Neuronal Circuit and Synapse Analysis with Deep Neural Networks
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- Cite This Work
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Ghazi, Faezeh; Kha, Jason; Boassa, Daniela; Haberl, Matthias G. (2020). Neuronal Circuit and Synapse Analysis with Deep Neural Networks. In Data Science & Engineering Master of Advanced Study (DSE MAS) Capstone Projects. UC San Diego Library Digital Collections. https://doi.org/10.6075/J0QJ7FT8
- Description
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Biomedical image segmentation has led to numerous breakthroughs in neuroscience research by helping scientists map the brain. Brain mapping could be the key to understanding the progression of neurodegenerative diseases. Currently, the most accurate neural segmentations and synapse detections are annotated manually. However, manual annotation of synapses is unsustainable given the very large size of electron microscopy datasets of the brain. Deep learning tools such as CDeep3M can produce automated synapse segmentations on serial block-face scanning electron microscopy (SBEM), but the segmentations are relatively inaccurate. This is due to the numerous barriers including the inherent heterogeneity of neurons and their synapses and the limited tools for assessing and analyzing ultrastructure in molecularly defined synapses. Our developed solution for improving the automated segmentations of synapses, known as CDense3M, could help neuroscientists discover new insights in neurodegenerative diseases such as Alzheimer’s and Parkinson’s disease. We implement and apply two different modeling components to perform 3D segmentations and labeling to improve the accuracy of synaptic density segmentations. The first modeling component creates different algorithms for 3D concatenation, labeling, and filtering. As for 3D filtering, we also implement multiple models that use erosion and determine the statistical thresholds for 3D vesicle filtering on 3D objects. In each step of our 3D modeling, the new data is based off of previous modeling and as a result the data in each step of modeling becomes the new data for the next step. The evaluation for our image processing including 3D labeling and 2D and 3D vesicle filtering models is through the visualization and using the biological behavior of known neuronal structures. This improves the accuracy of defining the presynaptic areas based on the vesicle functions. The second modeling component applies flood-filling networks, a class of 3D convolutional neural networks, to perform cell-body segmentation on a 3D image volume. We train a custom flood-filling network model on membrane segmentations produced by the CDeep3M automated segmentation tool. The membrane model is more generalizable at segmenting cell bodies than the standard FIB-25 model trained on raw electron microscopy data from fruit flies. The improvement in the accuracy of presynaptic area recognition from applying both modeling components results in a 10% increase in precision and recall for the voxel-wise classification of synapses in a 3D image volume of the Nucleus accumbens from lab mice. This capstone project was conducted to fulfill the requirements for the Master of Advanced Study Degree in Data Science and Engineering at the University of California, San Diego.
- Scope And Content
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Unable to share the input and output data. They are being used for a future publication.
- Creation Date
- 2020-01-15 to 2020-06-05
- Date Issued
- 2020
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- Language
- English
- Identifier
- Related Resources
- GitHub repository of original algorithm code for CDeep3M version 2, a plug-and-play deep learning for image segmentation of large-scale microscopy data: https://github.com/CRBS/cdeep3m2
- Haberl, Matthias G., et al. "CDeep3M—Plug-and-Play cloud-based deep learning for image segmentation." Nature methods 15.9 (2018): 677-680. https://doi.org/10.1038/s41592-018-0106-z
- Januszewski, M., Kornfeld, J., Li, P.H. et al. High-precision automated reconstruction of neurons with flood-filling networks. Nat Methods 15, 605–610 (2018). https://doi.org/10.1038/s41592-018-0049-4
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Reference
- License
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Creative Commons Attribution 4.0 International Public License
- Rights Holder
- Ghazi, Faezeh; Kha, Jason
- Copyright
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Under copyright (US)
Use: This work is available from the UC San Diego Library. This digital copy of the work is intended to support research, teaching, and private study.
Constraint(s) on Use: This work is protected by the U.S. Copyright Law (Title 17, U.S.C.). Use of this work beyond that allowed by "fair use" or any license applied to this work requires written permission of the copyright holder(s). Responsibility for obtaining permissions and any use and distribution of this work rests exclusively with the user and not the UC San Diego Library. Inquiries can be made to the UC San Diego Library program having custody of the work.
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Research Data Curation Program, UC San Diego, La Jolla, 92093-0175 (https://lib.ucsd.edu/rdcp)
- Last Modified
2022-11-28