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Fixation and Sectioning01:03

Fixation and Sectioning

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Two basic types of preparation are used to visualize specimens with a light microscope: wet mounts and fixed specimens.
The simplest type of preparation is the wet mount, in which the specimen is placed in a drop of liquid on the slide. A liquid specimen can be directly deposited on the slide using a dropper. Solid specimens, such as skin scraping, can be placed on the slide before adding a drop of liquid to prepare the wet mount. Sometimes the liquid is simply water, but stains are often added...
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Deceptive learning in histopathology.

Sahar Shahamatdar1,2, Daryoush Saeed-Vafa3, Drew Linsley4,5

  • 1Center for Computational Molecular Biology, Brown University, Providence, RI, USA.

Histopathology
|April 1, 2024
PubMed
Summary
This summary is machine-generated.

Deep neural networks (DNNs) show promise in histopathology but can learn deceptive strategies. While trustworthy for tumor detection, DNNs failed to generalize for molecular profiling due to spurious correlations.

Keywords:
KRAScomputational pathologydeep learningexplainable artificial intelligencemolecular profiling

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Area of Science:

  • Computational pathology
  • Artificial intelligence in medicine
  • Histopathology image analysis

Background:

  • Deep learning (DL) offers potential for automating histopathology tasks and discovering novel biological insights.
  • Systematic evaluation of the trustworthiness of visual strategies learned by DL models in histopathology is lacking.

Purpose of the Study:

  • To systematically evaluate deep neural networks (DNNs) trained for histopathological analysis.
  • To determine if DNNs' learned strategies are trustworthy or deceptive.

Main Methods:

  • Trained various DNNs on 221 whole-slide images (WSIs) of lung adenocarcinoma.
  • Evaluated DNNs on molecular profiling (KRAS vs. EGFR mutations), primary tissue determination, and tumor detection.

Main Results:

  • DNNs achieved above-chance performance in molecular profiling by exploiting correlations between histological subtypes and mutations, failing to generalize to laser capture microdissection (LCM) test sets.
  • DNNs learned robust and trustworthy strategies for primary tissue determination and tumor detection/localization.

Conclusions:

  • DNNs show promise for aiding pathologists but can learn deceptive strategies using spurious correlations, rendering them unsuitable for research or clinical use.
  • A proposed framework for model evaluation and interpretation is crucial for developing reliable automated histopathological analysis systems.