A deep learning strategy to identify cell types across species from high-density extracellular recordings

Maxime Beau; David J. Herzfeld; Francisco Naveros; Marie E. Hemelt; Federico D'Agostino; Marlies Oostland; Alvaro Sánchez-López; Young Yoon Chung; Michael Maibach; Stephen Kyranakis; Hannah N. Stabb; M. Gabriela Martínez Lopera; Agoston Lajko; Marie Zedler; Shogo Ohmae; Nathan J. Hall; Beverley A. Clark; Dana Cohen; Stephen G. Lisberger; Dimitar Kostadinov; Court Hull; Michael Häusser; Javier F. Medina

doi:10.1016/j.cell.2025.01.041

A deep learning strategy to identify cell types across species from high-density extracellular recordings

Maxime Beau, David J. Herzfeld, Francisco Naveros, Marie E. Hemelt, Federico D'Agostino, Marlies Oostland, Alvaro Sánchez-López, Young Yoon Chung, Michael Maibach, Stephen Kyranakis, Hannah N. Stabb, M. Gabriela Martínez Lopera, Agoston Lajko, Marie Zedler, Shogo Ohmae, Nathan J. Hall, Beverley A. Clark, Dana Cohen, Stephen G. Lisberger, Dimitar KostadinovCourt Hull, Michael Häusser, Javier F. Medina

Bar-Ilan University

Research output: Contribution to journal › Article › peer-review

Abstract

High-density probes allow electrophysiological recordings from many neurons simultaneously across entire brain circuits but fail to reveal cell type. Here, we develop a strategy to identify cell types from extracellular recordings in awake animals and reveal the computational roles of neurons with distinct functional, molecular, and anatomical properties. We combine optogenetics and pharmacology using the cerebellum as a testbed to generate a curated ground-truth library of electrophysiological properties for Purkinje cells, molecular layer interneurons, Golgi cells, and mossy fibers. We train a semi-supervised deep learning classifier that predicts cell types with greater than 95% accuracy based on the waveform, discharge statistics, and layer of the recorded neuron. The classifier's predictions agree with expert classification on recordings using different probes, in different laboratories, from functionally distinct cerebellar regions, and across species. Our classifier extends the power of modern dynamical systems analyses by revealing the unique contributions of simultaneously recorded cell types during behavior.

Original language	English
Pages (from-to)	2218-2234.e22
Journal	Cell
Volume	188
Issue number	8
Early online date	25 Feb 2025
DOIs	https://doi.org/10.1016/j.cell.2025.01.041
State	Published - 17 Apr 2025

Keywords

Neuropixels
cell-type identification
cerebellar cortex
cerebellum
circuit mapping
classification
machine learning
variational autoencoder

All Science Journal Classification (ASJC) codes

General Biochemistry,Genetics and Molecular Biology

Access to Document

10.1016/j.cell.2025.01.041

Cite this

Beau, M., Herzfeld, D. J., Naveros, F., Hemelt, M. E., D'Agostino, F., Oostland, M., Sánchez-López, A., Chung, Y. Y., Maibach, M., Kyranakis, S., Stabb, H. N., Martínez Lopera, M. G., Lajko, A., Zedler, M., Ohmae, S., Hall, N. J., Clark, B. A., Cohen, D., Lisberger, S. G., ... Medina, J. F. (2025). A deep learning strategy to identify cell types across species from high-density extracellular recordings. Cell, 188(8), 2218-2234.e22. https://doi.org/10.1016/j.cell.2025.01.041

@article{4108842e0f9549f6b7131f08fcc88518,

title = "A deep learning strategy to identify cell types across species from high-density extracellular recordings",

abstract = "High-density probes allow electrophysiological recordings from many neurons simultaneously across entire brain circuits but fail to reveal cell type. Here, we develop a strategy to identify cell types from extracellular recordings in awake animals and reveal the computational roles of neurons with distinct functional, molecular, and anatomical properties. We combine optogenetics and pharmacology using the cerebellum as a testbed to generate a curated ground-truth library of electrophysiological properties for Purkinje cells, molecular layer interneurons, Golgi cells, and mossy fibers. We train a semi-supervised deep learning classifier that predicts cell types with greater than 95% accuracy based on the waveform, discharge statistics, and layer of the recorded neuron. The classifier's predictions agree with expert classification on recordings using different probes, in different laboratories, from functionally distinct cerebellar regions, and across species. Our classifier extends the power of modern dynamical systems analyses by revealing the unique contributions of simultaneously recorded cell types during behavior.",

keywords = "Neuropixels, cell-type identification, cerebellar cortex, cerebellum, circuit mapping, classification, machine learning, variational autoencoder",

author = "Maxime Beau and Herzfeld, {David J.} and Francisco Naveros and Hemelt, {Marie E.} and Federico D'Agostino and Marlies Oostland and Alvaro S{\'a}nchez-L{\'o}pez and Chung, {Young Yoon} and Michael Maibach and Stephen Kyranakis and Stabb, {Hannah N.} and {Mart{\'i}nez Lopera}, {M. Gabriela} and Agoston Lajko and Marie Zedler and Shogo Ohmae and Hall, {Nathan J.} and Clark, {Beverley A.} and Dana Cohen and Lisberger, {Stephen G.} and Dimitar Kostadinov and Court Hull and Michael H{\"a}usser and Medina, {Javier F.}",

note = "Publisher Copyright: {\textcopyright} 2025",

year = "2025",

month = apr,

day = "17",

doi = "10.1016/j.cell.2025.01.041",

language = "الإنجليزيّة",

volume = "188",

pages = "2218--2234.e22",

journal = "Cell",

issn = "0092-8674",

publisher = "Elsevier B.V.",

number = "8",

}

Beau, M, Herzfeld, DJ, Naveros, F, Hemelt, ME, D'Agostino, F, Oostland, M, Sánchez-López, A, Chung, YY, Maibach, M, Kyranakis, S, Stabb, HN, Martínez Lopera, MG, Lajko, A, Zedler, M, Ohmae, S, Hall, NJ, Clark, BA, Cohen, D, Lisberger, SG, Kostadinov, D, Hull, C, Häusser, M & Medina, JF 2025, 'A deep learning strategy to identify cell types across species from high-density extracellular recordings', Cell, vol. 188, no. 8, pp. 2218-2234.e22. https://doi.org/10.1016/j.cell.2025.01.041

TY - JOUR

T1 - A deep learning strategy to identify cell types across species from high-density extracellular recordings

AU - Beau, Maxime

AU - Herzfeld, David J.

AU - Naveros, Francisco

AU - Hemelt, Marie E.

AU - D'Agostino, Federico

AU - Oostland, Marlies

AU - Sánchez-López, Alvaro

AU - Chung, Young Yoon

AU - Maibach, Michael

AU - Kyranakis, Stephen

AU - Stabb, Hannah N.

AU - Martínez Lopera, M. Gabriela

AU - Lajko, Agoston

AU - Zedler, Marie

AU - Ohmae, Shogo

AU - Hall, Nathan J.

AU - Clark, Beverley A.

AU - Cohen, Dana

AU - Lisberger, Stephen G.

AU - Kostadinov, Dimitar

AU - Hull, Court

AU - Häusser, Michael

AU - Medina, Javier F.

PY - 2025/4/17

Y1 - 2025/4/17

N2 - High-density probes allow electrophysiological recordings from many neurons simultaneously across entire brain circuits but fail to reveal cell type. Here, we develop a strategy to identify cell types from extracellular recordings in awake animals and reveal the computational roles of neurons with distinct functional, molecular, and anatomical properties. We combine optogenetics and pharmacology using the cerebellum as a testbed to generate a curated ground-truth library of electrophysiological properties for Purkinje cells, molecular layer interneurons, Golgi cells, and mossy fibers. We train a semi-supervised deep learning classifier that predicts cell types with greater than 95% accuracy based on the waveform, discharge statistics, and layer of the recorded neuron. The classifier's predictions agree with expert classification on recordings using different probes, in different laboratories, from functionally distinct cerebellar regions, and across species. Our classifier extends the power of modern dynamical systems analyses by revealing the unique contributions of simultaneously recorded cell types during behavior.

AB - High-density probes allow electrophysiological recordings from many neurons simultaneously across entire brain circuits but fail to reveal cell type. Here, we develop a strategy to identify cell types from extracellular recordings in awake animals and reveal the computational roles of neurons with distinct functional, molecular, and anatomical properties. We combine optogenetics and pharmacology using the cerebellum as a testbed to generate a curated ground-truth library of electrophysiological properties for Purkinje cells, molecular layer interneurons, Golgi cells, and mossy fibers. We train a semi-supervised deep learning classifier that predicts cell types with greater than 95% accuracy based on the waveform, discharge statistics, and layer of the recorded neuron. The classifier's predictions agree with expert classification on recordings using different probes, in different laboratories, from functionally distinct cerebellar regions, and across species. Our classifier extends the power of modern dynamical systems analyses by revealing the unique contributions of simultaneously recorded cell types during behavior.

KW - Neuropixels

KW - cell-type identification

KW - cerebellar cortex

KW - cerebellum

KW - circuit mapping

KW - classification

KW - machine learning

KW - variational autoencoder

UR - http://www.scopus.com/inward/record.url?scp=105000629799&partnerID=8YFLogxK

U2 - 10.1016/j.cell.2025.01.041

DO - 10.1016/j.cell.2025.01.041

M3 - مقالة

C2 - 40023155

SN - 0092-8674

VL - 188

SP - 2218-2234.e22

JO - Cell

JF - Cell

IS - 8

ER -

A deep learning strategy to identify cell types across species from high-density extracellular recordings

Abstract

Keywords

All Science Journal Classification (ASJC) codes

Access to Document

Other files and links

Fingerprint

Cite this