Brain organoids are powerful experimental models to study fundamental neurodevelopmental processes and the pathology of neurological disorders. Brain organoids can now be generated from human-induced pluripotent stem cells, which pave the way for using them to investigate effective therapies for various neurodegenerative disorders and diseases. However, brain organoids possess complex cellular architecture, various unknown functionalities, and a lack of vascular networks, which have limited their use in biomedicine and clinical research. Micro/nanoscale devices and technologies can help overcome these limitations. This review critically examines recently developed micro/nano devices for integration with brain organoids. The review focuses on devices designed to achieve several key aims: to improve methodologies for in vitro culture; to enable electrophysiological recordings from organoids; to screen drugs for chemotherapy and new treatments; to understand the effects of psychoactive drugs; and to enable development of vascular networks in organoids. Along with the specific device features and their relevance for these applications, we also discuss the current challenges to overcome and future strategies to advance the use of brain organoids in clinical research. The interdisciplinary convergence of brain organoids research with materials science, device engineering, neuroscience, and stem cell biology holds remarkable potential for replicating the human brain in vitro. Micro/nano devices are an important part of realizing this potential that will afford both fundamental insights into the mechanisms underlying brain function and a pathway for developing novel treatments for neurophysiological and neurodegenerative disorders.
Keywords: Brain organoids; Drug screening; Electrophysiology; Micro/nano devices; Organoid-on-a-chip; Vascularization.
Copyright © 2022 The Authors. Published by Elsevier B.V. All rights reserved.