Cell Injury Dr Ban 2024-2025 PDF

Summary

This document explores cell adaptation, injury, and death, emphasizing concepts like hypertrophy, hyperplasia, atrophy, and metaplasia. It also details the mechanisms of cell injury, including the role of ATP depletion and oxidative stress. The material pertains to medical and biological education at the undergraduate level.

Full Transcript

Cell Adaptation, Cell
Injury and Cell Death

Prof. Dr. Ban J. Qasim
MBChB, MSc, PhD Path
Objectives

The students will understand:
´ Concept of adaptation and cell injury
´ Reversible vs. irreversible cell injury
´ Causes and mechanisms of cell injury
´ Apoptosis vs. necrosis
 Extracellular stresses

homeostasis

Adapt
atrophy
hypertrophy
X hyperplasia
metaplasia

Cell death
necrosis
apoptosis Cell injury
 Adaptations
´ are reversible changes
in the cells in response
to changes in their
environment.
´ When the stress is
eliminated the cell can
recover to its original
state.
 HYPERTROPHY

´Is an increase in the size of cells, resulting
in an increase in the size of the organ.
´No new cells, just bigger cells enlarged by
an increased amount of structural proteins
and organelles.
´Hypertrophy and hyperplasia (increase in
cell number) can also occur together, and
result in an enlarged (hypertrophic) organ.
´Enlargement of the uterus during
pregnancy occurs as a
consequence of estrogen-
stimulated smooth muscle
hypertrophy and smooth muscle
hyperplasia.
´ In contrast, the striated muscle cells in
both the skeletal muscle and the heart
can undergo only hypertrophy in
response to increased demand because
in the adult they have limited capacity
to divide.
Can be:
´ Physiological
Ø Muscles hypertrophy of bodybuilders caused
by increased workload.

Ø Enlargement of the uterus during pregnancy
caused by estrogen.
´ Pathological: myocardial muscle fibers
hypertrophy resulting from hypertension.
 HYPERPLASIA
´Hyperplasia is an increase in the
number of cells in an organ or
tissue, usually resulting in
increased mass of the organ or
tissue.
´Occurs in cells capable of
replication
´Hyperplasia can be physiologic or
pathologic.
 Physiologic Hyperplasia
´The proliferation of the glandular
epithelium of the female breast in
puberty and pregnancy.
´When a liver is partially resected,
mitotic activity in the remaining cells
begins as early as 12 hours later,
eventually restoring the liver to its
normal weight.
 Pathologic Hyperplasia

´Endometrial hyperplasia due to
increases in the amount of estrogen,
with consequent hyperplasia of the
endometrial glands. This is a common
cause of abnormal menstrual
bleeding.
´Benign prostatic hyperplasia induced
by androgens.
Benign prostatic hyperplasia
Normal uterus Pathologic Hyperplasia

Dr.T.Krishna MD, www.mletips.com
´Pathologic hyperplasia constitutes a
risk for cancerous proliferation.
´Thus, patients with hyperplasia of the
endometrium are at increased risk of
developing endometrial cancer.
 ATROPHY
´Shrinkage of the size of the cell by the
loss of cell substance.
´When a sufficient number of cells
involved , the entire tissue or organ
diminishes in size , becoming atrophic.
´Although atrophic cells may have
diminished function, they are not dead.
´Atrophy results from decreased protein
synthesis and increased protein
degradation in cells.
 The common causes of atrophy are the
following:
q Decreased workload (disuse atrophy).
skeletal muscle atrophy due to
immobilization caused by fractured bone
q Loss of innervation (denervation atrophy).
Nerve damage
q Diminished blood supply (ischemia). brain
atrophy in elderly because of reduced blood
supply as a result of atherosclerosis.
q Inadequate nutrition. is associated with the
use of skeletal muscle as a source of
energy after other reserves such as
adipose stores have been depleted.
q Loss of endocrine stimulation. loss of
hormone stimulation after menapause
leads to endometrial atrophy.
q Aging. senile atrophy
 Blood supply
Nerve Supply

Nutrition Does A Function
 METAPLASIA
´Metaplasia is a reversible change in
which one adult cell type (epithelial
or mesenchymal) is replaced by
another adult cell type.
´It may represent substitution of cells
that are sensitive to stress by cell
types better able to withstand the
adverse environment.
 METAPLASIA

´It is a genetic “reprogramming” of stem
cells and not changing of already
differentiated cells.
´Metaplastic cells survive but protective
mechanism is lost.
´If the influences are persistent, there is
an increased chance of malignant
transformation.
 Types of metaplpasia

1) Epithelial metaplasia
´A) Metaplasia from columnar to
squamous (Squamous metaplasia).
E.g.,In the habitual cigarette smoker, the
normal ciliated columnar epithelial cells of
the trachea and bronchi are often
replaced by stratified squamous epithelial
cells.
´ Although the metaplastic squamous
epithelium has survival advantages,
important protective mechanisms are lost,
such as mucus secretion and ciliary
clearance.
Lung cancer (squamous cell carcinoma)
may arise later in areas of squamous
metaplasia.
´ B) Metaplasia from squamous to
columnar type may also occur, as in
Barrett esophagus, in which the
esophageal squamous epithelium is
replaced by intestinal-like columnar
cells under the influence of refluxed
gastric acid.
´ Cancers may arise in these areas; these
are typically glandular
(adeno)carcinomas
Barrett esophagus
2) Mesenchymal tissue metaplasia
Bone is occasionally formed in soft tissues
in foci of injury.

Formation of
Scar bone in fibrous
tissue in case of
healing of a
Bone wound
 Cell Injury and Cell Death

´Cell injury occurs when cells are
exposed to severe stress or damaging
agents that they are no longer able to
adapt.
´Cell injury is reversible up to a certain
point, but if the stimulus persists or is
severe, the cell suffers irreversible injury
and ultimately cell death.
Reversible cell injury
In early stages or mild forms of injury, the
changes are reversible if the damaging
stimulus is removed.
At this stage, although there may be
significant structural and functional
abnormalities, the injury has not
progressed to severe membrane
damage and nuclear dissolution.
´ The hallmarks of reversible injury is
depletion of energy stores (ATP), and
cellular swelling.
Irreversible cell injury (cell
death)
´With continuing damage, the injury
becomes irreversible, at which
time the cell cannot recover and it
dies.
´When large numbers of cells die
the tissue or organ is said to be
necrotic.
´Necrosis is the major pathway of
cell death in many injuries, such as
those resulting from ischemia,
exposure to toxins, various
infections, and trauma.
´Severe depletion of ATP and loss of
membrane integrity are typically
associated with necrosis
´There is membrane damage of necrotic
cells ;their contents leak out, this can
result in an inflammation in the
surrounding tissue.
´ The enzymes that digest the necrotic
cell are derived from the lysosomes of
the dying cells (autolysis).
´Cellular function may be lost long before cell
death occurs, and the morphologic changes
of cell injury (or death) occur later.
´For example, myocardial cells become
noncontractile after 1 to 2 minutes of
ischemia, although they do not die until 20 to
30 minutes have passed.
Causes of Cell Injury
Changes of REVERSIBLE INJURY

´ Two features of reversible cell injury can be
recognized under the light microscope:
´ 1.Cellular swelling (hydropic degeneration) is the
result of failure of energy-dependent ion pumps in
the plasma membrane.
´ 2. Fatty change :It is the appearance of
lipid vacuoles in the cytoplasm. It is seen
in cells dependent on fat metabolism,
such as hepatocytes and myocardial
cells.
Changes of reversible cell injury by
electron microscopy (ultrastructural
changes):
 Changes of irreversible cell
injury “necrosis”
By light microscopy :
´Cytoplasm show increased eosinophilia.
´Nuclear changes are:
´Pyknosis: nuclear shrinkage and increased
basophilia.
´Karyorrhexis: nuclear fragmentation.
´Karyolysis: The basophilia of the chromatin
may fade and nucleus totally disappears.
 Changes of irreversible cell
injury “necrosis”

normal pyknosis

karyolysis
karyorrhexis
Liver cell necrosis
Changes of irreversible cell injury
“necrosis” by electron microscopy
(ultrastructural changes):

Changes of irreversible cell
injury “necrosis”
 Patterns (types) of Tissue Necrosis

´1.Coagulative necrosis :the
architecture of dead tissues is
preserved. The cells are eosinophilic,
anucleated cells.
´Cause :Ischemia in all organs except
the brain.
´ A localized area of coagulative
necrosis is called an infarct.
Normal cardiac muscle
´2.Liquefactive necrosis: is
characterized by digestion of the dead
cells, resulting in transformation of the
tissue into a liquid.
Examples :
´Hypoxic cell death of the brain
´Abscess
´3.Gangrenous necrosis :It is usually applied to
a limb, generally the lower leg, that has lost its
blood supply and has undergone necrosis
(coagulative necrosis).
´4.Caseous necrosis :is seen in tuberculous
infection.The term “caseous”
(cheeselike) is derived from the friable
white appearance of the area of necrosis.
 5.Fat necrosis :
´ Enzymatic fat necrosis: occurs in acute pancreatitis
,pancreatic enzymes leak out and liquefy the fat cells
in the peritoneum. The derived fatty acids, combine
with calcium to produce chalky-white areas (fat
saponification).
´ Traumatic fat necrosis :e.g.fat necrosis of
breast after trauma which induces rupture of
fat cells. The released fat causes chronic
inflammation and foreign body reaction
resulting in a hard mass mistaken as
malignant tumor.
 Mechanisms of Cell Injury

1.DEPLETION OF ATP
´The major causes are reduced supply
of oxygen (ischemia) and nutrients, and
some toxins (e.g., cyanide).

´Depletion of ATP to less than 5% to 10%
of normal levels has widespread effects
on many critical cellular systems:
2.INFLUX OF CALCIUM
Ischemia and certain toxins cause an
increase in cytosolic calcium
concentration.
Increased cytosolic Ca2+ activates a
number of enzymes, including:
 3. ACCUMULATION OF OXYGEN-
DERIVED FREE RADICALS (OXIDATIVE
STRESS)
´Free radicals are chemical species with a
single unpaired electron in an outer
orbital.
´Such chemical states are extremely
unstable and readily react with inorganic
and organic chemicals;
´ when generated in cells they avidly
attack nucleic acids as well as a variety of
cellular proteins and lipids (cell
membrane).
´ Reactive oxygen species (ROS) are a
type of oxygen-derived free radical
whose role in cell injury is well
established.
´They are produced normally in cells
during mitochondrial respiration and
energy generation.
´Free radicals are unstable and
decay spontaneously or are
degraded and removed by
cellular defense systems:
Ø Superoxide dismutases (SODs)
Ø Glutathione (GSH) peroxidase
Ø Catalase
Ø Endogenous or exogenous antioxidants
(e.g., vitamins E, A, and C, and β-
carotene)
´When the production of ROS increases,
the result is an excess of these free
radicals, leading to a condition called
oxidative stress.
´Cell injury results from damage by free
radicals in the following situations:
ischemia-reperfusion , chemical and
radiation injury, oxygen toxicity,
infection, and inflammation.
 Apoptosis
´Apoptosis is a pathway of cell death
induced by a tightly regulated suicide
program in which cells destined to die
activate enzymes capable of degrading the
cells' own nuclear DNA and nuclear and
cytoplasmic proteins.
´Fragments of the apoptotic cells then break
off (apoptosis: falling off).
´The plasma membrane of the
apoptotic cell remains intact, its
fragments become avid targets for
phagocytes.
´Therefore cell death by this
pathway does not elicit an
inflammatory reaction in the host.
 MORPHOLOGIC CHANGES IN
APOPTOSIS

´Cell shrinkage.
´The nucleus break up into small
fragments.
´Formation of apoptotic bodies
composed of cytoplasm ,nuclear
fragments and organelles
´The apoptotic bodies are rapidly
ingested by phagocytes.
´ On histologic examination, in tissues
stained with hematoxylin and eosin, the
apoptotic cell appears as a round or
oval mass of intensely eosinophilic
cytoplasm with dense nuclear chromatin
fragments.
 CAUSES OF APOPTOSIS

Physiologic
´ During embryogenesis
´ Involution of hormone-dependent tissues upon
hormone withdrawal, such as, the regression of
the lactating breast after weaning
´ Cell loss in proliferating cell populations, such
as, epithelial cells in intestinal crypts, to maintain
a constant number.
 CAUSES OF APOPTOSIS

Physiologic

´ Death of cells that served their purpose:
Neutrophils in an acute inflammatory response
´ Elimination of potential harmful self-reactive
lymphocytes (Prevents reaction against one’s
own tissue).
´ Cell death by cytotoxic T lymphocytes , a
defense mechanism against viruses and
tumors.
Pathologic
q DNA damage. Radiation, cytotoxic
anticancer drugs
q Accumulation of misfolded proteins.
because of mutations in the genes or free
radicals.
q Viral infections e.g. viral hepatitis in which
apoptotic cells are known as councilman
bodies.
q Pathologic atrophy in paranchymal organs
after duct obstruction such pancreas and
parotid gland.
Feature Necrosis Apoptosis
Cell size Enlarged Reduced (shrinkage)
(swelling)
Nucleus Pyknosis ➙ Fragmentation into
karyorrhexis ➙ nucleosome-size fragments
karyolysis
Plasma Disrupted Intact
membrane
Cellular contents Enzymatic Intact
digestion; may
leak out of cell
Adjacent Frequent No
inflammation
Physiologic or pathologic Often physiologic,
pathologic role may be pathologic after
some forms of cell injury,
especially DNA damage