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A deep learning model to predict cell force from microscopy bright field images of single-cell or spheroid

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S2FApp
S2FApp
 
 
ckp
ckp
 
 
config
config
 
 
data
data
 
 
models
models
 
 
notebooks
notebooks
 
 
outputs
outputs
 
 
training
training
 
 
utils
utils
 
 
.gitattributes
.gitattributes
 
 
.gitignore
.gitignore
 
 
README.md
README.md
 
 
requirements.txt
requirements.txt
 
 

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tags license
biology
microscopy
traction-force
pytorch
pix2pix
gan
mit

Shape2Force (S2F)

Predict force maps from bright-field microscopy images of single-cell or spheroid.

If you find this software useful, please cite:

Lautaro Baro#, Kaveh Shahhosseini#, Amparo Andrés-Bordería, Claudio Angione*, and Maria Angeles Juanes*. "Shape-to-force (S2F): Predicting Cell Traction Forces from LabelFree Imaging", 2026.

Ways to Use S2F

1. Web App (local)

Run the Streamlit GUI from S2FApp/:

git clone https://github.com/Angione-Lab/Shape2Force.git
cd Shape2Force/S2FApp
pip install -r requirements.txt
streamlit run app.py
  1. Choose Model type: Single cell or Spheroid
  2. Place checkpoints (.pth) in S2FApp/ckp/ for local use.
  3. Select a Checkpoint from ckp/
  4. For single-cell: pick Substrate (e.g. fibroblasts_PDMS)
  5. Upload an image or pick from samples/
  6. Click Run prediction

2. Web App Online

Use the online app on Hugging Face.

Shape2Force Web App

3. Jupyter Notebooks

For interactive usage and custom analysis, use the notebooks in notebooks/:

  • notebooks/Singlecell_inference.ipynb – Load a folder of brightfield images, run single-cell predictions, plot samples, and save all predictions with metrics.
  • notebooks/Singlecell_evaluation.ipynb – Evaluate single-cell model on a dataset with ground truth; compute metrics and plot predictions.
  • notebooks/Spheroid_inference.ipynb – Run spheroid predictions on brightfield images, plot samples, and save predictions.
  • notebooks/Spheroid_evaluation.ipynb – Evaluate spheroid model on as dataset with ground truth; compute metrics and plot predictions.

Once cloned, open a notebook in Jupyter and adjust the configuration cell (paths, model type, substrate).

4. Training & Fine-Tuning

Dataset layout: A folder with train/ and test/ subfolders. Each subfolder has:

  • BF_001.tif (bright-field image)
  • *_gray.jpg (force map / heatmap)
  • Optional .txt (cell_area, sum_force)

Single-cell:

python -m training.train \
  --data path/to/dataset \
  --model single_cell \
  --epochs 100 \
  --substrate fibroblasts_PDMS

Spheroid:

python -m training.train \
  --data path/to/dataset \
  --model spheroid \
  --epochs 100

Resume / fine-tune from checkpoint:

python -m training.train \
  --data path/to/dataset \
  --model single_cell \
  --resume ckp/last_checkpoint.pth \
  --epochs 150

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A deep learning model to predict cell force from microscopy bright field images of single-cell or spheroid

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