Download - Cell Injury, Adaptation, Free Radicals
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CONCEPT OF INJURY AND CELLULAR RESPONSE TO INJURY
Cells are constantly exposed to a variety of stresses. When too severe, INJURY results.
Injury alters the preceding normal steady state of the cell.
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Causes of Cell Injury/Lesions
1. oxygen deprivation (anoxia) 2. physical agents 3. chemical agents 4. infections agents 5. immunologic reactions 6. genetic defects7. Nutritional imbalances8. Aging
What hurts cells?
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This is a lesion caused by
infectious agent
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This is a lesion caused by
oxygen deprivation
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This is a lesion caused by
chemical agent
Hepatic necrosisHepatic necrosis (patient poisoned by carbon tetrachloride)
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This is a lesion caused by
infectious agent
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This is a lesion caused by
physical agent
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The “boutonnière” (buttonhole) deformityThe “boutonnière” (buttonhole) deformity
This is a lesion caused by
intrinsic factors(auto aggression)
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This is a lesion caused by
infectious agent
(chemical:alcohol, genetic:1-AT
deficiency)
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This is a lesion caused by HBVinfectious agent
(chemical:alcohol, genetic:a1AT deficiency)
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General principles:- The cellular response to injurious stimuli depends on 1. type of injury
2. Its duration3. Severity
-The consequences depend onthe type, status, adaptability, and genetic
makeup of the injured cell.
-The structural and biochemical components of a cell are so integrally connected that multiple
secondary effects rapidly occur
-Cellular function is lost far before cell death occurs
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1. EXCESS or DEFICIENCY OF OXYGEN2. PHYSICAL AGENTS3. CHEMICAL AGENTS4. INFECTION5. IMUNOLOGICAL REACTIONS6. GENETIC DERANGEMENTS7. NUTRITIONAL IMBALANCE
Etiologic agents
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CONCEPT OF INJURY AND CELLULAR RESPONSE TO INJURY
• one of two things can happen to the cell:
1. It can survive in a damaged state and adapt to the injury (REVERSIBLE INJURY) or
2. It can die (IRREVERSIBLE INJURY) or cell death.
• Injury of a CHRONIC nature: the cell may be able to adapt to it, resulting in a variety of cellular changes known as
ADAPTATIONS
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Environment – ECM – other cells
Signals/injury
No change Adjustment Adaptation
1. Atrophy 2. Metaplasia 3. Hypertrophy 4. Hyperplasia 5. Dysplasia
No adaptation No adjustment Change
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Cellular adaptations include:
1. Atrophy - shrinkage of cells
2. Hypertrophy - increase in the size of cells which results in enlargement of the organs
3. Hyperplasia - increased number of cells in an organ or tissue
4. Metaplasia - transformation or replacement of one adult cell type with another
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Atrophy Hypoplasia:
•Developmental failure•Atrophy of organ•Failure in morphogenesis
Reversible
Decrease in size of cell (-s) previously of normal size
Physiologic
•Morphogenetic (apoptosis)•Thymus•Ductus arteriosus•Uterus•Bones
Pathologic •Decreased function•Loss of innervation•Pressure (“bed soars”)•Malnutrition/cahexia/cancer-TNF•Loss of endocrine stimulation•Aging
Branchial cleftsNotochordMullerian ductsWolffian ducts
Net results: tissue /organ smaller than normal
Signals/injury
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Atrophy - testis
Normal
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Small intestine
Normal Atrophy
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Alzheimer disease – brain atrophy
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Hypertrophy – cell or organ
Reversible
Increase in size of cell (-s) in response to increased functional demand (-s) and/or in response to H/GF stimulation
Physiologic
•Cardiac muscle•Athletes muscle•Uterine muscle•Prostatic tissue (elderly)
Pathologic
•Cardiac muscle•Thyroid•Arterial smooth muscle•Cushing syndrome
Net effect: increase in size/volume/weight of tissue / organ
Signals/injury
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Hyperplasia – cell or organ
Reversible
Increase in number of cell (-s) in response to increased functional demand (-s) and/or in response to H/GF stimulation
Physiologic
•Lactating breast•Uterine muscle•Prostatic tissue (elderly)
Pathologic
•Thyroid•Arterial smooth muscle•Breast , fibrocystic disease •Focal nodular hyperplasia (liver)
Net effect :increase in size/volume/weight of tissue / organ
Signals/injury
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Polipoid endometrium
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Endometrial carcinoma and endometrial hyperplasia
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Signals/injurySignals/injury
Reversible
But not always
Metaplasia
Substitution of mature (differentiated) cell for another mature cell
Physiologic (metaplastic tissue/organs)
•cervical canal
Pathologic (metaplastic tissue/organs)•Gastric/duodenal metaplasia•Squamous metaplasia-cervix•Ciliated to squamous•Osseous metaplasia•Barret’s oesophagus•Myeloid metaplasia
Net effect: another cell/tissue - protective – changes in function
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Metaplasia
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Metaplasia
Ciliated
Squamous
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Metaplasia
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Overview of Cell Injury and Cell Death◦ Reversible cell injury ( nonlethal hit)◦ Irreversible injury and cell death ( lethal hit)
Mechanisms of Cell Injury Free radical injury Necrosis Apoptosis
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Overview of Cell Injury and Cell Death◦ Reversible cell injury (nonlethal hit)◦ Irreversible injury and cell death ( lethal hit)
Mechanisms of Cell Injury Free radical injury Necrosis Apoptosis
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Causes of Cell Injury/Lesions
1. oxygen deprivation (anoxia, hypoxia) 2. physical agents 3. chemical agents 4. infections agents 5. immunologic reactions 6. genetic defects7. Nutritional imbalances8. Aging
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Nature and Severity of Injurious Stimulus
Cellular Response
Altered physiologic stimuli: Cellular adaptations:
Increased demand, increased trophic stimulation (e.g. growth factors, hormones)
Hyperplasia, hypertrophy
Decreased nutrients, stimulation Atrophy
Chronic irritation (chemical or physical)
Metaplasia
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Nature and Severity of Injurious Stimulus
Cellular Response
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The most important targets of injurious stimuli are:
(1) aerobic respiration involving mitochondrial oxidative phosphorylation and production of ATP
Result: 1- ATP depletoion 2- Mitochondrial damage
3- loss of Calcium homeostasis 4- Generation of reactive oxygen species
(2) the integrity of cell membranes, on which the ionic and osmotic homeostasis of the cell and its organelles depends
(3) the cytoskeleton (4) the integrity of the genetic apparatus of the cell (5) protein synthesis
MECHANISMS OF CELL INJURY
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The most important targets of injurious stimuli are:
(1) aerobic respiration involving mitochondrial oxidative phosphorylation and production of ATP
Result: 1- ATP depletoion 2- Mitochondrial damage
3- loss of Calcium homeostasis 4- Generation of reactive oxygen
species (2) the integrity of cell membranes, on which the ionic and
osmotic homeostasis of the cell and its organelles depends (3) the cytoskeleton (4) the integrity of the genetic apparatus of the cell (5) protein synthesis
MECHANISMS OF CELL INJURY
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(1) DEPLETION OF ATP ATP depletion and decreased ATP synthesis are frequently
associated with both hypoxic and chemical (toxic) injury Depletion of ATP to <5% to 10% of normal levels has widespread
effects on many critical cellular systems:
◦ Plasma membrane energy-dependent sodium pump is reduced, resulting in cell swelling
◦ increased rate of anaerobic glycolysis, glycogen stores are rapidly depleted. Glycolysis results in the accumulation of lactic acid. This reduces the intracellular pH, resulting in decreased activity of many cellular enzymes.
◦ Failure of the Ca2+ pump leads to influx of Ca2+ ◦ In cells deprived of oxygen or glucose, unfolded protein formed,
that may lead to cell injury and even death.
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MITOCHONDRIAL DAMAGE◦ Mitochondria are important targets for virtually
all types of injurious stimuli, including hypoxia and toxins.
◦ Cell injury is frequently accompanied by morphologic changes in mitochondria.
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Result in apoptosis
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INFLUX OF INTRACELLULAR CALCIUM AND LOSS OF CALCIUM HOMEOSTASIS
Calcium ions are important mediators of cell injury. Cytosolic free calcium is maintained at extremely low
concentrations (<0.1 μmol) compared with extracellular levels of 1.3 mmol, and most intracellular calcium is sequestered in mitochondria and endoplasmic reticulum.
Such gradients are modulated by membrane-associated, energy-dependent Ca2+, Mg2+-ATPases.
Ischemia and certain toxins cause an early increase in cytosolic calcium concentration, owing to the net influx of Ca2+ across the plasma membrane and the release of Ca2+ from mitochondria and endoplasmic reticulum
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Failure of intracellular calcium homeostasis
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Important mechanism of cell damage.Free radical are chemical species with a single
unpaired electron in an outer orbital.This state is unstable and react with organic
and inorganic chemical.
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Cell injury by oxygen radicals
1. Superoxide2. Hydrogen peroxide3. Hydroxy radical
MECHANISMS OF INJURY BY FREE RADICALS
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Cell injury by oxygen radicals
1. Superoxide2. Hydrogen peroxide3. Hydroxy radical What happen when the cell is injured by free radicals?
1. Lipid peroxidation 2. Protein damage3. DNA damage
MECHANISMS OF INJURY BY FREE RADICALS
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GENERAL MECHANISMS OF INJURY –FREE RADICALS
Normal mechanism to protect against free radical injury
1. Enzyme A. Superoxide dismutase. 2O2
- + 2H ---> H2O2 + O2
B. Glutathione peroxidase.
H2O2 + 2 GSH ---> 2H2O + GSSG
C. Catalase.
2H2O2 ----> O2 + 2 H2O
2. Antioxidant:• vit. E, vit. C• Sulfhydryl containing compounds e.g. cysteine • Proteins e.g., transferrin and albumin
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The most important targets of injurious stimuli are:
(1) aerobic respiration involving mitochondrial oxidative phosphorylation and production of ATP
(2) the integrity of cell membranes, on which the ionic and osmotic homeostasis of the cell and its organelles depends
(3) the cytoskeleton (4) the integrity of the genetic apparatus of the cell (5) protein synthesis
MECHANISMS OF CELL INJURY
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Integrity of Cell Membranes
Mechanisms of membrane damage in cell injury: Decreased O2 and increased cytosolic Ca2+ are
typically seen in ischemia but may accompany other forms of cell injury.
Production of reactive oxygen species Lysis of enzymes Activation of complement system Lysis by viruses
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Effect of plasma membrane damage
1. Loss of structural integrity2. Loss of function
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The most important targets of injurious stimuli are:
(1) aerobic respiration involving mitochondrial oxidative phosphorylation and production of ATP
(2) the integrity of cell membranes, on which the ionic and osmotic homeostasis of the cell and its organelles depends
(3) the cytoskeleton (4) the integrity of the genetic apparatus of the cell (5) protein synthesis
MECHANISMS OF CELL INJURY
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Cytoskeletal abnormalities
Cytoskeletal filaments serve as anchors connecting the plasma membrane to the cell interior.
Activation of proteases by increased cytosolic calcium may cause damage to elements of the cytoskeleton.
This damage results, particularly in myocardial cells, in detachment of the cell membrane from the cytoskeleton, rendering it susceptible to stretching and rupture.
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The most important targets of injurious stimuli are:
(1) aerobic respiration involving mitochondrial oxidative phosphorylation and production of ATP
(2) the integrity of cell membranes, on which the ionic and osmotic homeostasis of the cell and its organelles depends
(3) the cytoskeleton (4) the integrity of the genetic apparatus of the cell (5) protein synthesis
MECHANISMS OF CELL INJURY
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(4) the integrity of the genetic apparatus of the cell
Caused by:1. Ionizing radiation 2. Viruses3. Mutagenic chemicals
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(4) the integrity of the genetic apparatus of the cell
Effect of DNA abnormalities: 1. Failure of synthesis of proteins and enzyme
2. Failure of mitosis 3. Progression to cancer
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The most important targets of injurious stimuli are:
(1) aerobic respiration involving mitochondrial oxidative phosphorylation and production of ATP
(2) the integrity of cell membranes, on which the ionic and osmotic homeostasis of the cell and its organelles depends
(3) the cytoskeleton (4) the integrity of the genetic apparatus of the cell (5) protein synthesis
MECHANISMS OF CELL INJURY
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Oxygen is required for oxidative phosphorylation. Defective ATP production occur in: a] Hypoglycaemia. b] Hypoxia due to : 1. Respiratory obstruction or disease. 2. Ischemia. 3. Anaemia. 4. Alteration of hemoglobin. c] Enzyme inhibition by cyanide. d] Uncoupling of oxidative phosphorylation. First cells affected are those with highest demand of
oxygen.
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Effect of defective energy production: Morphologic changes in reversible injury: A] Intracellular accumulation of water and electrolytes due to
failure of energy-dependent sodium pump (cloudy swelling or hydropic changes) B] Changes in organelles, swollen due to loss of osmotic regulation. C] Switch to anaerobic metabolism with production of lactic acid, reduction in intracellular pH and detachment of ribosomes from RER. D] Clumping of nuclear chromatin. These changes are reversible if oxygenation is restored.
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Vacuolar (hydropic) change in cells lining the proximal tubules of the kidney
Reversible changes
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Hydropic vacuoles in the endoplasmic reticulum of hepatocyte
Reversible changes
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Vacuoles
Hydropic vacuoles in the endoplasmic reticulum of hepatocyte
M
Nucleus
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Morphologic changes in irreversible injury:
1. Severe vacuolization of the mitochondria, with accumulation of calcium-rich densities.
2. Extensive damage to plasma membranes.
3. Massive calcium influx activate phospholipase, proteases, ATPase and endonucleases with break down of cell component.
4. Leak of proteins, ribonucleic acid and metabolite.
5. Breakdown of lysosomes with autolysis.
6. Nuclear changes: Pyknosis, karyolysis, karyorrhexis.
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IRREVERSIBLE CELL INJURY- NECROSIS
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- Dead cell are either collapsed and form a whorled phospholipid masses or degraded into fatty acid with calcification.- Cellular enzymes are released into circula- tion. This provides important clinical parameter of cell death.
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This is a lesion caused by
oxygen deprivation
Cell Pathology
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Following ischemic heart injury, the following sequence is observed: -rapid biochemical and ultrastructural responses-light microscopic evidence of reversible injury after several minutes -ultrastructural evidence of irreversible injury in 20-60 minutes -unequivocal light microscopic evidence of cell death after 11-12 hours
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How Ionizing Radiation Kills Cells
•Proliferating Cells - by DNA damage. Leads to apoptosis.
•Nonproliferating cells- by lipid peroxidation.
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How Viruses Kill Cells
•Directly Cytopathic Viruses – e.g. Poliovirus •Indirectly cytopathic Viruses - e.g. hepatitis B Summary of Cytopathic Viruses
•Direct cytopathic viruses insert their proteins into the plasma membranes, disrupting the cells permeability (membrane damage)
•Indirect cytopathic viruses also in insert their proteins into the plasma membrane, but to create an antigenic target for cytotoxic T lymphocytes.
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How Chemicals Kill Cells :
Group I : interact directly with cellular contents to cause damage (mercury, lead and iron (toxic heavy metals) Group II: whose metabolite is toxic e.g. hepatotoxins: (Carbon tetrachloride(CCl4), acetominophen, bromobenzene)Group III: bind cytochrome P450 (the mixed function oxygenase involved in drug metabolism) Summary of Liver Necrosis by Cytotoxic Chemicals
The metabolism of hepatotoxic chemicals by mixed function oxidation (cytochrome P450) leads to irreversible cell injury. This is caused by membrane damage to the cell as a result of lipid peroxidation.
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