Week 11: Cellular pathology

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    Created by
    Deborah Otunji

    Cards (13)

    • Sample Types and Their Importance
      • Small Tissue Samples
      • Medium Tissue Samples
      • Large Tissue Samples
      • Cytological Samples
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    • Small Tissue Samples
      • Endoscopic Samples: Obtained from colon, esophagus, and bronchial tubes; essential for diagnosing diseases accessible via luminal surfaces
      • Needle Biopsy: Used for organs like liver, lung, breast, and prostate; crucial for diagnosing solid tumors
      • Scrapes/Curettings: Involves mechanical removal of epithelium, such as skin or endometrial curettings, typically for surface lesions
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    • Medium Tissue Samples
      • Incisional Biopsy: A diagnostic approach involving the removal of a small portion of tissue including the lesion and some normal tissue to determine the nature of the abnormality
      • Excisional Biopsy: Curative procedure where the entire lesion or affected organ is removed with a margin of healthy tissue to ensure no residual disease
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    • Large Tissue Samples
      • These can include whole organs or large resections, both benign and malignant, and are critical for removing diseased tissue completely to prevent the spread of conditions like cancer
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    • Immunohistochemistry (IHC)

      • Technique: Involves the layering of specific antibodies to detect proteins or antigens within tissues, used for both diagnostic and prognostic purposes
      • Applications: Identifies markers such as ER and PR in breast cancer, which can predict response to treatments like Tamoxifen or Herceptin
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    • Immunofluorescence (IMF)

      • Direct IMF: Used for diagnosing conditions like pemphigus or renal diseases by detecting immune deposits in tissues
      • Indirect IMF: Utilizes patient serum to detect auto-antibodies against specific tissue antigens, critical in diagnosing autoimmune diseases
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    • Fluorescence In Situ Hybridisation (FISH)

      • Application: Particularly useful in oncology for identifying chromosomal abnormalities in cancer cells, such as HER2 gene amplification in breast cancer, which determines the suitability of specific therapies
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    • Polymerase Chain Reaction (PCR)

      • Utility: Amplifies DNA to detect very low levels of genetic material, useful in identifying pathogens, cancer markers, or genetic mutations from minute samples
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      1. Fixation: Stops cellular breakdown and preserves tissue architecture. Formalin is most commonly used due to its effectiveness in preserving cellular details
    • 2. Processing: To replace tissue water with wax, providing stability for thin sectioning. Tissue samples undergo a sequence from formalin to alcohol (IMS), xylene, and then to wax
    • 3. Embedding and Sectioning:

      Embedding - Tissue is oriented in wax within a cassette to ensure proper alignment for slicing.

      Sectioning - Achieved using a microtome to cut thin tissue sections (2-4 µm thick) that allow for light transmission during microscopy
    • 4. Staining:
      Routine Staining (H&E) - Haematoxylin binds to acidic components of the nucleus, and eosin stains basic cellular structures, providing a contrast essential for distinguishing cellular components under a microscope.

      Special Stains and IHC - Used when routine stains do not provide enough detail.
      IHC employs antibodies tagged with dyes to highlight specific cellular antigens, aiding in detailed diagnosis and prognostic evaluations
    • Histopathology Sample Handling Steps:
      1. Fixation
      2. Processing
      3. Embedding and Sectioning
      4. Staining
      5. Sectioning
      6. Staining