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Published January 23, 2017 | Supplemental Material
Journal Article Open

Neural Circuit Inference from Function to Structure

Real, Esteban
Asari, Hiroki
Gollisch, Tim
Meister, Markus ORCID icon

Abstract

Advances in technology are opening new windows on the structural connectivity and functional dynamics of brain circuits. Quantitative frameworks are needed that integrate these data from anatomy and physiology. Here, we present a modeling approach that creates such a link. The goal is to infer the structure of a neural circuit from sparse neural recordings, using partial knowledge of its anatomy as a regularizing constraint. We recorded visual responses from the output neurons of the retina, the ganglion cells. We then generated a systematic sequence of circuit models that represents retinal neurons and connections and fitted them to the experimental data. The optimal models faithfully recapitulated the ganglion cell outputs. More importantly, they made predictions about dynamics and connectivity among unobserved neurons internal to the circuit, and these were subsequently confirmed by experiment. This circuit inference framework promises to facilitate the integration and understanding of big data in neuroscience.

Additional Information

© 2016 Elsevier Ltd. Received 12 September 2016, Revised 17 November 2016, Accepted 17 November 2016, Available online 5 January 2017 Published: January 5, 2017. We would like to thank Ofer Mazor, Haim Sompolinsky, Arjun Krishnaswami, Yoram Burak, Uri Rokni, Andreas Liu, Evan Feinberg, Joel Greenwood, Stan Cotreau, Aravinthan Samuel, and especially Edward Soucy for many useful discussions. This work was supported by Harvard's Mind/Brain/Behavior Initiative (E.R.), a Gosney postdoctoral fellowship at Caltech (H.A.), and grants from the NIH (7R01EY014737 and 1U01NS090562 to M.M.). Author Contributions: E.R. performed the extracellular array recordings constituting the main dataset. H.A. performed the simultaneous intracellular and extracellular recordings used to test the models. M.M., E.R., and T.G. designed the models; E.R. coded the models and ran the simulations; and E.R. and H.A. analyzed the results. E.R., H.A., and M.M. wrote the manuscript.

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August 22, 2023
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October 24, 2023