{"id":29978,"date":"2024-12-04T08:08:01","date_gmt":"2024-12-03T23:08:01","guid":{"rendered":"https:\/\/ircn.jp\/?p=29978"},"modified":"2025-05-08T14:34:17","modified_gmt":"2025-05-08T05:34:17","slug":"20241204_kenichi_ohki","status":"publish","type":"post","link":"https:\/\/ircn.jp\/en\/pressrelease\/20241204_kenichi_ohki","title":{"rendered":"Separating signal from noise in the brain"},"content":{"rendered":"

<\/p>\n

Separating signal from noise in the brain<\/font><\/strong><\/div>\n

Understanding how primate neural mechanism distinguishes between spontaneous and stimulus-related activity<\/strong><\/center><\/span><\/p>\n


\nWhen the brain is observed through imaging, there is a lot of \u201cnoise,\u201d which is spontaneous electrical activity that comes from a resting brain. This appears to be different from brain activity that comes from sensory inputs, but just how similar \u2014 or different \u2014 the noise is from the signal has been a matter of debate.<\/p>\n

New research led by a team at the University of Tokyo further untangles the relationship between internally generated noise and stimulus-related patterns in the brain, and finds that the patterns of spontaneous activity and stimulus-evoked response are similar in lower visual areas of the cerebral cortex, but gradually become independent, or \u201corthogonal,\u201d as one moves from lower to higher visual areas. The findings not only enhance our understanding of the mechanism that enables the brain to distinguish between signal and noise, but could also provide clues for developing noise-resistant artificial intelligence incorporating a mechanism similar to that found in the biological brain.<\/p>\n

\u201cThe brain is very noisy,\u201d said Professor Kenichi Ohki<\/font color=blue><\/a> of the Graduate School of Medicine. \u201cIt is constantly active even without any sensory inputs. Despite the noise, our sensory perception is very stable. We were interested in the mechanism by which the brain handles internally generated noise to achieve stable perception.\u201d<\/p>\n

An orthogonal, or independent, relationship between this internal brain noise and stimulus-related signals would explain how sensory perception remains stable.<\/p>\n

In order to test which theory explains the relationship between brain noise and stimulus-related activity, researchers observed marmoset monkeys, which have a flat neocortex (the largest region in primate brains) that makes it easier to observe cortical areas involved in the brain\u2019s higher functions. They injected a virus carrying a genetically encoded calcium indicator called GCaMP, which includes a green fluorescent protein that is bound to calcium ions that highlights brain activity on imaging scans.<\/p>\n

At first, the spontaneous brain activity looked like waves with patchy spatial patterns. This patchy activity seems to be a general characteristic of primate brains. The spontaneous noise and the stimulus-related activity looked similar in lower cortical areas, which is consistent with previous research. However, as researchers looked closer at a higher cortical area, a part of the primate brain that helps monkeys process a moving image, there were less similarities between the two types of brain activity.<\/p>\n

Cellular imaging and analysis of the neural activity found a hierarchy in place that helped separate brain noise and stimulus-related signal.<\/p>\n

\u201cThe hierarchical structure of the cortical network is crucial for separating internal noise from sensory outputs. This separation process is called orthogonalization,\u201d said now-Professor Teppei Matsui of the Graduate School of Brain Science at Doshisha University in Kyoto, who was lecturer at the University of Tokyo\u2019s Graduate School of Medicine at the time of this research.<\/p>\n

Looking ahead, researchers hope to continue to study the brain to understand this orthogonal relationship and hope to understand what this means for artificial intelligence. Unlike artificial neural networks, spontaneous activity is a characteristic feature of the biological brain. \u201cThe next step is to identify neocortical neural circuits critical for the hierarchical orthogonalization,\u201d said Ohki. \u201cWe are also hoping that the present finding contributes to developing new noise-resistant artificial intelligence.\u201d<\/p>\n


\n\"\"<\/p>\n

\n

Two-photon imaging reveals a novel role of the hierarchical visual cortical network in marmoset monkeys.<\/strong> Scientists from the University of Tokyo performed two-photon imaging in the visual cortex of marmoset monkeys to examine spontaneous and visual stimulus-evoked neuronal activities (top left). Visual cortical neurons showed vigorous spontaneous activities even in the absence of visual stimuli (top right). Spontaneous and visually evoked activities are progressively orthogonalized as they propagate through the hierarchical visual cortical network. \u00a9Kenichi Ohki, The University of Tokyo<\/div>\n

Papers<\/strong>
\nTeppei Matsui, Takayuki Hashimoto, Tomonari Murakami, Masato Uemura, Kohei Kikuta, Toshiki Kato, Kenichi Ohki, \"Orthogonalization of spontaneous and stimulus-driven activity by hierarchical neocortical areal network in primates,\" Nature Communications: December 4, 2024, doi:10.1038\/s41467-024-54322-x<\/font color=blue><\/a>.<\/p>\n

<\/p>\n

This article is reprinted from UTokyo FOCUS<\/font><\/a><\/strong>.<\/div>\n

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