the world’s first trial using liver stem cells

An Indian-origin professor in the U.K. will head the world’s first trial using liver stem cells that could avoid transplant surgery.

Paediatric liver consultant Professor Anil Dhawan, who will head the trial at King’s College Hospital, has described the use of stem cells to treat liver disease as an “exciting breakthrough”, The Daily Mail reported.

Doctors have developed a pioneering treatment for liver disease that could save hundreds of lives a year and avoid the need for transplant surgery, it said.

Eighteen British children suffering from rare and life threatening liver conditions are to receive infusions of specially treated liver cells removed from the organs of dead donors, the paper said.

It said that doctors believe they will make vital stem cells — the building blocks of life — and repair the damaged organ.

“We have many very sick children and babies who need transplants. If we can cure them without a transplant that will be a fantastic development.

“We have tried using ordinary liver cells with limited success, but is the first time a treatment has been developed that gets the liver to regrow using stem cells,” Mr. Dhawan was quoted, as saying by the daily.

He added that if all goes well, the children, who are being treated with the cells, will show an improvement within a couple of months.

“We would expect those children to come off their medicines and therapy. It will mean the liver cells have done their job and corrected the defects that made them ill. “Then we will have to see how long the effect lasts and whether we have to top up these children with further infusions. I am optimistic the treatment will work,” he said.

Discovery could lead to 'next-gen' vaccines

The discovery of how a vital immune cell recognises dead and damaged body cells could open the way to next-gen vaccines that are more effective and have fewer side-effects.

Scientists from the Walter and Eliza Hall Institute have identified, for the first time, how a protein found on the surface of immune cells called dendritic cells recognises dangerous damage and trauma that could signify infection.

Dendritic cells are critical for raising an alarm about the presence of foreign invaders in the body such as viruses, bacteria and parasites as well as tumour cells and other dead or damaged cells, the journal Immunity reported.

Also known as antigen-presenting cells, they digest and present molecules from damaged cells to other immune cells that recognise foreign invaders and launch an immune response, said a university statement.

The research was a collaborative effort involving a team of immunologists, protein chemists and structural biologists, led by Mireille Lahoud, Jian-Guo Zhang, Peter Czabotar and Ken Shortman from Eliza Hall.

Lahoud said the study demonstrated that the immune system has evolved a very clever way of detecting damaged and dead cells to help promote an immune response.

Lahoud said that the finding could develop or increase the efficacy of vaccines for diseases that do not currently have good preventive options, such as malaria or HIV.

“There is also the possibility that the system could be used to develop therapeutic vaccines for treating diseases, such as some forms of cancer, as well as for preventing them,” Lahoud added.

‘A blood test could crack Alzheimer’s code’

The earlier the detection of Alzheimer’s disease the more likely it is that decline could be slowed or even stopped.

The testing currently on offer is invasive and expensive, and scientists around the world are looking for a cheaper and easier method. Researchers at Newcastle University say they are making progress in coming up with a blood test that could complement brain imaging.

“We detect it very late with imaging techniques,” said research leader Pablo Moscato. “When a lot of damage has been done in your brain, it’s unlikely we can come up with a solution.” The aim is for a 50-dollar blood test with a high level of accuracy.

“If we can catch this early, then the possibility of drug intervention is there because the drug companies would see a market and try and come up with one,” Professor Moscato said.

In a paper published in the PLoS (Public Library of Science) ONE journal, the team delivered a progress report on their work in developing a cheap two-part blood test that could determine whether a mild intellectual impairment was going to progress to Alzheimer’s.

“We’re looking at pairs of markers,” Moscato said. “The best possible measurement is if you take them at the baseline and then again in 12 months. Then you compare the variation between the pairs of proteins over that 12 months.” What the team look for acceleration. “It’s the rate of change of values that rings the bells,” he said. “If it grows and grows exponentially then we know we have something wrong.”

People with mild cognitive impairment do not inevitably develop Alzheimer’s. Some maintain a level of functioning and some progress to another form of dementia.

Genes identified for common childhood obesity

An international team of genetics researchers have identified at least two new gene variants that increase the risk of common childhood obesity, according to a study published online this week in Nature Genetics.

As one of the major health issues affecting modern societies, obesity has increasingly received public attention, especially given a rising prevalence of the condition among children. Research indicates that obese adolescents tend to have higher risk of mortality as adults. Although environmental factors such as food choices and sedentary habits contribute to the increasing rates of obesity in childhood, twin studies and other family-based evidence have suggested a genetic component to the disease as well.

Previous studies have identified gene variants contributing to obesity in adults and in children with extreme obesity, but relatively little is known about genes implicated in regular childhood obesity.

In the new study, researchers at the Children’s Hospital of Philadelphia recruited and genotyped the world’s largest collection of DNA from children with common obesity. In order to have sufficient statistical power to detect novel genetic signals, they formed a large international consortium to combine results from similar datasets from around the world. The U.S. National Institutes of Health partly funded this research, which analyzed previous studies supported by many other European, Australian and North American organizations.

The current meta-analysis included 14 previous studies encompassing 5,530 cases of childhood obesity and 8,300 control subjects, all of European ancestry. The study team identified two novel loci, one near the OLFM4 gene on chromosome 13, the other within the HOXB5 gene on chromosome 17. They also found a degree of evidence for two other gene variants. None of the genes were previously implicated in obesity.

“This work opens up new avenues to explore the genetics of common childhood obesity,” said lead investigator Struan Grant, associate director of the Center for Applied Genomics at The Children’s Hospital of Philadelphia. “Much work remains to be done, but these findings may ultimately be useful in helping to design future preventive interventions and treatments for children, based on their individual genomes.”

Why is the flame of the candle yellow in colour?

The flame of a burning candle is dominated by yellow color although there are other color regions in particular blue color in a small way.

In the flame, mechanism(s) of light production for different regions differ and determined by the ambient atmosphere during the course of candle burning (that is presence or absence of oxygen/air, hydrogen from the break-down of hydrocarbons, the usual constituent of the candle material).

As the candle wick is lighted, it picks up the fuel through capillary action of the wick from the immediate surrounding region of the burning wick.

This molten region of the paraffin/wax-hydrocarbons gets burnt and undergoes molecular transitions determined by the environ.

The miniscule blue region of the flame can be attributed to hydrogen burning resulting from the break-down of hydrocarbons from the candle stuff while the incandescent wick material, the carbonaceous materials such as soot from the burning of candle stuff, with limited supply of oxygen dominating the scenario results in a yellow flame . The latter process can be better described by incandescence, a process of light generation through burning analogizing glow of tungsten filament in an electrical bulb or glow of lighted match stick and so on yielding yellow flames where most of the energy is dissipated as heat radiation.

It should be borne in mind that a blue flame yields higher temperate than does a yellow flame.

Also it is common experience to see a domestic gas stove showing difference in flame color changing from yellowish blue to deep blue as we change the control knob ( letting air through nozzle determining the speed of combustion of the gas) from sim mode to high flame mode.

New Electronic Concept: How Hybrid Motors Could Become Cheaper

New Electronic Concept: How Hybrid Motors Could Become Cheaper

Honeycombs of magnets could lead to new type of computer processing

Honeycombs of magnets could lead to new type of computer processing

Hybrid Copper-Gold Nanoparticles Convert CO2

Copper -- the stuff of pennies and tea kettles -- is also one of the few metals that can turn carbon dioxide into hydrocarbon fuels with relatively little energy. When fashioned into an electrode and stimulated with voltage, copper acts as a strong catalyst, setting off an electrochemical reaction with carbon dioxide that reduces the greenhouse gas to methane or methanol.
     

Various researchers around the world have studied copper's potential as an energy-efficient means of recycling carbon dioxide emissions in powerplants: Instead of being released into the atmosphere, carbon dioxide would be circulated through a copper catalyst and turned into methane -- which could then power the rest of the plant. Such a self-energizing system could vastly reduce greenhouse gas emissions from coal-fired and natural-gas-powered plants.
But copper is temperamental: easily oxidized, as when an old penny turns green. As a result, the metal is unstable, which can significantly slow its reaction with carbon dioxide and produce unwanted byproducts such as carbon monoxide and formic acid.
Now researchers at MIT have come up with a solution that may further reduce the energy needed for copper to convert carbon dioxide, while also making the metal much more stable. The group has engineered tiny nanoparticles of copper mixed with gold, which is resistant to corrosion and oxidation. The researchers observed that just a touch of gold makes copper much more stable. In experiments, they coated electrodes with the hybrid nanoparticles and found that much less energy was needed for these engineered nanoparticles to react with carbon dioxide, compared to nanoparticles of pure copper.
A paper detailing the results will appear in the journal Chemical Communications; the research was funded by the National Science Foundation. Co-author Kimberly Hamad-Schifferli of MIT says the findings point to a potentially energy-efficient means of reducing carbon dioxide emissions from powerplants.
"You normally have to put a lot of energy into converting carbon dioxide into something useful," says Hamad-Schifferli, an associate professor of mechanical engineering and biological engineering. "We demonstrated hybrid copper-gold nanoparticles are much more stable, and have the potential to lower the energy you need for the reaction."
Going small
The team chose to engineer particles at the nanoscale in order to "get more bang for their buck," Hamad-Schifferli says: The smaller the particles, the larger the surface area available for interaction with carbon dioxide molecules. "You could have more sites for the CO₂ to come and stick down and get turned into something else," she says.
Hamad-Schifferli worked with Yang Shao-Horn, the Gail E. Kendall Associate Professor of Mechanical Engineering at MIT, postdoc Zichuan Xu and Erica Lai '14. The team settled on gold as a suitable metal to combine with copper mainly because of its known properties. (Researchers have previously combined gold and copper at much larger scales, noting that the combination prevented copper from oxidizing.)
To make the nanoparticles, Hamad-Schifferli and her colleagues mixed salts containing gold into a solution of copper salts. They heated the solution, creating nanoparticles that fused copper with gold. Xu then put the nanoparticles through a series of reactions, turning the solution into a powder that was used to coat a small electrode.
To test the nanoparticles' reactivity, Xu placed the electrode in a beaker of solution and bubbled carbon dioxide into it. He applied a small voltage to the electrode, and measured the resulting current in the solution. The team reasoned that the resulting current would indicate how efficiently the nanoparticles were reacting with the gas: If CO₂ molecules were reacting with sites on the electrode -- and then releasing to allow other CO₂ molecules to react with the same sites -- the current would appear as a certain potential was reached, indicating regular "turnover." If the molecules monopolized sites on the electrode, the reaction would slow down, delaying the appearance of the current at the same potential.
The team ultimately found that the potential applied to reach a steady current was much smaller for hybrid copper-gold nanoparticles than for pure copper and gold -- an indication that the amount of energy required to run the reaction was much lower than that required when using nanoparticles made of pure copper.
Going forward, Hamad-Schifferli says she hopes to look more closely at the structure of the gold-copper nanoparticles to find an optimal configuration for converting carbon dioxide. So far, the team has demonstrated the effectiveness of nanoparticles composed of one-third gold and two-thirds copper, as well as two-thirds gold and one-third copper.
Hamad-Schifferli acknowledges that coating industrial-scale electrodes partly with gold can get expensive. However, she says, the energy savings and the reuse potential for such electrodes may balance the initial costs.
"It's a tradeoff," Hamad-Schifferli says. "Gold is obviously more expensive than copper. But if it helps you get a product that's more attractive like methane instead of carbon dioxide, and at a lower energy consumption, then it may be worth it. If you could reuse it over and over again, and the durability is higher because of the gold, that's a check in the plus column."