最先端研究セミナー
講演者:池内 与志穂(東京大学 生産技術研究所 教授)
演題:Let’s Get Connected: Building Networks with Brain Organoids
日時:2025年10月15日(水) 12:00-13:00
開催場所:発生医学研究所1階 カンファレンス室
※ZOOMミーティングのURLはMoodleの「S-HIGO最先端研究セミナーA、B」にてご確認ください。
https://md.kumamoto-u.ac.jp/course/view.php?id=120331
Abstract
Brain organoids (neural organoids) derived from human pluripotent stem cells are artificial tissues that recapitulate structures and cell compositions of the human brain. Brain organoids are expected to play an important role in advancing our understanding of the brain and in developing new therapies. However, current brain organoids face several challenges. While early developmental stages can be reproduced, they remain immature and it is difficult to model the adult brain. Moreover, because neural organoids form spontaneously based solely on cellular properties, they reproduce only parts of the brain and cannot mimic the way many regions are interconnected in vivo.
To address this, we are developing methods to assemble neural organoids into neural circuits by controlling axonal outgrowth within microdevices. In this approach, iPS cell–derived cerebral organoids are placed in small wells at the ends of narrow microchannels. Axons extending from each organoid grow through the channel and connect to the organoid on the opposite side, ultimately forming a reciprocally connected structure. The axon bundles linking the organoids can be regarded as mimicking nerve-fiber tracts such as the corpus callosum and subcortical axonal tracts. We refer to brain organoids connected via axonal bundles as “connectoids.”
Connectoids exhibit more complex and vigorous activity than single organoids or assembloids. In connectoids, when action potentials in the inter-organoid axons are suppressed, synchrony between organoids is lost and the overall level of neural activity drops sharply. As these examples illustrate, a key advantage of constructing neural circuits in vitro is the ability to alter structure and patterns of axonal connectivity to interrogate resulting changes in neural activity.
Another major challenge for brain organoids is the absence of continuous input signals from sensory organs. We are therefore also developing methods to induce functional changes in circuit architecture through sustained stimulation. Including these efforts, I would like to discuss the current state and future potential of brain organoid research.
担当分野:分子生理学講座 中條(5051)
