AI Article Synopsis
- Deep learning methods have shown great success in biomedical image processing, particularly for automatic diagnosis, but often prioritize accuracy over interpretability and appropriate data separation.
- Many studies shuffle data randomly for training and testing, which can lead to misleading accuracy and irrelevant feature learning since images from the same patient may be split across different sets.
- In contrast, models trained with strict patient-level separation demonstrate better performance on new patient images and provide clearer visualizations of relevant features, indicating a more reliable approach for improving real-life applicability.
Article Abstract
Following the great success of various deep learning methods in image and object classification, the biomedical image processing society is also overwhelmed with their applications to various automatic diagnosis cases. Unfortunately, most of the deep learning-based classification attempts in the literature solely focus on the aim of extreme accuracy scores, without considering interpretability, or patient-wise separation of training and test data. For example, most lung nodule classification papers using deep learning randomly shuffle data and split it into training, validation, and test sets, causing certain images from the Computed Tomography (CT) scan of a person to be in the training set, while other images of the same person to be in the validation or testing image sets. This can result in reporting misleading accuracy rates and the learning of irrelevant features, ultimately reducing the real-life usability of these models. When the deep neural networks trained on the traditional, unfair data shuffling method are challenged with new patient images, it is observed that the trained models perform poorly. In contrast, deep neural networks trained with strict patient-level separation maintain their accuracy rates even when new patient images are tested. Heat map visualizations of the activations of the deep neural networks trained with strict patient-level separation indicate a higher degree of focus on the relevant nodules. We argue that the research question posed in the title has a positive answer only if the deep neural networks are trained with images of patients that are strictly isolated from the validation and testing patient sets.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11408573 | PMC |
| http://dx.doi.org/10.1007/s13246-024-01419-8 | DOI Listing |
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