Virtual reality-empowered deep-learning analysis of brain cells

Doris Kaltenecker; Rami Al-Maskari; Moritz Negwer; Luciano Hoeher; Florian Kofler; Shan Zhao; Mihail Todorov; Zhouyi Rong; Johannes Christian Paetzold; Benedikt Wiestler; Marie Piraud; Daniel Rueckert; Julia Geppert; Pauline Morigny; Maria Rohm; Bjoern H. Menze; Stephan Herzig; Mauricio Berriel Diaz; Ali Ertürk

doi:10.1038/s41592-024-02245-2

Virtual reality-empowered deep-learning analysis of brain cells

Doris Kaltenecker, Rami Al-Maskari, Moritz Negwer, Luciano Hoeher, Florian Kofler, Shan Zhao, Mihail Todorov, Zhouyi Rong, Johannes Christian Paetzold, Benedikt Wiestler, Marie Piraud, Daniel Rueckert, Julia Geppert, Pauline Morigny, Maria Rohm, Bjoern H. Menze, Stephan Herzig, Mauricio Berriel Diaz, Ali Ertürk

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

11 Scopus citations

Abstract

Automated detection of specific cells in three-dimensional datasets such as whole-brain light-sheet image stacks is challenging. Here, we present DELiVR, a virtual reality-trained deep-learning pipeline for detecting c-Fos⁺ cells as markers for neuronal activity in cleared mouse brains. Virtual reality annotation substantially accelerated training data generation, enabling DELiVR to outperform state-of-the-art cell-segmenting approaches. Our pipeline is available in a user-friendly Docker container that runs with a standalone Fiji plugin. DELiVR features a comprehensive toolkit for data visualization and can be customized to other cell types of interest, as we did here for microglia somata, using Fiji for dataset-specific training. We applied DELiVR to investigate cancer-related brain activity, unveiling an activation pattern that distinguishes weight-stable cancer from cancers associated with weight loss. Overall, DELiVR is a robust deep-learning tool that does not require advanced coding skills to analyze whole-brain imaging data in health and disease.

Original language	English
Journal	Nature Methods
DOIs	https://doi.org/10.1038/s41592-024-02245-2
State	Accepted/In press - 2024

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Kaltenecker, D., Al-Maskari, R., Negwer, M., Hoeher, L., Kofler, F., Zhao, S., Todorov, M., Rong, Z., Paetzold, J. C., Wiestler, B., Piraud, M., Rueckert, D., Geppert, J., Morigny, P., Rohm, M., Menze, B. H., Herzig, S., Berriel Diaz, M., & Ertürk, A. (Accepted/In press). Virtual reality-empowered deep-learning analysis of brain cells. Nature Methods. https://doi.org/10.1038/s41592-024-02245-2

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title = "Virtual reality-empowered deep-learning analysis of brain cells",

abstract = "Automated detection of specific cells in three-dimensional datasets such as whole-brain light-sheet image stacks is challenging. Here, we present DELiVR, a virtual reality-trained deep-learning pipeline for detecting c-Fos+ cells as markers for neuronal activity in cleared mouse brains. Virtual reality annotation substantially accelerated training data generation, enabling DELiVR to outperform state-of-the-art cell-segmenting approaches. Our pipeline is available in a user-friendly Docker container that runs with a standalone Fiji plugin. DELiVR features a comprehensive toolkit for data visualization and can be customized to other cell types of interest, as we did here for microglia somata, using Fiji for dataset-specific training. We applied DELiVR to investigate cancer-related brain activity, unveiling an activation pattern that distinguishes weight-stable cancer from cancers associated with weight loss. Overall, DELiVR is a robust deep-learning tool that does not require advanced coding skills to analyze whole-brain imaging data in health and disease.",

author = "Doris Kaltenecker and Rami Al-Maskari and Moritz Negwer and Luciano Hoeher and Florian Kofler and Shan Zhao and Mihail Todorov and Zhouyi Rong and Paetzold, {Johannes Christian} and Benedikt Wiestler and Marie Piraud and Daniel Rueckert and Julia Geppert and Pauline Morigny and Maria Rohm and Menze, {Bjoern H.} and Stephan Herzig and {Berriel Diaz}, Mauricio and Ali Ert{\"u}rk",

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year = "2024",

doi = "10.1038/s41592-024-02245-2",

language = "English",

journal = "Nature Methods",

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AU - Kaltenecker, Doris

AU - Al-Maskari, Rami

AU - Negwer, Moritz

AU - Hoeher, Luciano

AU - Kofler, Florian

AU - Zhao, Shan

AU - Todorov, Mihail

AU - Rong, Zhouyi

AU - Paetzold, Johannes Christian

AU - Wiestler, Benedikt

AU - Piraud, Marie

AU - Rueckert, Daniel

AU - Geppert, Julia

AU - Morigny, Pauline

AU - Rohm, Maria

AU - Menze, Bjoern H.

AU - Herzig, Stephan

AU - Berriel Diaz, Mauricio

AU - Ertürk, Ali

PY - 2024

Y1 - 2024

N2 - Automated detection of specific cells in three-dimensional datasets such as whole-brain light-sheet image stacks is challenging. Here, we present DELiVR, a virtual reality-trained deep-learning pipeline for detecting c-Fos+ cells as markers for neuronal activity in cleared mouse brains. Virtual reality annotation substantially accelerated training data generation, enabling DELiVR to outperform state-of-the-art cell-segmenting approaches. Our pipeline is available in a user-friendly Docker container that runs with a standalone Fiji plugin. DELiVR features a comprehensive toolkit for data visualization and can be customized to other cell types of interest, as we did here for microglia somata, using Fiji for dataset-specific training. We applied DELiVR to investigate cancer-related brain activity, unveiling an activation pattern that distinguishes weight-stable cancer from cancers associated with weight loss. Overall, DELiVR is a robust deep-learning tool that does not require advanced coding skills to analyze whole-brain imaging data in health and disease.

AB - Automated detection of specific cells in three-dimensional datasets such as whole-brain light-sheet image stacks is challenging. Here, we present DELiVR, a virtual reality-trained deep-learning pipeline for detecting c-Fos+ cells as markers for neuronal activity in cleared mouse brains. Virtual reality annotation substantially accelerated training data generation, enabling DELiVR to outperform state-of-the-art cell-segmenting approaches. Our pipeline is available in a user-friendly Docker container that runs with a standalone Fiji plugin. DELiVR features a comprehensive toolkit for data visualization and can be customized to other cell types of interest, as we did here for microglia somata, using Fiji for dataset-specific training. We applied DELiVR to investigate cancer-related brain activity, unveiling an activation pattern that distinguishes weight-stable cancer from cancers associated with weight loss. Overall, DELiVR is a robust deep-learning tool that does not require advanced coding skills to analyze whole-brain imaging data in health and disease.

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SN - 1548-7091

JO - Nature Methods

JF - Nature Methods

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Virtual reality-empowered deep-learning analysis of brain cells

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