Posturepro: Parkinson #39;s Patient Pre and Post Gait With Postural Insoles
Instability issues severly decreased in a Parkinson #39;s patient with Posturology. Changes in alignment, stability and pain reduction up to 90% were noted in the first consultation. Impressive results have also been seen in the case of serious neurological conditions such as strokes, multiple sclerosis, Parkison #39;s Disease, Cavernous Angioma and Cerebral Palsy. Please contact us at 877.315.8489 or education@posturepro.net http://www.posturepro.netFrom:posturepro1Views:58 3ratingsTime:01:50More inScience Technology

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Posturepro: Parkinson's Patient Pre and Post Gait With Postural Insoles - Video

Parkinson #39;s patients receive focused ultrasound treatment at University of Virginia
Neurosurgeon W. Jeffrey Elias, MD and his team at the University of Virginia are once again charting new territory for focused ultrasound. As a follow-up to their ground-breaking and successful essential tremor pilot clinical trial, they have launched a new study using focused ultrasound to treat patients with tremor-dominant Parkinson #39;s disease. To be eligible for the study, patients must have symptoms that remain disabling despite optimal doses of medication. So far, the study has treated four patients and is expected to enroll 26 more. The trial is following a randomized double-blinded protocol, and patients do not immediately know if they are receiving an actual focused ultrasound treatment or a sham procedure. The randomization process will ultimately assign 20 patients to the study #39;s treatment arm and 10 to the sham group. Three months after-treatment, assignments will be "un-blinded" and sham arm patients will be eligible to crossover into the treatment group. More information about the clinical trial can be found here: http://www.healthsystem.virginia.eduFrom:FUSFoundationViews:19 0ratingsTime:02:34More inScience Technology

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Parkinson's patients receive focused ultrasound treatment at University of Virginia - Video

Parkinson #39;s Disease Protein Causes Disease Spread and Neuron Death in Healthy Animals
Researchers from the Perelman School of Medicine at the University of Pennsylvania have been able to piece together important steps in how Parkinson #39;s disease (PD) spreads from cell to cell and leads to nerve cell death.From:PennInstituteonAgingViews:4 0ratingsTime:03:01More inScience Technology

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Parkinson's Disease Protein Causes Disease Spread and Neuron Death in Healthy Animals - Video

I #39;m Not Going To Tell You Everything Is All Right mdash;A WPC 2013.mov
Poet Gary Turchin explores the lessons and longings of his journey with Parkinson #39;s disease in a frank and spacious poem. Dedicated to all our Parkie brothers and sisters everywhere, and to the World Parkinson #39;s Congress 2013. May your convening be fruitful, important, and fun!From:Gary TurchinViews:13 1ratingsTime:03:30More inNonprofits Activism

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I'm Not Going To Tell You Everything Is All Right—A WPC 2013.mov - Video

Mucuna Formulation No.25813 for Parkinson #39;s Disease: Pankaj Oudhia #39;s Medicinal Plant Database
Mucuna pruriens (L.) DC. Formulations for Parkinson #39;s disease from Pankaj Oudhia #39;s Medicinal Plant Database: Septenary Ingredients Important Septenary Ingredients of Mucuna pruriens (Wild Collection) based Traditional Herbal Formulations used for treatment of Parkinson #39;s disease. In Indian Traditional Healing thousands of Mucuna based Traditional Herbal Formulations are used for treatment of Parkinson #39;s disease. Most of these Herbal Formulations are still waiting for documentation. Pankaj Oudhia has collected information about +40000 promising Formulations during his Ethnobotanical surveys during 1990-2012. Present series is a part of the documentation work. - This video is a part of Compilation of Pankaj Oudhia #39;s Research Works at Indira Gandhi Agricultural University, Raipur, India (1990-2001), - This video is a part of Pankaj Oudhia #39;s report on Indo-African Traditional Healing and Forgotten Herbal Formulations. - This video is a part of Pankaj Oudhia #39;s report on Endangered Species of India. - This video is a part of Pankaj Oudhia #39;s report on Forgotten Herbal Formulations of the World with special reference to Asia. - This video is a part of Pankaj Oudhia #39;s report on North American and European Medicinal Species in Traditional Healing of Asia. - This video is a part of Pankaj Oudhia #39;s series on Forgotten Traditional Formulations for Parkinson #39;s disease. - This video is a part of Pankaj Oudhia #39;s report on Mucuna species in Indian Traditional Healing. - This video is a ...From:Pankaj OudhiaViews:0 0ratingsTime:00:14More inScience Technology

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Mucuna Formulation No.25813 for Parkinson's Disease: Pankaj Oudhia's Medicinal Plant Database - Video

Android Application for Spiral Analysis in Parkinson #39;s Disease
DOTNET PROJECTS,2012 DOTNET PROJECTS,IEEE 2012 PROJECTS,2012 IEEE PROJECTS,IT PROJECTS,ACADEMIC PROJECTS,ENGINEERING PROJECTS,CS PROJECTS,JAVA PROJECTS,APPLICATION PROJECTS,PROJECTS IN MADURAI,ME PROJECTS,M.TECH PROJECTS,MCA PROJECTS,BE PROJECTS,IEEE PROJECTS AT MADURAI,IEEE PROJECTS AT...From:ranjith kumarViews:4 0ratingsTime:00:22More inEducation

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Android Application for Spiral Analysis in Parkinson's Disease - Video

Mucuna Formulation No.25818 for Parkinson #39;s Disease: Pankaj Oudhia #39;s Medicinal Plant Database
Mucuna pruriens (L.) DC. Formulations for Parkinson #39;s disease from Pankaj Oudhia #39;s Medicinal Plant Database: Septenary Ingredients Important Septenary Ingredients of Mucuna pruriens (Wild Collection) based Traditional Herbal Formulations used for treatment of Parkinson #39;s disease. In Indian Traditional Healing thousands of Mucuna based Traditional Herbal Formulations are used for treatment of Parkinson #39;s disease. Most of these Herbal Formulations are still waiting for documentation. Pankaj Oudhia has collected information about +40000 promising Formulations during his Ethnobotanical surveys during 1990-2012. Present series is a part of the documentation work. - This video is a part of Compilation of Pankaj Oudhia #39;s Research Works at Indira Gandhi Agricultural University, Raipur, India (1990-2001), - This video is a part of Pankaj Oudhia #39;s report on Indo-African Traditional Healing and Forgotten Herbal Formulations. - This video is a part of Pankaj Oudhia #39;s report on Endangered Species of India. - This video is a part of Pankaj Oudhia #39;s report on Forgotten Herbal Formulations of the World with special reference to Asia. - This video is a part of Pankaj Oudhia #39;s report on North American and European Medicinal Species in Traditional Healing of Asia. - This video is a part of Pankaj Oudhia #39;s series on Forgotten Traditional Formulations for Parkinson #39;s disease. - This video is a part of Pankaj Oudhia #39;s report on Mucuna species in Indian Traditional Healing. - This video is a ...From:Pankaj OudhiaViews:0 0ratingsTime:00:19More inScience Technology

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Mucuna Formulation No.25818 for Parkinson's Disease: Pankaj Oudhia's Medicinal Plant Database - Video

Mucuna Formulation No.25831 for Parkinson #39;s Disease: Pankaj Oudhia #39;s Medicinal Plant Database
Mucuna pruriens (L.) DC. Formulations for Parkinson #39;s disease from Pankaj Oudhia #39;s Medicinal Plant Database: Septenary Ingredients Important Septenary Ingredients of Mucuna pruriens (Wild Collection) based Traditional Herbal Formulations used for treatment of Parkinson #39;s disease. In Indian Traditional Healing thousands of Mucuna based Traditional Herbal Formulations are used for treatment of Parkinson #39;s disease. Most of these Herbal Formulations are still waiting for documentation. Pankaj Oudhia has collected information about +40000 promising Formulations during his Ethnobotanical surveys during 1990-2012. Present series is a part of the documentation work. - This video is a part of Compilation of Pankaj Oudhia #39;s Research Works at Indira Gandhi Agricultural University, Raipur, India (1990-2001), - This video is a part of Pankaj Oudhia #39;s report on Indo-African Traditional Healing and Forgotten Herbal Formulations. - This video is a part of Pankaj Oudhia #39;s report on Endangered Species of India. - This video is a part of Pankaj Oudhia #39;s report on Forgotten Herbal Formulations of the World with special reference to Asia. - This video is a part of Pankaj Oudhia #39;s report on North American and European Medicinal Species in Traditional Healing of Asia. - This video is a part of Pankaj Oudhia #39;s series on Forgotten Traditional Formulations for Parkinson #39;s disease. - This video is a part of Pankaj Oudhia #39;s report on Mucuna species in Indian Traditional Healing. - This video is a ...From:Pankaj OudhiaViews:0 0ratingsTime:00:13More inScience Technology

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Mucuna Formulation No.25831 for Parkinson's Disease: Pankaj Oudhia's Medicinal Plant Database - Video

Rytary (IPX066): A New Medication for Parkinson #39;s disease, Robert A. Hauser, MD
In this interview, Robert A. Hauser, MD, director of the University of South Florida Byrd Parkinson #39;s Disease and Movement Disorders Center reviews current information on Rytary (IPX066), a new, investigational, extended release formulation of carbidopa/levodopa. To read an article on Rytary (IPX066) click here: http://www.scribd.comFrom:Robert HauserViews:22 0ratingsTime:05:49More inEducation

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Rytary (IPX066): A New Medication for Parkinson's disease, Robert A. Hauser, MD - Video

ScienceDaily (Oct. 24, 2012) Scientists may have discovered why the standard treatment for Parkinson's disease is often effective for only a limited period of time. Their research could lead to a better understanding of many brain disorders, from drug addiction to depression, that share certain signaling molecules involved in modulating brain activity.

A team led by Bernardo Sabatini, Takeda Professor of Neurobiology at Harvard Medical School, used mouse models to study dopamine neurons in the striatum, a region of the brain involved in both movement and learning. In people, these neurons release dopamine, a neurotransmitter that allows us to walk, speak and even type on a keyboard. When those cells die, as they do in Parkinson's patients, so does the ability to easily initiate movement. Current Parkinson's drugs are precursors of dopamine that are then converted into dopamine by cells in the brain.

The flip side of dopamine dearth is dopamine hyperactivity. Heroin, cocaine and amphetamines rev up or mimic dopamine neurons, ultimately reinforcing the learned reward of drug-taking. Other conditions such as obsessive-compulsive disorder, Tourette syndrome and even schizophrenia may also be related to the misregulation of dopamine.

In the October 11 issue of Nature, Sabatini and co-authors Nicolas Tritsch and Jun Ding reported that midbrain dopamine neurons release not only dopamine but also another neurotransmitter called GABA, which lowers neuronal activity. The previously unsuspected presence of GABA could explain why restoring only dopamine could cause initial improvements in Parkinson's patients to eventually wane. And if GABA is made by the same cells that produce other neurotransmitters, such as depression-linked serotonin, similar single-focus treatments could be less successful for the same reason.

"If what we found in the mouse applies to the human, then dopamine's only half the story," said Sabatini.

A detailed view of dopamine neurons.

The surprising GABA story began in the Sabatini lab with a series of experiments designed to see what happens when cells release dopamine. The scientists used optogenetics, a powerful technique that relies on genetic manipulation to selectively sensitize cells to light. In laboratory dishes, researchers tested brain tissue from mice engineered to show activity in dopamine neurons. Typically in such experiments, other neurotransmitters would be blocked in order to highlight dopamine, but Tritsch, a postdoctoral fellow in the Sabatini lab, decided instead to keep the cell in as natural a state as possible.

When Tritsch activated the dopamine neurons and examined their effects on striatal neurons, he naturally expected to observe the effects of dopamine release. Instead, he saw rapid inhibition of the striatal neurons, making it clear that another neurotransmitter -- which turned out to be the quick-acting GABA -- was at work. This was so unusual that the team launched a series of experiments to confirm that GABA was being released directly by these dopamine neurons.

A standard way to detect GABA is to look for vesicular GABA transporter, or VGAT, a protein that packages and carries GABA into neurotransmitter vesicles. The scientists silenced the gene that makes VGAT in mice and found that the dopamine neurons released GABA even in the absence of VGAT.

The researchers then tested other transporters, zeroing in on one that ferries dopamine and a variety of other neurotransmitters. For reasons they don't yet understand, this protein -- the vesicular monoamine transporter -- also shuttles GABA.

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Challenging Parkinson's dogma: Dopamine may not be the only key player in this tragic neurodegenerative disease

Dear Drs. Donohue and Roach My dad, age 77, has just been told he has Parkinson's disease. We, his children, aren't sure of the implications of this for him, our mother or us. Currently, he isn't greatly impaired. He moves more slowly, but his thinking is clear. His hands don't shake.

What can we expect? B.B.

Answer Parkinson's disease, PD, is estimated to affect a million North Americans. It's a difficult illness difficult to have, difficult to treat and difficult to understand. Most of the time, the illness strikes people over the age of 60, and most cases of Parkinson's disease are not inherited.

The underlying problem is a depletion of dopamine, a brain chemical that is vital to smooth, coordinated muscle movement and to thinking. Four prominent signs distinguish this illness. One is tremor, a shaking of the hands when they're at rest, as they are when they're lying in the lap. The index finger and thumb constantly roll over each other. Muscle rigidity is obvious when a doctor tries to move the arms or legs of the patient. They tend to be tightly frozen. Parkinson's patients find it hard to button a shirt or tie shoes. Bradykinesia, slowness of movement, is another sign of PD. Typically, patients walk with slow, shuffling steps. They're quite prone to falls. As times passes, many patients develop trouble with clear thinking.

The treatments for Parkinson's disease are many. Often the first choice is Sinemet, a combination of levodopa and carbidopa. It restores brain dopamine levels. I'll mention some other drugs to give you an idea of available medicines, but I can't elaborate on the way they work space isn't available for that. Amantadine, Artane, Requip and Comtan are but a few of the Parkinson's medicines that can be turned to if Sinemet fails to bring a satisfactory response.

From the time of diagnosis, Parkinson's patients average 10 more years of life.

Dear Drs. Donohue and Roach Doctors, three, told me they thought I had ovarian cancer and that I needed urgent surgery. I was taken to surgery but I didn't have ovarian cancer. I had a dermoid cyst.

How come three doctors, all of whom had me get ultrasounds, couldn't diagnose this without sending me to surgery? N.C.

Answer Dermoid cysts contain cells that belong to skin, hair, oil glands, teeth, muscle, lungs and the digestive tract. Although ultrasound pictures of the ovary are able to furnish an answer on the nature of such a mass, the pictures don't always provide a definitive answer.

Write Drs. Paul Donohue and Keith Roach at P.O. Box 536475, Orlando, Fla. 32853-6475.

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A primer on Parkinson's disease

--Moving Day, A Walk for Parkinson's, to benefit the Parkinson Foundation of the National Capital Area and the National Parkinson Foundation--

WASHINGTON, Oct. 29, 2012 /PRNewswire-USNewswire/ --The National Parkinson Foundation (NPF) in partnership with Parkinson Foundation of the National Capital Area (PFNCA) is holding Moving Day, a fundraising walk for Parkinson's disease (PD) in Washington, D.C. Moving Day will be held at Nationals Park on Sunday, November 4th with gates opening at 8:30 AM. The money the local community raises through Moving Day will help improve the lives of Parkinson's patients and families affected by the disease in the greater D.C. area.

Each walk will feature a "Movement Pavilion," with activities such as yoga, Pilates, Tai Chi, dance and much more. Studies show that movement is beneficial and proven to help manage the symptoms of PD, improving flexibility and mobility. The aim is to encourage people to stay active and move for better health.

Katie Couric joined Moving Day last year as honorary national chair to help spread awareness about the disease and promote NPF's goal of generating funds to support needed research for PD. Couric watched her father battle PD for years. "I am proud to be a part of this mission and in doing so, honor my wonderful father, who was a true profile in courage as he soldiered on every day to remain an active and vibrant part of the family he so loved," said Couric.

People who take part in Moving Day become part of a nationwide movement to beat Parkinson's by supporting education and outreach, cutting-edge research aimed at better treatment and care, advancement of clinical care through healthcare professional training and raising general awareness about the disease.

Almost everyone is touched by Parkinson's in one way or another with an estimated 1 million people in the United States living with the disease. To learn more about Moving Day Washington, D.C. and how you, your family and friends can get involved, please visit http://www.movingdaydc.org.

About Parkinson's DiseaseParkinson's disease is a neurodegenerative brain disorder that progresses slowly in most people with PD. When 60 to 80 percent of the dopamine-producing cells in the brain are damaged, and do not produce enough dopamine, the motor symptoms of Parkinson's disease appear. In the United States, 50-60,000 new cases are diagnosed each year, adding to the 1 million people who have Parkinson's disease. It is estimated that 4 to 6 million people around the world have Parkinson's.

About The National Parkinson Foundation (NPF)Founded in 1957, NPF's mission is to improve the quality of care for people with Parkinson's disease. NPF has funded more than $164 million in care, research and support services. For more information about NPF and the Moving Day event, please visit http://www.parkinson.org or call toll-free 1-800-4PD-INFO (473-4636).

About Parkinson Foundation of the National Capital Area (PFNCA)PFNCA is the largest local provider of support, education and exercise programs for Parkinson's patients and their loved ones. Exercise, Dance, Yoga, Pilates, Choir and Aerobics classes are available every week and there is no charge for Parkinson's community members to participate. Connect with us by calling 703-734-1017 or visit http://www.parkinsonfoundation.org.

Contact: Lou Nistler Executive Director Parkinson Foundation of the National Capital Area lnistler@parkinsonfoundation.org 703-734-1017

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It's Time for Washington, D.C. To Get "Moving" For Parkinson's Disease

A research project underway at Lund University and funded by the Michael J. Fox Foundation will use optogenetics to monitor the effectiveness of transplanted cells in combating the effects of Parkinson's disease, the latest step in the use of the technique to study this condition.

The team led by Merab Kokaia proposes to take human skin cells and modify them to act as nerve cells, a "reprogramming" step known as transdifferentiation and which involves introducing new foreign genes into the cell.

Each cell will also be equipped with genes for a light-sensitive protein, which allows them to react when irradiated with light, in this case blue light from a laser or LED supplied via optical fiber. This responsiveness, and the ability to target it onto specific cells of interest, is the basis of optogenetics.

Once prepared, the cells will be transplanted into the brains of laboratory rats modeling Parkinson's disease.

"This is the first time such an approach is going to be used," said Kokaia. "If we get signals from the host brain as a response to light, we know that they come from the transplanted cells since they are the only ones to carry the light-sensitive protein. This gives us a much more specific way of studying the brain's reactions compared to inserting an electrode, which is the current method. With an electrode, we do not know whether the electric signals that are detected come from 'new' or 'old' brain cells."

Dopamine release One particular goal is to investigate more fully the factors affecting the release of dopamine, a chemical responsible for transmitting the signals within the brain that allow for coordination of movement, and one therefore of keen interest to researchers hoping to understand Parkinson's disease.

"The principle is that optogenetic stimulation or activation of the cells would increase release of dopamine from these cells," Kokaia commented to Optics.org. "Dopamine is the main neurotransmitter that is in short supply in Parkinson's disease, since the cells producing dopamine die. Our idea is to transform cells derived from human skin into neurons that can produce dopamine, and then use optogenetics to try to increase dopamine release from these transplanted cells."

Although this ambition might still be some way off, Kokaia believes that the approach is a sound one as a route to tackle the disease. "We know that this is long term research, but the methodology is interesting and it will be exciting to see what we can come up with," he said.

The Michael J. Fox Foundation agrees, and has provided a grant of $75,000 to the project. Established by actor Michael J. Fox in 2000, the Foundation has invested over $300 million towards combating Parkinson's disease, and is said to be the largest private funder of research into the condition in the world.

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Optogenetics assists in fight against Parkinson's disease

Public release date: 24-Oct-2012 [ | E-mail | Share ]

Contact: Marla Paul marla-paul@northwestern.edu 312-503-8928 Northwestern University

CHICAGO --- In an early-stage breakthrough, a team of Northwestern University scientists has developed a new family of compounds that could slow the progression of Parkinsons disease.

Parkinsons, the second most common neurodegenerative disease, is caused by the death of dopamine neurons, resulting in tremors, rigidity and difficulty moving. Current treatments target the symptoms but do not slow the progression of the disease.

The new compounds were developed by Richard B. Silverman, the John Evans Professor of Chemistry at the Weinberg College of Arts and Sciences and inventor of the molecule that became the well-known drug Lyrica, and D. James Surmeier, chair of physiology at Northwestern University Feinberg School of Medicine. Their research was published Oct. 23 in the journal Nature Communications.

The compounds work by slamming the door on an unwelcome and destructive guest -- calcium. The compounds target and shut a relatively rare membrane protein that allows calcium to flood into dopamine neurons. Surmeiers previously published research showed that calcium entry through this protein stresses dopamine neurons, potentially leading to premature aging and death. He also identified the precise protein involved -- the Cav1.3 channel.

These are the first compounds to selectively target this channel, Surmeier said. By shutting down the channel, we should be able to slow the progression of the disease or significantly reduce the risk that anyone would get Parkinsons disease if they take this drug early enough.

Weve developed a molecule that could be an entirely new mechanism for arresting Parkinsons disease, rather than just treating the symptoms, Silverman said.

The compounds work in a similar way to the drugisradipine, which is commercially available FDAapproved for treatment ofhypertension, for which a Phase 2 national clinical trial withParkinson'spatients -- led by Northwestern Medicine neurologist Tanya Simuni,M.D. -- was recentlycompleted. Isradipine studies in Parkinson's disease aremoving forward, but because isradipinewas developed for treatment ofhypertension, it interacts with other channels found in the walls ofbloodvessels. This limits the dose of the drug that can be administered to patientswithParkinson's disease.

The challenge for Silverman was to design new compounds that specifically target this rare Cav1.3 channel, not those that are abundant in blood vessels. He and colleagues first used high-throughput screening to test 60,000 existing compounds, but none did the trick.

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Parkinson's breakthough could slow disease progression

ScienceDaily (Oct. 19, 2012) By reprogramming skin cells from Parkinson's disease patients with a known genetic mutation, researchers at the Salk Institute for Biological Studies have identified damage to neural stem cells as a powerful player in the disease. The findings, reported online October 17th in Nature, may lead to new ways to diagnose and treat the disease.

The scientists found that a common mutation to a gene that produce the enzyme LRRK2, which is responsible for both familial and sporadic cases of Parkinson's disease, deforms the membrane surrounding the nucleus of a neural stem cell. Damaging the nuclear architecture leads to destruction of these powerful cells, as well as their decreased ability to spawn functional neurons, such as the ones that respond to dopamine.

The researchers checked their laboratory findings with brain samples from Parkinson's disease patients and found the same nuclear envelope impairment.

"This discovery helps explain how Parkinson's disease, which has been traditionally associated with loss of neurons that produce dopamine and subsequent motor impairment, could lead to locomotor dysfunction and other common non-motor manifestations, such as depression and anxiety," says Juan Carlos Izpisua Belmonte, a professor in Salk's Gene Expression Laboratory, who led the research team. "Similarly, current clinical trials explore the possibility of neural stem cell transplantation to compensate for dopamine deficits. Our work provides the platform for similar trials by using patient-specific corrected cells. It identifies degeneration of the nucleus as a previously unknown player in Parkinson's."

Although the researchers say that they don't yet know whether these nuclear aberrations cause Parkinson's disease or are a consequence of it, they say the discovery could offer clues about potential new therapeutic approaches.

For example, they were able to use targeted gene-editing technologies to correct the mutation in patient's nuclear stem cells. This genetic correction repaired the disorganization of the nuclear envelope, and improved overall survival and functioning of the neural stem cells.

They were also able to chemically inhibit damage to the nucleus, producing the same results seen with genetic correction. "This opens the door for drug treatment of Parkinson's disease patients who have this genetic mutation," says Belmonte.

The new finding may also help clinicians better diagnose this form of Parkinson's disease, he adds. "Due to the striking appearance in patient samples, nuclear deformation parameters could add to the pool of diagnostic features for Parkinson's disease," he says.

The research team, which included scientists from China, Spain, and the University of California, San Diego, and Scripps Research Institute, made their discoveries using human induced pluripotent stem cells (iPSCs). These cells are similar to natural stem cells, such as embryonic stem cells, except that they are derived from adult cells. While generation of these cells has raised expectations within the biomedical community due to their transplant potential -- the idea that they could morph into tissue that needs to be replaced -- they also provide exceptional research opportunities, says Belmonte.

"We can model disease using these cells in ways that are not possible using traditional research methods, such as established cell lines, primary cultures and animal models," he says.

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Key player in Parkinson's disease neuron loss pinpointed

/sci-tech/article/45157

A team of scientists at Northwestern University have discovered what might slow the progression of Parkinson's disease. This compound was developed by Richard B. Silverman at the Weinberg College of Arts and Sciences and creator of the molecule that became the drug Lyrica.

This compound or rather the family of compounds work by blocking calcium flow in the brains neurons. The main mechanism is the suppression of a membrane protein, which allows calcium to flow into the dopamine neurons. With this membrane protein blocking calcium flow into the dopaime neuron it avoids further cell damage.

D. James Surmeier, the chair of physiology at Northwestern previously published research which showed that calcium entry through the protein channel Cav1.3 stresses the dopamine neurons which could potentially lead to premature aging and death. The research team at Northwestern has previously published research showing how calcium entry through the protein channel Cav1.3 stresses the dopamine neurons, which has been shown to lead to premature aging and death.

"We've developed a molecule that could be an entirely new mechanism for arresting Parkinson's disease, rather than just treating the symptoms," Silverman explained.

A Phase 2 national clinical trail with Parkinson's patients was led by Northwestern Medicine neurologist Tanya Simuni, M.D. The new compound works in a similar way as the drug Isradipine (A calcium channel blocker used to reduce risk of stroke and heart attack). However Irasdiphine interacts with other channels found in the walls of blood vessels and Isradipine can not be used in a high enough concentration to be effective against Parkinson's.

One challenge for Silverman was in creating a new compound that would specifically target the rare Cav1.3 channel. He and his colleagues did a high-throughput screening to test 60,000 existing compounds, none of which did what Silverman required. Subsequently, Silverman looked at compounds he had developed for other neurodegenerative diseases and identified one compound he believed had promise. Soosung Kang, a postdoctoral associate in Silverman's lab was tasked with refining the molecules until they where able to only shut the Cav1.3. It took Mr. Kang 9 months to finally succeed.

"The drug relived the stress on the cells," Surmeier said. "We have a long way to go before we are ready to give this drug, or a reasonable facsimile, to humans, but we are very encouraged,"

The next step for the Northwestern team is to improve the pharmacology of the compounds to make them suitable for human use and eventually move to Phase 1 clinical trials.

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Slowing Down Parkinson's

TORONTO, ONTARIO--(Marketwire - Oct 29, 2012) - Cynapsus Therapeutics Inc. (TSX VENTURE:CTH) today announced that its APL-130277 for Parkinson''s was recognized as one of the Top Ten Neurology Projectsto Watch in 2012 by a joint selection committee including Dr. Harry Tracy, a noted authority on pharmacological interventions for diseases of the brain and editor of the highly respected biotechnology publication NeuroPerspective, as well as with Elsevier Business Intelligence, the publishers of In Vivo, Startup and The Pink Sheet.Cynapsus has been invited to present the APL-130277 Project at Elsevier''s Therapeutic Area Partnerships Meeting taking place on November 28-30, 2012 at the Westin Copley in Boston.

Criteria for selection of the Top 10 Neurology Projects to Watch in 2012 were:

APL130277 is a unique and innovative, sublingual thin film strip formulation of apomorphine. Apomorphine is an approved drug prescribed in the US, Europe and several other countries. It is administered as a subcutaneous injection or infusion to Parkinson''s patients experiencing daily "OFF" or motor fluctuation episodes. APL130277 would provide patients with a convenient and more tolerable alternative to multiple daily injections. As a new means of delivering an approved drug, this clinical stage project is expected to follow a bioequivalence regulatory and clinical path which would culminate in a New Drug Approval application in 2015.

"We are humbled to be recognized from among several hundred worthy neuroscience projects, worldwide. This is a significant honor and further independent validation of the potential of APL-130277. This comes only a few months after receiving a significant grant from The Michael J. Fox Foundation for Parkinson''s Research (MJFF) to help support our next clinical study (CTH103). The MJFF Clinical Intervention Award was provided through the Edmond J. Safra Core Programs for Parkinson''s Research," said Mr. Anthony Giovinazzo, President and Chief Executive Officer of Cynapsus."Since we started this project, we determined that there are a large number of Parkinson''s patients who would benefit from needle-free delivery of the drug.This includes patients who want a convenient alternative to a very painful injection regimen, patients who have resisted initiating therapy because of the needle issues, and the increase in PD population as a result of the growing aging baby boomer generation. These factors combined indicate that the number of Parkinson''s patients worldwide could potentially increase 2-to-3 fold over the next 8 to 10 years. This significant potential unmet medical need coupled with a short and lower risk clinical pathway would be of interest to many in global and specialty pharma, especially given that our pending patent estate, when approved and granted, would provide protection to 2031 at a minimum."

About Parkinson''s Disease

Parkinson''s disease is a chronic, degenerative neurological disorder that results from the loss of dopamineproducing nerve cells in the brain. Currenttreatments for Parkinson''s disease are able to reduce the symptoms of the disease but are not able to treat the underlying neurodegenerative processes that lead to a decline in physical and cognitive functions that affects some patients with Parkinson''s disease. It is estimated that over one million people in the United States and 5 million people globally are living with Parkinson''s disease. According to the National Institute of Neurodegenerative Disease and Stroke, the average age of onset is 60, although some people are diagnosed at age 40 or younger.

About Cynapsus Therapeutics

Cynapsus is a specialty pharmaceutical company developing the only orally administered convenient (sublingual) delivery of the only approved drug (apomorphine) to treat the motor symptoms of Parkinson''s disease. Over one million people in the United States and an estimated 5 million people globally suffer from Parkinson''s disease. Parkinson''s disease is a chronic and progressive neurodegenerative disease that impacts motor activity, and its prevalence is increasing with the aging of the population. Based on the IMPACT Registry Study and the results of Cynapsus'' Global 500 Neurologists Survey, is estimated that between 25 percent and 50 percent of patients experience "OFF episodes" in which they have impaired movement or speaking capabilities. Current medications only control the disease''s symptoms, and most drugs become less effective over time as the disease progresses.

Cynapsus'' lead drug candidate, APL130277, is an easytoadminister, fastacting reformulation of an approved drug, apomorphine, used to rescue patients from OFF episodes. Cynapsus is focused on rapidly maximizing the value of APL130277 by completing pivotal studies in advance of a New Drug Application expected to be submitted in 2015. Cynapsus anticipates outlicensing to an appropriate pharmaceutical partner before such an application is submitted.

More information about Cynapsus (TSX VENTURE:CTH) is available at http://www.cynapsus.ca and at the System for Electronic Document Analysis and Retrieval (SEDAR) at http://www.sedar.com.

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Cynapsus Therapeutics' APL 130277 for Parkinson's Chosen As One Of The Top Ten Neurology Projects To Watch For 2012

Pilot Study in Neurosurgery Shows Safety and Benefits of Extradural Stimulation

Newswise Philadelphia, Pa. (October 16, 2012) Electrical stimulation using extradural electrodesplaced underneath the skull but not implanted in the brainis a safe approach with meaningful benefits for patients with Parkinson's disease, reports the October issue of Neurosurgery, official journal of the Congress of Neurological Surgeons. The journal is published by Lippincott Williams & Wilkins, a part of Wolters Kluwer Health.

The technique, called extradural motor cortex stimulation (EMCS), may provide a less-invasive alternative to electrical deep brain stimulation (DBS) for some patients with the movement disorder Parkinson's disease. The study was led by Dr. Beatrice Cioni of Catholic University, Rome.

Study Shows Safety and Effectiveness of Extradural Brain Stimulation The researchers evaluated EMCS in nine patients with Parkinson's disease. Over the past decade, DBS using electrodes implanted in specific areas within the brain has become an accepted treatment for Parkinson's disease. In the EMCS technique, a relatively simple surgical procedure is performed to place a strip of four electrodes in an "extradural" locationon top of the tough membrane (dura) lining the brain.

The electrodes were placed over a brain area called the motor cortex, which governs voluntary muscle movements. The study was designed to demonstrate the safety of the EMCS approach, and to provide preliminary information on its effectiveness in relieving the various types of movement abnormalities in Parkinson's disease.

The electrode placement procedure and subsequent electrical stimulation were safe, with no surgical complications or other adverse events. In particular, the patients had no changes in intellectual function or behavior and no seizures or other signs of epilepsy.

Extradural stimulation led to small but significant and lasting improvements in control of voluntary movement. After one year, motor symptoms improved by an average of 13 percent on a standard Parkinson's disease rating scale, while the patient was off medications.

'Remarkable' Improvement in Walking and Related Symptoms The improvement appeared after three to four weeks of electrical stimulation and persisted for a few weeks after stimulation was stopped. In one case where the stimulator was accidentally switched off, it took four weeks before the patient even noticed.

Extradural stimulation was particularly effective in relieving the "axial" symptoms of Parkinson's disease, such as difficulties walking. Patients had significant improvement in walking ability, including fewer problems with "freezing" of gait. The EMCS procedure also reduced tremors and other abnormal movements while improving scores on a quality-of-life questionnaire.

Although DBS is an effective treatment for Parkinson's disease, it's not appropriate for all patients. Some patients have health conditions or old age that would make surgery for electrode placement too risky. Other patientsincluding four of the nine patients in the new studyare eligible for DBS but don't want to undergo electrode placement surgery.

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Less-Invasive Method of Brain Stimulation Helps Patients with Parkinson's Disease

Published: Wednesday, October 17, 2012 at 5:40 p.m. Last Modified: Wednesday, October 17, 2012 at 5:40 p.m.

A decade ago, deep-brain stimulation for Parkinsons disease was considered a risky procedure. Today, its on the cutting edge of personalized medicine, and researchers at the University of Floridas McKnight Brain Institute are at the forefront of its evolution.

When we started in 2002, there were only a handful of places in the U.S. that did it. There was a lot of skepticism about the operation from internists and neurologists, said Dr. Michael Okun, a neurologist at UF. Now it has gone from crazy to cool to completely accepted.

Okun published an article today in the New England Journal of Medicine that explains how the procedure is helping with Parkinsons disease and other neurological conditions such as obsessive compulsive disorder, Tourettes syndrome and depression.

Okun and Dr. Kelly Foote, a neurosurgeon at UF, have performed more than 800 procedures in the past decade, mostly in Parkinsons patients whose medications have become less effective, leading to complications such as on-off fluctuations.

During the off periods, the medication stops working and patients symptoms such as tremors or immobility worsen. This happens in most patients after about five years, said Okun, and patients with off periods of more than three hours a day are good candidates for deep-brain stimulation.

During the procedure, doctors first identify the part of the brain to target. For most patients, that will be either the subthalamic nucleus or the globus pallidus, two tiny sites involved in controlling movement.

Doctors then drill a dime-sized hole in the skull so they can place a lead that delivers electric current to the troublesome spot responsible for the degeneration caused by the disease.

You want to make sure that you take your time and get it right. Those leads have to be within a half-millimeter to work their magic, Okun said.

Deciding where to place the lead also depends on the patient. If you see a patient and tremors are important maybe they are a dentist or a chef, they might choose one target in the brain. If its a singer or trial litigator, they may target another part of the brain.

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UF: Deep-brain stimulation helping with OCD, Tourette's, along with Parkinson's

Newswise BIRMINGHAM, Ala. For decades, patients with Parkinsons disease (PD) have had the same experience. Their hands start to shake uncontrollably, their limbs become rigid and they lose their balance. Years before those movement problems set in, many begin struggling with fainting, incontinence, sexual dysfunction, anxiety and depression. Many patients are still treated with a 42-year-old drug called L-DOPA, which temporarily staves off symptoms but can itself cause heart arrhythmias, stomach bleeding and hallucinations.

This punishing experience may explain in part why patients with PD die at twice the rate of those without the disease in the years after their diagnosis. In this light, its best to tread carefully when talking about early study results that promise something better. That said, a team of researchers at the University of Alabama at Birmingham is excited.

The UAB team has identified a set of experimental drugs called LRRK2 inhibitors that may go beyond symptom relief to directly counter the inflammation and nerve cell death at the root of Parkinsons. At least, these effects have been suggested in mouse and cell culture studies meant to approximate human disease. UAB researchers reported on these findings today in a presentation at Neuroscience 2012, the annual meeting of the Society for Neuroscience in New Orleans.

We dont yet know what percentage of patients might benefit from LRKK2 inhibitors, but LRRK2 is without a doubt the most exciting target for neuroprotection to have ever been identified in Parkinsons disease, says Andrew West, Ph.D., associate professor in the Department of Neurology within the UAB School of Medicine, who gave the presentation at Neuroscience 2012. We will repeat our experiments many times before drawing final conclusions, but our ultimate goal is see our compound or something like it enter toxicology studies, and ultimately, clinical trials as soon as is prudent.

While Wests compounds are promising, they still face many crucial tests that will decide whether or not they reach human trials. But the field is excited, because this is the first time such a drug target has been found for any neurodegenerative disease. Along with evidence that LRRK2 plays a crucial role in the mechanisms of Parkinsons disease, it is a protein kinase, the same kind of enzyme (although not the same one) that has been safely and potently targeted by existing treatments for other diseases, including the cancer drugs Herceptin, Tarceva and Erbitux.

Why LRRK2? LRRK2 stands for leucine-rich repeat kinase 2. Kinases are enzymes that attach molecules called phosphates to other molecules to start, stop or adjust cellular processes. Past studies found that the most common LRRK2 mutation, called G2019S, makes LRRK2 slightly over-active. The idea is to dial LRRK2 back with drugs.

Whether its a bad version of a gene, an unlucky flu infection, a head injury or just age, something makes a protein called alpha-synuclein build up in the nerve cells of Parkinsons patients, contributing to their self-destruction. Unfortunately, alpha-synuclein and proteins like it are not part of a traditional set of drug-able targets. Once alpha-synuclein builds up, the question becomes whether the brain will handle it well or amplify the disease.

LRRK2, to Wests mind, is a critical decision-maker in the bodys answer to that question. He thinks it operates at the intersection between alpha-synuclein, neurotransmission and immune responses, which fight infectious diseases but also create disease-related inflammation when unleashed at the wrong moment, or in the wrong place or amount. Not everyone who has a LRRK2 mutation develops the disease, but Wests team thinks it becomes important when combined with other factors.

Past studies have shown that alpha-synuclein build-up in nerve cells activates nearby immune cells of the brain called microglia, and that these microglia express high levels of LRRK2. Recent cell studies in Wests lab suggest that mutated, overactive LRRK2 strengthens inflammatory responses in microglia and that inhibiting LRRK2 reduces them. Preliminary data also suggests LRRK2-driven inflammation raises the rate of nerve cell death. Its worth noting, however, that neither these mechanisms nor their relationships with each other and Parkinsons disease have been fully confirmed.

The beauty is that we dont necessarily need to confirm an exact mechanism to move drugs into clinical trials, says West. One could argue that human PD is too complex to fully model in other animals. Many predict that we will not know if we understand Parkinsons disease until we get safe, potent, specific drugs into human studies and until one of them halts or reverses the disease process.

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UAB Team Sets Sights on Neuroprotective Treatment for Parkinson's Disease