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These images were obtained using functional MRI scans taken as cognitively normal people performed tasks that required them to pay attention to changing stimuli. Yellow/orange regions indicate brain areas that become active during the task. Blue regions become less active during the task. In people with evidence of beta-amyloid in the brain, these areas of deactivation are abnormal, meaning they don't fully deactivate. (Image: Bill Jagust's group)
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Alzheimer's disease is known as a disease of the elderly. Where the brain is shrinking along with increasing age. This disease leads to death. However, that does not mean the disease does not occur at a young age. A five-year study conducted by Lawrence Berkeley National Laboratory lead by Jagust, gave a surprising result. He heads a team that conducts the cohort study, which so far includes about 80 volunteers.
Research conducted by volunteers over the age of 70 years, underwent a number of research methods. They were asked to solve puzzles and memorizing lists of words. Magnetic resonance imaging (MRI) scans image the structure of their brains in exquisite detail. Functional MRI scans allow scientists to watch portions of their brains light up as they form memories. And Positron emission tomography (PET) scans measure any accumulation of beta-amyloid, a destructive protein that’s a hallmark of Alzheimer’s.
The goal of the Berkeley Aging Cohort Study is to reveal how our brains change as we age. The scientists also compare their findings with brain scans of Alzheimer’s patients.
They’ve noticed something odd—and perhaps a little hopeful. Some volunteers have the same level of beta-amyloid deposition as an Azheimer’s patient. Yet they show no signs of the disease.
Why is this? How can two people, the same age and with the same signs of the disease, take such different paths?
“It turns out that Alzheimer’s is more complicated than we thought,” says Jagust, a faculty senior scientist in the Berkeley Lab’s’s Life Sciences Division who also has appointments at UC Berkeley’s School of Public Health and the Helen Wills Neuroscience Institute.
“Until recently, we thought the more amyloid accumulation in the brain, the greater the chance of developing the disease” says Jagust. “But we now believe that amyloid unleashes a chain of events that may or may not cause Alzheimer’s.”
It’s well known that many normal, older people have some beta-amyloid deposits in their brain. It’s also likely true that people with beta-amyloid have a greater risk of cognitive decline and Alzheimer’s.
But the picture gets cloudy from there. Jagust’s group has found structural and functional changes in the brains of healthy people that are associated with beta-amyloid. Some of these changes may be a prelude to Alzheimer’s.
And some changes may be signs that a person is actually resisting this path.
In a recent study, Jagust and colleagues asked people to commit pictures to memory while they watched their brain activity with functional MRI. Normal people with beta-amyloid deposition showed more—not less—activity than people without beta-amyloid. One possible interpretation for this heightened activity is that it enables memory formation despite the presence of beta-amyloid. Their brains are working harder.
“We’re beginning to detect changes that may help people ward off cognitive decline and possibly Alzheimer’s,” says Jagust.
Jagust’s group is pursuing other questions: Is the cognitive decline associated with beta-amyloid deposition linked to the rate of deposition? Or is it more closely associated with changes in brain function that occur after beta-amyloid has done its damage?
Or perhaps cognitive decline is most closely associated with changes in brain structure. In another study, Jagust’s team found that the more beta-amyloid plaque in a person’s brain, the more a person is likely to have a smaller hippocampus, which is the part of the brain that forms new memories. They also found that someone with this damage is more likely to have impaired memory.
This research will help scientists determine how this constellation of events—beta-amyloid deposition, changes in brain function, hippocampus atrophy—contributes to Alzheimer’s.
The search for the earliest signs of the disease has gained importance in recent years as pharmaceutical companies work to develop drug therapies that are designed to block the deposition of beta-amyloid.
“There is a strong belief that Alzheimer’s must be treated very early, before symptoms appear, in order to be effective,” says Jagust. “We know that amyloid leads to negative consequences in the brain. We now need to determine how to stop these effects before they happen.”
This story had edited by author of threelas
Source: Berkeley Lab
I definitely agree with you
ReplyDeleteI definitely agree with you! We need to prevent AD by avoiding the early signs of this disease. I believe that we can acquire this by having healthy life style.
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