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CMOS-based bio-image sensor spatially resolves neural activity-dependent proton dynamics in the living brain

Hiroshi Horiuchi, Masakazu Agetsuma, Junko Ishida, Yusuke Nakamura, Dennis Lawrence Cheung, Shin Nanasaki, Yasuyuki Kimura, Tatsuya Iwata, Kazuhiro Takahashi, Kazuaki Sawada, Junichi Nabekura

2020Nature Communications30 citationsDOIOpen Access PDF

Abstract

Recent studies have shown that protons can function as neurotransmitters in cultured neurons. To further investigate regional and neural activity-dependent proton dynamics in the brain, the development of a device with both wide-area detectability and high spatial-ltemporal resolution is necessary. Therefore, we develop an image sensor with a high spatial-temporal resolution specifically designed for measuring protons in vivo. Here, we demonstrate that spatially deferent neural stimulation by visual stimulation induced distinct patterns of proton changes in the visual cortex. This result indicates that our biosensor can detect micrometer and millisecond scale changes of protons across a wide area. Our study demonstrates that a CMOS-based proton image sensor with high spatial and temporal precision can be used to detect pH changes associated with biological events. We believe that our sensor may have broad applicability in future biological studies.

Topics & Concepts

MillisecondTemporal resolutionImage resolutionProtonBiological systemVisual cortexBrain functionComputer scienceNeurosciencePhysicsArtificial intelligenceBiologyOpticsQuantum mechanicsAstronomyPhotoreceptor and optogenetics researchNeural dynamics and brain functionNeuroscience and Neuropharmacology Research
CMOS-based bio-image sensor spatially resolves neural activity-dependent proton dynamics in the living brain | Litcius