Cell Injury Lec1 - Pathophysiology PDF

Summary

This document provides an introduction to cell injury, discussing homeostasis, adaptations, and the various causes of cellular damage. It covers different categories of injuries, ranging from oxygen deprivation to physical and chemical agents, infections, and genetic abnormalities.

Full Transcript

Introduction & Cell Injury ‫ فرع االمراض‬/ ‫كلية طب نينوى‬
‫ اروى البرهاوي‬. ‫د‬

 Pathology focuses on the study of disease processes, examining structural, biochemical,
and functional changes in cells and tissues
 General Pathology addresses cellular responses to injury, while Systemic Pathology
focuses on disease mechanisms in specific organs.
 Core aspects include etiology, pathogenesis, morphologic changes, and clinical
manifestations.
 Etiology involves genetic and environmental factors; pathogenesis explores the sequence
of events leading to disease

Cell Homeostasis, Adaptation, and Injury:

1. Cell Homeostasis:
o Definition: Cells maintain normal homeostasis by keeping their internal
environment stable and within a narrow range of physiological parameters. This
steady state allows cells to function optimally under normal conditions.
2. Adaptations:
o Definition: Adaptations are reversible changes in cell function and structure in
response to changes in physiological conditions (e.g., pregnancy) or pathological
stimuli.
o Purpose: These adaptations allow cells to achieve a new, altered steady state that
enables them to survive and continue functioning despite the changes in their
environment.
3. Cell Injury:
o Definition: Cell injury refers to the set of biological and morphological changes
that occur when a cell's equilibrium or homeostasis is disrupted by harmful
influences.
o Outcome: When the cell can no longer maintain homeostasis, injury occurs,
which can be either reversible or irreversible depending on the nature and severity
of the stress.

KEY CONCEPT:

 Loss of Homeostasis = Cell Injury: When a cell's ability to maintain its steady state is
compromised, it leads to cell injury, disrupting normal cellular function and potentially
leading to cell death if the injury is severe or prolonged.
CAUSES OF CELL INJURY:

1. Oxygen Deprivation (Hypoxia):
o Definition: Hypoxia is a decrease in the oxygen supply to cells, which can result
in cell injury.
o Causes:
 Ischemia: Loss of blood supply due to blocked arteries.
 Inadequate Oxygenation: Conditions like cardiac or respiratory failure
that impair oxygen delivery.
 Reduced Oxygen-Carrying Capacity: Examples include anemia and
carbon monoxide (CO) poisoning.
2. Physical Agents:
o Examples: Mechanical trauma, extremes of temperature (e.g., burns, frostbite),
sudden atmospheric pressure changes, radiation, and electric shock.
3. Chemical Agents and Drugs:
o Simple Chemicals: Hypertonic concentrations of glucose or salt can directly
injure cells or disrupt electrolyte and fluid balance.
o Toxicity: High concentrations of oxygen can be toxic.
o Environmental and Occupational Hazards: Includes pollutants, insecticides,
herbicides, carbon monoxide, asbestos, and recreational drugs like alcohol.
4. Infectious Agents:
o Examples: Viruses, bacteria, fungi, rickettsiae, worms, and other pathogens.
5. Immunologic Reactions:
o Function: While the immune system defends against pathogens, it can also cause
cell injury.
o Autoimmune Diseases: Injurious immune reactions against self-antigens cause
conditions like autoimmune diseases.
6. Genetic Abnormalities:
o Examples:
 Chromosomal Abnormalities: Such as the extra chromosome in Down
syndrome.
 Single-Gene Mutations: Like the base pair substitution in sickle cell
anemia.
 Protein Function Deficiency: Includes enzyme defects in metabolic
disorders or the accumulation of damaged DNA/misfolded proteins,
leading to cell death.
7. Nutritional Imbalances:
o Deficiencies: Protein-calorie deficiencies cause widespread death, especially in
low-income populations, and vitamin deficiencies are common globally.
o Excesses: Nutritional excess, such as obesity, is also a significant cause of cell
injury.
8. Cell Aging:
o Aging: As cells age, they become more susceptible to injury, contributing to
various age-related diseases and conditions
Mechanism of cell injury :

The mechanisms of cell injury involve a complex interplay of biochemical processes, influenced
by various factors that determine the outcome of cellular damage. Here are the key points
regarding the mechanisms of cell injury:

1. Nature, Duration, and Severity of Injury

 The cellular response to harmful stimuli is closely tied to the nature of the injury, how
long it lasts, and its intensity. Small doses of a toxin or brief ischemia might cause
reversible injury, allowing for potential recovery. In contrast, larger doses or prolonged
exposure can lead to either rapid cell death or a gradual, irreversible injury.

2. Cell Type, State, and Adaptability

 The consequences of cell injury vary depending on the type of cell, its current condition,
and its ability to adapt. Factors such as the cell’s nutritional status, hormonal
environment, metabolic needs, and specific functions play a significant role in
determining how it responds to injury.
 Different cell types have different vulnerabilities. For example, skeletal muscle cells can
withstand periods of ischemia better than cardiac muscle cells, which are more
susceptible to damage from loss of blood supply.

3. Individual Variability

 There is significant variability in how different individuals respond to the same injurious
agent. This variability can be due to genetic differences, such as polymorphisms in genes
 that encode enzymes responsible for metabolizing toxins. For example, exposure to the
toxin carbon tetrachloride (CCl₄) may cause cell death in one individual but have no
effect on another, depending on differences in their hepatic enzyme profiles.

4. Multiple Interconnected Mechanisms

 Injurious stimuli often activate multiple, interconnected pathways that contribute to cell
damage. This complexity makes it challenging to pinpoint a single dominant biochemical
mechanism responsible for the injury in a given situation. Instead, multiple factors often
work together to cause cellular damage.

MITOCHONDRIAL DAMAGE AND ITS ROLE IN CELL INJURY

Mitochondria are essential for cell survival because they produce ATP, the energy currency
required for numerous cellular processes. However, they are also highly susceptible to various
injurious stimuli, making them critical determinants of cell fate—whether the cell survives,
undergoes apoptosis, or experiences necrosis.

Major Consequences Of Mitochondrial Damage:

1. ATP Depletion:
o ATP Production Pathways: ATP is primarily produced through oxidative
phosphorylation in mitochondria. Under normal conditions, oxygen is reduced by
the mitochondrial electron transport chain to generate ATP. An alternative, less
efficient pathway is glycolysis, which can produce ATP anaerobically from
glucose.
o Causes of ATP Depletion: ATP depletion can occur due to mitochondrial
damage, reduced oxygen and nutrient supply (as seen in ischemia and hypoxia),
and exposure to toxins (e.g., cyanide).
o When ATP levels fall below 5-10% of normal, critical cellular functions are
compromised.
2. Disruption of Cellular Functions:
o Sodium-Potassium Pump Failure: The energy-dependent sodium-potassium
(Na⁺/K⁺-ATPase) pump relies on ATP to maintain ion gradients across the cell
membrane. ATP depletion reduces the activity of this pump, causing sodium to
accumulate inside the cell while potassium levels drop. This ionic imbalance leads
to water influx, causing cell swelling and endoplasmic reticulum (ER) dilation.
o Altered Metabolism: In response to reduced oxygen supply, cells shift from
oxidative phosphorylation to glycolysis to generate ATP. This leads to rapid
depletion of glycogen stores and accumulation of lactic acid and inorganic
phosphates, lowering intracellular pH. The acidification inhibits many cytosolic
enzymes, further disrupting cellular metabolism.
 o Protein Synthesis Impairment: Prolonged ATP depletion causes structural
disruption of the protein synthesis machinery, particularly detachment of
ribosomes from the rough ER and dissociation of polysomes. This results in
reduced protein synthesis and increased protein misfolding, which can further
damage the cell.
3. Irreversible Cell Damage and Death:
o Necrosis: Severe or prolonged mitochondrial damage leads to irreversible injury
to mitochondrial and lysosomal membranes, culminating in necrosis, a form of
uncontrolled cell death.
o Reactive Oxygen Species (ROS) Generation: Incomplete oxidative
phosphorylation during mitochondrial damage increases the production of ROS,
which can damage lipids, proteins, and DNA, exacerbating cell injury.
o Apoptosis Initiation: Mitochondrial damage can also trigger apoptosis,
particularly through the

MEMBRANE DAMAGE AND ITS ROLE IN CELL INJURY

Membrane damage is a critical and consistent feature of cell injury.

Mechanisms of Membrane Damage:

1. ATP Depletion and Calcium-Mediated Phospholipase Activation:
o In ischemic cells, ATP depletion and increased cytosolic calcium activate
phospholipases, leading to the breakdown of membrane phospholipids.
2. Direct Damage by External Agents:
o The plasma membrane can be directly damaged by bacterial toxins, viral proteins,
lytic complement components, and various physical and chemical agents.
3. Reactive Oxygen Species (ROS):
o ROS cause oxidative damage to cell membranes through lipid peroxidation, and
attack the lipid bilayer, leading to loss of membrane integrity.
4. Decreased Phospholipid Synthesis:
o Phospholipid production may be reduced due to defective mitochondrial function
or hypoxia, which decrease ATP availability and impair energy-dependent
biosynthetic pathways. This reduction affects all cellular membranes, including
those of mitochondria.
5. Increased Phospholipid Breakdown:
o Severe cell injury leads to increased degradation of membrane phospholipids due
to activation of calcium-dependent phospholipases. This breakdown produces
lipid degradation products like free fatty acids, acyl carnitine, and
lysophospholipids, which can act as detergents, disrupting the membrane structure
and altering permeability and electrophysiological properties.
6. Cytoskeletal Abnormalities:
o Cytoskeletal filaments anchor the plasma membrane to the cell interior. Proteases
activated by increased cytosolic calcium can damage these tethers. In conditions
 like myocardial cell swelling, this damage leads to membrane detachment from
the cytoskeleton, making the membrane more prone to stretching and rupture.

Consequences of Membrane Damage:

1. Mitochondrial Membrane Damage:
o Damage to the mitochondrial membrane results in decreased ATP production.
And mitochondrial damage which also causes the release of proteins that can
trigger apoptotic cell death.
2. Plasma Membrane Damage:
o Plasma membrane damage disrupts osmotic balance, leading to the influx of
fluids and ions, and the loss of cellular contents. This also includes the leakage of
metabolites essential for ATP production, further depleting cellular energy stores.
3. Lysosomal Membrane Damage:
o Injury to lysosomal membranes causes the release of digestive enzymes into the
cytoplasm. These enzymes, including RNases, DNases, proteases, phosphatases,
and glucosidases, become active in the acidic environment of an injured cell,
leading to the degradation of RNA, DNA, proteins, phosphoproteins, and
glycogen, pushing the cell toward necrosis

DNA DAMAGE AND ITS CONSEQUENCES IN CELL INJURY

DNA damage is a critical factor in cell injury, activating cellular responses aimed at preserving
genomic integrity or eliminating cells with irreparable damage to prevent malignancy. Here’s a
detailed summary of how DNA damage impacts cellular processes:

Causes of DNA Damage:

 External Factors: DNA can be damaged by radiation, chemotherapeutic (anticancer)
drugs, and reactive oxygen species (ROS).
 Spontaneous and Aging-Related Damage: Over time, DNA damage can occur
spontaneously as part of the aging process

Cellular Response to DNA Damage:

 Activation of p53: When DNA damage is detected, the cell activates p53, a crucial tumor
suppressor protein. p53 is responsible for maintaining genomic stability by controlling
the cell cycle and initiating DNA repair.
 G1 Phase Arrest: p53 halts the cell cycle in the G1 phase, preventing the cell from
progressing to DNA replication. This arrest gives the cell time to repair the damaged
DNA before it continues through the cell cycle.