UNI-EM: An Environment for Deep Neural Network-Based Automated Segmentation of Neuronal Electron Microscopic Images

Urakubo, Hidetoshi; Bullmann, Torsten; Kubota, Yoshihiro; Oba, Shigeyuki; Ishii, Shin

doi:10.1038/s41598-019-55431-0

Cited by 32 publications

(24 citation statements)

References 36 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This raises a genuine concern about inter-animal variability and, therefore, the reproducibility of data sets. To surmount these limitations, several automated segmentation tools have recently been developed that use machine learning approaches (Arganda-Carreras et al, 2015 ; Berger et al, 2018 ; Lee et al, 2019 ; Urakubo et al, 2019 ) and the continuous refinement of segmentation tools aims to make their accuracy similar to that of a human annotator. With the future development of imaging and analysis tools, it will be possible to substantially increase the throughput of three-dimensional studies.…”

Section: Technical Considerations and Limitations Of Volume Em Studiesmentioning

confidence: 99%

Three-Dimensional Structure of Dendritic Spines Revealed by Volume Electron Microscopy Techniques

Parajuli

Koike

2021

Front. Neuroanat.

View full text Add to dashboard Cite

Electron microscopy (EM)-based synaptology is a fundamental discipline for achieving a complex wiring diagram of the brain. A quantitative understanding of synaptic ultrastructure also serves as a basis to estimate the relative magnitude of synaptic transmission across individual circuits in the brain. Although conventional light microscopic techniques have substantially contributed to our ever-increasing understanding of the morphological characteristics of the putative synaptic junctions, EM is the gold standard for systematic visualization of the synaptic morphology. Furthermore, a complete three-dimensional reconstruction of an individual synaptic profile is required for the precise quantitation of different parameters that shape synaptic transmission. While volumetric imaging of synapses can be routinely obtained from the transmission EM (TEM) imaging of ultrathin sections, it requires an unimaginable amount of effort and time to reconstruct very long segments of dendrites and their spines from the serial section TEM images. The challenges of low throughput EM imaging have been addressed to an appreciable degree by the development of automated EM imaging tools that allow imaging and reconstruction of dendritic segments in a realistic time frame. Here, we review studies that have been instrumental in determining the three-dimensional ultrastructure of synapses. With a particular focus on dendritic spine synapses in the rodent brain, we discuss various key studies that have highlighted the structural diversity of spines, the principles of their organization in the dendrites, their presynaptic wiring patterns, and their activity-dependent structural remodeling.

show abstract

Section: Technical Considerations and Limitations Of Volume Em Studiesmentioning

confidence: 99%

Three-Dimensional Structure of Dendritic Spines Revealed by Volume Electron Microscopy Techniques

Parajuli

Koike

2021

Front. Neuroanat.

View full text Add to dashboard Cite

show abstract

“…Unfortunately, in many cases, the application of these methods is not easy and requires significant knowledge in computer sciences, making it difficult to adapt by many researchers. Software developers have already started to address this challenge by developing user-friendly deep learning tools, such as Cell Profiler [ 10 ], Ilastik [ 11 ], ImageJ plug-ins DeepImageJ [ 12 ] and U-net [ 13 ], CDeep3M [ 5 ], and Uni-EM [ 14 ] that are especially suitable for biological projects. However, the overall usability is limited because they either rely on pre-trained networks without the possibility of training on new data [ 10 – 12 ], are limited to electron microscopy (EM) datasets [ 14 ], or have specialized computing requirements [ 5 , 13 ].…”

Section: Introductionmentioning

confidence: 99%

DeepMIB: User-friendly and open-source software for training of deep learning network for biological image segmentation

Belevich

Jokitalo

2021

PLoS Comput Biol

View full text Add to dashboard Cite

We present DeepMIB, a new software package that is capable of training convolutional neural networks for segmentation of multidimensional microscopy datasets on any workstation. We demonstrate its successful application for segmentation of 2D and 3D electron and multicolor light microscopy datasets with isotropic and anisotropic voxels. We distribute DeepMIB as both an open-source multi-platform Matlab code and as compiled standalone application for Windows, MacOS and Linux. It comes in a single package that is simple to install and use as it does not require knowledge of programming. DeepMIB is suitable for everyone interested of bringing a power of deep learning into own image segmentation workflows.

show abstract

“…https://www.zooniverse.org/projects/h-spiers/etch-a-cell) [44]. Alternatively, computational approaches with traditional algorithms or deep learning approaches have been proposed to detect membrane neuronal and mitosis detection in breast cancer [45], mitochondria [46,47], synapses [48] and proteins [49]. Besides the well-known limitations of deep learning architectures, of significant computational power, large amount of training data and problems with unrelated datasets which show little value for unseen biological situations [50][51][52][53][54][55], the resolution of the EM data sets can enable or restrict their use for specific purposes.…”

Section: Introductionmentioning

confidence: 99%

Volumetric Semantic Instance Segmentation of the Plasma Membrane of HeLa Cells

Karabağ

Jones

Reyes-Aldasoro

2021

Preprint

View full text Add to dashboard Cite

In this work, the unsupervised volumetric semantic segmentation of the plasma membrane of HeLa cells as observed with Serial Block Face Scanning Electron Microscopy is described. The resin background of the images was segmented at different slices of a 3D stack of 518 slices with 8, 192 x 8, 192 pixels each. The background was used to create a distance map which helped identify and rank the cells by their size at each slice. The centroids of the cells detected at different slices were linked to identify them as a single cell that spanned a number of slices. A subset of these cells, i.e., largest ones and those not close to the edges were selected for further processing. The selected cells were then automatically cropped to smaller regions of interest of 2, 000 x 2, 000 x 300 voxels that were treated as cell instances. Then, for each of these volumes the nucleus was segmented and the cell was separated from any neighbouring cells through a series of traditional image processing steps that followed the plasma membrane. The segmentation process was repeated for all the regions selected. For one cell for which the ground truth was available, the algorithm provided excellent results in Accuracy (AC) and Jaccard Index (JI): Nucleus: JI = 0.9665, AC= 0.9975, Cell and Nucleus JI = 0.8711, AC = 0.9655, Cell only JI = 0.8094, AC = 0.9629. A limitation of the algorithm for the plasma membrane segmentation was the presence of background, as in cases of tightly packed cells. When tested for these conditions, the segmentation of the nuclear envelope was still possible. All the code and data are released openly through GitHub, Zenodo and EMPIAR.

show abstract

UNI-EM: An Environment for Deep Neural Network-Based Automated Segmentation of Neuronal Electron Microscopic Images

Cited by 32 publications

References 36 publications

Three-Dimensional Structure of Dendritic Spines Revealed by Volume Electron Microscopy Techniques

Three-Dimensional Structure of Dendritic Spines Revealed by Volume Electron Microscopy Techniques

DeepMIB: User-friendly and open-source software for training of deep learning network for biological image segmentation

Volumetric Semantic Instance Segmentation of the Plasma Membrane of HeLa Cells

Contact Info

Product

Resources

About