Neuroscience research articles are provided.
What is neuroscience? Neuroscience is the scientific study of nervous systems. Neuroscience can involve research from many branches of science including those involving neurology, brain science, neurobiology, psychology, computer science, artificial intelligence, statistics, prosthetics, neuroimaging, engineering, medicine, physics, mathematics, pharmacology, electrophysiology, biology, robotics and technology.
– These articles focus mainly on neurology research. – What is neurology? – Definition of neurology: a science involved in the study of the nervous systems, especially of the diseases and disorders affecting them. – Neurology research can include information involving brain research, neurological disorders, medicine, brain cancer, peripheral nervous systems, central nervous systems, nerve damage, brain tumors, seizures, neurosurgery, electrophysiology, BMI, brain injuries, paralysis and spinal cord treatments.
What is Psychology? Definition of Psychology: Psychology is the study of behavior in an individual, or group. Psychology news articles are listed below.
Artificial Intelligence articles involve programming, neural engineering, artificial neural networks, artificial life, a-life, floyds, boids, emergence, machine learning, neuralbots, neuralrobotics, computational neuroscience and more involving A.I. research.
Robotics articles will cover robotics research press releases. Robotics news from universities, labs, researchers, engineers, students, high schools, conventions, competitions and more are posted and welcome.
Genetics articles related to neuroscience research will be listed here.
Neurotechnology research articles deal with robotics, AI, deep learning, machine learning, Brain Computer Interfaces, neuroprosthetics, neural implants and more. Read the latest neurotech news articles below.
Summary: Ketamine, an anesthetics which has been commonly used as an illicit party drug, is helping people overcome depression. The drug works rapidly and provides lasting relief from depressive symptoms for weeks after exposure. Researchers are examining how ketamine works in the brain to help positively influence behavior in those with mood disorders.
Source: The Conversation
It’s been 50 years in the making, but the anaesthetic and illicit party drug ketamine is now having a clinical comeback. New studies show that this commonly used anaesthetic can provide quick relief of core symptoms associated with severe depression, including suicidal ideation.
Amazingly, ketamine works within hours and its effects are maintained for at least one week. Most strikingly, ketamine is effective in those patients who are resistant to ordinary antidepressants, and they make up around 30 to 50 percent of the depressed population.
Now, efforts in Mexico, Australia, France, Canada and the United States, among others, are focusing on understanding exactly how ketamine does this, and to what extent it is safe and effective in a clinical setting. Together, these studies will increase our understanding of depression around the world and perhaps expand ketamine’s potential to treat other forms of mental illness as well.
The focus of our lab at the University of Guelph is to understand how specific drugs, such as ketamine, work in the brain and influence behaviour.
My doctoral research, specifically, looks at the link between stress, inflammation and behaviour. I am studying how ketamine influences behaviour and can reduce the effects of stress, and what this means for mood disorders, such as major depression.
The first dissociative anaesthetic
Initially, ketamine was developed as an alternative to the well-known, illegal party drug, phencyclidine (PCP). In the late 1950s, PCP was the focus of Parke-Davis pharmaceuticals for its use as an anesthetic. However, the drug came with uncomfortable side effects such as delirium and a loss of feeling in the limbs, which lasted for several hours after the drug was taken.
To fix this issue, Cal Bratton of Parke-Davis encouraged scientists to look into possible ways to modify PCP, with a primary goal of reducing side effects. In 1962, the organic chemist, Calvin Stevens, made a PCP-like compound which he said had similar anaesthetic properties, with shorter acting psychoactive effects than PCP.
This compound, originally known as CI-581, was eventually named ketamine based on the ketone and amine group that formed its chemical structure.
Followings its discovery, ketamine was then used in the first human trials in the mid-1960s which included testing on volunteer inmates of Jackson Prison in Michigan, United States.
After consistent reports of feeling “disconnected” from the environment when given ketamine, it was classified as the first dissociative anesthetic.
In the years after its initial testing, the effects of ketamine rapidly gained popularity around the globe, and the approval as a human anaesthetic was passed by the U.S. Food and Drug Administration (FDA) in 1970 — to be sold as Ketalar.
Unique antidepressant effect
Recent studies describing ketamine’s antidepressant properties have led to a dramatic shift in how we view the drug and treat mental illness.
Typical antidepressants work by controlling levels of neurotransmitters in the brain known as monoamines, such as serotonin and norepinephrine. Ketamine’s antidepressant effect is unique, as it modifies the activity of glutamate, which is the main excitatory neurotransmitter in the brain and is not a monoamine.
One of the fascinating findings about ketamine is that it can rapidly reduce depressive symptoms in patients who do not respond to typical monoamine antidepressants. This suggests the role of glutamate in depression.
In fact, studies have related ketamine’s antidepressant effect with its ability to maintain connections between neurons (or nerve cells) in the brain. These connections are known to continuously change in response to our environment, which is a process known as plasticity. Interestingly, the ability of these neurons to change connections highly relies on normal glutamate activity.
A combination of human and animal studies suggest that ketamine’s antidepressant effect may involve regulating glutamate levels to strengthen these connections and/or restore them back to a pre-stressed state.
Further study of ketamine’s ability to restore these neural connections and how glutamate relates to mood disorders will surely open new doors for understanding mental illness.
Nasal sprays and biomarkers
Current research has shown positive effects of ketamine for other forms of mental illness as well, such as post-traumatic stress disorder (PTSD) and bipolar disorder. Though the results seem quite positive, more studies are required to validate their use beyond depression.
Other studies using a repeated treatment method over several weeks showed that ketamine can produce long-term reductions in symptoms of treatment-resistant depression, lending potential to its safety and effectiveness over longer periods of treatment.
Recently, the FDA has approved esketamine (ketamine’s “close cousin”) in the U.S., sold as Spravato in the form of a nasal spray. Importantly, the spray is only prescribed to treatment-resistant patients who continue to take an oral antidepressant and can only be used under the supervision of a health-care provider.
Finally, studies are also looking into biological markers that can predict response to treatment, also known as biomarkers. If successful, this research would allow for more accurate and effective treatment delivery in the form of personalised treatment plans.
Increasing accessibility to ketamine treatment for depression will be the next major milestone for this drug. It is sure to provide effective relief for those who continue to experience treatment-resistant and severe depression.
The promise of ketamine for treating mood disorders only applies in a carefully monitored clinical setting. The street drug Special K can be addictive, put users at high risk and cause long-term psychological harm.
Funding: Brett Melanson is affiliated with Canadian Biomarker Integration Network (CAN-BIND; www.canbind.ca). CAN-BIND is an Integrated Discovery Program carried out in partnership with, and financial support from, the Ontario Brain Institute, an independent non-profit corporation, funded partially by the Ontario government. The opinions, results, and conclusions are those of the authors, and no endorsement by the Ontario Brain Institute is intended or should be inferred.
[divider]About this neuroscience research article[/divider]
Source: The Conversation Media Contacts: Brett Melanson – The Conversation Image Source: The image is credited to Teresa Crawford.
[divider]Feel free to share this Neuroscience News.[/divider]