DoGNet: A deep architecture for synapse detection in multiplexed fluorescence images

Autor: Anne E. Carpenter, Syuan-Ming Guo, Mark Bathe, Allen Goodman, Victor Kulikov, Matthew T. Stone, Victor Lempitsky
Rok vydání: 2018
Předmět:
0301 basic medicine
Source code
Databases
Factual
Computer science
Physiology
Overfitting
Convolutional neural network
Multiplexing
Synaptic Transmission
Nervous System
Synapse
Mice
0302 clinical medicine
Fluorescence Microscopy
Image Processing
Computer-Assisted
Medicine and Health Sciences
Segmentation
Electron Microscopy
Biology (General)
media_common
Cerebral Cortex
Neurons
Microscopy
Ecology
Artificial neural network
Physics
Light Microscopy
Condensed Matter Physics
Electrophysiology
Computational Theory and Mathematics
Optical Equipment
Modeling and Simulation
Physical Sciences
Engineering and Technology
Anatomy
Research Article
Computer and Information Sciences
Difference of Gaussians
Neural Networks
QH301-705.5
Imaging Techniques
media_common.quotation_subject
Models
Neurological
Materials Science
Material Properties
Neurophysiology
Equipment
Nerve Tissue Proteins
Research and Analysis Methods
03 medical and health sciences
Cellular and Molecular Neuroscience
Fluorescence Imaging
Genetics
Animals
Computer Simulation
Molecular Biology
Ecology
Evolution
Behavior and Systematics
business.industry
Computational Biology
Biology and Life Sciences
Pattern recognition
Prisms
030104 developmental biology
Microscopy
Fluorescence
Multiphoton
Synapses
Anisotropy
Artificial intelligence
Neural Networks
Computer
business
030217 neurology & neurosurgery
Software
Neuroscience
Zdroj: PLoS Computational Biology
PLoS Computational Biology, Vol 15, Iss 5, p e1007012 (2019)
ISSN: 1553-7358
Popis: Neuronal synapses transmit electrochemical signals between cells through the coordinated action of presynaptic vesicles, ion channels, scaffolding and adapter proteins, and membrane receptors. In situ structural characterization of numerous synaptic proteins simultaneously through multiplexed imaging facilitates a bottom-up approach to synapse classification and phenotypic description. Objective automation of efficient and reliable synapse detection within these datasets is essential for the high-throughput investigation of synaptic features. Convolutional neural networks can solve this generalized problem of synapse detection, however, these architectures require large numbers of training examples to optimize their thousands of parameters. We propose DoGNet, a neural network architecture that closes the gap between classical computer vision blob detectors, such as Difference of Gaussians (DoG) filters, and modern convolutional networks. DoGNet is optimized to analyze highly multiplexed microscopy data. Its small number of training parameters allows DoGNet to be trained with few examples, which facilitates its application to new datasets without overfitting. We evaluate the method on multiplexed fluorescence imaging data from both primary mouse neuronal cultures and mouse cortex tissue slices. We show that DoGNet outperforms convolutional networks with a low-to-moderate number of training examples, and DoGNet is efficiently transferred between datasets collected from separate research groups. DoGNet synapse localizations can then be used to guide the segmentation of individual synaptic protein locations and spatial extents, revealing their spatial organization and relative abundances within individual synapses. The source code is publicly available: https://github.com/kulikovv/dognet.
Author summary Multiplexed fluorescence imaging of synaptic proteins facilitates high throughput investigations in neuroscience and drug discovery. Currently, there are several approaches to synapse detection using computational image processing. Unsupervised techniques rely on the a priori knowledge of synapse properties, such as size, intensity, and co-localization of synapse markers in each channel. For each experimental replicate, these parameters are typically tuned manually in order to obtain appropriate results. In contrast, supervised methods like modern convolutional networks require massive amounts of manually labeled data, and are sensitive to signal/noise ratios. As an alternative, here we propose DoGNet, a neural architecture that closes the gap between classical computer vision blob detectors, such as Difference of Gaussians (DoG) filters, and modern convolutional networks. This approach leverages the strengths of each approach, including automatic tuning of detection parameters, prior knowledge of the synaptic signal shape, and requiring only several training examples. Overall, DoGNet is a new tool for blob detection from multiplexed fluorescence images consisting of several up to dozens of fluorescence channels that requires minimal supervision due to its few input parameters. It offers the ability to capture complex dependencies between synaptic signals in distinct imaging planes, acting as a trainable frequency filter.
Databáze: OpenAIRE
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