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An aerial view of the ITER construction site in Cadarache, France. Photograph: Agence ITER France
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Issue no. 21, 2009
Published: Jun 19, 2009 |
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 Nuclear fusion power project to start in 2018 | | NASA launches probes to scout the moon | | Lung-on-a-chip could replace countless lab rats | | 3D printing for new tissues and organs | | Synthetic cells get together to make electronics | | Light sensor breakthrough could enhance digital cameras | | Do bow and arrow predate modern humans? |
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| Nuclear fusion power project to start in 2018 |
An experimental reactor that could harness nuclear fusion will begin
operation in southern France in 2018. The International Thermonuclear
Experimental Reactor (ITER) should be fully operational in 2026, says
the ITER Council, the project's governing body.
The seven-nation council endorsed a 'phased' completion of the reactor,
with a target date for 'first plasma' by the end of 2018. ITER is
designed to produce 500 megawatts of power for extended periods, 10
times the energy needed to keep the energy-generating plasma at
extremely high temperatures. It will also test a number of key
technologies for fusion including the heating, control and remote
maintenance that will be needed for a full-scale fusion power station.
Preliminary trials would use only hydrogen. Key experiments using
tritium and deuterium that can validate fusion as a producer of large
amounts of power would not take place until 2026.
Launched in 2006 after years of debate, the pilot project at Cadarache,
near Marseille, has seven backers: the European Union (EU), China,
India, South Korea, Japan, Russia and the United States. Kazakhstan is
poised to become the eighth member. If ITER is a success, the next step
would be to build a commercial reactor. |
| PhysOrg / AFP
Jun 18, 2009 |
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| NASA launches probes to scout the moon |
NASA launched an unmanned Atlas rocket on Thursday carrying a pair of
probes to map the moon and hunt for water. The Lunar Reconnaissance
Orbiter (LRO) carries seven science instruments, including several
cameras, infrared detectors and a laser altimeter to measure topography.
The satellite also carries a telescope outfitted with synthetic human
skin to assess how the radiation environment may affect human health.
Scientists have targeted 50 potential landing sites that will be imaged
with LRO's highest-quality cameras, which are capable of seeing objects
as small as about 50 centimetres in diameter. The spacecraft also will
scout for minerals, make detailed temperature maps, find areas of
maximum sunlight and chart the moon's topography. The agency is
preparing for a new wave of human expeditions to the moon, with bigger
crews, longer stays and more flexibility to select scientifically
interesting landing sites. Of particular interest are the polar caps,
where permanently shadowed craters may hide pockets of frozen water.
Once LRO reaches the moon, it will spend about two months getting into
position to begin its survey, which is scheduled to last a year. After
the mapping is finished, the spacecraft is then expected to be turned
over to NASA scientists for an extended two- to three-year mission. |
| Reuters
Jun 18, 2009 |
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| Lung-on-a-chip could replace countless lab rats |
'Microlungs' grown from human tissue might one day help to replace the
vast numbers of rats used to check the safety of drugs, cosmetics and
other chemicals.
The work is part of a growing drive to develop toxicology tests based on
human cells as a replacement for animal testing. Such efforts are made
partly for ethical concerns, and partly because animal testing is so
time-consuming and expensive. The obvious alternative is to test
chemicals on human cells grown in the lab. The difficulty, however, lies
in enticing those cells to form complex tissue that responds as our
organs do.
Researchers at the University of Cardiff, UK, have already managed to
grow human lung cells into flat differentiated layers that resemble the
inner lining of the lungs. But when allowed to grow in three dimensions,
as in the body, cells arrange themselves very differently, and this can
change how they respond to chemical stimuli. A popular approach is to
seed plastic scaffolds with stem cells to grow artificial 'organs'.
But the researchers have found an alternative which could allow
thousands of drugs to be screened at once. Instead of large scaffolds,
they have grown lung cells on the surface of plastic spheres half a
millimetre in diameter, essentially producing a tiny inside-out lung
around each bead. The ultimate aim is to develop a chip on which
thousands of microlungs can be grown then tested simultaneously. |
| New Scientist
Jun 17, 2009 |
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| 3D printing for new tissues and organs |
A more effective way to build plastic scaffolds on which new tissues and
even whole organs might be grown in the laboratory is being developed by
an international collaboration between teams in Portugal and the UK. The
new technique known as rapid prototyping, or three-dimensional printing,
could enable tissue engineering that replicates the porous and
hierarchical structures of natural tissues at an unprecedented level.
Scaffold structures for tissue engineering that allow researchers to
grow cells in a three-dimensional way could allow medical science to
create natural artificial organs. However, conventional techniques have
several limitations. In particular, current scaffold construction lacks
full control of the often microscopic pores and their architecture.
Researchers at the Leiria Polytechnic Institute, and the University of
Wolverhampton, are borrowing a technique from more conventional
manufacturing to solve this problem. In rapid prototyping, a computer
controls a laser that cures a vat of polymer resin layer by layer and
building up a solid object. It allows designers and manufacturers to
rapidly produce a prototype component created on a CAD machine.
But it is the precision with which a material can be constructed that
could be crucial to developing rapid prototyping as a tissue engineering
technique. It overcomes many of the limitations of conventional scaffold
techniques. Rapid prototyping might one day allow kidney, liver and
muscle tissues to be constructed in the laboratory from a patient's own
cells with close-to-natural detail ready for transplantation. |
| PhysOrg / International Journal of Computer Applications in Technology
Jun 18, 2009 |
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| Synthetic cells get together to make electronics |
A network of artificial cells that work together to act as an AC/DC
converter has been built. Demonstrating that synthetic cells can team up
to achieve such feats is a step towards building synthetic tissues to
interface biology with electronics, according to researchers at the
University of Oxford and the University of Massachusetts.
Synthetic biologists have show they can reprogram living cells to make
them produce drug compounds, and are even working towards building cells
from scratch to create artificial life. But that work focuses on only
individual cells. Now the group has made a step towards making
artificial tissue in which individual synthetic cells work together.
They connected together multiple artificial 'protocells' so that they
share electrical signals. Like real cells, the protocells are droplets
of watery fluid enclosed in an oily membrane. When two protocells are
brought together, the membranes around them fuse on contact to form a
double-thickness boundary membrane.
To transform such groups into electronic devices, the researchers added
pores to the double membranes between protocells, using a bacterial
toxin that punches holes in the membranes of mammalian cells during an
infection. The pores allow charged ions to flow from one protocell to
another if electrodes are connected to the protocells to supply a
current. Because those pores only remain open if current flows in one
direction, it is possible to use the cells to form electronic circuits.
By connecting four droplets together the team created a rectifier that
converts alternating current into direct current. |
| New Scientist / Nature Nanotechnology
Jun 17, 2009 |
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| Light sensor breakthrough could enhance digital cameras |
New research by a team of University of Toronto scientists could lead to
substantial advancements in the performance of a variety of electronic
devices including digital cameras.
In solar cells and digital cameras, particles of light - known as
photons - are absorbed in a semiconductor, such a silicon, and generate
excited electrons, known as excitons. The semiconductor chip then
measures a current that flows as a result. Normally, each photon is
converted into at most one exciton. This lowers the efficiency of solar
cells and it limits the sensitivity of digital cameras. When a scene is
dimly lit, small portable cameras like those in laptops suffer from
noise and grainy images as a result of the small number excitons.
The researchers created a light sensor that benefits from a phenomenon
known as multi-exciton generation (MEG). Until now, no group had
collected an electrical current from a device that takes advantage of
MEG. Multi-exciton generation breaks the conventional rules that bind
traditional semiconductor devices, according to the researchers. |
| EurekaAlert / University of Toronto
Jun 18, 2009 |
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| Do bow and arrow predate modern humans? |
Bows and arrows may not be the preserve of modern humans. It seems that
simple stone blades make adequate arrowheads, so they might have been
used in lightweight projectile weapons as far back as 100,000 years ago,
when the blades first appeared.
Spears and arrows would have let early hunters catch small fast-moving
creatures rather than tackling large dangerous animals with hand-held
blades.
Researchers from Stony Brook University in New York have shown that
so-called Levallois points make effective arrowheads. They turned 51
reproduction blades into arrows and successfully shot them into an
animal carcass. The earliest definite arrowheads date to around 20,000
years ago and are the handiwork of modern humans. |
| New Scientist / Journal of Archaeological Science
Jun 18, 2009 |
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