.ac.uk
Aston University establishes Design Factory Birmingham as a global innovation hub for Midlands
• Birmingham becomes the latest city to join a global network of design and digital consultancies • Based at Aston University, expertise in areas such as 3D printing will be shared to boost the local economy • It will include a space named after the late Dame Margaret Weston, former director of the Science Museum. Birmingham has become the latest city to join a global network of design and digital consultancies set up to solve real world challenges through effective problem-solving. Design Factory Birmingham will be based at Aston University, one of just two hubs in the UK outside of London. The city officially joined the Design Factory Global Network on Wednesday 14 February and as a result Aston University will open the doors to its state-of-the-art facilities to other organisations. Shared understanding and common ways of working enable Design Factories in the network to collaborate efficiently across cultures, time zones and organisational boundaries fostering radical innovations. Businesses, industry partners, entrepreneurs, staff and students will be able to collaborate on projects that will involve technologies such as 3D printers and design software. The University will be sharing its expertise in artificial intelligence, additive manufacturing, data science and web, app and graphic design to boost the local economy. Currently there are 39 innovation hubs in 25 countries across five continents based in universities and research organisations. The Design Factory will include a space named after the late Dame Margaret Weston, former director of the Science Museum. Dame Margaret had studied electrical engineering at one of Aston University’s predecessor institutions and went on to be the first woman appointed to lead a national museum. She left a generous gift to Aston University in her will, which will be commemorated in the Birmingham Design Factory in honour of her engineering background. (l-r) Felipe Gárate, Professor Aleks Subic, Professor Stephen Garrett The Vice-Chancellor and Chief Executive of Aston University, Professor Aleks Subic said: “The Design Factory Birmingham is another key milestone in our ambition to be a leader in science, technology, and innovation, driving socio-economic transformation in our city and region. It is important to the Midlands because it will make a direct contribution to innovation led growth in partnership with industry and businesses. However, this is not only a local launch but also a global launch as Design Factory Birmingham is a global innovation hub, and an integral part of the Design Factory Global Network involving 39 innovation hubs around the world.” The head of the Design Factory Global Network Felipe Gárate from Aalto University in Helsinki, Finland attended the official launch in Birmingham. He said: “I am delighted to welcome Aston University as our latest member. “We are on a mission to create change in the world of learning and research through passion-based culture and effective problem-solving. “Shared understanding and common ways of working enable Design Factories in the network to collaborate efficiently across cultures, time zones and organisational boundaries fostering radical innovations.” The launch event was used to showcase design projects that are already running and companies attending were given the chance to meet placement students who could boost their existing expertise. Associate Pro-Vice-Chancellor and Deputy Head of the College of Engineering and Physical Sciences, Professor Tony Clarke said “This unique space on campus will bring together multi-disciplinary teams of hands-on innovators, collaborative thinkers and creators. “We will be delivering a wide range of services including software application development, product design, creating protypes using a variety of technologies including laser and water cutting, digital and design training courses, and helping companies obtain innovation grants for projects.” As a member of the global network the Birmingham Design Factory at Aston University will participate in two global design challenges - one run by McDonalds and the other run by the Ford Motor Company. ENDS Notes to Editors There are 39 Design Factory hubs around the world https://dfgn.org/ In the UK there are three; London, Birmingham and Manchester. About Aston University For over a century, Aston University’s enduring purpose has been to make our world a better place through education, research and innovation, by enabling our students to succeed in work and life, and by supporting our communities to thrive economically, socially and culturally. Aston University’s history has been intertwined with the history of Birmingham, a remarkable city that once was the heartland of the Industrial Revolution and the manufacturing powerhouse of the world. Born out of the First Industrial Revolution, Aston University has a proud and distinct heritage dating back to our formation as the School of Metallurgy in 1875, the first UK College of Technology in 1951, gaining university status by Royal Charter in 1966, and becoming The Guardian University of the Year in 2020. Building on our outstanding past, we are now defining our place and role in the Fourth Industrial Revolution (and beyond) within a rapidly changing world. For media inquiries in relation to this release, contact Nicola Jones, Press and Communications Manager, on (+44) 7825 342091 or email: n.jones6@aston.ac.uk
Reinventing the laser diode: free public lecture by Professor Richard Hogg
Professor Richard Hogg joined Aston University in spring 2023 His inaugural lecture is about laser diodes, the tiny components that are a vital part of everyday life The free event will take place on Tuesday 28 November. The latest inaugural lecture at Aston University will explore the laser diode and what’s in store for it in the future. Professor Richard Hogg will explain how his future research might make laser diodes do some of the things that they currently can’t do. The laser diode turned 61 years old this month and the tiny components are a critical part of everyday life. Professor Hogg said: “They are now at the heart of the continuous transformation of society. “They transmit data to allow instantaneous, ubiquitous communication and data access. “They allow light to be used for cutting and welding, for sensing and imaging, for displays and illumination, and data storage. “And in the guise of a laser pointer they can even be used to entertain your cat!” He will discuss different classes of laser diode and their operation and applications. Professor Hogg joined Aston University in spring 2023 and is based at Aston Institute of Photonic Technologies (AIPT). It is one of the world’s leading photonics research centres and its scientific achievements range from medical lasers and bio-sensing for healthcare, to the high-speed optical communications technology that underpins the internet and the digital economy. The professor is also chief technology officer at III-V Epi, which provides compound semiconductor wafer foundry services. The free event will take place on the University campus at Conference Aston, on Tuesday 28 November from 6pm to 8pm and will be followed by a drinks reception. It can also be viewed online. To sign up for a place in person visit https://www.eventbrite.co.uk/e/717822585677?aff=oddtdtcreator To sign up for a place online visit https://www.eventbrite.co.uk/e/717824260687?aff=oddtdtcreator
Fashioning Fusion: Villanova Professor Explains Clean Energy Breakthrough
On December 13, scientists at Lawrence Livermore National Laboratory announced a breakthrough that could change the future of clean energy. The long-awaited achievement of nuclear fusion was accomplished by researchers and, if harnessed on a larger scale, fusion energy could provide an energy option without the pollution of fossil fuels and without the radioactive waste of nuclear energy. A new world running on clean energy may not be imminent, but the state of ignition achieved is an important first step. Villanova University professor of mechanical engineering David Cereceda, PhD, received a U.S. Department of Energy Early Career Award from the Office of Fusion Energy Sciences for his research on fusion energy materials—and has worked at the Lawrence Livermore National Laboratory, located in California. "Ignition means that a nuclear fusion reaction becomes self-sustainable," Dr. Cereceda said. "The experiments performed at NIF [National Ignition Facility] last week reached for the first time in history a condition called scientific breakeven, meaning the scientists produced more energy from fusion than the laser energy used to drive it." The breakthrough discovery was made when 192 lasers focused on a cylinder the size of a pencil eraser. That container was filled with a small amount of hydrogen that was encased in a diamond. The resulting reaction that occurred was brief but significant, as this important step has proved allusive to researchers for decades. "Those who criticized fusion said that fusion was always five decades away. That's not true anymore," Dr. Cereceda remarked. "I'm not surprised about the announcement. It finally arrived after decades of hundreds of brilliant scientists and engineers carefully working on it." Still, the national laboratory says much work still lies ahead. Scientists will continue to push toward a higher fusion output and are looking at more efficient ways to produce ignition. Researchers also believe they may still be decades away from making fusion energy a mainstay and usable for the general public. "In my opinion, some of the most important challenges that remain on the path to commercial fusion energy are related to structural materials, tritium breeding blankets and laser technology, among others," mentioned Dr. Cereceda. "Multiple challenges remain to making it a commercial energy source, but this recent and historic breakthrough was a critical milestone."
Planet 9 Doesn’t Exist, So Why Does It Matter How We Get There? Let Our Expert Explain.
Planet 9 is an oft-discussed hypothetical planet in the outer region of the solar system. A new study involving Florida Tech astrobiologist Manasvi Lingam helps illustrate how we could possibly get there. The study, “Can We Fly to Planet 9?” is from Lingam and researchers Adam Hibberd and Andreas Hein. The team discovered that using current, unmanned transportation methods, it would take 45 to 75 years to get to Planet 9, which is about 42 billion miles away from Earth. By comparison, Pluto, which is the ninth object from the Sun, is roughly three billion miles from Earth. The research and work of Lingam, Hibberd and Hein is also getting a lot of attention from websites like UniverseToday.com. The team also studied near-future transportation methods nuclear thermal propulsion and laser sails. Using nuclear thermal propulsion, it would take approximately 40 years to reach Planet 9. It would take merely six to seven years to reach Planet 9 using laser sail propulsion, which involves using light from lasers to propel the vehicle. In its research, the team used the principles of orbital mechanics, sometimes called spaceflight mechanics. They inputted the complex and nonlinear mathematical equations into a computer, and then solved those equations with some optimization constraints. “What I mean by the latter is that ideally you want to maximize or minimize some quantity as much as possible,” Lingam said. “You might say, ‘Well, I want to minimize the flight time of the spacecraft as much as possible.’ So, what we did is that we put in an optimization constraint. In this case, it happens to be minimizing the time of journey. You solve the mathematical equations for a spacecraft with this condition, and then you end up with the results.” Lingam is inspired by the trendsetting Voyager spacecraft missions of the late 1970s, and one of his goals is to gain additional information about other worlds in our solar system, in addition to Planet 9 Voyager still provides valuable information regarding the outer solar system, though by 2025 it is expected that there may no longer be sufficient power to operate its science instruments. “Any mission to Planet Nine would likewise not just provide valuable information about that hypothetical planet, but it would also yield vital information about Jupiter, because what we do in some of the trajectories is a slingshot or powered flyby around Jupiter,” Lingam said. “It could also provide valuable information about the Sun because we also do a maneuver around the Sun, so you would still be getting lots of interesting data along the journey. And the length of the journey is comparable to that of the functioning time of the Voyager spacecraft today.” If you're a reporter looking to know more - then let us help get you connected to an expert. Manasvi Lingam is an Assistant Professor in the Department of Aerospace, Physics and Space Sciences at the Florida Institute of Technology. He is an author and go-to expert for media when it comes to anything in outer space or out of this world - just recently he was featured in Astronomy.com where he was asked to answer the illusive question - Are we alone? Manasvi is available to speak with media - simply click on his icon now to arrange an interview today.
November has been a busy month for Cedarville University’s Mark Caleb Smith. As the Director of the Center for Political Studies at Cedarville, Smith has found himself doing double duty as both professor and the go-to person and pundit for local, state and national political coverage In November Smith was interviewed by TV, radio and print for issues pertaining to impeachment, Michael Bloomberg entering the presidential race and the DNC debates. Mark Caleb Smith averages approximately 160 media interviews a year – and for good reason. He teaches courses in American Politics, Constitutional Law, and Research Methodology/Data Analysis and has fast become a media-ready expert who provides accurate, objective and laser-cut insight to reporters and journalists covering politics. If you’re a journalist covering politics – let Mark Caleb Smith help with your stories. He’s available, simply click on his icon to arrange an interview today.
Gene therapy and the next frontier of medicine
Genetic testing today is mainstream, marketing to consumers who want to know where in Europe they came from or what types of hereditary diseases they could develop. For around $200 you can trace your family tree to learn your origins or identify genetic abnormalities that could signal disease. James Dahlman, assistant professor in the College of Engineering’s biomedical engineering department, specializes in genetics and believes these genotyping services can be helpful, as long as they are used responsibly. “If you’re going to start making medical predictions, you have to be careful,” said Dahlman. “Most people are not equipped to interpret statistics correctly, which can lead to negative predicting and ethical dilemmas. In a few years, genetic counselors will be in high demand so folks can make better decisions about their health.” Dahlman is fascinated by genetics, citing gene therapy as the most interesting field in the world. And it’s a field that he is revolutionizing through his research. Gene therapy is an experimental technique that uses genes to treat or prevent diseases, including hemophilia, Parkinson’s, cancer and HIV. It can help manage a number of diseases by leveraging genes instead of drugs or surgery. Although gene therapy shows promise, there are still risks involved, including unwanted immune system reactions or the risk of the wrong cells being targeted. That’s where Dahlman’s research comes in. Dahlman’s lab focuses on drug delivery vehicles, which are nanoparticles. The nanoparticle delivers gene therapies to the right place in the body to fight disease. It’s critical that the gene therapies only target the unhealthy cells to avoid damaging healthy ones. Dahlman is laser focused on ensuring the nanoparticles know what paths to take to reach the correct organ to start the healing process. “The issue with genetically-engineered drugs is that they don’t work unless they get to the right cell in the body,” said Dahlman. “You can have the world’s best genetic drug that's going to fix a tumor or eradicate plaque, but it’s not going to be effective unless it travels to the right organ. In my lab, we design different nanoparticles to deliver the genetically-engineered drugs to the correct location.” The field of genetic therapy is fascinating – and if you are a journalist looking to cover this topic or have questions for upcoming stories – let our experts help. James Dahlman is an Assistant Professor in the Georgia Tech BME Department. He is an expert in the area of biomedical engineering and uses molecular biology to rationally design the genetic drugs he delivers. This research is redefining the field of genetic therapy. Dr. Dahlman is available to speak with media – simply click on his icon to arrange an interview.
Vielight Featured on CBC's "The Nature of Things" with Dr. David Suzuki
“The Brain’s Way of Healing”, an episode on The Nature of Things – aired on the CBC news network with David Suzuki and Dr. Norman Doidge. The episode featured the Vielight intranasal photobiomodulation technology. This episode featured Dr. Margaret Naeser a Research Professor of Neurology at Boston University who is researching the uses of an LED light helmet to treat PTSD victims. There are 1.7 million cases of traumatic brain injury right now in the United States and we don't have a really good treatments for them. We give them cognitive rehabilitation therapy which is very important but we're doing the photon work and light therapy to give the cells more energy to work with." To view the CBC Television episode please click below Dr. Margaret Naeser, Research Professor of Neurology at Boston University Select Publications PUBLISHED ON 2/10/2017 Saltmarche AE, Naeser MA, Ho KF, Hamblin MR, Lim L. Significant Improvement in Cognition in Mild to Moderately Severe Dementia Cases Treated with Transcranial Plus Intranasal Photobiomodulation: Case Series Report. Photomed Laser Surg. 2017 Aug; 35(8):432-441. PMID: 28186867. PUBLISHED ON 12/1/2016 Naeser MA, Martin PI, Ho MD, Krengel MH, Bogdanova Y, Knight JA, Yee MK, Zafonte R, Frazier J, Hamblin MR, Koo BB. Transcranial, Red/Near-Infrared Light-Emitting Diode Therapy to Improve Cognition in Chronic Traumatic Brain Injury. Photomed Laser Surg. 2016 Dec; 34(12):610-626. PMID: 28001756. PUBLISHED ON 8/17/2015 Naeser MA, Hamblin MR. Traumatic Brain Injury: A Major Medical Problem That Could Be Treated Using Transcranial, Red/Near-Infrared LED Photobiomodulation. Photomed Laser Surg. 2015 Sep; 33(9):443-6. PMID: 26280257. PUBLISHED ON 5/8/2014 Naeser MA, Zafonte R, Krengel MH, Martin PI, Frazier J, Hamblin MR, Knight JA, Meehan WP, Baker EH. Significant improvements in cognitive performance post-transcranial, red/near-infrared light-emitting diode treatments in chronic, mild traumatic brain injury: open-protocol study. J Neurotrauma. 2014 Jun 1; 31(11):1008-17. PMID: 24568233.
