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[email protected] Cell Injury - 4 interrelated cell systems especially susceptible to injury o Membranes (cellular and organellar) o Aerobic system o Protein synthesis (enzymes, structural proteins, etc) o Genetic apparatus (DNA, RNA, etc) - Mechanisms for cell injury o Loss of Ca++ homeostasis o Membrane permeability defects o ATP depletion o O2 and O2 derived free radicals - Causes of Cell Injury o Hypoxia (ischemia – block in blood flow, hypoxemia – decreased partial pressure of oxygen in blood, anemia – decreased oxygen carrying capacity) Block in ventilation( foreign body), oxygen diffusion (pneumonia, pulmonary edema), perfusion (pulmonary embolus), decreased cardiac output o Free radical damage o Chemicals, drugs, toxins o Infections o Physical agents o Immunologic reactions o Genetics o Nutritional imbalance - Oxygen tension falls disrupts oxidative phosphorylation decreased ATP o ↓ Na+ /K+ ATPase increased intracellular Na+ swelling o ↓ ATP-dependent Ca++ pumps increased cytosolic Ca++ o Depletion of glycogen from altered metabolism o Decreased pH from lactic acid accumulation o Decreased protein synthesis from ribosome detachment from RER - End result – cytoskeletal disruption with loss of microvilli, bleb formation, etc
- Excess cytoplasmic Ca++ denatures proteins, poisons mitochondria, inhibits cellular enzymes o Therefore, membrane damage and Ca++ homeostasis is critical o Injured membranes allow intracellular components to enter the serum and can be measured - Free radical injury (acetaminophen – Tylenol overdose) o Lipid peroxidation – damage to cellular and organellar membranes o Protein crosslinking/fragmentation from oxidative modification of amino acids and proteins o DNA damage from free radical reaction with thymine - Types o Chemical o Inflammation/microbial killing o Irradiation o Oxygen o Age-related - Free Radical Derivations o Superoxide – O2 ● - – produced by cellular oxidases o H2O2 – produced by superoxide mutase or catalase o OH● - – produced by ionizing radiation, H2O2 and O2 ● - , and fenton reaction
- Morphological changes follow functional changes o Reversible injury Light microscope – cell swelling, fatty change Ultrastructural changes – cell membrane alterations, swelling and small deposits of mitochondria, RER and attached ribosome swelling o Irreversible injury Light microscope Loss of RNA (which is basophilic) – increased cytoplasmic eosinophilia (pink colour) Cytoplasmic vacuolization Nuclear chromatin clumping Ultrastructural Membrane breakage Large amorphous densities in mitochondria Nuclear changes Pyknosis – nuclear shrinkage, increased basophilia (blue colour) Karyorrhexis – fragmentation of pyknotic nucleus Karyolysis – fading of basophilia of chromatin - Types of Cell Death o Apoptosis – usually regulated, may be pathogenic, has a role in embryogenesis o Necrosis – always pathologic, many causes - Apoptosis o Programmed cell death in embryogenesis o Hormone dependent involution of adult organs (thymus) o Cell deletion in proliferative populations o Cell death in tumors o Cell injury in some viral diseases (hepatitis) - Necrosis o Causes Coagulative (most common) Cells basic outlines are preserved Homogenous, glassy eosinophilic appearance due to loss of cytoplasmic RNA (basophilic) and glycogen (granular) Nucleus may show any of pyknosis, karyorrhexis, or karyolysis Liquefactive – most often in CNS and abscess – usually from enzymatic dissolution of necrotic cells (usually due to release of proteolytic enzymes from neutrophils)
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