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Tokyo, Japan - Alzheimer\u2019s disease is in many ways like a clock whose time is off, researchers have found. The \u2018internal neural timescale\u2019 of a part of the brain is running \u2018short\u2019 and throwing off the timing of the rest of a key region.<\/p>\n
A paper describing these findings was published in the journal Brain Communications on July 11.<\/p>\n
Recent human neuroimaging studies reported atypical anatomical and functional changes in some regions in the default mode network (DMN) in Alzheimer\u2019s patients. The DMN is a collection of brain regions that are active when an individual is at rest or not focused on the outside world. It is often referred to as one of the brain's \"resting state networks\" because it becomes more active when the mind is wandering, daydreaming, or engaging in internally focused tasks such as self-reflection, envisioning the future, or recalling memories.<\/p>\n
The DMN is composed of interconnected brain regions, including the medial prefrontal cortex, posterior cingulate cortex, precuneus, and the angular gyrus. These regions work together to facilitate introspection, social cognition and memory retrieval. <\/p>\n
\u201cDisruptions in the DMN have long been implicated in Alzheimer's disease, but the key DMN brain area whose atrophy disturbs the rest of the DMN, and consequently contributes to Alzheimer\u2019s symptoms has until now remained unidentified,\u201d said lead author of the study, Associate Professor Takamitsu Watanabe<\/font><\/a> of the International Research Center for Neurointelligence at the University of Tokyo.<\/p>\n The team examined two types of magnetic resonance imaging (MRI) techniques used to compare the differences in the resting state of the brains of people with and without Alzheimer\u2019s. They made use of functional MRI (fMRI), which captures changes in blood flow and oxygen levels in the brain, in order to allow researchers to observe brain activity and detect which areas of the brain are active during specific tasks. And they also investigated structural MRI data, which provide detailed images of the brain's anatomy, including its size, shape, and identify any abnormalities such as lesions or atrophy. This latter type of imaging is essential for diagnosing neurological conditions and monitoring disease progression.<\/p>\n In this way, the researchers identified a link between the structural changes in the left portion of the angular gyrus, its altered neural activity, and the cognitive decline observed in Alzheimer's disease. <\/p>\n The left angular gyrus is a region located in the parietal lobe of the brain. It is involved in tasks such as reading, writing, language processing, comprehension of complex stimuli, problem-solving and memory retrieval. <\/p>\n Different regions of the brain process time differently, even though some brain areas, such as prefrontal and parietal cortices, integrate these different intrinsic neural timescales (INTs), or \u201cneural clocks,\u201d to integrate diverse information at a single useful timescale. These various neural clocks mediate our behaviors and cognition, and play a decisive role in our sense of self. <\/p>\n Through the comparison of MRI data of Alzheimer\u2019s patients and those without the disease, they found that the neural clock of the DMN in the patients was unusually \u201cshort\u201d compared to the cognitively typical subjects. <\/p>\n \u201cWhen neuroscientists say that a neural clock is running \u2018shorter\u2019 or \u2018longer,\u2019 we are referring to how quickly or stably neurons in a region hold information within them,\u201d said Shota Murai, another member of the research team.<\/p>\n This atypically short DMN neural clock was also associated with an unusually short neural clock in the left angular gyrus.<\/p>\n This in turn was associated with an unusually low volume of grey matter\u2014the tissue in the brain involved in the integration of diverse information including memory, emotions and movement \u2014in this region.<\/p>\n The researchers believe that the low grey matter volume of the angular gyrus is what shortens its neural clock, which then destabilizes the neural clock of the entire DMN\u2014which contributes to the cognitive decline observed in Alzheimer\u2019s patients. <\/p>\n They hope that tracking such disturbance of the neural clock could be used as a biomarker to detect early onset of Alzheimer\u2019s disease. Better still, they aim to investigate whether stabilizing this neural clock could slow down progression of the disease. <\/p>\n ### JOURNAL<\/strong>
\nThe article, \u201cAtypical intrinsic neural timescale in the left angular gyrus in Alzheimer's disease\u201d, was published in Brain Communications at DOI: 10.1093\/braincomms\/fcae199<\/a>.<\/font><\/p>\n
\nBrain Communications<\/p>\n