Endometrial stem cells could repair Parkinson”s related brain cell damage

May 7, 2010 By Leave a Comment

Washington, May 7 (ANI): In a study on mice, researchers found that stem cells derived from the endometrium (uterine lining) could repair brain cells damaged by Parkinson”s disease, according to Yale School of Medicine researchers.

Although these are preliminary results, the findings increase the likelihood that endometrial tissue could be harvested from women with Parkinson”s disease and used to re-grow brain areas that have been damaged by the disease, according to lead author Dr. Hugh S. Taylor.

Because of their ability to divide into new cell types, stem cells could be the key to treating many different kinds of diseases, like Parkinson”s, in which the body”s own cells are damaged or depleted.

Parkinson”s is caused by a breakdown of dopamine-producing nerve cells in the brain stem. Dopamine is a neurotransmitter that stimulates the motor neurons that in turn control muscles.

When dopamine production is reduced, the nerves fail to control movement or maintain coordination.

In their study, the researchers collected and cultured endometrial tissue from nine women, and verified that they could be transformed into dopamine-producing nerve cells like those in the brain.

“The dopamine levels in the mice increased once we transferred the endometrial stem cells into their brains. This is encouraging because women have a ready supply of stem cells that are easily obtained, can differentiate into other cell types. They may have great potential for treating multiple diseases,” said Taylor.

Highlighting the benefits of using endometrial stem cells, Taylor said the ethical concerns surrounding the use of embryonic stem cells are eliminated when using adult stem cells.

Taylor also pointed out that endometrial stem cells are one of the best sources for generating neurons because they appear to be less likely to be rejected than stem cells from other sources.

“This is just the tip of the iceberg of what we will be able to do with these cells. We believe these neurons are only the first of many cell types derived from endometrium that will be used to treat a variety of diseases,” said Taylor.

The findings are published in the Journal of Cellular and Molecular Medicine. (ANI)

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Common drug can function as ‘off switch’ for Parkinson therapy

August 29, 2009 By Leave a Comment

Washington, Aug 29 (ANI): A common antibiotic can act as an “off switch” for a gene therapy that is being developed for Parkinson’s disease, according to a study on rats conducted by University of Florida researchers.

The findings of the study have explained how new, therapeutic genes that have been irrevocably delivered to the human brain to treat Parkinson’s can be controlled if the genes unexpectedly start causing problems.

Meanwhile, in a review of Parkinson treatments, the researchers have said that earlier experiments using growth factors – naturally occurring substances that cause cells to grow and divide – to rescue dying brain cells may have failed because they occurred too late in the course of the disease.

Taken together, the findings have indicated that gene therapy to enable the brain to retain its ability to produce dopamine- a neurotransmitter that falls in critically short supply in Parkinson’s patients- could be safely attempted during earlier stages of the disease with an added likelihood of success.

“We have worked every day for 10 years to design a construct to the gene delivery vector that enhances the safety profile of gene transfer for Parkinson’s disease,” said Ronald Mandel, a professor of neuroscience at UF.

He added: “With that added measure of safety, we believe we can intervene with gene transfer in patients at earlier stages of the disease. We strongly believe that trials to save dopamine-producing connections in patients with Parkinson’s disease have failed because the therapy went into patients who were in the late stages of the disease and who had too few remaining dopamine-producing connections.”

Often patients are given prescriptions for levodopa (L-dopa), which is converted into dopamine by enzymes in the brain. But such treatment is not effective over time, and does nothing to slow the disease’s progression.

In the meantime, trials in the US to treat Parkinson’s involving direct infusion of growth factors or the transplantation of genes that produce growth factors have had limited success, with some side effects.

Mandel’s research group has concentrated on using an adeno-associated virus to engineer brain cells in animal models with genes that can protect dopamine-producing cells, which then do the vital work of producing glial cell line-derived neurotrophic factor (GDNF).

The naturally occurring protein is important for the survival of dopamine-producing neurons during brain development, and a survival factor when given to adults.

For the current study, the researchers engineered the virus with two genes that must act in concert to produce the protein.

But this precise interaction can be inhibited with dietary doxycycline, an antibiotic that is often prescribed in low doses to treat bacterial growth related to acne.

Depending on the amount of the antibiotic, protein production can be reduced or stopped, which would for the first time give medical investigators the ability to regulate gene therapy after the treatment was delivered.

“With this technique, you could adjust the therapy in the patient. That would be extremely helpful because no one is really certain yet what dosage is required for a protective effect in humans. The process is also much more sensitive than we had imagined it would be. GDNF production can be shut down completely with a dose of doxycycline that is much smaller than what is commonly prescribed,” said Fredric P. Manfredsson, a postdoctoral associate in UF’s department of neuroscience.

The researchers used a number of methods to gauge GDNF production, but one was uncommon and involved the novel observation of the rats’ weight.

The scientists found that they could control the rate of weight gain in the rats with dietary doxycycline, which essentially verified they were controlling the GDNF therapy.

The study has been published in the journal Molecular Therapy. (ANI)

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Depressed people less likely to crave for pleasure

August 13, 2009 By Leave a Comment

Washington, Aug 13 (ANI): People, who suffer from anhedonia, a key symptom of depression, are less likely to pursue rewards if there is any need to put an effort to obtain them, according to new study.

The research has indicated that decreased cravings for pleasure may be at the root of a core symptom of major depressive disorder.

The research, led by Vanderbilt psychologists Michael Treadway and David Zald, is contrary to the long-held notion that those suffering from depression lack the ability to enjoy rewards, rather than the desire to seek them.

“This initial study shows that decreased reward processing, which is a core symptom of depression, is specifically related to a reduced willingness to work for a reward,” said Treadway.

Decreased motivation to seek and experience pleasurable experiences, known as anhedonia, is a primary symptom of major depressive disorder. Anhedonia is less responsive to many antidepressants and often persists after other symptoms of depression subside.

But, researchers have always found it difficult to understand the different components of anhedonia- the desire to obtain something pleasurable versus experiencing pleasure-in humans.

“In the last decade and a half, animal models have found that the neurotransmitter dopamine, long known to be involved in reward processing, is involved in craving or motivation, but not necessarily enjoyment. To date, research into reward processing in individuals with anhedonia has focused on enjoyment of rewards, rather than assessing the drive to work for them. We think this task is one of the first to do that,” said Treadway.

For the study, the researchers devised the Effort-Expenditure for Rewards Task, or EEfRT, to explore the role of reduced desire and motivation in individuals reporting symptoms of anhedonia.

EEfRT involved having individuals play a simple video game that gave them a chance to choose between two different tasks, one hard, one difficult, to obtain monetary rewards.

Participants were eligible but not guaranteed to receive money each time they completed a task successfully.

The subjects were told at the beginning of each trial whether they had a high, medium or low probability of winning a prize if they successfully completed the trial.

The researchers found that subjects who reported symptoms consistent with anhedonia where less willing to make choices requiring greater effort in exchange for greater reward, particularly when the rewards were uncertain.

“Consistent with our hypotheses, we found that individuals with self-reported anhedonia made fewer hard-task choices. These findings are consistent with theoretical models linking anhedonia to decreased (dopamine levels),” wrote the authors.

Treadway said: “By addressing the motivational dimension of anhedonia, our findings suggest a plausible theoretical connection between dopamine deficiency and reward processing in depression, which may eventually help us better understand how anhedonia responds to treatment.”

The research was recently published by the online journal PLoS One. (ANI)

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Artificial nerve cells come closer to reality

July 8, 2009 By Leave a Comment

London, July 8 (ANI): Taking a step closer towards the creation of artificial nerve cells, scientists have now found that neurotransmitters can be used to communicate between the nerve cells in the body.

Just like cochlear implants and electrodes, current methods to stimulate nerve signals in the nervous system are based on electrical stimulation.

Cochlear implants are surgically inserted into the cochlea in the inner ear, while electrodes are used directly in the brain.

One problem with this method is that all cell types in the vicinity of the electrode are activated, which gives undesired effects.

But scientists have now used an electrically conducting plastic to create a new type of “delivery electrode” that instead releases the neurotransmitters that brain cells use to communicate naturally.

The technique is beneficial because only neighbouring cells that have receptors for the specific neurotransmitter, and that are thus sensitive to this substance, will be activated.

The scientists have shown that the delivery electrode can be used to control the hearing function in the brains of guinea pigs.

“The ability to deliver exact doses of neurotransmitters opens completely new possibilities for correcting the signalling systems that are faulty in a number of neurological disease conditions,” Nature magazine quoted professor Agneta Richter-Dahlfors, who has led the work, as saying.

Scientists want to continue with the development of a small unit that can be implanted into the body.

The unit could be programmed such that the release of neurotransmitters takes place as often as, or as seldom as, required in order to treat the individual patient.

Research projects that are already under way are targeted towards hearing, epilepsy and Parkinson’s disease.

The technology has been published in an article in Nature Materials. (ANI)

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Scientists identify alcohol-binding site in the brain

June 29, 2009 By Leave a Comment

London, June 29 (ANI): Scientists at the Salk Institute for Biological Studies have a step closer to understanding how alcohol alters the way brain cells work.

The researchers say that they have identified a binding site for alcohol in an ion channel that plays a key role in several brain functions associated with drugs of abuse and seizures.

They believe that their results could lead to the development of novel treatments for alcoholism, drug addiction, and epilepsy.

Ethanol, the alcohol in intoxicating beverages, is known to alter the communication between brain cells.

“There’s been a lot of interest in the field to find out how alcohol acts in the brain,” Nature magazine quoted Dr. Paul A. Slesinger, an associate professor in the Peptide Biology Laboratory at the Salk Institute, as saying.

“One of several views held that ethanol works by interacting directly with ion channel proteins, but there were no studies that visualized the site of association,” added the lead researcher.

He says that his study has shown that alcohols directly interact with a specific nook contained within a channel protein.

According to him, this ion channel plays a key role in several brain functions associated with drugs of abuse and seizures.

In their previous research, Slesinger’s team focused on the neural function of these ion channels, called GIRK channels, which open up during periods of chemical communication between neurons and dampen the signal, creating the equivalent of a short circuit.

“When GIRKs open in response to neurotransmitter activation, potassium ions leak out of the neuron, decreasing neuronal activity,” says UCSD Biology graduate student and first author Prafulla Aryal.

While alcohols have been previously shown to open up GIRK channels, no study ever determined whether this was a direct effect or whether this was the by-product of other molecular changes in the cell.

The researchers say that the identification of the location of a physical alcohol-binding site important for GIRK channel activation could point to new strategies for treating related brain diseases.

They believe that this protein structure may be used to develop a drug that antagonizes the actions of alcohol for the treatment of alcohol dependence.

“(Alternatively) If we could find a novel drug that fits the alcohol-binding site and then activate GIRK channels, this would dampen overall neuronal excitability in the brain and perhaps provide a new tool for treating epilepsy,” says Slesinger.

A research article describing the study has been published in the journal Nature Neuroscience. (ANI)

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Genetic make-up may influence one’s economic decisions

May 6, 2009 By Leave a Comment

Washington, May 6 (ANI): It’s the genetic make-up of a person that determines how he or she would take economic decisions on the basis of whether the options have been framed negatively or positively, according to a study from University College London (UCL).

Decision-making is a complex process, particularly when we are uncertain about outcomes, which in turn depends on whether the options are phrased positively or negatively, known as the “framing effect”.

In earlier research, it was found that the amygdala, an area of the brain known to be involved in processing emotions, becomes active during decisions influenced by the framing effect.

And, in the new study, the researchers have shown that a person’s susceptibility to the framing effect – and the response of their amygdala – could be at least partially influenced by their genetic make-up.

“We know that people from across a variety of cultures are susceptible to biases when making decisions, and that even with training these biases are hard to overcome. This implies that hard-wired genetic influences might play an important role in determining how susceptible different individuals are to the framing effect,” said Dr Jonathan Roiser from the UCL Institute of Cognitive Neuroscience.

They showed that decision-making is affected by variation in the serotonin transporter gene, at a region known as the 5-HTTLPR, which has previously been reported to affect the response of the amygdala and is

The gene is involved in the recycling of serotonin, a neurotransmitter essential for communication between nerve cells.

The researchers analysed two common variants of this gene, known as the “short” and “long” versions and selected thirty healthy volunteers carrying a pair of either of the two variants.

Essentially, those participants with two copies of the short variant were found to be more susceptible to the framing effect.

“This doesn’t mean that people with the short variants are risk takers. In fact, they were risk averse in the ‘gain frame’ whilst risk seeking in the ‘loss frame’, which implies inconsistency in their decision-making,” explained Roiser.

On taking brain images, it was found that participants with two copies of the short genetic variant had greater amygdala responses than their counterparts when making decisions influenced by the frame effect.

They also measured the degree of interaction, or connectivity, between the amygdala and the prefrontal cortex, the brain region most implicated in human intelligence, personality and decision-making

And it was found that while resisting the frame effect, the participants with two copies of the long variant had stronger connectivity between the prefrontal cortex and amygdala, while those with a pair of short variants did not.

“This difference in connectivity is really interesting. It suggests that the volunteers carrying the long variant might regulate automatic emotional responses, which are driven by the amygdala, more efficiently, lessening their vulnerability to the framing effect,” said Roiser.

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

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Scientists identify ‘molecule trio’ that kills neurons in Parkinson’s

May 2, 2009 By Leave a Comment

Washington, Apr 30 (ANI): In a novel study, researchers at Columbia University Medical Centre have identified a trio of molecules that are responsible for killing brain cells in Parkinson’s patients.

They have showed that three molecules – the neurotransmitter dopamine, a calcium channel, and a protein called alpha-synuclein – act together to kill the neurons.

The symptoms of Parkinson’s – including uncontrollable tremors and difficulty in moving arms and legs – are blamed on the loss of neurons from the substantia nigra region of the brain.

“Though the interactions among the three molecules are complex, the flip side is that we now see that there are many options available to rescue the cells,” said Dr Eugene Mosharov, associate research scientist and study’s author.

The researchers showed that neurons die because calcium channels lead to an increase of dopamine inside the cell; excess dopamine then reacts with alpha-synuclein to form inactive complexes; and then the complexes gum up the cell’s ability to dispose of toxic waste that builds up in the cell over time. The waste eventually kills the cell.

The neurons will survive if just one of the three factors is missing, said the researchers.

“It may be possible to save neurons and stop Parkinson’s disease by interfering with just one of the three factors,” Dr. Mosharov added.

The researchers hope that a drug already in clinical trials – which blocks the culprit calcium channel – may work to slow or stop the progression of the disease.

The study is published in journal Neuron. (ANI)

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Novel target for migraine prevention identified

May 2, 2009 By Leave a Comment

Washington, Apr 29 (ANI): Researchers have found a potential target for developing new treatment for acute migraine attacks.

The new research by Addex Pharmaceuticals showed that targeting glutamate receptor ‘mGluR5′, the most common neurotransmitter in the brain, could prevent migraines.

The research team suggest that mGluR5 could play a role in the “migraine circuit,” a positive feedback loop that generates the symptoms of a migraine attack.

During the study, the researchers conducted trials with the help og potential drug candidate ADX10059, a negative mGluR5 allosteric modulator.

It showed efficacy in treating acute migraine attacks and provides evidence that inhibition of this glutamate receptor subtype could play a role in stopping migraine attacks before they start.

In the study involving 129 migraine patients, the researchers found that more patients taking ADX10059 than those taking placebo were pain-free two hours after dosing.

ADX10059 administration yielded better pain improvement at all time points up to two hours after treatment of a migraine attack.

“Medication is available to prevent migraine but these treatments are often secondary uses of the drug and come with potentially limiting side-effects,” said Dr. Peter Goadsby of the UCSF Headache Center.

“New therapies specifically developed for migraine prevention are urgently needed especially for the substantial proportion of migraine sufferers who have frequent attacks and have significant disability in their daily lives.

“Targeting mGluR5 signaling with ADX10059 is an interesting approach that is showing significant promise in early clinical evaluation.

“The clinical trial data for ADX10059 proved the concept that by terminating acute attacks in some patients, mGluR5 inhibition plays a role in migraine pathophysiology.

The study was presented at annual meeting of the American Academy of Neurology. (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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Novel compounds may prove effective against cerebral palsy

February 26, 2009 By Leave a Comment

Washington, Feb 26 (ANI): Researchers at Northwestern University have developed two compounds that may be effective in protecting against cerebral palsy, a condition caused by neurodegeneration that affects body movement and muscle coordination.

“The results were just stunning, absolutely amazing. There was a remarkable difference between animals treated with a small dose of one of our compounds and those that were not,” said Richard B. Silverman, John Evans Professor of Chemistry in the Weinberg College of Arts and Sciences at Northwestern, who led the drug development effort.

The findings suggest that a preventive strategy for cerebral palsy may be feasible for humans in the future.

In the study, researchers found that none of the fetuses born to animals treated with the two compounds died; more than half of those born to untreated animals died.

Eighty-three percent of animals treated with one of the compounds were born normal, with no cerebral palsy characteristics.

Sixty-nine percent of animals treated with the other compound were born normal. There was no sign of toxicity in the treated animals, and their blood pressure was normal.

Cerebral palsy is caused by an injury to the brain before, during or shortly after birth, although it typically is not diagnosed until after the age of one.

The new compounds developed inhibit an enzyme found in brain cells that produces nitric oxide, thus lowering nitric oxide levels.

At normal levels, nitric oxide acts as a neurotransmitter and is important to neuronal functioning, but at high levels it has been shown to damage brain tissue. An overabundance of nitric oxide is believed to play a role in cerebral palsy.

The study has been published online by the journal Annals of Neurology. (ANI)

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Statins may lessen brain function

February 24, 2009 By Leave a Comment

Washington, Feb 24 (ANI): Statins, commonly used to lower cholesterol levels, have been found to adversely affect patients’ brain functions, claim researchers.

Lead researcher Yeon-Kyun Shin, a biophysics professor at Iowa State University has shown that drugs that inhibit the liver from making cholesterol may also keep the brain from making cholesterol, which is vital to efficient brain function.

“If you deprive cholesterol from the brain, then you directly affect the machinery that triggers the release of neurotransmitters,” said Shin.

“Neurotransmitters affect the data-processing and memory functions. In other words-how smart you are and how well you remember things,” he added.

Cholesterol-reducing statin drugs keep the liver from synthesizing cholesterol so less of the substance is carried to the cells. This lowers bad cholesterol, but this function may also harm cognition.

“If you try to lower the cholesterol by taking medicine that is attacking the machinery of cholesterol synthesis in the liver, that medicine goes to the brain too. And then it reduces the synthesis of cholesterol which is necessary in the brain,” said Shin.

During the study, Shin tested the activity of the neurotransmitter-release machinery from brain cells without cholesterol present and measured how well the machinery functioned.

He also included cholesterol in the system and again measured the protein function. Cholesterol increased protein function by five times.

“Our study shows there is a direct link between cholesterol and the neurotransmitter release,” said Shin.

“And we know exactly the molecular mechanics of what happens in the cells. Cholesterol changes the shape of the protein to stimulate thinking and memory,” he added.

The study appears in journal Proceedings of the National Academy of Sciences. (ANI)

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Licorice ingredient may help treat cocaine addiction

February 19, 2009 By Leave a Comment

Washington, Feb 19 (ANI): Researchers in Korea and Pennsylvania have claimed that an ingredient in licorice shows promise as an antidote for the toxic effects of cocaine abuse.

The study has been published in the January 2 issue of ACS’ Journal of Proteome Research, a monthly publication.

In the new study, Meeyul Hwang, Chae Ha Yang, and colleagues note that there is currently no effective medicine for treating cocaine abuse or addiction. Recent animal studies conducted by the researchers show that a licorice ingredient called isoliquiritigenin (ISL) can block the nervous system’s production of dopamine. That neurotransmitter is involved in emotion, movement, and other brain activities.

Cocaine and other addictive drugs stimulate dopamine and help produce the pleasurable and addictive effects. Drugs that block dopamine block this response.

To reach the conclusion, the scientists used rats as model animals to show that rats injected with ISL just prior to cocaine-administration showed 50 percent less of the behavioral effects associated with the illicit drug.

They also showed that ISL injections protected nerve cells in the brain from cocaine-associated damage. (ANI)

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Licorice ingredient may help treat cocaine addiction

February 19, 2009 By Leave a Comment

Washington, Feb 19 (ANI): Researchers in Korea and Pennsylvania have claimed that an ingredient in licorice shows promise as an antidote for the toxic effects of cocaine abuse.

The study has been published in the January 2 issue of ACS’ Journal of Proteome Research, a monthly publication.

In the new study, Meeyul Hwang, Chae Ha Yang, and colleagues note that there is currently no effective medicine for treating cocaine abuse or addiction. Recent animal studies conducted by the researchers show that a licorice ingredient called isoliquiritigenin (ISL) can block the nervous system’s production of dopamine. That neurotransmitter is involved in emotion, movement, and other brain activities.

Cocaine and other addictive drugs stimulate dopamine and help produce the pleasurable and addictive effects. Drugs that block dopamine block this response.

To reach the conclusion, the scientists used rats as model animals to show that rats injected with ISL just prior to cocaine-administration showed 50 percent less of the behavioral effects associated with the illicit drug.

They also showed that ISL injections protected nerve cells in the brain from cocaine-associated damage. (ANI)

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Licorice ingredient may help treat cocaine addiction

February 19, 2009 By Leave a Comment

Washington, Feb 19 (ANI): Researchers in Korea and Pennsylvania have claimed that an ingredient in licorice shows promise as an antidote for the toxic effects of cocaine abuse.

The study has been published in the January 2 issue of ACS’ Journal of Proteome Research, a monthly publication.

In the new study, Meeyul Hwang, Chae Ha Yang, and colleagues note that there is currently no effective medicine for treating cocaine abuse or addiction. Recent animal studies conducted by the researchers show that a licorice ingredient called isoliquiritigenin (ISL) can block the nervous system’s production of dopamine. That neurotransmitter is involved in emotion, movement, and other brain activities.

Cocaine and other addictive drugs stimulate dopamine and help produce the pleasurable and addictive effects. Drugs that block dopamine block this response.

To reach the conclusion, the scientists used rats as model animals to show that rats injected with ISL just prior to cocaine-administration showed 50 percent less of the behavioral effects associated with the illicit drug.

They also showed that ISL injections protected nerve cells in the brain from cocaine-associated damage. (ANI)

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Common respiratory drugs may lead to cognitive decline in elderly

January 27, 2009 By Leave a Comment

Washington, Jan 27 (ANI): Certain drugs used to treat respiratory and gastrointestinal problems may lead to cognitive decline in older adults, says a new study.

During the study, researchers from Yale University Department of Internal Medicine examined the effects of exposure to anticholinergic medications, on over 500 relatively healthy men aged 65 years or older with high blood pressure.

These drugs can affect neurotransmitters in the brain that are important to overall brain function.

The researchers examined the total effects of all medications taken by the patients, both prescription and over-the-counter, that were believed to affect the function of a particular neurotransmitter, acetylcholine.

They found that chronic use of medications with anticholinergic properties may have detrimental effects on memory and the ability to perform daily living tasks, such as shopping and managing finances.

The participants showed deficits in both memory and daily function when they took these medications over the course of a year.

Moreover, the degree of memory difficulty and impairment in daily living tasks also increased proportionally to the total amount of drug exposure.

Study co-author Dr. Ling Han of the Yale University Department of Internal Medicine said that elderly patients may be more vulnerable to these types of medications due to neurological and pharmacokinetical changes related to aging.

“This study extends our previous findings on acute cognitive impairment following recent anticholinergic exposure in older medical inpatients,” said Han.

“Prescribing for older adults who take multiple prescription and over-the-counter medications requires careful attention to minimize the risk of potential harms of the drugs while maximizing their health benefits,” Han added.

This study is published in Journal of the American Geriatrics Society. (ANI)

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Protein that control hormones critical to women’s health found in pituitary gland

January 12, 2009 By Leave a Comment

London, Jan 12 (ANI): Researchers at the University of Wisconsin-Madison have uncovered the location of a protein, called on Syt IV, which regulates hormones critical to women’s health- the pituitary gland.

Scientists found that the “rogue protein,” whose main location and function were unknown until now, is located in a specific area of the pituitary gland.

The puzzling protein acts as control knob and may adjust the release of the two hormones that come almost exclusively from the posterior pituitary: oxytocin, which controls many reproductive functions, and vasopressin, which controls fluid balance.

“The findings raise very interesting possibilities for women’s health, in which rising and falling hormone levels play a key role in many biological processes,” Nature magazine quoted senior author Meyer Jackson, a professor of physiology at the UW-Madison School of Medicine and Public Health (SMPH), as saying.

The research focused on Syt IV, which is a member of the synaptotagmin family of 17 proteins, present in both mice and humans.

Synaptotagmins are usually embedded in the membranes of small sacs, or vesicles, filled with neurotransmitters and hormones within nerve terminals.

At the time when an electrical impulse from one cell reaches a nerve terminal, Syt IV triggers the release of calcium.

Calcium, in its turn triggers the spilling out of the vesicle’s contents – neurotransmitters and hormones – so they can act on other cells.

“Most synaptotagmins are triggering molecules that drive a vesicle’s membrane into the membrane that surrounds a neighboring cell so that chemicals inside the vesicle can come out,” said Jackson.

However, Syt IV is different as it doesn’t bind to calcium and is found only sparsely in most parts of the brain.

But the researchers were shocked a few years ago after they discovered large amounts of it in the posterior pituitary, one of the three primary parts of the gland.
For the study, the researchers conducted high-powered biophysical measurements, and then compared the pituitaries from normal mice and mice in which Syt IV had been knocked out.

It was found that like other members of the synaptotagmin family, Syt IV resides on vesicles. But unlike the others, Syt IV doesn’t trigger neurotransmitter or hormone release.

“It does not simply translate a calcium signal into a command for hormone release. Unlike other synaptotagmins, Syt IV tunes the triggering command and determines whether the same electrical impulse will let a large or small amount of hormone out of the nerve terminal,” said Jackson

This ability to modulate hormone release may have important implications for pregnancy, birth, lactation and the menstrual cycle, all of which are linked to fluctuations in oxytocin levels.

“Any change in the body that entails releasing more or less of this hormone into the bloodstream could well be a result of the brain’s making more or less of this protein,” said Jackson.

He further added that more studies will be needed to better understand the protein.

The study appeared in the recent issue of Nature Neuroscience. (ANI)

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