Organoid intelligence (OI) is an emerging field of study in computer science and biology that develops and studies biological computing using 3D cultures of human brain cells (or brain organoids) and brain-machine interface technologies.[1] Such technologies may be referred to as OIs.
Differences with non-organic computing
As opposed to traditional non-organic silicon-based approaches, OI seeks to use lab-grown cerebral organoids to serve as "biological hardware." Scientists hope that such organoids can provide faster, more efficient, and more powerful computing power than regular silicon-based computing and AI while requiring only a fraction of the energy. However, while these structures are still far from being able to think like a regular human brain and do not yet possess strong computing capabilities, OI research currently offers the potential to improve the understanding of brain development, learning and memory, potentially finding treatments for neurological disorders such as dementia.[2]
John Hartung, a professor from Johns Hopkins University, argues that "while silicon-based computers are certainly better with numbers, brains are better at learning." Furthermore, he claimed that with "superior learning and storing" capabilities than AIs, being more energy efficient, and that in the future, it might not be possible to add more transistors to a single computer chip, while brains are wired differently and have more potential for storage and computing power, OIs can potentially harness more power than current computers.[3]
Intended functions
Brain-inspired computing hardware aims to emulate the structure and working principles of the brain and could be used to address current limitations in artificial intelligence technologies. However, brain-inspired silicon chips are still limited in their ability to fully mimic brain function, as most examples are built on digital electronic principles. One study performed OI computation (which they termed Brainoware) by sending and receiving information from the brain organoid using a high-density multielectrode array. By applying spatiotemporal electrical stimulation, nonlinear dynamics, and fading memory properties, as well as unsupervised learning from training data by reshaping the organoid functional connectivity, the study showed the potential of this technology by using it for speech recognition and nonlinear equation prediction in a reservoir computing framework.[4]
Ethical concerns
While researchers are hoping to use OI and biological computing to complement traditional silicon-based computing, there are also questions about the ethics of such an approach. Examples of such ethical issues include OIs gaining consciousness and sentience as organoids and the question of the relationship between a stem cell donor (for growing the organoid) and the respective OI system.[5]
References
- ↑ Smirnova, Lena; Caffo, Brian S.; Gracias, David H.; Huang, Qi; Morales Pantoja, Itzy E.; Tang, Bohao; Zack, Donald J.; Berlinicke, Cynthia A.; Boyd, J. Lomax; Harris, Timothy D.; Johnson, Erik C.; Kagan, Brett J.; Kahn, Jeffrey; Muotri, Alysson R.; Paulhamus, Barton L. (2023-02-28). "Organoid intelligence (OI): the new frontier in biocomputing and intelligence-in-a-dish". Frontiers in Science. 1. doi:10.3389/fsci.2023.1017235. ISSN 2813-6330.
- ↑ "Organoid intelligence: a new biocomputing frontier". Frontiers. Archived from the original on 2023-06-23. Retrieved 2024-01-11.
- ↑ Hollender, Liad. "Scientists unveil plan to create biocomputers powered by human brain cells". Frontiers. Archived from the original on 2024-01-10. Retrieved 2024-01-11.
- ↑ Cai, Hongwei; Ao, Zheng; Tian, Chunhui; Wu, Zhuhao; Liu, Hongcheng; Tchieu, Jason; Gu, Mingxia; MacKie, Ken; Guo, Feng (2023). "Brain organoid reservoir computing for artificial intelligence". Nature Electronics. 6 (12): 1032–1039. doi:10.1038/s41928-023-01069-w. S2CID 266278255.
- ↑ Smirnova, L.; Morales Pantoja, I. E.; Hartung, T. (2023). "Organoid intelligence (OI) - the ultimate functionality of a brain microphysiological system". Altex. 40 (2): 191–203. doi:10.14573/altex.2303261. PMID 37009773.