Scientists have developed a simple ‘air shower’ device which, when fitted into existing showerheads, fills the water droplets with a tiny bubble of air. The result is the shower feels just as wet and just as strong as before, but now uses much less water.

The researchers, from CSIRO Manufacturing Materials Technology in Melbourne, say the device increases the volume of the shower stream while reducing the amount of water used by about 30 per cent.

Given the average Australian household uses about 200,000 litres of water a year, and showers account for nearly a third of this, the ‘air shower’ could help the average household save about 15,000-20,000 litres a year. If you extend this across the population, that is an annual saving of more than 45,000 Olympic-sized swimming pools.
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Sex selection 1: undercover reporters from the Sunday Times newspaper have found that a prominent IVF specialist in London is sending patients to Cyprus so that they can choose the sex of their baby, at a cost of up to £12,000. Sex selection for “family balancing” is illegal in Britain — and it turns out that it is illegal in Cyprus as well. Cypriot authorities are investigating whether criminal charges should be laid. The Sunday Times also revealed that Rainsbury’s partner in Cyprus, the well-known Dr Panos Zavos, was also offering sex selection — but he was prepared to undercut him by £3,000. ~ Sunday Times, Nov 5

Sex selection 2: Britain’s best-known IVF expert, Professor Lord Robert Winston, has backed sex selection for “family balancing”. “I think there are a lot of shibboleths to which we have paid lip service, but when you analyse them they certainly don’t threaten the moral fabric of our society,” he told the Sunday Herald. “And one of them is sex selection. I think if sex selection was freely available in Britain it would change the balance of society hardly at all, if at all.” ~ Sunday Herald, Nov 5

Rescued from deep freeze: A Spanish woman has given birth to a baby from a donated embryo which had been frozen for 13 years in a Barcelona IVF clinic. The news is expected to give fresh impetus to researchers who claim that thousands of embryos are being destroyed every year because Britain lacks an embryo adoption program. ~ London Times, Nov 4
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Clearly, the more time children spend indoors with technology like video games and television, the less time they’re spending outside, getting in touch with nature. Now, studies are suggesting that children are beginning to suffer from “nature deficit disorder,” leading to hyperactivity, obesity and attention deficit. These studies point to this as a growing health threat… yet recommend that kids spend more time outdoors to foster their creativity and challenge their intellect.

Source: World Future Society
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Researchers at the UCLA Henry Samueli School of Engineering and Applied Science today announced they have developed a new reverse osmosis (RO) membrane that promises to reduce the cost of seawater desalination and wastewater reclamation.

Reverse osmosis desalination uses extremely high pressure to force saline or polluted waters through the pores of a semi-permeable membrane. Water molecules under pressure pass through these pores, but salt ions and other impurities cannot, resulting in highly purified water.

The new membrane, developed by civil and environmental engineering assistant professor Eric Hoek and his research team, uses a uniquely cross-linked matrix of polymers and engineered nanoparticles designed to draw in water ions but repel nearly all contaminants. These new membranes are structured at the nanoscale (the width of human hair is approximately 100,000 nanometers) to create molecular tunnels through which water flows more easily than contaminants.

Unlike the current class of commercial RO membranes, which simply filter water through a dense polymer film, Hoek’s membrane contains specially synthesized nanoparticles dispersed throughout the polymer — known as a nanocomposite material.

“The nanoparticles are designed to attract water and are highly porous, soaking up water like a sponge, while repelling dissolved salts and other impurities,” Hoek said. “The water-loving nanoparticles embedded in our membrane also repel organics and bacteria, which tend to clog up conventional membranes over time.”

With these improvements, less energy is needed to pump water through the membranes. Because they repel particles that might ordinarily stick to the surface, the new membranes foul more slowly than conventional ones. The result is a water purification process that is just as effective as current methods but more energy efficient and potentially much less expensive. Initial tests suggest the new membranes have up to twice the productivity — or consume 50 percent less energy — reducing the total expense of desalinated water by as much as 25 percent.

“The need for a sustainable, affordable supply of clean water is a key priority for our nation’s future and especially for that of California — the fifth largest economy in the world,” Hoek said. “It is essential that we reduce the overall cost of desalination — including energy demand and
environmental issues — before a major draught occurs and we lack the ability to efficiently and effectively increase our water supply.”

A critical limitation of current RO membranes is that they are easily fouled — bacteria and other particles build up on the surface and clog it. This fouling results in higher energy demands on the pumping system and leads to costly cleanup and replacement of membranes. Viable alternative desalination technologies are few, though population growth, over-consumption and pollution of the available fresh water supply make desalination and water reuse ever more attractive alternatives.

With his new membrane, Hoek hopes to address the key challenges that limit more widespread use of RO membrane technology by making the process more robust and efficient.

“I think the biggest mistake we can make in the field of water treatment is to assume that reverse osmosis technology is mature and that there is nothing more to be gained from fundamental research,” Hoek said. “We still have a long way to go to fully explore and develop this technology, especially with the exciting new materials that can be created through nanotechnology.

Hoek is working with NanoH2O, LLP, an early-stage partnership, to develop his patent-pending nanocomposite membrane technology into a new class of low-energy, fouling-resistant membranes for desalination and water reuse. He anticipates the new membranes will be commercially available within the next year or two.

“We as a nation thought we had enough water, so a decision was made in the 1970s to stop funding desalination research,” Hoek said. “Now, 30 years later, there is renewed interest because we realize that not only are we running out of fresh water, but the current technology is limited, we lack implementation experience and we are running out of time. I hope the discovery of new nanotechnologies like our membrane will continue to generate interest in desalination research at both fundamental and applied levels.”

The first viable reverse osmosis membrane was developed and patented by UCLA Engineering researchers in the 1960s.

The school also is home to the Water Technology Research Center, founded in 2005, which seeks to advance the state of desalination technology and to train the next generation of desalination experts. Hoek co-founded the center with UCLA chemical engineering professor and center director Yoram Cohen. Hoek also collaborates with UCLA’s California NanoSystems Institute.

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[Date: 2006-11-06]

‘We are going to make sure in Germany, that scientifically excellent results in nanotechnology are turned faster and more efficiently into the products of tomorrow,’ said German Minister for Education and Research, Annette Schavan, as she launched the ‘Nano-initiative action plan 2010′ on 6 November.

The action plan is intended to provide a single framework for action that goes beyond individual government departments, and which brings together goals and plans for nanotechnology. The initial focus will be on future fields, the creation of better framework conditions, responsible use of the technology and a comprehensive dialogue with the public.

‘This is one of the most promising technology fields with a huge market potential,’ said Ms Schavan.

According to the Ministry of Education and Research, Germany leads in nanotechnology in Europe. This leadership can be measured in terms of research and development (R&D) expenditure and the number of companies and research institutes engaged with nanotechnology.

In the past year, Germany invested around €310 million in nano R&D. For 2006, and this figure is expected to reach €330 million for 2006. Some 600 companies are already involved in the development and use of nanotechnology products, employing around 50,000 people. The ministry predicts that many more jobs are yet to be created, particularly in start-ups and small and medium sized enterprises (SMEs). A boom in market potential is also predicted - over €1 billion by 2015, according to the German ministry.
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Anyone who has ever smelled E. coli bacteria knows that they smell bad. Putridly bad. So, a group of student bioengineers at MIT set out to sweeten the scent of this commonly used lab bacteria. The team constructed its creation from a collection of biological “parts”–bits of DNA that, when inserted into living organisms, can make the organisms glow, detect light, and perform a number of other unusual functions. The team will showcase its sweet-smelling bug this weekend at the International Genetically Engineered Machine competition (iGEM) at MIT, along with 37 other student groups from around the world.
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A new nanotechnology-based treatment developed by researchers at the University of Texas’s Southwestern Medical Center at Dallas could double the effectiveness of cancer drugs without increasing side effects, while allowing doctors to see immediately whether the treatment is working.
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NEWCASTLE, England, Oct. 31 (UPI) — British scientists have grown a liver from stem cells in the first step toward creating fully viable livers, perhaps within 10 years.
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BERKELEY – A new research center being launched this summer at the University of California, Berkeley, will seek to make it as quick and easy to engineer biology as it now is to assemble microprocessors, hard drives and memory chips into a computer.
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ZURICH, SEPTEMBER 11-12 2006
for the presentations see here

Mechanical ‘artificial hearts’ can be used to return severely failing hearts to their normal function, potentially removing the need for heart transplantation, according to new research.
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A Virginia-based startup called Luna nanoWorks is nearing commercialization of a novel version of buckyballs–soccerball-shaped carbon molecules–that the company says could improve magnetic resonance imaging (MRI) and lead to high-efficiency solar cells. Each buckyball is made of 80 carbon atoms with metal-nitride clusters trapped inside, creating a nanomaterial with novel electronic, optical, and magnetic properties.
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Luna Nanoworks

(Nanowerk News) A research center newly created by the University of California, Berkeley, and Lawrence Berkeley National Laboratory (LBNL) aims to put light-sensitive switches in the body’s cells that can be flipped on and off as easily as a remote control operates a TV.
Optical switches like these could trigger a chemical reaction, initiate a muscle contraction, activate a drug or stimulate a nerve cell - all at the flash of a light.
One major goal of the UC Berkeley-LBNL Nanomedicine Development Center is to equip cells of the retina with photoswitches, essentially making blind nerve cells see, restoring light sensitivity in people with degenerative blindness such as macular degeneration.
“We’re asking the question, ‘Can you control biological nanomolecules - in other words, proteins - with light?’” said center director and neurobiologist Ehud Y. Isacoff, professor of molecular and cell biology and chair of the Graduate Group in Biophysics at UC Berkeley. “If we can control them by light, then we could develop treatments for eye or skin diseases, even blood diseases, that can be activated by light. This challenge lies at the frontier of nanomedicine.”

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