Top 5 Reasons you Should Look to North East England for Nanotechnology Investment

Companies are often looking for opportunities to develop their business further. In the nanotechnology area it is important that you have the right staff and the right backing in the region you are moving into. North East England has the largest and best equipped public sector facilities in the UK.

The resources that are all ready located in the North East of England are already huge. INEX is the largest and best equipped public sector micro and nano device fabrication facility in the UK. It was founded in 2002 as the business arm of the Institute of Nanoscale Science and Technology at Newcastle University, but has been an independent organisation since 2004.

The facility has generated millions of pounds worth of new technology since its formation, so far spinning out 11 companies in the process.

The Centre of Excellence for Nanotechnology, Micro and Photonic Systems (Cenamps) is funding research and development programmes that will lead to further commercial opportunities and spin-outs in North East England.

Here are the top 5 reasons you should consider investing in North East England for nanotechnology expertise.

1. The University of Newcastle upon Tyne is the leading UK Higher Education Institute in government contract and the commercialisation of research undertaking work in laboratories including Inex: the largest public sector micro and nano device fabrication facility in the UK providing ample nanotechnology investment opportunities.

2. A cooperation agreement has been established between Institute for Nanoscale Science & Technology, University of Newcastle upon Tyne and NTT Basic Research Laboratories, Nippon Telegraphy & Telephone Corporation conducting research in information technology, microelectronics, submicron technology and bionanotechnology.

3. Key new centres in the region include a Plastic Electronics Technology Centre (PETeC) that will draw expertise from Newcastle, Durham and Cambridge Universities, an open access Flexible Electronics Facility that will establish the region as a focal point for flexible electronics materials in the UK and a National Microfluidics Application Centre.

4. The UK Department of Trade’s University Innovation Centre (UIC) for nanotechnology is in North East England. Newcastle has a 5* Research Assessment Exercise (RAE) rating in biological and biomedical applications whilst the University of Durham was one of only three UK Chemistry departments to be awarded a 5* RAE and specialises in film and surface technologies.

5. Northumbria University’s strengths include advanced materials and surface technologies and the University of Sunderland works on biosensors. The University of Teesside Centre for Nanotechnology and Microfabrication carries out research into manufacturing techniques.

Expertise and support organisations place North East England in a unique position to support companies in the commercialisation of research and getting new products to market through nanotechnology research and development.

Top 5 Reasons you Should Look to North East England for Nanotechnology Investment

Companies are often looking for opportunities to develop their business further. In the nanotechnology area it is important that you have the right staff and the right backing in the region you are moving into. North East England has the largest and best equipped public sector facilities in the UK.

The resources that are all ready located in the North East of England are already huge. INEX is the largest and best equipped public sector micro and nano device fabrication facility in the UK. It was founded in 2002 as the business arm of the Institute of Nanoscale Science and Technology at Newcastle University, but has been an independent organisation since 2004.

The facility has generated millions of pounds worth of new technology since its formation, so far spinning out 11 companies in the process.

The Centre of Excellence for Nanotechnology, Micro and Photonic Systems (Cenamps) is funding research and development programmes that will lead to further commercial opportunities and spin-outs in North East England.

Here are the top 5 reasons you should consider investing in North East England for nanotechnology expertise.

1. The University of Newcastle upon Tyne is the leading UK Higher Education Institute in government contract and the commercialisation of research undertaking work in laboratories including Inex: the largest public sector micro and nano device fabrication facility in the UK providing ample nanotechnology investment opportunities.

2. A cooperation agreement has been established between Institute for Nanoscale Science & Technology, University of Newcastle upon Tyne and NTT Basic Research Laboratories, Nippon Telegraphy & Telephone Corporation conducting research in information technology, microelectronics, submicron technology and bionanotechnology.

3. Key new centres in the region include a Plastic Electronics Technology Centre (PETeC) that will draw expertise from Newcastle, Durham and Cambridge Universities, an open access Flexible Electronics Facility that will establish the region as a focal point for flexible electronics materials in the UK and a National Microfluidics Application Centre.

4. The UK Department of Trade’s University Innovation Centre (UIC) for nanotechnology is in North East England. Newcastle has a 5* Research Assessment Exercise (RAE) rating in biological and biomedical applications whilst the University of Durham was one of only three UK Chemistry departments to be awarded a 5* RAE and specialises in film and surface technologies.

5. Northumbria University’s strengths include advanced materials and surface technologies and the University of Sunderland works on biosensors. The University of Teesside Centre for Nanotechnology and Microfabrication carries out research into manufacturing techniques.

Expertise and support organisations place North East England in a unique position to support companies in the commercialisation of research and getting new products to market through nanotechnology research and development.

Nanotechnology – Just What the Doctor Orders!

What if you were terminally ill and your doctor informed you that the venom from a snail could save your life?

What if the technology was available to produce a non-addictive painkiller that was thousands of times more potent than any morphine based product available today?

What if nanotechnology could provide the method of administering these potentially life-saving, pain elimination medicines within the near future? Would you be willing to support its advancement?

Well, nanotechnology is rapidly taking the “what if” out of just such medical conundrums. Biochemists, working in close liaison with nano-scientists, have discovered that the highly lethal venom contained in cone snails, which are found in coastal waters near coral reefs, can be extracted and, when administered via nanotechnologic methods, can potentially be used as a safe and effective alternative to highly addictive morphine-based medications.

Nanotechnology initiative programs are leading the highly competitive worldwide race in mining and providing a conduit for administering spiral snail toxins (known as conotoxins) and are developing methods of administering this peptide in a safe and positive manner.

Changes to the ion channels in human cells are directly responsible for a myriad of health disorders. Ion channels, which traditionally allow only calcium and potassium through their highly specific filtering system, can now be treated with toxins that have the ability to deactivate these channels. However, in the past, administration of these life altering conotoxins has offered a bit of a challenge to biology experts. That is, until now. This is where nanotechnology, with its innate ability to connect quantum dots, has provided a viable method of probing and infiltrating the cells in order to safely administer life altering drugs.

Due to its ability to specifically target finite and defined cells, nano-quantum dot technology provides the wherewithal to deliver conotoxins to targeted areas. Quantum dot, a nano-scale crystalline structure, is being investigated as a method of introducing medicine to specific areas of the body where the crystals act as probes that are able to track and report on antibodies, any viral activity, proteins in the area and even DNA composition.

By a system of imaging, this biochemistry and nanotechnology combination allows scientists and medical personnel alike to monitor the progression of the administered conotoxins within the body and allow the manipulation of toxin released at the designated sites.

Conotoxins have been proven as effective early detection and treatment methods for small cell lung cancer and for promoting anti-seizure treatment in epileptics. In addition, some success has been shown in treating patients who have suffered spinal cord injury, re-activating cells damaged due to oxygen deprivation and in treating clinical depression, irregular heart rhythms and some instances of urinary incontinence. Nanotechnology plays a vital role in the success of administering this innovative treatment by providing a safe and non-invasive method of administering treatment while reducing the risk of rejection by the body.

The possibility of advanced medical treatments when biochemistry, medicine and nanotechnology work in conjunction with one another is limitless.

Nanotechnology research has showed some promise in treatment of aging-related tissue degeneration in humans. With its in- vivo therapy, nanotechnology is credited with repairing degraded components of human DNA which significantly counterbalances and, in some cases, actually corrects the effects of common crippling age-related afflictions such as arthritis, osteoporosis and other debilitating diseases.

Nanotechnology as Career

Nanotechnology – the science of the miniature, and the technology of the future – is one of the most exciting and wide area of research which may lead to the greatest technological advances of the 21st century. It is a global phenomenon and an emerging field, that finds its way into a myriad of industrial applications spanning across all areas of science and technology. A form of molecular engineering, it is the technology associated with the creation and scrutiny of minute objects, measuring between 1 to 100 nanometers. Nanotechnology can be defined as the application of science, engineering and technology to develop novel materials and devices in different fields in the nano-range.

‘Nano’ in Greek means dwarf. Nanometer (nm) is a unit of measurement used to measure very small particles like atoms and molecules. One nanometer is equal to one-billionth (10-9) of a meter. Entirely different from bulk material, nano-materials are 5,000 to 50,000 times smaller than the diameter of a human hair. These light but strong, transparent materials are very active and aggressive in any chemical reaction. Nano-materials can be mixed with strong or weak materials to make them thousand times stronger and more efficient. Carbon and diamond are super examples of nano-materials. The concept of Nanotechnology originated in 1959 and was founded by the American physicist Richard P Feynmam. But the term ‘Nanotechnology’ was first used in 1974 by Japanese scientist Prof. Norio Taniguchi at the Tokyo Science University. However it was introduced to the world in 1986 by K. Eric Drexler, an American Engineer and the founder of Foresight Nanotech Institute.

Nanotechnology is a unique and special branch of science that essentially combines physics, chemistry, biology, engineering etc. Sometimes known as molecular manufacturing, it deals with the design and manufacture of extremely small electronic circuits and mechanical devices built at the molecular level of matter. The application of Nanotechnology will open new avenues of research in the world of science and engineering in almost every field, from medicine to fabrics. Due to this, the relatively new field is fast emerging as the favorite of all kinds of technological arena and will be one of the most significant enabling technologies in the future.

Even though the field is popular abroad, it is quite recently that Indian industries have started realizing the commercial viability of Nanotechnology. In India, Nanotechnology is at its infancy stage and is targeted towards the main streams like electronics, healthcare markets, and other industrial products. Many scientific institutions have been doing Research and Development (R&D) in this field. The scope and application of Nanotechnology is tremendous and mind-boggling and it is one of the hottest career option available to Indian Engineering graduates. It is an apt career for those who have a scientific bent of mind and a passion for solving mysteries of the minutest molecules. Students with a science and engineering background and even mathematics with physics background can pursue Nanotechnology as a career. Candidates with M.Tech in Nanotechnology are in great demand both in India and abroad.

It is a powerful technology which aids the development of products with futuristic performance. All major sectors of life will be effected by this new area. The two major categories of Nanotechnolgy are Nanoscale technology and Molecular manufacturing. Nanoscale technology covers small structures and can be used for introducing stronger materials, better medicines, faster computers and so on. Molecular manufacturing is an attempt at building mechanical and chemical manufacturing systems that join molecules together.

Nanofactory Animation

Welcome to nanofacs.com – Nanofacs is the short term for nanofactories. A nanofactory is a proposed system in which nanomachines (resembling molecular assemblers, or industrial robot arms) would combine molecules to build larger atomically precise parts. These, in turn, would be assembled by positioning mechanisms of assorted sizes to build macroscopic (visible) but still atomically-precise products. A functioning nanofactory could create virtually any product at the cost of only the input raw material and energy.

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