Eating up to 100 g of chocolate every day is linked to lowered heart disease and stroke risk. The calculations showed that compared with those who ate no chocolate higher intake was linked to an 11% lower risk of cardiovascular disease and a 25% lower risk of associated death.
There doesn't seem to be any evidence for cutting out chocolate to lower the risk of cardiovascular disease, conclude the researchers.
They base their findings on almost 21,000 adults taking part in the EPIC-Norfolk study, which is tracking the impact of diet on the long term health of 25,000 men and women in Norfolk, England, using food frequency and lifestyle questionnaires.
The researchers also carried out a systematic review of the available international published evidence on the links between chocolate and cardiovascular disease, involving almost 158,000 people--including the EPIC study participants.
The EPIC-Norfolk participants (9214 men and 11 737 women) were monitored for an average of almost 12 years, during which time 3013 (14%) people experienced either an episode of fatal or non-fatal coronary heart disease or stroke.
Researchers perfected a noninvasive "chemogenetic" technique that allows them to switch off a specific behavior in mice - such as voracious eating - and then switch it back on.
The method found by researchers at the University of North Carolina School of Medicine and the National Institutes of Health (NIH) works by targeting two different cell surface receptors of neurons that are responsible for triggering the specific chemical signals that control brain function and complex behaviors.
When this complex signaling system goes awry, the results can lead to a plethora of diseases, including schizophrenia, depression, Alzheimer's Disease, Parkinson's Disease, eating disorders, and epilepsy. Cell surface receptors also play roles in cancers, diabetes, digestive conditions, and other diseases. This new technique could be modified to study them, as well.
This is the first technology to stem from the initial set of NIH BRAIN Initiative grants to create new cutting-edge research tools to improve our understanding of the brain.
The feeling of being inside one's own body is not as self-evident as one might think.
In a new study from Sweden's Karolinska Institutet, neuroscientists created an out-of-body illusion in participants placed inside a brain scanner. They then used the illusion to perceptually 'teleport' the participants to different locations in a room and show that the perceived location of the bodily self can be decoded from activity patterns in specific brain regions.
The sense of owning one's body and being located somewhere in space is so fundamental that we usually take it for granted. To the brain, however, this is an enormously complex task that requires continuous integration of information from our different senses in order to maintain an accurate sense of where the body is located with respect to the external world. Studies in rats have shown that specific regions of the brain contain GPS-like 'place cells' that signal the rat's position in the room -- a discovery that was awarded the 2014 Nobel Prize in Physiology or Medicine. To date, however, it remains unknown how the human brain shapes our perceptual experience of being a body somewhere in space, and whether the regions that have been identified in rats are involved in this process.
In a new study, published in the scientific journal Current Biology, the scientists created an out-of-body illusion in fifteen healthy participants placed inside a brain scanner. In the experiment, the participants wore head-mounted displays and viewed themselves and the brain scanner from another part of the room. From the new visual perspective, the participant observes the body of a stranger in the foreground while their physical body is visible in the background, protruding from the bore of the brain scanner. To elicit the illusion, the scientist touches the participant's body with an object in synchrony with identical touches being delivered to the stranger's body, in full view of the participant.
"In a matter of seconds, the brain merges the sensation of touch and visual input from the new perspective, resulting in the illusion of owning the stranger's body and being located in that body's position in the room, outside the participant's physical body," says Arvid Guterstam, lead author of the present study.
In the most important part of the study, the scientists used the out-of-body illusion to perceptually 'teleport' the participants between different places in the scanner room. They then employed pattern recognition techniques to analyze the brain activity and show that the perceived self-location can be decoded from activity patterns in specific areas in the temporal and parietal lobes. Furthermore, the scientists could demonstrate a systematic relationship between the information content in these patterns and the participants' perceived vividness of the illusion of being located in a specific out-of-body position.
"The sense of being a body located somewhere in space is essential for our interactions with the outside world and constitutes a fundamental aspect of human self-consciousness," says Arvid Guterstam. "Our results are important because they represent the first characterization of the brain areas that are involved in shaping the perceptual experience of the bodily self in space."
One of the brain regions from which the participants' perceived self-location could be decoded was the hippocampus -- the structure in which the Nobel Prize awarded 'place cells' have been identified.
"This finding is particularly interesting because it indicates that place cells are not only involved in navigation and memory encoding, but are also important for generating the conscious experience of one's body in space," says principal investigator Henrik Ehrsson, professor at the Department of Neuroscience.
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