PyTomography

Why?

PyTomography is an open-source, GPU-accelerated python library which provides both extensive system modeling for SPECT/PET systems as well as associated reconstruction algorithms for quantitative imaging. It aims at creating a central platform for the development, validation, and deployment of novel tomographic reconstruction algorithms. For those familiar with python programming, it is simple to install and use, and there are a variety of tutorials available to assist in learning the software.

Where to find it?

The source code can be found on github (https://github.com/qurit/PyTomography). Documentation, installation instructions, and tutorials can be found at https://pytomography.readthedocs.io/en/latest/

Sample Results

Coronal slices of activity concentration (colored) and Hounsfield Unit values (greyscale) reconstructed using the OSEM, BSREM, and KEM algorithms. Data corresponds to the first time point of patient 4 from the ``Lu-177 DOTATATE Anonymized Patient Datasets: Multi-Time Point Lu-177 SPECT/CT Scans'' dataset (https://deepblue.lib.umich.edu/data/concern/data_sets/dn39x173n?locale=…)

Introduction

While the development of new reconstruction techniques remains an active field of research it can often be difficult to share and disseminate one’s findings. Additionally, while manufacturers of tomographic modalities such as Single Photon Emission Computed Tomography (SPECT) and Positron Emission Tomography (PET) cameras provide their own internal reconstruction algorithms, users cannot access all the implementation details; this limits reproducibility in scientific studies focused on assessing reconstruction algorithms. These issues can be solved by moving to an open-source paradigm for medical image reconstruction. Here, the imaging community can easily contribute to the implementation of novel reconstruction and correction algorithms in a way that is open and transparent. Such a framework will allow for the standardization needed to produce comparable results, improving the reliability, validity, and reproducibility of findings. This can ultimately help accelerate the development and translation of new diagnostic imaging capabilities into clinical practice.

PyTomography provides GPU-accelerated implementation of a variety of reconstruction algorithms for fast implementation and to promote research comparing reconstruction algorithms in different imaging domains. In addition, it provides features for assisting in the reconstruction of clinical DICOM data, such as (i) creation/alignment of attenuation maps from CT data (ii) stitching reconstructions from multiple bed positions. The list of available features is kept up to date on the readthedocs home page (https://pytomography.readthedocs.io/en/latest/).

How to cite PyTomography

If you are incorporating PyTomography in one of your projects, we kindly request that you cite us in one of the following ways

Polson L, Fedrigo R, Li C, Sabouri M, Dzikunu O, Ahamed S, Rahmim A, Uribe C
PyTomography: A Python Library for Quantitative Medical Image Reconstruction.
arXiv preprint arXiv:2309.01977 (2023).

BibTeX:

@misc{polson2023pytomography,

      title={PyTomography: A Python Library for Quantitative Medical Image Reconstruction},

      author={Lucas Polson and Roberto Fedrigo and Chenguang Li and Maziar Sabouri and Obed Dzikunu and Shadab Ahamed and Arman Rahmim and Carlos Uribe},

      year={2023},

      eprint={2309.01977},

      archivePrefix={arXiv},

      primaryClass={physics.med-ph}

}

Back to top