Unit 2 Part 2 Cell Adaptation, Injury & Death 2024-2025 PDF

Summary

This document is a collection of notes on cell biology and pathology, focusing on topics such as cell adaptation, cell injury, and cell death. It covers various types of cell adaptation, including hypertrophy, hyperplasia, atrophy, and metaplasia, and explores the mechanisms and consequences of cell injury.

Full Transcript

UNIT 2 –
INTRODUCTION
TO PATHOLOGY
Sarah Tan de Luna, MD, MPH
PART 2
Cell Injury, Death,
and Adaptation
Sarah Tan de Luna, MD, MPH
CELL ADAPTATION
Pathology: the Study of Disease
◼ Etiology or cause: infection, genetic etc. and
often mutifactoral

◼ Pathogenesis: progression of the disease

◼ (Molecular and Morphologic Changes)

◼ Clinical Manifestations: signs and symptoms
Injury: Altered Homeostasis
 Overview
◼ Cells are the structural and functional units
of tissues and organs.
◼ When a cell is exposed to physiologic or
pathologic stress, it undergoes a
reversible functional and structural
response during which new but altered
states are achieved allowing the cell to
survive and to continue to function.
◼ This capability is called cellular
adaptation.
◼ Adaptation results in a NEW STEADY
STATE and PRESERVING VIABILITY
Adapted-Normal-Injured Cells
 Overview
◼ Whether a specific form of stress induces
adaptation or causes reversible or
irreversible injury depends not only on the
nature and severity of the stress, but also
on several other cell-specific variables,
including vulnerability, differentiation, blood
supply, nutrition, and the previous state of
the cell
Cell Proliferation Varies
◼ Labile cells – continuously dividing
(epithelium, bone marrow, hematopoietic
cells)
◼ Stable cells – quiescent (in G0 stage;
hepatocytes, smooth muscle,
lymphocytes, fibroblasts, endothelial cells)
◼ Permanent cells – nondividing (neurons,
skeletal and cardiac muscle)
Various Types of Adaptations

◼ Cells may undergo various adaptations in
physiological and pathological conditions.
These are controlled by complex
molecular mechanisms.
 Cellular Adaptations
◼ Hypertrophy
◼ Hyperplasia
◼ Atrophy
◼ Metaplasia
◼ Dysplasia*
 Cellular Adaptations
◼ Physiologic – occurs due to a normal
stressor/stimuli; results in enhanced
function
◼ Pathologic – occurs due to an abnormal
stressor/stimuli; results in dysfunction and
mortality
◼ Compensatory – adaptation to positively
counteract reduction in function
Hypertrophy-
◼ Increase in the size of cells that results in
an increase in the size of the affected
organs.
◼ There are no new cells, just bigger cells,
enlarged by an increased amount of
structural proteins and organelles
(increase in mRNA and proteins)
Hypertrophy-
◼ Occurs in response to increased demands
◼ It is mostly seen in cells that cannot divide
or multiply, such as:
 skeletal muscle (pumping iron),
 cardiac muscle (hypertension).
◼ These changes usually revert to normal if
the cause is removed.
Physiologic Hypertrophy
Pathologic Hypertrophy
◼ Cross-section of the
heart of a patient with
long-standing
hypertension shows
pronounced,
concentric left
ventricular
hypertrophy
Hyperplasia-
◼ Increased number of cells in an organ or
tissue in response to a stimuli. Hyperplasia
may sometimes co-exist with hypertrophy.
◼ Takes place if the cell is capable of
replication
Mechanisms of Hyperplasia
◼ Growth factor-driven proliferation of
mature cells and
◼ By increased output of new cells from
tissue stem cells
Physiologic Hyperplasia
◼ Female breast during pregnancy
(epithelium)
◼ Liver - In individuals who donate one lobe
of the liver for transplantation, the
remaining cells proliferate so that the
organ soon grows back to its original size
◼ Bone marrow in response to supplements
◼ Endometrium – after menstruation
Physiologic Hyperplasia
Pathologic Hyperplasia
◼ Endometrium – in response to hormones
◼ Hyperplasia of prostate in old age
◼ Epidermal hyperplasia (warts) in response
to viral infection
Pathologic Hyperplasia
Hypertrophy and Hyperplasia
Atrophy
◼ Shrinkage in the size of the cell by loss of
substance
◼ When a sufficient number of cells is
involved, the entire tissue or organ
diminishes in size
◼ Although atrophic cells may have
diminished function, they are not dead
Atrophy results from both…

◼ Decreased protein synthesis
◼ Increased protein degradation
-Lysosomes with hydrolytic enzymes
-The ubiquitin-proteasome pathway
Physiologic Atrophy
◼ Embryonic structures – notochord,
thyroglossal duct
◼ Post partum uterus
Physiologic Atrophy
Pathologic Atrophy
◼ Disuse atrophy
◼ Denervation atrophy
◼ Ischemic atrophy
◼ Loss of nutrition – Marasmus, cachexia
◼ Loss of endocrine stimulation - Breast
after menopause
◼ Pressure atrophy - Tumor compressing
normal tissue
Pathologic Atrophy
Metaplasia
◼ A reversible change in which one ADULT
cell type is replaced by another ADULT cell
type that is able to withstand the adverse
environment
◼ Reversible change in which one
differentiated cell type (epithelial or
mesenchymal) is replaced by another cell
type.
◼ Usually occurs in response to stress or
chronic irritation.
Mechanisms of Metaplasia
◼ Re-programing of stem cells that exist in
normal tissue.
◼ Induced by cytokines, growth factors and
other environmental signals
◼ Retinoic acid may play a role.
◼ Exact mechanism is unknown.
Squamous cells replace columnar cells
Metaplasia
◼ Squamous metaplasia
◼ Osseous metaplasia
◼ Myeloid metaplasia
Squamous Metaplasia
Squamous Metaplasia
Esophagus: glandular epithelium (R) is metaplastic
Bronchus with Columnar to
Squamous Metaplasia
Esophagus with Squamous to
Columnar metaplasia
Endometrial Osseous
Metaplasia
Myeloid Metaplasia
◼ Atrophy, Hypertrophy, Hyperplasia and
Metaplasia are reversible changes!
◼ Hyperplasia and Metaplasia are not
premalignant changes, however they are
“fertile fields” for Dysplasia which is a
premalignant change
Dysplasia
◼ Atypical proliferative changes due to
chronic irritation or inflammation;
◼ Cells vary in size and shape, large nuclei
are frequently present, and rate of mitosis
is increased
◼ Premalignant change
DYSPLASIA IN THE CERVIX

Mild dysplasia Moderate Marked
dysplasia dysplasia
Anaplasia
◼ Cells are undifferentiated with variable
nuclear and cell structures and numerous
mitotic figures
◼ Characteristic of cancer and tumor and is
the basis for grading the aggressiveness
of a tumor
Neoplasia
◼ “New growth”
◼ A tumor
◼ Benign – considered less serious because
they do not spread and are not life
threatening (except in the brain)
◼ Malignant - cancer
Aplasia
◼ Failure of cell production. During fetal
development, aplasia results in agenesis,
or absence of an organ due to failure of
production.

Hypoplasia
Incomplete development of an organ so
that it fails to reach adult size; decrease in
cell production that is less extreme than in
aplasia.
Examples of Hypoplasia

Hypoplastic Left Ventricle

Hypoplastic Kidney
UNIT 2 –
INTRODUCTION
TO PATHOLOGY
Sarah Tan de Luna, MD, MPH
PART 2
Cell Injury, Death,
and Adaptation
Sarah Tan de Luna, MD, MPH
CELL INJURY
Cell Injury
Overview of Cell Injury
◼ Cells actively control the composition of
their immediate environment and
intracellular milieu within a narrow range of
physiological parameters
(“homeostasis”)
◼ Under physiological stresses or
pathological stimuli (“injury”), cells can
undergo adaptation to achieve a new
steady state that would be compatible with
their viability in the new environment.
Overview of Cell Injury
◼ When cells are exposed to inherently damaging
agents, cells are stressed so severely that they
are no longer able to adapt resulting in:
◼ Reversible cell injury – denotes pathologic
changes that can be reversed when the
stimulus is removed, or if the cause of injury is
mild
◼ Irreversible injury – denotes pathologic
changes that are permanent and cause cell
death
Timeline of Cell Injury
Causes of Cellular Injury
1. Hypoxic Cell injury – oxygen deprivation
a) Ischemia – loss of blood supply(oxygen
and nutrients); more rapidly and
severely injures tissues than does
hypoxia alone
b) Inadequate oxygenation –
cardiorespiratory failure
c) Loss of oxygen carrying capacity of blood
– anemia, carbon monoxide poisoning
Cell Proliferation Varies
◼ Labile cells – continuously dividing
(epithelium, bone marrow, hematopoietic
cells)
◼ Stable cells – quiescent (in G0 stage;
hepatocytes, smooth muscle,
lymphocytes, fibroblasts, endothelial cells)
◼ Permanent cells – nondividing (neurons,
skeletal and cardiac muscle)
Susceptibility of Cells to
Hypoxic Injury
High Neurons (3-4 min)

Intermediate Myocardium, hepatocytes,
renal epithelium (30 min-2hr)

Low Fibroblasts, epidermis, skeletal
muscle (many hours)
Causes of Cellular Injury
2. Free Radical Injury
◼ ROS – Hydroxyl, Hydrogen, Superoxide
◼ Chemical species with a single unpaired
electron in an outer orbital
◼ Chemically unstable and therefore react with
other molecules, resulting in chemical damage
◼ Initiate autocatalytic reactions; molecules that
react with free radicals are in turn converted to
free radicals
Free-Radical Induced Injury
◼ If not adequately neutralized, free radicals
can damage cells by
1. Lipid peroxidation of membranes –
double bonds in polyunsaturated
membrane lipids are vulnerable to attack
by oxygen free radicals
Free-Radical Induced Injury
2. DNA fragmentation – Free radicals react
with thymine in nuclear and mitochondrial
DNA to produce single strands breaks
3. Protein cross-linking – Free radicals
promote sulfhydryl-mediated protein cross
linking, resulting in increased degradation
and loss of activity
Neutralization of Free Radicals
1. Spontaneous decay
2. Superoxide dismutase
3. Glutathione (GSH)
4. Catalase
5. Endogenous and exogenous antioxidants
(Vitamins E, A, C and β carotene)
Causes of Cellular Injury
3. Physical Agents – trauma, heat, cold,
radiation, electric shock
4. Chemical Agents -
a) Therapeutic drugs - paracetamol
b) Nontherapeutic agents – lead, alcohol
c) Binding of mercuric chloride to sulfhydryl
groups of proteins
d) Generation of toxic metabolites such as
conversion of CCl4 to CCL3* free radicals in
the SER of the liver
Causes of Cellular Injury
5. Infectious Agents -
a) Viruses
b) Bacteria
c) Fungi
d) Rickettsia
e) Parasites
Infectious agents
◼ Infectious agents - direct effects of
bacterial toxins; cytopathic effects of
viruses and other actions such as:
 interfering with DNA,RNA, proteins, cell
membranes or
 inducing apoptosis.
 -indirect effects via the host immune reaction.
Causes of Cellular Injury
6. Immune System - anaphylaxis, loss of
immune tolerance leading to autoimmunity
7. Genetic Abnormalities - sickle cell
disease, inborn errors of metabolism
Causes of Cellular Injury
8. Nutritional imbalances – vitamin
deficiencies, obesity leading to type II DM,
fat leading to atherosclerosis
9. Aging – degeneration as a result of
trauma, intrinsic cellular senesence
Reversible Cell Injury
◼ Return to steady state by altering cell
conditions
◼ Return to normal
◼ Sub-lethal and short lasting
◼ Caused by hypoxia/ischemia
◼ Best examples of reversible cell injury are
cellular swelling and fat accumulation
Reversible Cell Injury – Cell
Swelling
◼ Cell swelling is the first manifestation of most
forms of cell injury.
◼ Also called hydropic change or vacuolar
degeneration
◼ Caused by failure of energy dependent ion pumps
◼ Gross changes: It causes some pallor, increased
turgor, and increase in weight of the organ
◼ Microscopic changes: Small, clear vacuoles seen
in the cytoplasm which represent distended and
pinched off segments of ER
Reversible Cell Injury – Cell
Swelling
Reversible Cell Injury – Fatty
Change
◼ Steatosis/Fatty change occurs in hypoxic, toxic
or metabolic injuries.
◼ It is characterized by the appearance of lipid
vacuoles in the cytoplasm.
◼ Abnormal accumulations of triglycerides within
parenchymal cells
◼ These changes are encountered by the cells
involved in the fat metabolism such as
hepatocyte, myocardial cells, muscle, kidney.
Reversible Cell Injury – Fatty
Change
PREVALENCE OF FATTY
LIVER DISEASE
◼ Global Prevalence of NAFLD estimated at
38% in 2018.
◼ Prevalence in the Philippines:
-12.2% at a tertiary hospital in 2008
-38-39% in two small series in private
hospitals in 2015 and 2020
Other Ultrastructural Changes
Plasma
membrane blebbing
Plasma membrane
blunting
Distortion of microvilli
Creation of myelin
figures
Loosening of
intercellular
attachments
Plasma Membrane Blebbing
◼ Membrane blebs are formed when plasma
membrane is detached from underlying
actin cytoskeleton.
◼ The detachment is caused by the increase
of intracellular pressure or by the local
rupture of actin filaments.
Myelin Figures
◼ Aggregates of damaged cell membranes
(phospholipids).
◼ They either are phagocytosed by other
cells or further degraded into fatty acids
and calcify.
Myelin Figures
Other Ultrastructural Changes
Mitochondrial swelling
Mitochondrial
rarefaction
Small phospholipid-
rich amorphous
densities
Other Ultrastructural Changes
Endoplasmic
reticulum - Dilation of
the ER leads to the
detachment and
disaggregation
of polysomes
Nucleus -
Disaggregation of
granular and fibrillar
elements
Irreversible Cell Injury
◼ Severe types of cell injury, leads to cell
death
◼ Has passed the point of no return
◼ Lethal and long lasting
◼ Results in NECROSIS an APOPTOSIS
◼ Leads to permanent cell loss
Mechanisms of Cell Injury
(Necrosis/Apoptosis)
CELL DEATH
Cell Death

◼ Death of cells occurs in two ways:
 Necrosis--(irreversible injury) changes
produced by enzymatic digestion of dead
cellular elements
 Apoptosis--vital process that helps eliminate
unwanted cells--an internally programmed
series of events effected by dedicated gene
products
Necrosis
◼ Morphologic expression of cell death
◼ Progressive disintegration of cell
structure
◼ Initiated by overwhelming stress
◼ Usually elicits an acute inflammatory cell
response (neutrophils may be present).
Necrosis
◼ Result from denaturation of intracellular
proteins and enzymatic digestion of cells
◼ Loss of membrane integrity
◼ Digestion enzyme: from lysosomes of
dying cells and from leukocytes
(inflammatory response)
◼ Vacuolation due to digestion of
cytoplasmic organelles
◼ Plasma and membrane discontinuities
Types of Necrosis
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes
Coagulative necrosis:
◼ Typically seen in hypoxic environments
(ischemia caused by obstruction in a
vessel)
◼ The outline of the dead cells are
maintained and the tissue is somewhat
firm.
◼ The injury denatures not only structural
proteins but also enzymes and so blocks
the proteolysis of the dead cells
◼ Example: myocardial infarction
Coagulative Necrosis
Coagulative Necrosis
Coagulative Necrosis
◼ When there is marked cellular
injury, there is cell death. This
microscopic appearance of
myocardium is a mess
because so many cells have
died that the tissue is not
recognizable. Many nuclei
have become pyknotic
(shrunken and dark) and have
then undergone karorrhexis
(fragmentation) and karyolysis
(dissolution). The cytoplasm
and cell borders are not
recognizable.
Morphology of necrosis –
cytoplasmic changes
Increased
◼ Gross eosinophilia due to
Loss of
◼ Microscopy Inflammatio cytoplasmic RNA
n that binds Cellular
◼ Ultrastructure (Electron microscopy)
hematoxylinswelling
When enzymes have
digested
the cytoplasmic
organelles, the
cytoplasm becomes
vacuolated
and appears moth-
eaten
Source: Robbins Textbook of pathology, 9E
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes
 Liquefactive necrosis: the dead cells
undergo disintegration and affected tissue is
liquified.
◼ Example: cerebral infarction.
◼ usually associated with cellular destruction
and pus formation (e.g. pneumonia).
◼ ischemia (restriction of blood supply) in the
brain produces liquefactive rather than
coagulative necrosis.
Brain Abscess with
Liquefactive Necrosis
Abscess/Liquefactive Necrosis
Liquefactive necrosis
◼ This is liquefactive
necrosis in the brain in a
patient who suffered a
"stroke" with focal loss of
blood supply to a portion
of cerebrum. This type of
infarction is marked by
loss of neurons and
neuroglial cells and the
formation of a clear space
at the centre left.
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes
◼ Caseous necrosis:
 specific form of coagulation necrosis typically
caused by mycobacteria (e.g. tuberculosis).
 a form of coagulative necrosis.
 The term “caseous” (cheese like) is derived
from the friable white appearance of the area
of necrosis
 Example: tuberculosis lesions.
◼ Caseous necrosis hilar
lymph node lung
Granulomatous Inflammation with Central Necrosis
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes

◼ Gangrenous necrosis:
 Necrosis (secondary to ischemia)
 usually with superimposed infection.
 Example: necrosis of distal limbs, usually foot
and toes in diabetes.
Gangrenous Necrosis
Gangrenous Necrosis
◼ In this case, the toes
were involved in a
frostbite injury. This is
an example of "dry"
gangrene in which
there is mainly
coagulative necrosis
from the anoxic injury.
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes
◼ Fibrinoid necrosis is caused by immune-
mediated vascular damage. This pattern of
necrosis typically occurs when complexes of
antigens and antibodies are deposited in the
walls of arteries.
◼ Deposits of these “immune complexes,” together
with fibrin that has leaked out of vessels, result
in a bright pink and amorphous appearance in
H&E stains, called “fibrinoid” (fibrin-like) by
pathologists.
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes

◼ Fatnecrosis:
Traumatic fat necrosis
Enzymatic fat necrosis - necrosis of
fat by pancreatic enzymes.
Fat Necrosis
◼ This is fat necrosis of the
pancreas. Cellular injury
to the pancreatic acini
leads to release of
powerful enzymes which
damage fat by the
production of soaps, and
these appear grossly as
the soft, chalky white
areas seen here on the
cut surfaces.
Fat Necrosis
Fat Necrosis (L) and Normal Pancreas (R)
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes
 Gummatous necrosis is restricted to necrosis
involving spirochaetal infections (e.g. syphilis).
Patterns of Necrosis In Tissues or
Organs – Macroscopic Changes
 Haemorrhagic necrosis is due to blockage of the
venous drainage of an organ or tissue (e.g. in
testicular torsion).
Apoptosis
◼ Pathway of cell death induced by a
tightly regulated suicide program.
◼ Controlled by specific genes.
◼ Fragmentation of nucleus, DNA
◼ Blebs form and apoptotic bodies are
released.
◼ Apoptotic bodies are phagocytized.
◼ No neutrophils.
Apoptosis
◼ In the human body ~ 100,000 cells are
produced every second by mitosis and a
similar number die by apoptosis.
◼ Development and morphogenesis
 During limb formation separate digits evolve
 Ablation of cells no longer needed (tadpole)
◼ Homeostasis
 Immune system
 >95% T and B cells die during maturation
(negative selection)
◼ Deletion of damaged/ dangerous cells
Causes of Apoptosis
◼ Physiologic
◼ Pathologic
Physiologic Apoptosis
◼ Hormone dependent involution - Prostate
glandular epithelium after castration;
Regression of lactating breast after
weaning, endometrium in menstrual cycle,
mammary gland in menopause
◼ Cell loss in proliferating cell populations –
Immature lymphocytes, Epithelial cells in
the GI tract
Physiologic Apoptosis
◼ Elimination of self-reactive lymphocytes
◼ Death of cells that have served their
function – neutrophils in acute
inflammation
◼ During development for removal of excess
cells during embryogenesis - Programmed
cell destruction, for example formation of
digits
Apoptosis (Cell Death)
Apoptosis (Cell Death)
Apoptosis (Cell Death)
Pathologic Apoptosis
◼ To eliminate cells with DNA damage by radiation,
cytotoxic agents etc.
◼ Accumulation of misfolded proteins - Improperly
folded proteins may arise because of mutations.
Excessive accumulation of these proteins in the
ER leads to a condition called ER stress
◼ Cell death in viral infections that induce
apoptosis such as HIV and Adenovirus
◼ Alzheimer's, Parkinson's and Huntington's
diseases, and stroke
Pathologic Apoptosis
◼ Councilman bodies in liver - Apoptotic Body or
Councilman Hyaline Body; eosinophilic globule that
represents a hepatocyte undergoing apoptosis and
sometimes necrosis; seen most commonly in Yellow
fever and other viral hemorrhagic fevers
◼ Organ atrophy after duct obstruction - in the pancreas,
parotid gland, and kidney
Initiation of Apoptosis

◼ Intrinsic Pathway - Begins when an
injury occurs within the cell and the
resulting stress activates the apoptotic
pathway; activated when BCL-2-family
pro-apoptotic proteins cause the
permeabilization of the mitochondrial outer
membrane
Initiation of Apoptosis

◼ Extrinsic Pathway - Begins outside a cell,
when conditions in the extracellular
environment determine that a cell must
die; activated when cell-surface death
receptors like Fas are engaged by their
ligands
Mechanisms of apoptosis
Morphology of Apoptosis

◼ Cell shrinkage
◼ Chromatin
condensation
◼ Formation of
cytoplasmic blebs
and apoptotic
bodies
◼ Phagocytosis of
apoptotic cells or
cell bodies, usually
by macrophages
Necrosis vs Apoptosis
INTRACELLULAR
ACCUMULATIONS
INTRACELLULAR
ACCUMULATIONS
◼ Metabolic derangements lead to
accumulation of different substances in the
cytoplasm or in organelles or in nucleus
PATHWAYS

Source: Robbins Textbook of pathology, 9E
LIPID
◼ Fatty change
◼ Atherosclerosis
◼ Xanthomas
◼ Cholesterosis
Fatty Change
◼ Characterized by the accumulation of
intracellular parenchymal triglycerides and is
observed most frequently in the liver, heart, and
kidney.
◼ For example, in the liver, fatty change may be
secondary to alcoholism, diabetes mellitus,
malnutrition, obesity, or poisonings.
◼ Cause: Imbalance among the uptake, utilization,
and secretion of fat
Fatty Change Mechanisms
◼ Increased transport of triglycerides or fatty
acids to affected cells
◼ Decreased mobilization of fat from cells,
most often mediated by decreased
production of apoproteins required for fat
transport.
◼ Decreased use of fat by cells
◼ Overproduction of fat in cells
Atherosclerosis
◼ In atherosclerotic
plaques, smooth muscle
cells and macrophages
within the intimal layer of
the aorta and large
arteries are filled with lipid
vacuoles, most of which
are made up of
cholesterol and
cholesterol esters.
◼ Such cells have a foamy
appearance (foam cells)
Xanthomas
◼ Clusters of foamy cells
are found in the
subepithelial connective
tissue of the skin and in
tendons
Cholesterosis
◼ This refers to the focal
accumulations of
cholesterol-laden
macrophages in the
lamina propria of the
gallbladder
PROTEINS
◼ Resorption
droplets in
proximal renal
tubules in
proteinuria
◼ Russel bodies
◼ α1 antitrypsin
deficiency
◼ Neurofibrillary
tangle found in
Alzheimer’s
HYALINE CHANGE
◼ An alteration within cells or in the
extracellular space that gives a
homogeneous, glassy, pink appearance in
routine histologic sections stained with
hematoxylin and eosin
◼ This morphologic change is produced by a
variety of alterations and does not
represent a specific pattern of
accumulation
HYALINE CHANGE
◼ Intracellular Hyaline
 Intracellular
accumulations of
protein, described
earlier (reabsorption
droplets, Russell
bodies, alcoholic
hyaline), are examples
of intracellular hyaline
deposits.
HYALINE CHANGE
◼ Extracellular Hyaline
 Collagenous fibrous tissue
in old scars may appear
hyalinized
 In long-standing
hypertension and diabetes
mellitus, the walls of
arterioles, especially in the
kidney, become hyalinized,
resulting from extravasated
plasma protein and
deposition of basement
membrane material
GLYCOGEN
◼ Glycogen is a readily
available energy source
stored in the cytoplasm of
healthy cells.
◼ Excessive intracellular
deposits of glycogen are
seen in patients with an
abnormality in either
glucose or glycogen
metabolism – Diabetes
mellitus/Glycogen storage
disorders
PIGMENTS
◼ Carbon
◼ Lipofuscin
◼ Hemosiderin
◼ Melanin
◼ Homogentisic acid
◼ Bilirubin
Carbon
◼ The most common exogenous pigment is carbon
(coal dust), a ubiquitous air pollutant in urban areas.
◼ ANTHRACOSIS
 When inhaled Carbon is picked up by macrophages
within the alveoli and is then transported through
lymphatic channels to the regional lymph nodes
 Accumulations of this pigment blacken the tissues
of the lungs and the involved lymph nodes.
◼ COAL WORKER’S PNEUMOCONIOSIS
 In coal miners the aggregates of carbon dust may
induce a fibroblastic reaction or even emphysema
and thus cause a serious lung disease.
◼ TATTOOING
 is a form of localized, exogenous pigmentation of
the skin. The pigments inoculated are phagocytosed
by dermal macrophages, in which they reside for Source: Robbins Textbook of pathology, 9E

the remainder of the
 The pigments do not usually evoke any
Inflammatory response.
Lipofuscin
◼ It is seen in cells
undergoing slow,
regressive changes
and is particularly
prominent in the liver
and heart of aging
patients
◼ Tell-tale sign of free
radical injury and lipid
peroxidation
◼ Not injurious to the
cell or its functions
Hemosiderin
◼ Hemosiderin, a hemoglobin-derived,
golden yellow to-brown, granular or
crystalline pigment derived from iron
◼ Under normal conditions small amounts
of hemosiderin can be seen in the
mononuclear phagocytes of the bone
marrow, spleen, and liver, which are
actively engaged in red cell breakdown
◼ Local excesses of hemosiderin -
Common bruise
Hemosiderin
Hemosiderin
◼ Systemic overload of iron - HEMOSIDEROSIS
 Hemochromatosis - increased absorption of
dietary iron due to an inborn error of
metabolism called
 Hemolytic anemias - premature lysis of red
cells leads to release of abnormal quantities
of iron
 Repeated blood transfusions - transfused
red cells constitute an exogenous load of iron
Melanin
◼ Formed from tyrosine by the
action of tyrosinase,
synthesized in melanosomes of
melanocytes within the
epidemis, and transferred by
melanocytes to adjacent
clusters of keratinocytes and
also to macrophages
(melanophores) in the subjacent
dermis.
◼ Increased melanin pigmentation
is associated with sun tanning
and with a wide variety of
disease conditions.
◼ Decreased melanin
pigmentation is observed in
albinism and vitiligo.
Homogentisic acid
◼ Black pigment that occurs
in patients with
alkaptonuria
◼ Here the pigment is
deposited in the skin,
connective tissue, and
cartilage, and the
pigmentation is known as Source: Robbins Textbook of pathology, 9E

oochronosis
Bilirubin
◼ This pigment is a catabolic product of the heme
moiety of hemoglobin and, to a minor extent,
myoglobin.
◼ In various pathologic conditions, bilirubin
accumulates and stains the blood, sclera,
mucosae, and internal organs, producing a
yellowish discoloration called jaundice.
PATHOLOGIC CALCIFICATION
◼ Pathologic calcification is the abnormal
tissue deposition of calcium salts, together
with smaller amounts of iron, magnesium,
and other mineral salts
◼ Types
 Dystrophic
 Metastatic
Dystrophic Calcification
◼ Deposition occurs locally in dying tissues
◼ It occurs despite normal serum levels of
calcium
◼ In absence of derangements in calcium
metabolism
Dystrophic Calcification
◼ Examples
 in the atheromas of advanced
atherosclerosis
 develops in aging or damaged heart
valves
◼ Morphology
 Gross - fine, white granules or
clumps, often felt as gritty deposits
 Microscopy –
◼ intracellular or extracellular,
basophilic, amorphous granular,
sometimes clumped
appearance
◼ The progressive acquisition of
outer layers may create
lamellated configurations,
called psammoma bodies – In
papillary lesions of thyroid, Source: Robbins Textbook of pathology, 9E
meningiomas etc
◼ In asbestosis of the lung, iron
and calcium deposition creates
dumbbell shaped forms
Metastatic Calcification
◼ Deposition of calcium salts in otherwise
normal tissues
◼ Results from hypercalcemia
◼ Secondary to some disturbance in calcium
metabolism.
Metastatic Calcification
◼ Principally affects the interstitial tissues of
the gastric mucosa, kidneys, lungs,
systemic arteries, and pulmonary veins
◼ All of these tissues excrete acid and
therefore have an internal alkaline
compartment that predisposes them to
metastatic calcification
Metastatic Calcification -
Causes
 Increased secretion of parathyroid hormone
(PTH) with subsequent bone resorption
◼ hyperparathyroidism due to parathyroid tumors,
and
◼ ectopic secretion of PTH-related protein by
malignant tumors
 Resorption of bone tissue
◼ primary tumors of bone marrow (e.g., multiple
myeloma, leukemia)
◼ diffuse skeletal metastasis (e.g., breast cancer),
accelerated bone turnover (e.g., Paget disease)
◼ Immobilization
Metastatic Calcification -
Causes
 Vitamin D–related disorders
◼ vitamin D intoxication,
◼ sarcoidosis (in which macrophages activate a
vitamin D precursor
◼ idiopathic hypercalcemia of infancy (Williams
syndrome) - characterized by abnormal sensitivity
to vitamin D
 Renal failure
◼ which causes retention of phosphate, leading to
secondary hyperparathyroidism.