A team of researchers from the University of Granada and the University of Seville, led by Juan Antonio Marchal Corrales and Miguel Ángel Gutiérrez Naranjo respectively, has published an innovative study in which an Artificial Intelligence is designed to improve the prediction of the evolution of cell migration in breast cancer. The study, entitled Using Deep Learning for Predicting the Dynamic Evolution of Breast Cancer Migration, represents an important advance in the combination of deep learning techniques and computational biology.
The multidisciplinary work, with the participation of Francisco M. García Moreno and PhD student Jesús Ruiz Espigares, both from the University of Granada, focuses on the development of a predictive framework called Prediction Wound Progression Framework (PWPF). This framework harnesses the power of deep learning to analyze and predict cell migration in two-dimensional models--technically known as Wound Healing--providing new insights into the understanding of the metastatic process of breast cancer.
"Metastasis is the main cause of mortality in breast cancer patients and understanding how cell migration occurs is crucial to develop better therapeutic strategies," explains Jesús Ruiz, co-principal investigator of the Department of Human Anatomy and Embryology at the University of Granada and member of the Center for Biomedical Research (CIBM).
The team has developed a Conv-LSTM-based neural network architecture that takes advantage of both the spatial and temporal characteristics of cell migration data. This architecture enables accurate prediction of the evolution of the Wound Healing technique over time, improving the ability to analyze the dynamics in the context of breast cancer models. This automated approach can be applied to more complex 3D models that better mimic tumor characteristics and promises to open new avenues for cancer research and treatment.
The research is the result of a multidisciplinary collaboration between different departments and centers: the Department of Languages and Computer Systems (LSI), the Department of Human Anatomy and Embryology and CITIC of the University of Granada, the Singular Laboratory BioFabi3D_Biofabrication and 3D (bio)printing of the CIBM, the Unit of Excellence "Modeling Nature" and the Institute of Biosanitary Research ibs.GRANADA, as well as the Department of Computer Science and Artificial Intelligence of the University of Seville.
The team’s breakthrough not only stands out for its scientific contribution, but also for its accessibility and promotion of open access, as the code and data generated are publicly available in its GitHub and Zenodo repositories, fostering open access and international collaboration in cancer research.
The project has been carried out thanks to funding from the Ministry of Science, Innovation and Universities (MICIN), the Ministry of Health of the Andalusian Regional Government and the Doctors Galera and Requena Chair of Research in Cancer Stem Cells of the UGR.