Implemenent DeepCAD-RT to denoise data by removing independent noise
Project description
DeepCAD-RT: A versatile toolbox for microscopy imaging denoising
Project page | Paper
Overview
Among the challenges of fluorescence microscopy, poor imaging signal-to-noise ratio (SNR) caused by limited photon budget lingeringly stands in the central position. Fluorescence microscopy is inherently sensitive to detection noise because the photon flux in fluorescence imaging is far lower than that in photography. For almost all fluorescence imaging technologies, the inherent shot-noise limit determines the upper bound of imaging SNR and restricts the imaging resolution, speed, and sensitivity. To capture enough fluorescence photons for satisfactory signal-to-noise ratio (SNR), researchers have to sacrifice imaging speed, resolution, and even sample health.
We present a versatile method DeepCAD-RT to denoise fluorescence images with rapid processing speed that can be incorporated with the microscope acquisition system to achieve real-time denoising. Our method is based on deep self-supervised learning and the original low-SNR data can be directly used for training convolutional networks, making it particularly advantageous in functional imaging where the sample is undergoing fast dynamics and capturing ground-truth data is hard or impossible. We have demonstrated extensive experiments including calcium imaging in mice, zebrafish, and flies, cell migration observations, and the imaging of a new genetically encoded ATP sensor, covering both 2D single-plane imaging and 3D volumetric imaging. Qualitative and quantitative evaluations show that our method can substantially enhance fluorescence time-lapse imaging data and permit high-sensitivity imaging of biological dynamics beyond the shot-noise limit.
For more details, please see the companion paper where the method first appeared: "Reinforcing neuron extraction and spike inference in calcium imaging using deep self-supervised denoising, Nature Methods (2021)".
Pytorch code
Our environment
- Ubuntu 16.04
- Python 3.6
- Pytorch 1.8.0
- NVIDIA GPU (GeForce RTX 3090) + CUDA (11.1)
Environment configuration
-
Create a virtual environment and install PyTorch. In the 3rd step, please select the correct Pytorch version that matches your CUDA version from https://pytorch.org/get-started/previous-versions/.
$ conda create -n deepcadrt python=3.6 $ conda activate deepcadrt $ pip install torch==1.8.0+cu111 torchvision==0.9.0+cu111 torchaudio==0.8.0 -f https://download.pytorch.org/whl/torch_stable.html
-
We made a pip installable realease of DeepCAD pypi. You can install it by simply entering following command:
$ pip install deepcad
Download the source code
$ git clone git://github.com/cabooster/DeepCAD-RT
$ cd DeepCAD-RT/DeepCAD_RT_pytorch/
Demos
To try out the python file, please activate deepcadrt
conda environment:
$ conda activate deepcadrt
$ cd DeepCAD-RT/DeepCAD_RT_pytorch/
Example training
To train your own DeepCAD-RT network, we recommend to start with the demo file demo_train_pipeline.py
in DeepCAD_RT_pytorch
subfolder. You can try our demo files directly or edit training parameters appropriate to your hardware and data.
python demo_train_pipeline.py
Example testing
To test the denoising performance with pre-trained models, you can use our demo data and correspoding models or edit parameters to test your own model in the demo file demo_test_pipeline.py
.
python demo_test_pipeline.py
Jupyter notebook
The notebooks demo_train_pipeline.ipynb
and demo_test_pipeline.ipynb
provide a simple and friendly way to implement DeepCAD-RT. They are located in the DeepCAD_RT_pytorch/notebooks
. Before you launch the Jupyter notebooks, please configure the deepcadrt
environment following the instruction in Environment configuration . And then, you can try out the notebooks by typing following commands:
$ conda activate deepcadrt
$ cd DeepCAD-RT/DeepCAD_RT_pytorch/notebooks
$ jupyter notebook
Colab notebook
We also provide a cloud-based demo implemented with Google Colab. You can run DeepCAD in your browser using a cloud GPU without configuring the environment.
This is a simple example with a slow rate because of the limited GPU performance offered by Colab. You can increase the train_datasets_size
and n_epochs
with a more powerful GPU, and training and testing time can be further shortened.
Matlab GUI
To achieve real-time denoising during imaging process, DeepCAD-RT is implemented on GPU with Nvidia TensorRT and delicately-designed time sequence to further accelerate the inference speed and decrease memory cost. We developed a user-friendly Matlab GUI for DeepCAD-RT , which is easy to install and convenient to use (has been tested on a Windows desktop with Intel i9 CPU and 128G RAM). Tutorials on installing and using the GUI has been moved to this page.
Results
1. Universal denoising for calcium imaging in zebrafish.
2. Denoising performance of DeepCAD-RT of neutrophils in the mouse brain in vivo.
3. Denoising performance of DeepCAD-RT on a recently developed genetically encoded ATP sensor.
More demo videos are demonstrated on our website.
Citation
If you use this code please cite the companion paper where the original method appeared:
Li, X., Zhang, G., Wu, J. et al. Reinforcing neuron extraction and spike inference in calcium imaging using deep self-supervised denoising. Nat Methods 18, 1395–1400 (2021). https://doi.org/10.1038/s41592-021-01225-0
@article{li2021reinforcing,
title={Reinforcing neuron extraction and spike inference in calcium imaging using deep self-supervised denoising},
author={Li, Xinyang and Zhang, Guoxun and Wu, Jiamin and Zhang, Yuanlong and Zhao, Zhifeng and Lin, Xing and Qiao, Hui and Xie, Hao and Wang, Haoqian and Fang, Lu and others},
journal={Nature Methods},
volume={18},
number={11},
pages={1395--1400},
year={2021},
publisher={Nature Publishing Group}
}
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