Non-disruptive collagen characterization in clinical histopathology using cross-modality image synthesis
Second-harmonic Generation Collagen Image Synthesis from Hematoxylin and Eosin Image Using Image-to-image Translation Neural Network
Program for a complete H&E-SHG synthesizing workflow
Paper accepted at https://www.nature.com/articles/s42003-020-01151-5
Intensity-based registration algorithm repository: https://github.com/uw-loci/shg_he_registration
| Input H&E | Synthesized Collagen Image (SHG) |
|---|---|
 |
 |
download the source code and upzip it to a local drive,eg in windows
E:\he_shg_synth_workflow
Install miniconda
then launch "Anaconda prompt", yielding eg in windows the base environment of conda as below:
(base) C:\Users\AccountName>
Required packages
Make the source code directory(eg E:\he_shg_synth_workflow) as the current working folder, using the following commands (in Windows)
cd E:\he_shg_synth_workflow
E:
Installation option 1:
These two commands will change the current directory to:
(base) E:\he_shg_synth_workflow>
then install [Mambaforge windows 64](https://github.com/conda-forge/miniforge/releases/latest/download/Mambaforge-Windows-x86_64.exe)
follow the guide of the repo to install the packages:
conda env create --name synMF --file env.yml
conda activate synMF
pip3 install jpype1==1.3.0 (additional step)
pip3 install PyQt5 (additional step)
conda install -c jasonb857 importlib-metadata (additional step, version 3.10.1)
python main.py --pilot=0
Installation option 2:
first to install a PyImageJ environment with all packages satisfied
conda install mamba -n base -c conda-forge
mamba create -n pyimagej -c conda-forge pyimagej openjdk=8
conda activate pyimagej
Then, inside this environment, install dependencies for [PyTorch](https://pytorch.org/) and a bunch of other image processing packages such as sciki-image.
Execute download.py
python download.py
Execute main.py
python main.py --pilot=0
Output images are saved in "output_test_default" folder by default.
[--use-cuda] # 1: use GPU, 0: use CPU default: (int) 1
[--which-gpu] # index of the GPU default: (int) 0
[--input-folder] # name of input folder (input_test_[NAME]) default: (str) default
[--intensity] # output intensity rescale default: (tuple) (20, 180)
[--pilot] # 1: process the first image, 0: process all images default: (int) 0
Test customized images:
- Create a folder named "input_test_[NAME]" containing input images (images from a 40x Aperio CS2 scanner are recommended).
- Execute main.py with option "--input-folder=[NAME]".
python main.py --input-folder=[NAME]
- Output images are saved in "output_test_[NAME]" folder.
@article{keikhosravi_non-disruptive_2020,
title = {Non-disruptive collagen characterization in clinical histopathology using cross-modality image synthesis},
volume = {3},
copyright = {2020 The Author(s)},
issn = {2399-3642},
url = {https://www.nature.com/articles/s42003-020-01151-5},
doi = {10.1038/s42003-020-01151-5},
number = {1},
journal = {Communications Biology},
author = {Keikhosravi, Adib and Li, Bin and Liu, Yuming and Conklin, Matthew W. and Loeffler, Agnes G. and Eliceiri, Kevin W.},
month = jul,
year = {2020},
note = {Publisher: Nature Publishing Group},
pages = {1--12}
}