Nanotechnology, Genetic Engineering & Robotics – Doomsday or Miracle?

Advances in nanotechnology have proven that incredible progress is not only possible today and in the future, it is pretty well inevitable. Fantastic advances in nanotechnologic medical research have resulted in life saving techniques that were unheard of even a decade ago.

Genetic engineering research and development provides a means of revolutionizing agricultural output by enhancing crop yields while encouraging a decrease in the necessity for pesticides. It also holds out a promise of attaining newer, improved species of plants and animals, the ability to someday replace or supplement reproduction with cloning and the hope that cures will be developed for many fatal and debilitating diseases, which can only result in increased life spans and improved quality of life.

Robotic engineers firmly believe that development of a truly intelligent machine that is capable of performing most tasks better than humans will be perfected within our lifetime. They envision a time when a highly organized system of machines will perform all tasks with little or no human input.

It is not hard to imagine the revolutionary advancements that are possible if nanotechnology, genetic engineering and robotics combine their expertise in future technological advancements. Either the result will be a utopian world free of disease or pestilence or a jumbled chaos of grey goo and confusion.

Regardless of the outcome, it is inevitable that the future holds profound changes because of nanotechnology, genetic engineering and robotics, whether the accomplishments are made on their own or as a result of a coordinated effort. Along with the imminent progression, however, we must also be aware of the philosophical, moral and ethical issues that will come about as a result of biological change.

In addition to the potential threat from the unleashed power of nanotechnology based scientific advancements, there is also the promise of an improved future for mankind and the world in which he dwells. The line of demarcation is thin and easily crossed and therefore great care and planning must go hand in hand with technological advances.

Naysayers are quick to point out the many pitfalls of unbridled nanotechnology, genetic engineering and robotics research and implementation; however, to the chagrin of futurists, these non-progressive individuals fail to fully conceive of the many benefits these scientific advancements can and will provide. Progressive thinkers are quick to embrace the very real possibility of incredibly low-cost solar power, cures for debilitating disease via intensification of the human immune system, the ability to clean up our environment and the overall improvement of human existence that is not only possible but entirely plausible in the very near future because of nanotechnology, genetic engineering and robotics.

So, are nanotechnology, genetic engineering and robotics to be feared as an impending doomsday event or should they be embraced as miracles of the future? Only by carefully reviewing the past while embracing the future will we be able to tell. After all, if we are willing to build an artificial brain, we must be willing to construct one that is able to see what we cannot.

Nanotechnology and the Emphatic Computer

People show their emotions in many diverse and specialized ways, some of which a computer can be programmed to detect. By employing nanotechnology, a camera and image analysis software, some computers are able to observe a user’s body language and, with proper programming can accurately interpret a person’s posture, restlessness and various facial expressions like grimacing, smiling or scowling. Nanotechnology advances provide onboard sensors which can monitor heartbeats, breathing rates, fluctuations in blood pressure, and other subtle body changes such as skin temperature and voice inflection.

Because human skin has the capability of transmitting electric signals which can be utilized as a method of transmission, nanotechnology researchers have already been able to develop computers that are designed with nano sensors that have the uncanny ability to actually ’see’ and ‘hear’ the people using them. Inevitably it is only a matter of time until the technology is available to create a computer that can readily identify whether their users are in high spirits or in a bad mood.

With ever advancing nanotechnology equipped computers, scientists figure it is entirely possible to develop a computer that is able to interpret a user’s mood via input it receives based on body language, voice tone and facial expressions and that it will be programmed to adjust itself by providing images designed to provide a feeling of comfort and serenity. Since emotions are ambiguous, transient and ultimately difficult to interpret, it would be very difficult for a computer to accurately construe the many human mood variances, regardless of how advanced the nanotechnology utilized. Therefore, in order to operate with any modicum of precision, a user would have to input the required data in advance.

Nanotechnology, with its sensor based abilities, gives programmers little problem with ‘intelligence’ based activities such as diagnosing a medical condition or participating in a game of chess, yet even with the major advancements in nanotechnology in recent years it is still somewhat of a challenge to design computers that accurately simulate human sight, audio functions, language interpretation and/or motor control.

Human vision and other sensory perceptions have evolved over billions of years and the how and why of their operations are still difficult to understand and/or simulate, while things like mathematics are explicitly taught and are, therefore, easier to express in a computer program.

Programmers are also attempting to employ nanotechnology advancements into programs that they expect to be able to accurately determine a person’s innate wishes regarding resuscitation should they fall ill and not be able to make that decision for themselves. Although, theoretically this information would be beneficial to medical teams, caution should be exercised whenever we allow a machine to determine matters relative to ethics. Regardless of the technology involved, machines are not equipped to differentiate between what is intrinsically right or wrong.

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.