Weekly Neuroscience Update

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painThe problem with diagnosing and treating pain is that it’s so subjective. But a new paper in Pain says that brain structure may hold some answers.

Adding cognitive-behavioral therapy (CBT) to the treatment of migraines in children and adolescents resulted in greater reductions in headache frequency and migraine-related disability compared with headache education, according to a new study.

Scientists have discovered how salt acts as a key regulator for drugs used to treat a variety of brain diseases including chronic pain, Parkinson’s disease, and depression.

Research focused on the amygdala can help identify children at risk for anxiety disorders and depression.

Whales, bats, and even praying mantises use ultrasound as a sensory guidance system – and now a new study has found that ultrasound can modulate brain activity to heighten sensory perception in humans.

Scientists have shown that there are widespread differences in how genes, the basic building blocks of the human body, are expressed in men and women’s brains.

A new study shows a leftward asymmetry of the choroid plexus in two-thirds of first-trimester human fetuses. This is the earliest brain asymmetry so far identified and may be a precursor to other asymmetries, including that of the temporal planum, which is evident from the 31st week of gestation.

Researchers have discovered the mechanism in the brain responsible for the motor and vocal tics found in Tourette Syndrome.  The study, published in the British Psychological Society’s Journal of Neuropsychology, could at some point lead to new non-drug therapies.

A new study by neuroscientists is the first to directly compare brain responses to faces and objects with responses to colors.

A study begun in Mexico with the collaboration of university students has analysed the effect of weekend alcohol consumption on the lipids comprising cell membrane and its genetic material, i.e. DNA.

Study reveals senses of sight and sound separated in children with autism

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Like watching a foreign movie that was badly dubbed, children with autism spectrum disorders (ASD) have trouble integrating simultaneous information from their eyes and their ears, according to a Vanderbilt study. The study, led by Mark Wallace, Ph.D., director of the Vanderbilt Brain Institute, is the first to illustrate the link and strongly suggests that deficits in the sensory building blocks for language and communication can ultimately hamper social and communication skills in children with autism.

To learn more about this research visit:

http://news.vanderbilt.edu/2014/01/senses-of-sight-and-sound-separated-in-children-with-autism/

Understanding how your brain works helps you learn better

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Evidence is accumulating that knowledge about the brain empowers learning. This is because understanding how your brain learns and remembers fosters a sense of autonomy (i.e. making your learning independent of someone/something else) and autonomy is recognised as a key factor in effective learning.

This 10 minute video can provide you with insights into how to prime your brain for effective learning and it may help if you are worried about exams and feel that you are not learning optimally.

Comments are welcome.

Inside The Emotional Brain

brain activity emotions

Scientists have found a way to determine what emotions you’re feeling by looking at brain activity measured by imaging technology.

The findings, published in the journal PLOS ONE, are important to emotion research because they bring “a new method with potential to identify emotions without relying on people’s ability to self-report,” study researcher Karim Kassam, an assistant professor of social and decision sciences at Carnegie Mellon University, said in a statement.

“It could be used to assess an individual’s emotional response to almost any kind of stimulus, for example, a flag, a brand name or a political candidate.”

For the study, researchers used a combination of brain imaging — functional magnetic resonance imaging — and machine learning. They recruited 10 actors from the university’s drama school to act out different emotions, such as anger, happiness, pride and shame, while inside an fMRI scanner, for multiple times in random order.

To make sure that researchers were able to measure the actual emotions and not just the acting out of emotions, they had the study participants also look at emotion-eliciting images while undergoing FMRI brain scans.

“Despite manifest differences between people’s psychology, different people tend to neurally encode emotions in remarkably similar ways,” study researcher Amanda Markey, a graduate student in the Department of Social and Decision Sciences at the university, said in a statement.

Source: Huffington Post

Slow brain waves play key role in coordinating complex activity

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UCSF neurosurgeons place 64-electrode grids on the surface of the brain's temporal and frontal lobes to locate regions where epileptic seizures originate. These grids allowed UC Berkeley neuroscientists to study the interaction of brain waves during simple tasks, such as word recognition or hand movements. (Images courtesy the Knight Lab)

UCSF neurosurgeons place 64-electrode grids on the surface of the brain’s temporal and frontal lobes to locate regions where epileptic seizures originate. These grids allowed UC Berkeley neuroscientists to study the interaction of brain waves during simple tasks, such as word recognition or hand movements. (Images courtesy the Knight Lab)

While it is widely accepted that the output of nerve cells carries information between regions of the brain, it’s a big mystery how widely separated regions of the cortex involving billions of cells are linked together to coordinate complex activity. Now a new study by neuroscientists at the University of California, Berkeley, and neurosurgeons and neurologists at UC San Francisco (UCSF) is beginning to answer that question.

“One of the most important questions in neuroscience is: How do areas of the brain communicate?” said Dr. Robert Knight, professor of psychology, Evan Rauch Professor of Neuroscience and director of the Helen Wills Neuroscience Institute at UC Berkeley. “A simple activity like responding to a question involves areas all over the brain that hear the sound, analyze it, extract the relevant information, formulate a response, and then coordinate your lips and mouth to speak. We have no idea how information moves between these areas.”

By measuring electrical activity in the brains of pre-surgical epilepsy patients, the researchers have found the first evidence that slow brain oscillations, or theta waves, “tune in” the fast brain oscillations called high-gamma waves that signal the transmission of information between different areas of the brain. In this way, the researchers argue, areas like the auditory cortex and frontal cortex, separated by several inches in the cerebral cortex, can coordinate activity.

“If you are reading something, language areas oscillate in theta frequency allowing high-gamma-related neural activity in individual neurons to transmit information,” said Knight. “When you stop reading and begin to type, theta rhythms oscillate in motor structures, allowing you to plan and execute your motor response by way of high gamma. Simple, but effective.”

The findings are reported in the Sept. 15 issue of Science.

Read more at UC Berkeley News

Top ten blog posts of 2013

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Top-10-ListThese were the most popular blog posts on Inside the Brain ranked according to most page views in 2013.

Does Addiction Exist?

What is ‘attention’ and where is it in the brain?

Understanding ADHD and Learning Disability

Understanding ADHD and Learning Disability Part V: Diagnosing ADHD

Could there an evolutionary advantage in having ADHD?

What can mirror neurons teach us about consciousness, mental health and well-being?

Inside The Musical Brain

This Is Your Brain On Poetry

Why Parkinson’s Disease Has Robbed Linda Ronstadt Of Her Singing Voice

How Did Tolerance Kill Cory Monteith?

New Discoveries Inside The Developing Brain

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Image shows the neocortex organised into thousands of columns of neurons. Each column has a diameter of 0.5mm and contains 10,000 neurons. The neocortex is also organised into 6 layers. In the background are other neurons making up the neocortical column.

Image shows the neocortex organised into thousands of columns of neurons. Each column has a diameter of 0.5mm and contains 10,000 neurons. The neocortex is also organised into 6 layers. In the background are other neurons making up the neocortical column.

The human brain develops with an exquisitely timed choreography marked by distinct patterns of gene activity at different stages from the womb to adulthood, report Yale researchers. The Yale team conducted a large-scale analysis of gene activity in cerebral neocortex —an area of the brain governing perception, behavior, and cognition — at different stages of development. The neocortex, Latin for “new bark,” is our third, newly human brain in terms of evolution. It is what makes possible our judgments and our knowledge of good and evil. It is also the site from which our creativity emerges and home to our sense of self.

The team found that the human brain is more like a neighbourhood, which is better defined by the community living within its borders than its buildings.“The neighborhoods get built quickly and then everything slows down and the neocortex focuses solely on developing connections, almost like an electrical grid,” said Nenad Sestan, professor of neurobiology at Yale’s Kavli Institute for Neuroscience and senior author of the study.  “Later when these regions are synchronized, the neighborhoods begin to take on distinct functional identities like Little Italy or Chinatown.”

The analysis shows the general architecture of brain regions is largely formed in the first six months after conception by a burst of genetic activity, which is distinct for specific regions of the neocortex. This rush is followed by a sort of intermission beginning in the third trimester of pregnancy. During this period, most genes that are active in specific brain regions are quieted — except for genes that spur connections between all neocortex regions. Then in late childhood and early adolescence, the genetic orchestra begins again and helps subtly shape neocortex regions that progressively perform more specialized tasks, a process that continues into adulthood.

The analysis is the first to show this “hour glass” sketch of human brain development, with a lull in genetic activity sandwiched between highly complex patterns of gene expression, said Sestan. Intriguingly, say the researchers, some of the same patterns of genetic activity that define this human “hour glass” sketch were not observed in developing monkeys, indicating that they may play a role in shaping the features specific to human brain development.

The findings emphasize the importance of the proper interplay between genes and environment in the child’s earliest years after birth when the formation of synaptic connections between brain cells becomes synchronized, which shape how brain structures will be used later in life, said Sestan. For instance, disruptions of in synchronization of synaptic connections during child’s earliest years have been implicated in autism.

Notes:

Mihovil Pletikos, Andre ́ M.M. Sousa, and Goran Sedmak of Yale are co-lead authors of the Yale study. Other Yale authors are Kyle A. Meyer, Ying Zhu, Feng Cheng, Mingfeng Li and Yuka Imamura Kawasawa.

The work was funded by the National Institute of Mental Health, the James S. McDonnell Foundation, and the Kavli Foundation.

Imagae Credit: IBM/EPFL Blue Brain Project

Weekly Neuroscience Update

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Overly connected: Many pairs of brain regions — including those involved in sensory processing, emotion and motivation — are more tightly synchronized in children with autism (right) than in controls (left).

Overly connected: Many pairs of brain regions — including those involved in sensory processing, emotion and motivation — are more tightly synchronized in children with autism (right) than in controls (left).

Three studies published over the past two months have found significant evidence that children and adolescents with autism have brains that are overly connected compared with the brains of controls. The findings complicate the theory that autism is fundamentally characterized by weakly connected brain regions. Meanwhile new findings suggest the oxytocin receptor, a gene known to influence mother-infant bonding and pair bonding in monogamous species, also plays a special role in the ability to remember faces. This research has important implications for disorders in which social information processing is disrupted, including autism spectrum disorder. In addition, the finding may lead to new strategies for improving social cognition in several psychiatric disorders.

Researchers are gaining a better understanding of the neurochemical basis of addiction with a new technology called optogenetics.

We know that getting even a measly extra hour of sleep a night can have major benefits for us–like more memories, less anxiety, and happier genes. But scientists have tested another hypothesis for why we need to spend so much time horizontal: Sleep cleans our brains.

Scientists have pinpointed a specific part of the brain where Alzheimer’s begins and traced how the disease spreads.

Scientists have zapped an electrical current to people’s brains to erase distressing memories, part of an ambitious quest to better treat ailments such as mental trauma, psychiatric disorders and drug addiction.

Finally this week, many people can recall reading at least one cherished story that they say changed their life. Now researchers at Emory University have detected what may be biological traces related to this feeling: Actual changes in the brain that linger, at least for a few days, after reading a novel.