Researchers identify promising new drug treatment for cocaine addiction

A team of researchers led by Cardiff University has discovered a promising new drug treatment for cocaine addiction.

The experimental therapy, which involves administering a drug currently used in cancer therapy trials, treats cocaine addiction by inhibiting memories responsible for cravings.

Professor Riccardo Brambilla from Cardiff University's School of Biosciences said: "We have demonstrated that a single administration of a trial drug from the pharmacompany Pfizer can completely obliterate cocaine associated memories and significantly accelerate the end of drug seeking behaviour in animals. With this drug currently being used in cancer trials, it could be easily repositioned for treatment of cocaine addiction and other drugs of abuse."

Cocaine produces its addictive effects partially by acting on the brain's limbic system - a set of interconnected regions that regulate pleasure and motivation. When a person uses cocaine, memories of the intense pleasure felt and the things associated with it are newly created. It is these long lasting memories and drug-associated cues, key to the transition from recreational drug taking to compulsive drug use, which the new treatment inhibited when tested on mice.

Dr Stefania Fasano from Cardiff University added, "With drug use recently on the rise, new treatments for breaking addiction are much needed. The availability of a powerful drug from Pfizer, already validated in humans, could speed up the clinical development of our findings."

The research is published in the journal eLife.

This was an experimental study in mice, which allows for conclusions to be made about cause and effect in this species. To learn about the effect of this treatment in people experimental trials with humans will be necessary.

Ref : https://elifesciences.org/content/5/e17111

Drug that stimulates neuron pruning promotes goal-directed behavior in mice

A drug that stimulates neuron pruning can nudge mice away from habit-driven behaviors when combined with retraining, neuroscientists have found.

The results were published online on November 30 by Nature Communications.

The drug fasudil, approved in Japan for cerebral vasospasm and stroke, inhibits an enzyme that stabilizes cells' internal skeletons. The researchers suggest that fasudil or similar compounds could be effective tools for facilitating the treatment of drug abuse and preventing relapse.

A large fraction of the actions people perform each day come from habits, not from deliberate decision making. Going on auto-pilot can free up attention for new things, but it can also be detrimental, in the case of drug abuse and drug-seeking behavior, says lead author Shannon Gourley, PhD, assistant professor of pediatrics, psychiatry and behavioral sciences at Emory University School of Medicine and Yerkes National Primate Research Center.

"Some habits are adaptive - for example, turning off a light when you exit a room - but others can be maladaptive, for example in the case of habitual drug use. We wanted to try to figure out a way to help 'break' habits, particularly those related to the highly-addictive drug cocaine," says Gourley.

Gourley and former graduate students Andrew Swanson, PhD and Lauren Depoy, PhD tested fasudil in situations where they had trained mice to poke their noses in two chambers, based on rewards of both food and cocaine. Then the researchers changed the rules of the game. The mice had to learn something new, in terms of where to poke their noses to get the reward.

In particular, the mice could now only get a reward from one chamber instead of both. Fasudil helped the mice adjust and display "goal-directed" behavior, rather than their previous habit-based behavior.

In addition, the researchers trained the mice to supply themselves a sweet cocaine solution. Then they changed the nature of that experience: the cocaine was paired with lithium chloride, which made the mice feel sick. Fasudil treatment nudged the mice to give themselves less cocaine afterwards, rather than continuing to respond habitually. The scientists envision this as modeling negative experiences associated with cocaine use in humans.

"Humans may seek treatment due to the negative consequences of cocaine abuse, but many people still relapse. We're trying to strengthen the goal of abstaining from drug taking," says Gourley.

The researchers conducted additional experiments that revealed that fasudil didn't make cocaine itself less pleasurable, but was specifically modifying the habit process. Also, fasudil did not affect other forms of decision making.

Un-learning of habits involves remodeling connections made by cells in the brain. In the mouse retraining experiments, the way that fasudil seems to work is that it promotes the pruning of dendritic spines. Dendritic spines are structures that help neurons communicate and embody the strength of connections between them.

Fasudil inhibits Rho kinase, which stabilizes F-actin, a major component of cells' internal skeletons. Thus, it loosens up cell structures. And in mice, fasudil appears to slightly reduce the density of dendritic spines in a region of the brain that is important for learning new behaviors.

"In this context, we imagine that fasudil is optimizing signal-to-noise, so to speak, allowing this brain region to efficiently guide decision making," says Gourley.

When fasudil is given to the mice a day after training, no changes in spine density are seen, indicating that it must be paired with new learning to have that effect.

Some caution is order, because overactive synaptic pruning is proposed to play roles in Alzheimer's disease and schizophrenia. In their paper, the authors conclude:

Pairing Rho kinase inhibitors with cognitive behavioral therapy in humans could be an effective pharmacological adjunct to reduce the rate of relapse... Given its favorable safety profile and our evidence that it can mitigate cocaine self-administration, fasudil is a strong candidate, with the caveats that we envision it administered as an adjunct to behavioral therapy and potentially during early phases of drug withdrawal.

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Drug that stimulates neuron pruning promotes goal-directed behavior in mice

FDA Approves Numbrino (cocaine hydrochloride) Nasal Solution for Nasal Anesthesia

In continuation of my update on Cocaine

Lannett Company, Inc. (NYSE: LCI),  announced that the U.S. Food and Drug Administration (FDA) has approved the New Drug Application (NDA), submitted under the 505(b)(2) regulatory pathway, for Cocaine Hydrochloride (HCl) Nasal Solution 4% (40 mg/mL), the company's branded local anesthetic product.Lannett Company, Inc. (NYSE: LCI) today announced that the U.S. Food and Drug Administration (FDA) has approved the New Drug Application (NDA), submitted under the 505(b)(2) regulatory pathway, for Cocaine Hydrochloride (HCl) Nasal Solution 4% (40 mg/mL), the company's branded local anesthetic product.

"The FDA's approval of our Cocaine HCl product, the first NDA approval to include full clinical trials in the company's history, marks a major milestone in Lannett's 70+ years of operations," said Tim Crew, chief executive officer of Lannett. "We believe the product has the potential to be an excellent option for the labeled indication. We expect to launch the product shortly, under the brand name Numbrino®."

Numbrino® (cocaine hydrochloride) nasal solution is an ester local anesthetic indicated for the introduction of local anesthesia of the mucous membranes for diagnostic procedures and surgeries on or through the nasal cavities of adults. The 505(b)(2) NDA submission was supported by two Phase III, randomized, double-blind, placebo-controlled, multicenter studies in several hundred patients, as well as a Phase I pharmacokinetic study.

About Lannett Company, Inc.:

Lannett Company, founded in 1942, develops, manufactures, packages, markets and distributes generic pharmaceutical products for a wide range of medical indications. For more information, visit the company's website at www.lannett.com.

This news release contains certain statements of a forward-looking nature relating to future events or future business performance.  Any such statement, including, but not limited to, successfully commercializing Numbrino®, whether expressed or implied, is subject to market and other conditions, and subject to risks and uncertainties which can cause actual results to differ materially from those currently anticipated due to a number of factors which include, but are not limited to, the risk factors discussed in the Company's Form 10-K and other documents filed with the SEC from time to time, including the prospectus supplement related to the proposed offering to be filed with the SEC.  These forward-looking statements represent the Company's judgment as of the date of this news release.  The Company disclaims any intent or obligation to update these forward-looking statements.

https://en.wikipedia.org/wiki/Cocaine

Methylphenidate facilitates recovery from drug addiction...

A brain-scanning study at the U.S. Department of Energy's (DOE) Brookhaven National Laboratory, conducted with collaborators from Stony Brook University, reveals that an oral dose of methylphenidate, commonly known as Ritalin, improves impaired brain function and enhances cognitive performance in people who are addicted to cocaine.

Researchers were encouraged by the fact that, methylphenidate does decrease behaviors such as risk taking and impulsivity and improves brain function and cognitive performance in a range of other conditions that also affect the brain's prefrontal cortex, including attention deficit hyperactivity disorder (ADHD), some forms of dementia, and certain kinds of brain injury. To begin with Goldstein's (lead researcher)  group performed functional magnetic resonance imaging (fMRI) on 13 cocaine users and 14 healthy control subjects who were asked to perform a cognitive task after being given either a low oral dose of methylphenidate (20 milligrams) or a placebo. The task involved pushing a button to correctly identify the color of a printed word; some words had to do with drug use, others were "neutral." Subjects received monetary rewards for correct answers. The scientists were particularly interested in two parts of the prefrontal cortex previously shown to be impaired during this cognitive activity in cocaine-addicted individuals.

"These regions help to regulate emotion, cognition, and behavior in response to salient stimuli - the things we find particularly interesting or relevant," Goldstein said. "Because drug users have deficits in these regions, they may have less ability to regulate their emotions and exert cognitive control over certain behaviors."

Researchers found that,  compared  with cocaine users given placebos - who (compared to healthy controls) exhibited reduced function in these prefrontal cortex regions - cocaine users given a low dose of methylphenidate had improved brain function such that they were more like the healthy control subjects. The subjects given methylphenidate were also less likely to make "errors of commission" (pressing a button incorrectly or prematurely), a measure of impulsivity, while performing the cognitive task than subjects given a placebo. Furthermore, the greater the improvement in task accuracy with methylphenidate, the larger the increase in fMRI signal in the prefrontal cortex regions of interest, showing that the improvements in brain function were directly related to improved cognitive performance.

Though future studies need to evaluate whether these results can be generalized to other tasks or activities that involve these specific brain regions, but these results do suggest that by enhancing prefrontal cortex function and associated cognitive performance - particularly the decrease in impulsivity - methylphenidate could help to improve clinical outcomes in people seeking to overcome drug addiction…

  

 Ref : http://www.pnas.org/content/early/2010/08/30/1011455107.full.pdf+html?sid=be34425f-b8cc-4a90-8929-03aca9f8bbe4

Scientists successfully test anti-alcoholism drug in animal models

Scientists at The University of Texas at Austin have successfully tested in animals a drug that, they say, may one day help block the withdrawal symptoms and cravings that incessantly coax people with alcoholism to drink. If eventually brought to market, it could help the more than 15 million Americans, and many more around the world who suffer from alcoholism stay sober.

If what has been shown to work in worms and rats addicted to alcohol can eventually be demonstrated to work in humans with minimal side effects, it would be a true breakthrough. Scientists point out, however, that the drug has more hoops to go through before that happens.

There are already drugs on the market prescribed to help people break their addiction to alcohol, but for many patients, they are not very effective and have negative side effects. The new drug, called JVW-1034, targets a different molecular pathway in the body and so far, in animal models, has no obvious side effects.

"There's clearly a huge need for something different and better," said James Sahn, research scientist in chemistry at UT Austin and co-first author of a new paper. "That's where our approach shines. It's modulating a pathway that doesn't seem to be associated with any of the other drugs that are available."

The researchers reported their findings in the journal Neuropsychopharmacology and have filed a patent on the drug.

The paper's other co-first authors are Luisa Scott, a research associate in neuroscience at UT Austin; and Antonio Ferragud, a postdoctoral associate at Boston University School of Medicine (BUSM). Senior authors are Stephen Martin, professor of chemistry, and Jonathan Pierce, associate professor of neuroscience, both at UT Austin; and Valentina Sabino, associate professor of pharmacology and psychiatry at BUSM.

While the drug is promising, the researchers plan to optimize its chemical properties to have a better chance of being effective in humans. They envision a pill that could one day be taken to block alcohol withdrawal symptoms and cravings, helping people avoid relapsing. But it isn't clear whether such a drug could actually cure alcoholism. That's because there are genetic and regulatory underpinnings to the disorder that researchers don't fully understand yet and that may not be permanently altered by this drug. But even a drug that could be taken chronically or in times of stress could have a huge benefit for people suffering from alcoholism.

"If we could achieve a medication that is effective for more people and doesn't have the negative side effects that some of these drugs have, that would be game-changing," said Martin.

It might also make a dent in the $250 billion annual cost of alcohol misuse in the U.S., as estimated by a 2015 study.

This work was supported by The Robert A. Welch Foundation, the Dell Medical School's Texas Health Catalyst program, donations from individuals including Tom Calhoon and June Waggoner through a crowdfunding program called Hornraiser, and the National Institute on Alcohol Abuse and Alcoholism.

Screening in Worm and Rat Models

The drug JVW-1034 was named in honor of James Virgil Waggoner, a UT Austin alumnus, businessman and philanthropist who donated funds to establish the university's Waggoner Center for Alcohol and Addiction Research.

It was one of many potential compounds developed in the lab by chemists Stephen Martin and James Sahn, which they suspected would interact with a cell receptor found throughout the central nervous systems of animals, called sigma 2. Other researchers had shown that that receptor was involved in cocaine addiction. So Martin and Sahn wondered whether it might also be involved in alcoholism.

To screen their compounds, their colleague Luisa Scott created hungover worms. She exposed C. elegans worms to alcohol for a day and then took it away. She could tell they were hungover because when she placed a tasty-smelling substance on the other side of their petri dish, they sluggishly meandered over.

"It smells like movie theater popcorn," Scott said. "Normal worms are quite speedy, but withdrawal worms go very slowly."

When she administered JVW-1034 to the hungover worms, they once again raced across the dish just like worms that had never been exposed to alcohol.

In follow-up experiments, Scott demonstrated that the receptor sigma 2 was in fact the target of JVW-1034. This also demonstrated for the first time that sigma 2 is involved in alcohol addiction. She noted that it can be difficult to identify which parts of an animal's cells a drug interacts with. In fact, scientists still don't know the targets of many drugs that have been in use for many years.

"So for me, being able to show that this really is the target it binds to, that's a big deal," she said.

Finally, a group of collaborators led by Valentina Sabino tested JVW-1034 in alcoholic rats. Alcoholic rats that could freely access alcohol and were then given JVW-1034 dramatically reduced their alcohol consumption.

The researchers are developing several other promising drugs that target the sigma 2 receptor to treat other neurological disorders, including traumatic brain injury, neuropathic pain and Alzheimer's disease.

Intriguing small molecule directs activity of key ‘clock proteins’

In research published in Nature Communications, Thomas Burris, Ph.D., chair of pharmacological and physiological science at Saint Louis University, reports intriguing findings about a small molecule that directs the activity of key "clock proteins," offering the potential to manage circadian rhythm and treat problems that are associated with its dysfunction, like sleep and anxiety disorders.

 

Circadian rhythm refers to biological processes that cycle every 24 hours. In mammals, the internal clock that maintains circadian rhythm is essential for normal physiological functions. The rhythms can, however, be disrupted, and dysregulation of circadian rhythm is associated with many disorders, including metabolic disease and neuropsychiatric disorders including bipolar disorder, anxiety, depression, schizophrenia and sleep disorders.

Burris and his colleagues examined compounds that target a protein called REV-ERB, which appears to play a key role in regulating mammals' internal clocks.

"It has been suggested that REV-ERB is a core component of our clock," said Burris. "Mice without it are arrhythmic. This study demonstrated that when we give mice a synthetic compound that turns REV-ERB on, it altered their circadian rhythm."

The team examined effects of the REV-ERB drug on patterns of sleep and wakefulness and found that the compound increases wakefulness, reduces REM and slow-wave sleep, and, notably, decreases anxiety.

This is an interesting finding because it is unusual. Frequently, drugs that increase arousal (wakefulness) also increase anxiety (ex. cocaine, amphetamines). And, vice versa: Drugs that decrease anxiety also decrease arousal (ex. benzodiazepines and ethanol). An exception to this common pattern is nicotine.

Intriguing small molecule directs activity of key ‘clock proteins’

CGP3466B compound may effectively treat depression

We know that, Omigapil (TCH346 or CGP3466) is a drug that was developed by Novartis and tested in clinical trials for its ability to help treat Parkinson's disease (PD) and amyotrophic lateral sclerosis (ALS). The development for PD and ALS have been terminated due to lack of benefit, but Santhera Pharmaceuticals bought the compound for development for the treatment of congenital muscular dystrophy (CMD). Omigapil was first synthesized at Ciba-Geigy, Basel, Switzerland. Santhera Pharmaceuticals has since taken over production of omigapil and preclinical trials for CMD. In May 2008, omigapil was granted orphan designation to commence clinical trials for. Pharmacokinetic trials are scheduled to commence enrollment in the second half of 2012 to determine the appropriate pharmacokinetic profile of the drug for children with laminin-α2-deficient congenital muscular dystrophy (MDC1A) and collagen VI related myopathy. Santhera Pharmaceuticals will use the phase 1 clinical trial to determine if the drug is safe and acts with the same pharmacokinetic profile in children as it does in adults. The impending clinical trial will take place in the United States at the National Institute of Neurological Disorders and Stroke/National Institute of Health(NNDCS/NINDS) (Bethesda, Maryland) and in the United Kingdom at Great Ormond Street Hospital (UCL

The compound CGP3466B, already proven nontoxic for people, may effectively and rapidly treat depression, according to results of a study in mice. The Johns Hopkins Medicine neuroscientists who conducted the research say that the compound -- previously shown to block cocaine craving in the brains of rodents -- delivers antidepressant effects to mice within hours instead of weeks or months, like currently available antidepressants. The results of the study will be summarized Jan. 12 online in the journal Molecular Psychiatry.

"One of the promising things about CGP3466B is that it targets a new network of proteins," says Solomon Snyder, M.D., professor of neuroscience at the Johns Hopkins University School of Medicine. "That means it may work in patients who are unresponsive to other types of drugs and it lays the foundation for the development of a new class of fast-acting antidepressants that target the same network."

The team's discovery came out of investigations into the workings of a different drug, ketamine, long used primarily at high doses to induce anesthesia during surgery but known, at lower doses, to be a fast-acting antidepressant. Unfortunately, Snyder says, ketamine is addictive and can produce schizophrenialike symptoms, making it unsuitable for prolonged use, but his team hoped it could shed light on how to make a better fast-acting antidepressant.

CGP3466B compound may effectively treat depression: