Posts tagged neuroscience

Aug. 20, 2012 by Quinn Eastman

People with Parkinson’s disease performed markedly better on a test of working memory after a night’s sleep, and sleep disorders can interfere with that benefit, researchers have shown.

The ability of sleep to improve scores on a test of working memory specifically depends on how much slow wave sleep Parkinson’s patients obtain, researchers have found.

While the classic symptoms of Parkinson’s disease include tremors and slow movements, Parkinson’s can also affect someone’s memory, including “working memory.” Working memory is defined as the ability to temporarily store and manipulate information, rather than simply repeat it. The use of working memory is important in planning, problem solving and independent living.

The findings underline the importance of addressing sleep disorders in the care of patients with Parkinson’s, and indicate that working memory capacity in patients with Parkinson’s potentially can be improved with training. The results also have implications for the biology of sleep and memory.

The results were published this week in the journal Brain.

"It was known already that sleep is beneficial for memory, but here, we’ve been able to analyze what aspects of sleep are required for the improvements in working memory performance," says postdoctoral fellow Michael Scullin, who is the first author of the paper. The senior author is Donald Bliwise, professor of neurology at Emory University School of Medicine.

The performance boost from sleep was linked with the amount of slow wave sleep, or the deepest stage of sleep. Several research groups have reported that slow wave sleep is important for synaptic plasticity, the ability of brain cells to reorganize and make new connections.

Sleep apnea, the disruption of sleep caused by obstruction of the airway, interfered with sleep’s effects on memory. Study participants who showed signs of sleep apnea, if it was severe enough to lower their blood oxygen levels for more than five minutes, did not see a working memory test boost.

In this study, participants took a “digit span test,” in which they had to repeat a list of numbers forward and backward. The test was conducted in an escalating fashion: the list grows incrementally until someone makes a mistake. Participants took the digit span test eight times during a 48-hour period, four during the first day and four during the second. In between, they slept.

Repeating numbers in the original order is a test of short-term memory, while repeating the numbers in reverse order is a test of working memory.

"Repeating the list in reverse order requires some effort to manipulate the numbers, not just spit them back out again," Scullin says. "It’s also a purely verbal test, which is important when working with a population that may have motor impairments."

54 study participants had Parkinson’s disease, and 10 had dementia with Lewy bodies: a more advanced condition, where patients may have hallucinations or fluctuating cognition as well as motor symptoms. Those who had dementia with Lewy bodies saw no working memory boost from the night’s rest. As expected, their  baseline level of performance was lower than the Parkinson’s group.

Participants with Parkinson’s who were taking dopamine-enhancing medications saw their performance on the digit span test jump up between the fourth and fifth test. On average, they could remember one more number backwards. The ability to repeat numbers backward improved, even though the ability to repeat numbers forward did not.

Patients needed to be taking dopamine-enhancing medications to see the most performance benefit from sleep. Patients not taking dopamine medications, even though they had generally had Parkinson’s for less time, did not experience as much of a performance benefit. This may reflect a role for dopamine, an important neurotransmitter, in memory.

Scullin and Bliwise are planning an expanded study of sleep and working memory, in healthy elderly people as well as patients with neurodegenerative diseases.

"Many elderly people go through a decline in how much slow wave sleep they experience, and this may be a significant contributor to working memory difficulties," Scullin says.

Source: Emory

20 August 2012 by Kayt Sukel

Some people can recall what happened on almost every day of their lives. Unlocking their secrets could shed light on the way all our memories work

IT WAS an email that memory researcher James McGaugh found hard to believe. The sender, a 34-year-old housewife named Jill Price, was claiming that she could recall key events on any date back to when she was about 12, as well as what she herself had done each day.

"Some people call me the human calendar," she wrote, "while others run out of the room in fear. But the one reaction I get from everyone who finds out about this ‘gift’ is amazement. I run my entire life through my head every day and it drives me crazy!"

McGaugh invited Price to his lab, making sure he had to hand a copy of 20th Century Day by Day, a book that lists important events by date. He opened the book to random pages and asked Price what had happened on those days. “Whether it was a plane crash or some elections or a movie star doing an outrageous thing, she was dead on,” he recalls. “Time and time again.”

That was in June 2000. McGaugh’s group has worked closely with Price ever since, and has discovered she is one of a select few with similar abilities. These individuals are neither autistic savants nor masters of mnemonic-based tricks of recall, yet they can remember key events from almost every day of their lives. Learning more about their abilities and how their brains are wired should lead to insights into the nature of human memory.

Intrigued by McGaugh’s findings, I arranged to visit his lab at the University of California, Irvine, to find out how these people live with such unusual abilities - and what it is like for the researchers working with them. “It never ceases to amaze me,” says McGaugh’s colleague, Aurora LePort. “Some of them can remember every day you give them.” She says studying people whose powers of recall seem to be enhanced, rather than impaired, offers us a new tool to explore memory.

It is certainly fair to say that most of our knowledge of memory derives from looking at memory loss. The classic case is that of Henry Molaison (better known as “HM”), who had surgery nearly 60 years ago to treat severe epilepsy. In a misguided attempt to remove the source of the seizures, several parts of the brain were cut out, including both hippocampi, curled up ridges on either side of the brain.

For HM, the consequences were catastrophic. Although he could still recall his early life, he was no longer able to lay down memories of things that happened to him after the surgery. Every day, the researchers studying his condition had to introduce themselves anew. Intriguingly, though, he could perform tasks that used short-term memory, like retaining a phone number for a few minutes.

Thanks to HM and many other people with neurological problems caused by head injuries and strokes, we now know that there are different kinds of remembering. Our short-term memories last up to about a minute, unless they are reinforced, or “rehearsed” through further repetition. While much about the neuroscience of memory remains mysterious, our hippocampi seem to be involved in turning these fleeting impressions into long-term memories, which are thought to be stored in the temporal lobes on either side of the brain.

Long-term memories can be subdivided into semantic ones to do with concepts, such as the fact that London is the UK capital, and autobiographical memories, about everyday events that we experience. Price has no special abilities with regard to her short-term or semantic memory, but when it comes to autobiographical memory, her scores are off the chart.

Read more …

ScienceDaily (Aug. 20, 2012) — The more that we understand the brain, the more complex it becomes. The same can be said about the genetics and neurobiology of psychiatric disorders. For “Mendelian” disorders, like Huntington disease, mutation of a single gene predictably produces a single clinical disorder, following relatively simple genetic principals. Compared to Mendelian disorders, understanding bipolar disorder has been extremely challenging. Its biology is not well understood and its genetics are complex.

In a new paper, Dr. Inti Pedroso and colleagues utilize an integrative approach to probe the biology of bipolar disorder. They combined the results of three genome-wide association studies, which examined the association of common gene variants with bipolar disorder throughout the genome, and a study of gene expression patterns in post-mortem brain tissue from people who had been diagnosed with bipolar disorder. The findings were analyzed within the context of how brain proteins relate to each other based on the Human Protein Reference Database protein-protein interaction network.

"None of our research approaches provides us with sufficient information, by itself, to understand the neurobiology of psychiatric disorders. This innovative paper wrestles with this challenge in a creative way that helps us to move forward in thinking about the neurobiology of bipolar disorder," commented Dr. John Krystal, Editor of Biological Psychiatry.

Dr. Pedroso explained, “We combined information about genetic variation from thousands of cases and controls with brain gene expression data and information from protein databases to identify networks of genes and proteins in the brain that are key in the development of bipolar disorder.”

The analysis resulted in the ability to define risk gene variants that were deemed functional, by virtue of the association with changes in gene expression levels, and to group these functional gene variants in biologically meaningful pathways.

The results implicated genes involved in several neural signaling pathways, including the Notch and Wnt signaling pathways. These pathways are key processes in neurotransmission and brain development and these findings indicate they are also likely to be involved in causing this severe disorder. The authors noted that three features stand out among these genes: i) they localized to the human postsynaptic density, which is crucial for neuronal function; ii) their mouse knockouts present altered behavioral phenotypes; and iii) some are known targets of the pharmacological treatments for bipolar disorder.

Dr. Gerome Breen, senior author on the study and Senior Lecturer at King’s College London Institute of Psychiatry, said, “Our study provides some of the first evidence to show the biochemical and developmental processes involved in causing risk for developing this life-long and costly illness. We have highlighted potential new avenues for new drug treatments and intervention.”

Source: Science Daily