pathology cell injury i
DESCRIPTION
cell injuryTRANSCRIPT
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Cell Injury I – Cell Injury and Cell Death
Dept. of Pathology
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Key Concepts
• Normal cells have a fairly narrow range of function or steady state: Homeostasis
• Excess physiologic or pathologic stress may force the cell to a new steady state: Adaptation
• Too much stress exceeds the cell’s adaptive capacity: Injury
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Key Concepts (cont’d)
• Cell injury can be reversible or irreversible
• Reversibility depends on the type, severity and duration of injury
• Cell death is the result of irreversible injury
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Cell Injury – General Mechanisms
• Four very interrelated cell systems are particularly vulnerable to injury:– Membranes (cellular and organellar)– Aerobic respiration– Protein synthesis (enzymes, structural
proteins, etc)– Genetic apparatus (e.g., DNA, RNA)
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Cell Injury – General Mechanisms
• Loss of calcium homeostasis
• Defects in membrane permeability
• ATP depletion
• Oxygen and oxygen-derived free radicals
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Causes of Cell Injury and Necrosis
• Hypoxia– Ischemia– Hypoxemia– Loss of oxygen carrying capacity
• Free radical damage• Chemicals, drugs, toxins• Infections• Physical agents• Immunologic reactions• Genetic abnormalities• Nutritional imbalance
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Reversible Injury
• Mitochondrial oxidative phosphorylation is disrupted first Decreased ATP – Decreased Na/K ATPase gain of
intracellular Na cell swelling– Decreased ATP-dependent Ca pumps
increased cytoplasmic Ca concentration– Altered metabolism depletion of glycogen– Lactic acid accumulation decreased pH– Detachment of ribosomes from RER
decreased protein synthesis
• End result is cytoskeletal disruption with loss of microvilli, bleb formation, etc
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Irreversible Injury
• Mitochondrial swelling with formation of large amorphous densities in matrix
• Lysosomal membrane damage leakage of proteolytic enzymes into cytoplasm
• Mechanisms include:– Irreversible mitochondrial dysfunction
markedly decreased ATP– Severe impairment of cellular and organellar
membranes
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Funky mitochondria
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Cell Injury
• Membrane damage and loss of calcium homeostasis are most crucial
• Some models of cell death suggest that a massive influx of calcium “causes” cell death
• Too much cytoplasmic calcium:– Denatures proteins– Poisons mitochondria– Inhibits cellular enzymes
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Clinical Correlation
• Injured membranes are leaky
• Enzymes and other proteins that escape through the leaky membranes make their way to the bloodstream, where they can be measured in the serum
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Free Radicals
• Free radicals have an unpaired electron in their outer orbit
• Free radicals cause chain reactions
• Generated by:– Absorption of radiant energy– Oxidation of endogenous constituents– Oxidation of exogenous compounds
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Examples of Free Radical Injury
• Chemical (e.g., CCl4, acetaminophen)
• Inflammation / Microbial killing
• Irradiation (e.g., UV rays skin cancer)
• Oxygen (e.g., exposure to very high oxygen tension on ventilator)
• Age-related changes
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Mechanism of Free Radical Injury
• Lipid peroxidation damage to cellular and organellar membranes
• Protein cross-linking and fragmentation due to oxidative modification of amino acids and proteins
• DNA damage due to reactions of free radicals with thymine
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Morphology of Cell Injury – Key Concept
• Morphologic changes follow functional changes
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Reversible Injury -- Morphology
• Light microscopic changes– Cell swelling (a/k/a hydropic change)– Fatty change
• Ultrastructural changes– Alterations of cell membrane– Swelling of and small amorphous deposits
in mitochondria– Swelling of RER and detachment of
ribosomes
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Irreversible Injury -- Morphology
• Light microscopic changes– Increased cytoplasmic eosinophilia (loss of
RNA, which is more basophilic)– Cytoplasmic vacuolization– Nuclear chromatin clumping
• Ultrastructural changes– Breaks in cellular and organellar membranes– Larger amorphous densities in mitochondria– Nuclear changes
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Irreversible Injury – Nuclear Changes
• Pyknosis– Nuclear shrinkage and increased basophilia
• Karyorrhexis– Fragmentation of the pyknotic nucleus
• Karyolysis– Fading of basophilia of chromatin
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Karyolysis & karyorrhexis -- micro
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Types of Cell Death
• Apoptosis– Usually a regulated, controlled process– Plays a role in embryogenesis
• Necrosis– Always pathologic – the result of
irreversible injury– Numerous causes
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Apoptosis
• Involved in many processes, some physiologic, some pathologic– Programmed cell death during
embryogenesis– Hormone-dependent involution of organs in
the adult (e.g., thymus)– Cell deletion in proliferating cell populations– Cell death in tumors– Cell injury in some viral diseases (e.g.,
hepatitis)
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Apoptosis – Morphologic Features
• Cell shrinkage with increased cytoplasmic density
• Chromatin condensation
• Formation of cytoplasmic blebs and apoptotic bodies
• Phagocytosis of apoptotic cells by adjacent healthy cells
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Apoptosis – Micro
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Types of Necrosis
• Coagulative (most common)
• Liquefactive
• Caseous
• Fat necrosis
• Gangrenous necrosis
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Coagulative Necrosis
• Cell’s basic outline is preserved
• Homogeneous, glassy eosinophilic appearance due to loss of cytoplasmic RNA (basophilic) and glycogen (granular)
• Nucleus may show pyknosis, karyolysis or karyorrhexis
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Splenic infarcts -- gross
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Infarcted bowel -- gross
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Myocardium photomic
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Adrenal infarct -- Micro
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3 stages of coagulative necrosis (L to R) -- micro
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Liquefactive Necrosis
• Usually due to enzymatic dissolution of necrotic cells (usually due to release of proteolytic enzymes from neutrophils)
• Most often seen in CNS and in abscesses
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Lung abscesses (liquefactive necrosis) -- gross
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Liver abscess -- micro
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Liquefactive necrosis -- gross
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Liquefactive necrosis of brain-- micro
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Macrophages cleaning liquefactive necrosis -- micro
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Caseous Necrosis
• Gross: Resembles cheese• Micro: Amorphous, granular eosinophilc
material surrounded by a rim of inflammatory cells– No visible cell outlines – tissue architecture
is obliterated
• Usually seen in infections (esp. mycobacterial and fungal infections)
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Caseous necrosis -- gross
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Extensive caseous necrosis -- gross
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Caseous necrosis -- micro
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Enzymatic Fat Necrosis
• Results from hydrolytic action of lipases on fat
• Most often seen in and around the pancreas; can also be seen in other fatty areas of the body, usually due to trauma
• Fatty acids released via hydrolysis react with calcium to form chalky white areas “saponification”
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Enzymatic fat necrosis of pancreas -- gross
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Fat necrosis -- micro
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Gangrenous Necrosis
• Most often seen on extremities, usually due to trauma or physical injury
• “Dry” gangrene – no bacterial superinfection; tissue appears dry
• “Wet” gangrene – bacterial superinfection has occurred; tissue looks wet and liquefactive
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Gangrene -- gross
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Wet gangrene -- gross
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Gangrenous necrosis -- micro
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Fibrinoid Necrosis
• Usually seen in the walls of blood vessels (e.g., in vasculitides)
• Glassy, eosinophilic fibrin-like material is deposited within the vascular walls
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