HYDERABAD: A genetic research
specialist from the twin cities Rao Papineni, working with Carestream Health
Inc, USA, along with other top researchers has devised a method to treat cancer
cells by using nanotechnology.
The researcher who is here to take part in the upcoming
BioAsia-09 said that the ‘invention’ is in U.S. patent process. It’s a known
fact that nanotechnology can be used to develop ways to kill cancer cells in
the body without damaging the healthy cells. “We have developed image-guided
targeted cancer-cell killers. The unique aspect is that we can deliver large
loads of drugs to the cancerous region without actually affecting the healthy
cells,” Dr. Papineni said.
The researcher is in the process of meeting local scientific and
research community in India and discuss about the invention. “We are hoping
that people back home here will notice such developments during the BioAsia
2009. I have already presented a paper on the same subject in Nanobio-2009 held
recently in Kochi,” he said.
Along with a research team consisting of Dr. Alan Pollock and
Dr. Mansoor Ahmed at University of Miami, Florida, plans are afoot to use the
cancer killer nanoparticles in curing prostrate cancer. “It’s not just
prostrate cancer; other cancers can also be cured.” Dr. Rao is also working on
a process to make nanoparticles carry large doses of Curcumin (Haldi), which
has anti-cancer properties, with another Indian researcher Bharat Agarwal.
“Apart from its known use in plastics, energy, and aerospace industry, nanotechnology
is beginning to grow rapidly in medical imaging and therapeutics,” he said.
Dr. Rao Papineni is
the Chief Scientist and senior Principal Investigator at Carestream Health Inc,
USA. (He can be reached at rao.papineni1@ carestreamhealth.com).
Courtesy: The Hindu
What
is NanoTechnology?
NanoTechnology involves development of materials (and even complete systems) at the atomic, molecular, or macromolecular levels in the dimension range of approximately 1-500 nanometers.Current research looks to provide detailed understanding of unique properties that materials exhibit at the NanoScale.Current focus of the research is positioned to create and use structures, devices, and systems that have unique and often contradictory properties as well as enhanced functions because of their small and/or intermediate size.NanoTechnology research and development includes control at the NanoScale and integration of NanoScale structures into larger material components, systems, and architectures as well as automated systems for the production of NanoMaterials and the automatic assembly of structures and systems.
NanoTechnology involves development of materials (and even complete systems) at the atomic, molecular, or macromolecular levels in the dimension range of approximately 1-500 nanometers.Current research looks to provide detailed understanding of unique properties that materials exhibit at the NanoScale.Current focus of the research is positioned to create and use structures, devices, and systems that have unique and often contradictory properties as well as enhanced functions because of their small and/or intermediate size.NanoTechnology research and development includes control at the NanoScale and integration of NanoScale structures into larger material components, systems, and architectures as well as automated systems for the production of NanoMaterials and the automatic assembly of structures and systems.
History
of NanoTechnology
NanoTechnology first gained recognition after Nobel Laureate, Richard Feynman, presented his talk, "There's Plenty of Room at the Bottom" to the American Physical Society in 1959.Activity surrounding NanoTechnology began to slowly increase over the next few decades.In 1988, Eric Drexler taught the first course on NanoTechnology.In that program, he suggested the possibility of nanosized objects that were self-replicating. Slow growth in this area of scientific investigation continued.The next major milestone was when Rice University Professor Richard Smalley won the 1996 Nobel Prize for discovering a new form of carbon: a molecule of sixty carbon atoms (referred to as C60).Today C60 has become one of a growing number of building blocks for a new class of nanosized materials.
The advancements in NanoTechnology really began to accelerate in the late 1990s.NanoTechnology captured the thoughts and imagination of scientists and venture capitalists after an entire issue of Scientific American addressed the promise of this new technology.
NanoTechnology first gained recognition after Nobel Laureate, Richard Feynman, presented his talk, "There's Plenty of Room at the Bottom" to the American Physical Society in 1959.Activity surrounding NanoTechnology began to slowly increase over the next few decades.In 1988, Eric Drexler taught the first course on NanoTechnology.In that program, he suggested the possibility of nanosized objects that were self-replicating. Slow growth in this area of scientific investigation continued.The next major milestone was when Rice University Professor Richard Smalley won the 1996 Nobel Prize for discovering a new form of carbon: a molecule of sixty carbon atoms (referred to as C60).Today C60 has become one of a growing number of building blocks for a new class of nanosized materials.
The advancements in NanoTechnology really began to accelerate in the late 1990s.NanoTechnology captured the thoughts and imagination of scientists and venture capitalists after an entire issue of Scientific American addressed the promise of this new technology.
Current
State of NanoTechnology
Research into NanoMaterials spans a significant spectrum of areas. Advanced material companies are producing innovative products in areas such as coatings, industrial powders, chemicals, and carbon nanotubes. Today, real world application of NanoTechnology exists in commercial business. About two-dozen serious applications of NanoMaterials and process have been fielded ranging from non-scuff floor tile to high strength brackets for running boards on vehicles to high temperature protective materials for spacecraft.While NanoMaterials are a significant portion of today's focus, several other areas are equally as promising.
Research into NanoMaterials spans a significant spectrum of areas. Advanced material companies are producing innovative products in areas such as coatings, industrial powders, chemicals, and carbon nanotubes. Today, real world application of NanoTechnology exists in commercial business. About two-dozen serious applications of NanoMaterials and process have been fielded ranging from non-scuff floor tile to high strength brackets for running boards on vehicles to high temperature protective materials for spacecraft.While NanoMaterials are a significant portion of today's focus, several other areas are equally as promising.
Trends
& Impact of NanoTechnology
NanoTechnology has the potential to become a more significant revolutionary force for business than the industrial revolution or the information technology revolution.In fact, many believe that the combined impact of both the industrial and information revolution may approach the magnitude of change that could result from the commercialization of NanoTechnology.Currently, NanoTechnology is moving from the basic research stage of its evolution into the applied research stage of technology maturity.Today there are several NanoTechnology companies already being traded on the public marketplace. As this technology evolves and matures, you can expect to see many more companies enter this space.
Today's manufacturing methods are very crude at the molecular level. Casting, grinding, milling, and even lithography move atoms in mass.It is like trying to make things out of LEGO blocks with boxing gloves on your hands.Yes, you can push the LEGO blocks into great heaps and pile them up; but you cannot really snap them together the way you would like.
NanoTechnology has the potential to become a more significant revolutionary force for business than the industrial revolution or the information technology revolution.In fact, many believe that the combined impact of both the industrial and information revolution may approach the magnitude of change that could result from the commercialization of NanoTechnology.Currently, NanoTechnology is moving from the basic research stage of its evolution into the applied research stage of technology maturity.Today there are several NanoTechnology companies already being traded on the public marketplace. As this technology evolves and matures, you can expect to see many more companies enter this space.
Today's manufacturing methods are very crude at the molecular level. Casting, grinding, milling, and even lithography move atoms in mass.It is like trying to make things out of LEGO blocks with boxing gloves on your hands.Yes, you can push the LEGO blocks into great heaps and pile them up; but you cannot really snap them together the way you would like.
Future
Advances
·
Self-assembling
products, systems and materials (self repairing system)
·
Computers billions of
times faster (reaching the size barrier of microprocessors)
·
Extremely novel
inventions (self-adapting fabrics)
·
Realistic space travel
and exploration (more economic)
·
NanoMedical (unique
treatment delivery capabilities)
·
Molecular food
syntheses (end of famine and starvation)
The
big question is "When will this technology enter into the
mainstream?" As the graphic below indicates, it will take another eight to
ten years. But, rest assured, several breakthroughs and advances will produce
significant advantages in materials science, semiconductors, optical
communications, and information technology.
Homeland
Security Applications
With the broad reach NanoTechnology has in terms of capabilities, the direct applications for Defense and Homeland Security are only limited by our imagination and how rapidly the technology advances.From shape-shifting armor to fabric that can turn away microbes as well as bullets to new power sources, the defense industries are launching major initiatives and planning for NanoTechnology.The Government is the major source of funding for current NanoTechnology initiatives.Centers of Excellence in NanoTechnology have been established around the country.The basic research in NanoTechnology conducted at these centers will provide the foundation upon which real world applications can be built.Other centers are already concentrating on military application of NanoTechnology.While there are efforts for new and improved weapons based on NanoTechnology, the vast majority of the NanoTechnology research and applied research fall into the support category.
With the broad reach NanoTechnology has in terms of capabilities, the direct applications for Defense and Homeland Security are only limited by our imagination and how rapidly the technology advances.From shape-shifting armor to fabric that can turn away microbes as well as bullets to new power sources, the defense industries are launching major initiatives and planning for NanoTechnology.The Government is the major source of funding for current NanoTechnology initiatives.Centers of Excellence in NanoTechnology have been established around the country.The basic research in NanoTechnology conducted at these centers will provide the foundation upon which real world applications can be built.Other centers are already concentrating on military application of NanoTechnology.While there are efforts for new and improved weapons based on NanoTechnology, the vast majority of the NanoTechnology research and applied research fall into the support category.
From improved powers
sources and batteries to advanced arming fuses the defense industry and
homeland security has great interest in how NanoTechnology their
capabilities.They believe that NanoTechnology will advance sensors and
protective equipment and will greatly assist them in their mission. In fact,
current research and development efforts are working on micro power generating
devices that can be used in a plethora of applications. If successful these MPG
can provide enough energy to power sensors and sensor networks that will be
deployed to protect critical infrastructure like water treatment plans,
roadways, and bridges.Other applications could include such things as microscopic
self-powered reconnaissance and surveillance devices like listening devices,
vibrations sensors as well as supplying power to sensor networks.Currently, DoD
is funding research in small-scale energetic device development and management.
The lifecycle development
and support requirements for NanoMEMS (micro-electro-mechanical systems) in
support of advanced applications in munitions and armament systems are critical
to advances in weaponry.NanoMEMS has direct implications on integrated
circuits, optical switches, pressure sensors, as well as the processes used to
produce weapons.However, current thoughts are that NanoMEMS can play a major
role in new weapons and intelligence and surveillance. Imagine using NanoMEMS
to construct a steam powered electrical generator systems for satellites.Steam
is currently used in conventional and nuclear power plants to turn turbines
that generate electricity.When used onboard a satellite, as the satellite spins
and out of direct sunlight, the steam condenses to liquid; and when it rotates
back in the sunlight, the liquid turns to steam again.The micro-size steam
power plant would generate enough electricity to operate the unit.The
satellite's overall demand for energy would have been greatly reduced because
of the use of extremely efficient electronics created with NanoTechnology.In
addition, the overall size of the units could be reduced by a factor of ten or
more, as well as the weight because of construction practices at the
NanoScale.Just think! A satellite so small that it could be launched by what
appears to be a large gun in place of conventional rockets.The cost savings
would be enormous as well as the difficulty in anyone being able to detect the
satellite in orbit.
As mentioned
previously, the area that NanoTechnology that holds the most significant
promise is in the area of sensors and sensor networks. Hybrid NanoMaterials
will produce orders of magnitude improvements in high-selectivity and
high-sensitivity sensors for biological and chemical detection. This advanced
detection of harmful chemical and biological agents; microsensors for
radioactivity, low-power or self-powering consumption security electronics,
polymer electronics, nano-optics will provide capabilities that are not
available today.
Just imagine. In a few
years advanced sensor networks self powered with the smarts to communicate from
sensor to sensor and have the ability to detect very small amounts of chemicals
or biological agents installed in the water supplies across the country.Once a
single sensor node detects the presence of one of the agents, it communicates
to the others what hit was found and receives their verification.Once verified,
the information is communicated to the control sensor that relays the information
back to the National Infrastructure Protection Center for immediate action.
Other applications like underwater sensor networks to detect the movement of
ships into and out of our ports could also be advanced using NanoTechnology.
Sensor networks that detect chemical, biological or radiological materials
could be built into cargo containers.
The applications of
NanoMaterials go far beyond semiconductors and sensors into
NanoFabrics.NanoFabrics with unique properties are under development at this
time.Properties like decreased receptivity to chemical or biological agents,
materials with the ability to expand and contract (like a thermostat) as to
exhaust or conserve body heat, or to resist the penetration of a bullet.
Consider that today a
soldier going into battle carries about 60 lbs of equipment.A significant part
of that weight is in the bullet -proof-vest.What if the weight burden was
reduced by 50%? How much more efficient would the soldier be? What if instead
of having multiple types of camouflage there was only one uniform that adapted
the outer colors to blend into the surroundings? How much physical stress would
be relieved if the uniform had that thermostatic characteristic discussed
earlier? When the soldier becomes over heated the vents open to allow the flow
of air and when the soldier becomes cold the vents close to conserve body
heat.In one discussion I had preparing for this article there was even the
notion that the materials could sense an injury and automatically constrict
like a tourniquet or mast trousers used to treat victims in shock.
One of the early
NanoTechnology successes was material that had the characteristics of Gortex
with the look and feel of regular wool. Remember of course that Gortex is
currently used in bulletproof vests. Today, ballistic resistant materials are
heavy and many are extremely brittle. Super strength nanofabrics sandwiched
into normal contraction materials are expected to improve blast resistant
construction practices making commercial and governmental structures much more
resilient against bomb blasts. Bomb resistant containers for cargo and luggage
on ships and aircraft, bomb resistant glass for office buildings and government
complexes, advanced structural members that have the strength by are pliable to
absorb the energy of a blast are all currently being investigated as real world
application of NanoTechnology.
Another area of
NanoTechnology that is receiving the greatest amount of attention is
semiconductors.The ability to further compact the number of transistors in a
given space increases the performance of a semiconductor.NanoScale construction
practices applied to semiconductors will substantially increase current
processing capability and could change the entire industry
overnight.NanoTechnology also has significant benefits in opto-electronics and
communications.The ability to construct an optical switch on a chip would
eliminate a significant amount of complexity and cost of optical networks, not
to mention increasing the capacity as well.
Conclusion
While NanoTechnology is based in the research labs today, the advances made to date have illustrated the significant value this technology will bring.The implication on manufacturing techniques, materials manufacturing and the semiconductor industry will be profound.The enhanced characteristics of materials will allow us to create new and innovative devices to protect all of us from terrorism, both directly through safer construction designs and indirectly through intelligence and surveillance.With each passing day, the promise of NanoTechnology becomes increasingly apparent. There is a long way to go before the NanoMaterials production techniques can provide adequate supply of high quality materials at affordable prices. This is one technology that requires close monitoring to properly time the significant opportunities that will be created in it wake.
While NanoTechnology is based in the research labs today, the advances made to date have illustrated the significant value this technology will bring.The implication on manufacturing techniques, materials manufacturing and the semiconductor industry will be profound.The enhanced characteristics of materials will allow us to create new and innovative devices to protect all of us from terrorism, both directly through safer construction designs and indirectly through intelligence and surveillance.With each passing day, the promise of NanoTechnology becomes increasingly apparent. There is a long way to go before the NanoMaterials production techniques can provide adequate supply of high quality materials at affordable prices. This is one technology that requires close monitoring to properly time the significant opportunities that will be created in it wake.
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