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Predicting Protein Cascade Expression from H&E Images.

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Summary
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Predicting downstream protein expression in cancer is crucial. A new cellular-level AI model, CellViT, successfully predicts apoptosis cascade proteins from pathology images, outperforming traditional patch-level approaches.

Keywords:
Artificial IntelligenceGeneticsOmicsReverse Phase Protein ArrayVision Transformers

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Area of Science:

  • Computational pathology
  • Artificial intelligence in oncology
  • Biomedical data analysis

Background:

  • Protein expression in oncogenic pathways is key to cancer development.
  • Predicting downstream protein signals is essential for understanding cancer progression.
  • Current AI models often predict single proteins, lacking insight into signal propagation.

Purpose of the Study:

  • To develop and evaluate an AI model for predicting downstream protein expression in breast cancer.
  • To compare the performance of cellular-level versus patch-level Vision Transformers (ViT) for this task.
  • To assess the utility of apoptosis and DNA damage/repair (DDR) cascades for predicting protein expression.

Main Methods:

  • Utilized Reverse Phase Protein Array (RPPA) and whole-slide images (WSIs) from the TCGA-BRCA dataset.
  • Developed a cellular-level ViT model (CellViT) and compared it with patch-level ViT models.
  • Focused on predicting five key proteins in the apoptosis cascade, using DDR cascades as a control.

Main Results:

  • Patch-level ViT models failed to achieve statistically significant predictive results (R-squared values < 0.1).
  • CellViT demonstrated predictive capabilities, achieving R-squared values > 0.1 across five test folds.
  • The apoptosis cascade, being morphologically indicative, yielded significantly higher predictive performance than the DDR cascade.

Conclusions:

  • Cellular-level AI models, like CellViT, are more effective than patch-level models for predicting downstream protein expression from WSIs.
  • Morphologically relevant biological pathways, such as apoptosis, are better targets for AI-driven protein expression prediction.
  • This approach offers a novel way to infer functional protein signaling in cancer.