Alzheimer’s disease drug may treat traumatic brain injury too

July 14, 2009 By Leave a Comment

Washington, July 13 (ANI): A class of drugs used for the treatment of Alzheimer’s Disease (AD) has been found to be effective in treating traumatic brain injury as well, according to researchers from Georgetown University Medical Center (GUMC).

The scientists have found that the destructive cellular pathways activated in AD are also triggered after traumatic brain injury, indicating that a new therapy could successfully treat both conditions.

Now, the researchers are all set to show that deactivating these pathways in part by using a class of AD drug, called gamma secretase inhibitor, could reduce loss of neurons in animal models of traumatic brain injury.

The drug also protected the animals against motor and cognitive deficits.

“The goal for both diseases is to prevent neuronal cell death, and this study suggests that one therapy could possibly work for both,” said the study’s lead author, neuroscientist Dr. Mark Burns.

Both disorders are associated with build-up of beta amyloid, a toxic brain peptide.

Burns says that build-up of beta amyloid occurs in a second wave of damage that follows immediate “necrotic” death of nerve cells after traumatic brain injury.

This secondary injury can last months, if not years, resulting in large holes within brain tissue.

Amyloid peptides are produced when a long brain protein known as the amyloid precursor protein (APP) is cut in two by the enzyme beta secretase, and then cut once again by a second enzyme known as gamma secretase.

Agents that inhibit the activity of gamma secretase are now being studied as treatment for Alzheimer’s disease.

In the study, researchers used mice that were either treated with DAPT, an experimental gamma secretase inhibitor, or mice which were “BACE knock-outs” -genetically altered in such a way that they could not produce beta secretase.

It was found that DAPT and BACE knockout mice had brain lesions that were as much as 70 percent smaller than control animals and they experienced minimal impairment.

Burns said that the findings further cement the connection between Alzheimer’s disease and traumatic brain injury.

In addition, the study showed that “modulation of beta and gamma secretase may provide novel therapeutic targets for the treatment of traumatic brain injury.”

The findings of the study will be presented at the Alzheimer’s Association 2009 International Conference on Alzheimer’s Disease. (ANI)

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How meningococcal bacteria break through body’s natural defence mechanism

May 14, 2009 By 1 Comment

Washington, May 14 (ANI): Scientists at The University of Nottingham claim to have discovered how the deadly meningococcal bacteria avoid the body’s natural defence mechanism and attack the brain.

Their work attains significance because it may pave the way for better treatment and vaccines for meningitis, and eventually save the lives of hundreds of children.

Bacterial meningitis in childhood is almost exclusively caused by the respiratory tract pathogens Streptococcus pneumoniae, Neisseria meningitidis, and Haemophilus influenzae.

Scientists struggled to understand the mechanism used by these lethal germs to break through the blood brain barrier until the current study.

Lead researcher Dlawer Ala’Aldeen, Professor of Clinical Microbiology and Head of the Molecular Bacteriology and Immunology Group at the Centre for Biomolecular Sciences, says that the research team’s discovery shows that all three pathogens target the same receptor on human cerebrovascular endothelial cells – the specialised filtering system that protects our brain from disease – to enable the organisms to cross the blood-brain barrier.

The researcher says that these findings suggest that disruption or modulation of this interaction of bacterial adhesins with the receptor might offer unexpectedly broad protection against bacterial meningitis, and may provide a therapeutic target for the prevention and treatment of disease.

Professor Ala’Aldeen, who has been studying meningitis and its causes for over 20 years, said: “This is a significant breakthrough which will help us design novel strategies for the prevention and treatment of bacterial meningitis.

Identification of the human receptor and bacterial ligands is like identifying a mysterious key and its lock, which will open new doors and pave the way for new discoveries.”

The research was carried out in collaboration with the Department of Infectious Diseases at St. Jude Children’s Research Hospital in Memphis Tennessee.

It involved students from the University who have been regular and willing volunteers in the research programme.

Professor Ala’Aldeen said: “The ultimate aim is to save lives by protecting the healthy and curing the sick. We are one step closer to new breakthroughs that would prevent disease or its complications. There still is a long way to go before we have the ultimate vaccine and the ultimate treatment of bacterial meningitis.”

The findings of the study have been published in The Journal of Clinical Investigation. (ANI)

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Scientists reveal new way to make narrower chip patterns

April 12, 2009 By Leave a Comment

Washington, April 12 (ANI): An Indian-origin researchers at the Massachusetts Institute of Technology (MIT) has come up with a new way for etching extremely narrow lines on a microchip by exposing it to certain wavelengths of light.

Research engineer Rajesh Menon and his colleagues call the new technique absorbance modulation.

The researchers say that this technique makes it possible to create lines that are only about one-tenth as wide as the wavelength of light used to create them.

They say that part of the trick was to find a suitable photochromic material whose clear and opaque parts would remain stable after the initial exposure to light.

The research team have revealed that this method has thus far enabled them to produce lines just 36 nanometres wide, and that they could also place many such lines spaced a similar distance apart.

Menon believes that such a technique “could have a significant impact on chip making,” and also help enable new work in a variety of emerging fields that rely on nano-scale patterning, including nanophotonics, nanofluidics, nanoelectronics, and nano-biological systems.

He expects the commercial production of this technology will begin within five years.

His team are pursuing possible use of the same system for imaging systems, which could enable new kinds of microscopes for observing at nanoscale resolution, with possible applications in biology and in materials science.

The researchers are even pursuing ways of using the technique to create even smaller patterns, down to the scale of individual molecules.

A research article on the novel technique has been published in the journal Science. (ANI)

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How the brain processes important information

April 3, 2009 By Leave a Comment

Washington, April 3 (ANI): Scientists at UT Southwestern Medical Center have gained fresh insights into how the neurotransmitter dopamine, which is used by nerve cells to communicate with one another, helps brain cells to process important information.

Studying cells in mice, the researchers have found that this neurotransmitter causes certain brain cells to become more flexible, and changes brain-cell circuitry to process important information differently than mundane information.

“This can help one remember a new, important episode as distinct from any other episode, such as remembering where you parked your car today versus yesterday,” said Dr. Robert Greene, professor of psychiatry at UT Southwestern.

“If we can one day manipulate the way that salient information is processed, we might be able to not only improve learning, but also improve the learning needed to extinguish severe fear responsiveness, such as when a soldier can’t forget emotional war memories associated with post-traumatic stress disorder,” he said.

Given that conditions like addictions and schizophrenia are associated with alterations in dopamine in the brain, the researchers believe that their findings may one day prove helpful in dealing with them.

It is known that dopamine is released in the brain in association with experiencing “important” events and remembering salient acts, such as learning to avoid a hot stove or that a good grade is rewarded.

Dr. Greene said that the current study focused on how dopamine operates on the cells associated with this type of memory formation.

He and his colleagues isolated slices of the hippocampus region of the animals’ brains, and electrically stimulated the cells.

To simulate what happens in the brain in response to a memory-worthy event, they then exposed the cells to a selective dopamine-like neurotransmitter agent and repeated the stimulation.

When the researchers compared the effects of the stimulation with and without the dopamine agent, they identified changes in the responses of NMDA receptors, proteins that mediate synaptic plasticity when activated.

“The NMDA responses changed to increase the cells’ plasticity, and we think that this facilitates learning and memory,” Dr. Greene said.

Besides that, according to the researchers, the changes in NMDA responses to dopamine agents changed the functional circuitry of the cells, making the cells more responsive to electrical impulses coming from an indirect route through three processing “stations” before they reached the output region of the hippocampus.

Dr. Greene said that in the absence of dopamine, the cells tend to respond instead to impulses travelling by a route that is more direct and requires less processing.

Information sent by this direct route may reflect what is already known, and is less likely to change the animal’s behaviour.

“While the current study involved isolated mouse brain tissue containing the memory circuits, the human brain likely works the same way,” Dr. Greene said.

“You don’t want to have interference from yesterday. You need to know where you parked your car today, and dopamine may help to ensure that information from today will be remembered as distinct from yesterday,” he added.

He and his colleagues will net study how dopamine modulation affects learning and memory-related behaviour, and exactly how dopamine acts on cells and their circuits.

The current study has been published in the Journal of Neuroscience. (ANI)

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Higher performance electrical and optical integrated circuits come closer to reality

March 20, 2009 By Leave a Comment

Washington, March 20 (ANI): Scientists at the University of Illinois have moved a step closer to realising higher speed electronics and higher performance electrical and optical integrated circuits, for they have successfully created a microwave signal mixer made from a tunnel-junction transistor laser.

The researchers have revealed that their mixing device accepts two electrical inputs, and produces an optical signal that was measured at frequencies of up to 22.7 gigahertz.

They say that the frequency range was limited by the bandwidth of the detector employed in the measurements, not by the transistor device.

“In addition to the usual current-modulation capability, the tunnel junction provides an enhanced means for voltage-controlled modulation of the photon output of the transistor laser. This offers new capabilities and a much greater sensitivity for unique signal-mixing and signal-processing applications,” said Nick Holonyak Jr., a John Bardeen Chair Professor of Electrical and Computer Engineering and Physics.

For making the device, the research team placed a quantum well inside the base region of a transistor laser, and then created a tunnel junction within the collector region.

“Within the transistor laser, the tunnelling process occurs predominantly through a process called photon-assisted absorption,” said Milton Feng, the Holonyak Chair Professor of Electrical and Computer Engineering.

According to Feng, the tunnelling process begins in the quantum well, where electrons and holes combine and generate photons, which are then reabsorbed to create new pairs of electrons and holes used for voltage modulation.

“The tunnel junction makes it possible to annihilate an electron in the quantum well, and then tunnel an electron out to the collector by the tunnel contact,” Feng said.

The transistor output is sensitive to third-terminal voltage control because of the electrons tunneling from the base to the collector, which also creates an efficient supply of holes to the quantum well for recombination.

“We are using the photon internally to modify the electrical operation and make the transistor itself a different device with additional properties,” said Holonyak, who also is a professor in the university’s Center for Advanced Study, one of the highest forms of campus recognition.

According to the researchers, high-speed signal mixing is made possible by the nonlinear coupling of the internal optical field to the base electron-hole recombination, minority carrier emitter-to-collector transport, and the base-to-collector electron tunneling at the collector junction.

The sensitivity of the tunnel-junction transistor laser to voltage control enables the device to be directly modulated by both current and voltage.

The researchers say that this flexibility facilitates the design of new non-linear signal processing devices for improved optical power output.

“The metamorphosis of the transistor is not yet complete. We’re still working on it, and the transistor is still changing,” Holonyak said.

The fabrication and operation of the mixing device has been described in the journal Applied Physics Letters. (ANI)

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Scientists report first time detection of light from transiting exoplanets

January 15, 2009 By Leave a Comment

Washington, Jan 15 (ANI): Scientists have for the first time detected light from transiting exoplanets from ground based telescopes.

Transiting exoplanets are routinely detected when they pass in front of their parent star as viewed from the Earth, which only happens by chance.

The transit event causes a small drop in the observed starlight, which can then be detected.

Fifty-five exoplanets have been detected this way since the observation of the first transiting planet HD 209458 b in 1999.

When the planet revolves around its star or when it goes behind, the light coming from the system also varies, though the resulting smaller modulation is much harder to detect.

This is mostly due to the small amount of light emitted by these exoplanets which are believed to be as dark as coal and reflect little of the incoming starlight.

Fortunately, some of these planets are very hot, thus emitting light, mostly at infrared wavelengths. Up to now, detections of this kind have only been made using the Spitzer infrared space telescope.

Now, two first ground-based detections of thermal emission from transiting, hot-Jupiter exoplanets have been reported from two independent teams of astronomers that used different approaches.

One team includes Ernst De Mooij and Ignas Snellen (University of Leiden, Netherlands) who used the William Hershel 4.2 meter telescope in La Palma (Canary Islands, Spain) to observe the star TrES-3 and its planet TrES-3b.

To be able to detect the light coming from the planet, they observed the planet exactly at the time when it passes behind the star.

They observed the event at infrared wavelengths, where the planet is at its brightest compared to the star.

As they detected the light coming from the planet, they estimated the temperature of its atmosphere to about 2000 Kelvins.

This indicates that the day side of the planet is extremely hot.

The other team, involving David Sing (IAP, France) and Mercedes Lopez-Morales (Carnegie Institution of Washington, USA), had a different approach.

They looked at a much fainter star and its planet, OGLE-TR-56b.

This planet is one of the most irradiated planets known so far, both because the planet is very close to the star and because the star is very hot.

The observed that the planet OGLE-TR-56b is heated so much by its star that it emits detectable amounts of light in the visible wavelengths, and not only in the infrared as TrES-3b does. (ANI)

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