TeraVR empowers precise reconstruction of complete 3-D neuronal morphology in the whole brain

Yimin Wang; Qi Li; Lijuan Liu; Zhi Zhou; Zongcai Ruan; Lingsheng Kong; Yaoyao Li; Yun Wang; Ning Zhong; Renjie Chai; Xiangfeng Luo; Yike Guo; Michael Hawrylycz; Qingming Luo; Zhongze Gu; Wei Xie; Hongkui Zeng; Hanchuan Peng

doi:10.1038/s41467-019-11443-y

TeraVR empowers precise reconstruction of complete 3-D neuronal morphology in the whole brain

Yimin Wang^*, Qi Li, Lijuan Liu, Zhi Zhou, Zongcai Ruan, Lingsheng Kong, Yaoyao Li, Yun Wang, Ning Zhong, Renjie Chai, Xiangfeng Luo, Yike Guo, Michael Hawrylycz, Qingming Luo, Zhongze Gu, Wei Xie, Hongkui Zeng, Hanchuan Peng

^*Corresponding author for this work

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

70 Citations (Scopus)

Abstract

Neuron morphology is recognized as a key determinant of cell type, yet the quantitative profiling of a mammalian neuron’s complete three-dimensional (3-D) morphology remains arduous when the neuron has complex arborization and long projection. Whole-brain reconstruction of neuron morphology is even more challenging as it involves processing tens of teravoxels of imaging data. Validating such reconstructions is extremely laborious. We develop TeraVR, an open-source virtual reality annotation system, to address these challenges. TeraVR integrates immersive and collaborative 3-D visualization, interaction, and hierarchical streaming of teravoxel-scale images. Using TeraVR, we have produced precise 3-D full morphology of long-projecting neurons in whole mouse brains and developed a collaborative workflow for highly accurate neuronal reconstruction.

Original language	English
Article number	3474
Journal	Nature Communications
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41467-019-11443-y
Publication status	Published - 1 Dec 2019
Externally published	Yes

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title = "TeraVR empowers precise reconstruction of complete 3-D neuronal morphology in the whole brain",

abstract = "Neuron morphology is recognized as a key determinant of cell type, yet the quantitative profiling of a mammalian neuron{\textquoteright}s complete three-dimensional (3-D) morphology remains arduous when the neuron has complex arborization and long projection. Whole-brain reconstruction of neuron morphology is even more challenging as it involves processing tens of teravoxels of imaging data. Validating such reconstructions is extremely laborious. We develop TeraVR, an open-source virtual reality annotation system, to address these challenges. TeraVR integrates immersive and collaborative 3-D visualization, interaction, and hierarchical streaming of teravoxel-scale images. Using TeraVR, we have produced precise 3-D full morphology of long-projecting neurons in whole mouse brains and developed a collaborative workflow for highly accurate neuronal reconstruction.",

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AU - Wang, Yimin

AU - Li, Qi

AU - Liu, Lijuan

AU - Zhou, Zhi

AU - Ruan, Zongcai

AU - Kong, Lingsheng

AU - Li, Yaoyao

AU - Wang, Yun

AU - Zhong, Ning

AU - Chai, Renjie

AU - Luo, Xiangfeng

AU - Guo, Yike

AU - Hawrylycz, Michael

AU - Luo, Qingming

AU - Gu, Zhongze

AU - Xie, Wei

AU - Zeng, Hongkui

AU - Peng, Hanchuan

PY - 2019/12/1

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N2 - Neuron morphology is recognized as a key determinant of cell type, yet the quantitative profiling of a mammalian neuron’s complete three-dimensional (3-D) morphology remains arduous when the neuron has complex arborization and long projection. Whole-brain reconstruction of neuron morphology is even more challenging as it involves processing tens of teravoxels of imaging data. Validating such reconstructions is extremely laborious. We develop TeraVR, an open-source virtual reality annotation system, to address these challenges. TeraVR integrates immersive and collaborative 3-D visualization, interaction, and hierarchical streaming of teravoxel-scale images. Using TeraVR, we have produced precise 3-D full morphology of long-projecting neurons in whole mouse brains and developed a collaborative workflow for highly accurate neuronal reconstruction.

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ER -

TeraVR empowers precise reconstruction of complete 3-D neuronal morphology in the whole brain

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