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Conventional Machine Learning versus Deep Learning for Magnification Dependent Histopathological Breast Cancer Image

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Summary
This summary is machine-generated.

This study compares conventional machine learning (CML) and deep learning (DL) for breast cancer diagnosis from histopathological images. DL methods show superior performance and provide visual explanations, enhancing trust in AI for early cancer detection.

Keywords:
breast cancerconventional machine learningdeep learninghistopathological imagestransfer learningvisual explanation

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Area of Science:

  • Medical Imaging
  • Artificial Intelligence
  • Computational Pathology

Background:

  • Breast cancer diagnosis relies heavily on histopathological image analysis.
  • Existing computer-aided diagnosis (CAD) methods often lack interpretability.
  • There is a need for explainable AI in medical diagnostics.

Purpose of the Study:

  • To compare the performance of conventional machine learning (CML) and deep learning (DL) methods for breast cancer classification.
  • To provide visual interpretations of classification decisions for improved clinical trust.
  • To evaluate the efficacy of DL models using attention maps for explainability.

Main Methods:

  • Handcrafted feature extraction and classical classifiers for CML methods.
  • Transfer learning with the VGG-19 deep learning architecture for DL methods.
  • Evaluation on the BreaKHis and KIMIA Path960 datasets, with attention map visualization for DL interpretability.

Main Results:

  • Deep learning methods outperformed conventional machine learning approaches.
  • DL achieved accuracies between 85.65%-89.32% (binary) and 63.55%-69.69% (eight-class).
  • Visual explanations using attention maps enhanced the interpretability of DL models.

Conclusions:

  • Deep learning models offer superior performance for breast cancer classification from histopathological images.
  • Visual interpretability through attention maps increases pathologist trust in AI diagnostic tools.
  • Explainable AI holds significant promise for supporting clinical decision-making in breast cancer diagnosis.