Author
Listed:
- Xudong Lin
(City University of Hong Kong)
- Xin Duan
(City University of Hong Kong)
- Claire Jacobs
(Department of Neurology, Harvard Medical School)
- Jeremy Ullmann
(Department of Neurology, Harvard Medical School)
- Chung-Yuen Chan
(City University of Hong Kong)
- Siya Chen
(City University of Hong Kong)
- Shuk-Han Cheng
(City University of Hong Kong)
- Wen-Ning Zhao
(Department of Neurology, Harvard Medical School)
- Annapurna Poduri
(Department of Neurology, Harvard Medical School)
- Xin Wang
(City University of Hong Kong
City University of Hong Kong)
- Stephen J. Haggarty
(Department of Neurology, Harvard Medical School)
- Peng Shi
(City University of Hong Kong
City University of Hong Kong)
Abstract
Technologies for mapping the spatial and temporal patterns of neural activity have advanced our understanding of brain function in both health and disease. An important application of these technologies is the discovery of next-generation neurotherapeutics for neurological and psychiatric disorders. Here, we describe an in vivo drug screening strategy that combines high-throughput technology to generate large-scale brain activity maps (BAMs) with machine learning for predictive analysis. This platform enables evaluation of compounds’ mechanisms of action and potential therapeutic uses based on information-rich BAMs derived from drug-treated zebrafish larvae. From a screen of clinically used drugs, we found intrinsically coherent drug clusters that are associated with known therapeutic categories. Using BAM-based clusters as a functional classifier, we identify anti-seizure-like drug leads from non-clinical compounds and validate their therapeutic effects in the pentylenetetrazole zebrafish seizure model. Collectively, this study provides a framework to advance the field of systems neuropharmacology.
Suggested Citation
Xudong Lin & Xin Duan & Claire Jacobs & Jeremy Ullmann & Chung-Yuen Chan & Siya Chen & Shuk-Han Cheng & Wen-Ning Zhao & Annapurna Poduri & Xin Wang & Stephen J. Haggarty & Peng Shi, 2018.
"High-throughput brain activity mapping and machine learning as a foundation for systems neuropharmacology,"
Nature Communications, Nature, vol. 9(1), pages 1-12, December.
Handle:
RePEc:nat:natcom:v:9:y:2018:i:1:d:10.1038_s41467-018-07289-5
DOI: 10.1038/s41467-018-07289-5
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