--- license: mit language: - en library_name: colipri pipeline_tag: zero-shot-image-classification --- # COLIPRI COLIPRI is a 3D vision–language transformer model trained to encode chest CT scans and reports. ## Model description COLIPRI was trained using tens of thousands of chest CT scans and reports, without any annotations, using multiple objectives to learn strong joint representations of 3D images and text. The procedure is described in detail in our manuscript, [_Comprehensive language-image pre-training for 3D medical image understanding_](https://arxiv.org/abs/2510.15042) (Wald et al. 2026). The weights shared here correspond to our best-performing model, COLIPRI-CRM. - **Developed by:** Microsoft Health Futures - **Model type:** 3D vision–language encoder - **License:** [MIT](./LICENSE) ## Uses COLIPRI is shared for research purposes only. It is **not meant to be used for clinical practice**. The encoders be plugged to other models, or used independently or jointly for many downstream tasks, such as: - Image classification with text prompts - Image clustering - Text clustering - Text-to-image retrieval - Image-to-image retrieval - Image-to-text retrieval - Text-to-text retrieval - Image classification with a classifier - Text classification with a classifier - Image segmentation with a decoder - Report generation with a language decoder Fine-tuning COLIPRI is typically not necessary to obtain good performance in downstream tasks. ## Getting started ### Installation ```shell pip install colipri ``` ### Usage examples Below we share some usage snippets to get started with COLIPRI. A more complete [Jupyter notebook](./COLIPRI_demo.ipynb) is also available. First, let's get a 3D chest CT we can use for demonstration. The plotted slices intersect a lung nodule near the heart. ```python >>> from colipri import load_sample_ct >>> image = load_sample_ct() >>> image ScalarImage(shape: (1, 512, 512, 139); spacing: (0.76, 0.76, 2.50); orientation: LPS+; dtype: torch.IntTensor; memory: 139.0 MiB) ``` The image looks like this: ![Input CT](assets/input.png) Now, let's instantiate the model and processor. ```python >>> from colipri import get_model >>> from colipri import get_processor >>> model = get_model().cuda() >>> processor = get_processor() ``` #### Zero-shot classification ```python >>> from colipri import ZeroShotImageClassificationPipeline >>> pipeline = ZeroShotImageClassificationPipeline(model, processor) >>> pipeline(image, ["No lung nodules", "Lung nodules"]) [ {'score': 0.005, 'label': 'No lung nodules'}, {'score': 0.995, 'label': 'Lung nodules'} ] ``` #### Feature extraction ```python >>> import torch >>> preprocessed_images = processor.process_images(image) >>> preprocessed_images[0] ScalarImage(shape: (1, 192, 192, 192); spacing: (2.00, 2.00, 2.00); orientation: SAR+; dtype: torch.FloatTensor; memory: 27.0 MiB) >>> images_batch = processor.to_images_batch(preprocessed_images) images_batch.shape torch.Size([1, 1, 192, 192, 192]) >>> with torch.no_grad(): ... patch_embeddings = model.encode_image(images_batch) >>> patch_embeddings.shape torch.Size([1, 768, 24, 24, 24]) >>> with torch.no_grad(): ... pooled_embeddings = model.encode_image(images_batch, pool=True, project=True) >>> pooled_embeddings.shape torch.Size([1, 768]) ``` ## Biases, risks, and limitations COLIPRI was trained with data from Turkey and the USA only, therefore it might be biased towards population in the training data. Underlying biases of the training datasets may not be well characterized. ## Environmental impact - **Hardware type:** NVIDIA A100 GPUs - **Hours used:** 72 hours × 4 GPUs = 288 GPU-hours - **Cloud provider:** Azure - **Compute region:** West US 2 - **Carbon emitted:** 21.6 kg CO₂ eq. ### Compute infrastructure COLIPRI was trained on [Azure Machine Learning](https://azure.microsoft.com/en-us/products/machine-learning). #### Hardware | Stage | Node type | Num. nodes | GPU type | GPUs per node | | --- | --- | --- | --- | --- | | Pre-training | [`Standard_NC96ads_A100_v4`](https://learn.microsoft.com/en-us/azure/virtual-machines/sizes/gpu-accelerated/nca100v4-series?tabs=sizeaccelerators) | 1 | NVIDIA A100 (80 GB) | 4 | | Evaluation | [`Standard_NC24ads_A100_v4`](https://learn.microsoft.com/en-us/azure/virtual-machines/sizes/gpu-accelerated/nca100v4-series?tabs=sizeaccelerators) | 1 | NVIDIA A100 (80 GB) | 1 | #### Software The main software libraries used in this work were [nnSSL](https://github.com/MIC-DKFZ/nnssl) for training, [TorchIO](https://torchio.org/) for preprocessing and augmentation, [`nifti-zarr-py`](https://github.com/neuroscales/nifti-zarr-py) for data loading, and [nnU-Net](https://github.com/MIC-DKFZ/nnUNet) for segmentation evaluation. ## Citation ### BibTeX ```bibtex @misc{ wald2026_colipri, title={Comprehensive language-image pre-training for 3D medical image understanding}, author={Tassilo Wald and Ibrahim Ethem Hamamci and Yuan Gao and Sam Bond-Taylor and Harshita Sharma and Maximilian Ilse and Cynthia Lo and Olesya Melnichenko and Anton Schwaighofer and Noel C. F. Codella and Maria Teodora Wetscherek and Klaus H. Maier-Hein and Panagiotis Korfiatis and Valentina Salvatelli and Javier Alvarez-Valle and P{\'e}rez-Garc{\'i}a}, year={2026}, eprint={2510.15042}, archivePrefix={arXiv}, primaryClass={cs.CV}, url={https://arxiv.org/abs/2510.15042}, } ``` ### APA > Wald, T., Hamamci, I. E., Gao, Y., Bond-Taylor, S., Sharma, H., Ilse, M., Lo, C., Melnichenko, O., Schwaighofer, A., Codella, N. C. F., Wetscherek, M. T., Maier-Hein, K. H., Korfiatis, P., Salvatelli, V., Alvarez-Valle, J., & Pérez-García, F. (2026). Comprehensive language-image pre-training for 3D medical image understanding. arXiv. ## Model card contact Fernando Pérez-García ([`fperezgarcia@microsoft.com`](mailto:fperezgarcia@microsoft.com)).