Cellular Injury Part III PDF

Summary

This document provides an overview of cellular injury, including a detailed description of exogenous and endogenous pigments and their effects on the human body. It covers various forms of cellular injury and associated conditions.

Full Transcript

Cellular injury III
Dr/ Sara Badawy
Dr/ Sara Badawy
Disturbance in pigment
metabolism
 Pigments are colored substances that are present in
most living beings including humans.
That are either classified into :
❑ Exogenous pigment (outside the body)
❑ Endogenous pigment (inside the body).

Abnormal deposition of colored substances in the
tissues either intracellular or extracellular or both
known as Disturbance in pigment metabolism
(Pathological pigmentation).
 Exogenous pigment:
1- Inhaled pigment
2- Ingested pigment
3- Injected pigment

Endogenous pigment:
1- Melanin
2-Haemoprotein derived
pigments
3- Lipofuscin (wear-and-tear
pigment)
Exogenous pigments
 Def:
Exogenous pigments come from outside the body either via inhalation,
ingestion or inoculation.

Pneumoconiosis
Pneumoconiosis is a term originally describe the non-neoplastic lung reaction
to inhalation of mineral dusts.
The lungs and their lymph nodes are the reservoir of various dust particles
that are inhaled in the air.
The dust particles act as mild irritants and induce slight increase in
connective tissue (fibrosis) and an accumulation of macrophages.
Since pneumoconiosis are associated with certain occupations, they are
considered as occupational lung diseases.
 Pneumoconiosis:
The presences of pigment and body
reaction in lung called
pneumoconiosis
The three most common mineral
dust pneumoconiosis are the coal
dust or carbon, silica, and
asbestos which always result from
exposure in the workplace.
 Anthracosis

Anthracosis is the deposition of
carbon or coal dust in the lungs.
It is seen in horses and mules
used in coal mines.
It also frequently occurs in dogs
that live in industrial areas where
coal dust, soot, and smoke pollute
the air.
 Anthracosis
Pulmonary anthracosis is the most common exogenous
pigment induced pulmonary lesion in coal miners and
also is commonly seen in all urban areas and
smokers.
Inhaled carbon pigment is engulfed by alveolar
macrophages, which then accumulate in the connective
tissue along the lymphatics, including the pleural
lymphatics and lymph nodes.
Asymptomatic anthracosis, in which pigment accumulates
without a perceptible cellular reaction, but the disease
divided into 2 categories:
1- Simple coal worker’s pneumoconiosis (CWP):
In which accumulations of macrophages occur with little
to no pulmonary dysfunction.
 Simple CWP is characterized by coal macules and the somewhat larger coal nodule. The
coal macule consists of dust-laden macrophages. In addition, the nodule contains
small amounts of collagen fibers arrayed in a delicate network.
2- Complicated CWP or progressive massive fibrosis in which fibrosis is extensive, and
lung function is compromised.
Complicated CWP occurs on a background of simple CWP characterized by coal
nodules and centrilobular emphysema generally requires many years to develop.
 Gross picture:
The carbon appears as black pigment in the
lungs which either as focal or diffuse
infiltration.
Although these lesions are scattered
throughout the lung, the ventral lobes are
more heavily involved.
Lungs are black in color due to multiple,
intensely blackened scars larger than 2 cm,
sometimes up to 10 cm in greatest
diameter
The regional lymph nodes are also involved
and black pigment being present in the
medulla.
The carbon is only mild irritant.
 Microscopically:
Black carbon particles either present free in
interalveolar space or in the alveolar walls
or around the bronchioles.
Also, can seen around alveolar blood
vessels.
Or inside macrophage.
The particles are just black in color,
extremely small and clustered together into
globular masses.
 Significant and
results:
Since carbon is insoluble in tissue fluids,
the pigmentation persists for the life of the
human and animal lung.
It has little harm or cause no symptoms.
Extensive deposits in the lung may cause
slight respiratory distress.
Heavy infiltration induce pulmonary
emphysema and fibrosis cause serious
pulmonary injury.
Silicosis
 Silicosis is the deposition of fine silica particles (silicon dioxide,
i.e., stone dust) in the lungs.
It is more common and important in humans than in animals.
In humans, it is currently the most prevalent chronic
occupational lung disease in the world.
Workers in several occupations but especially those involved in
sandblasting (dessert environment) and hard-rock mining are
at higher risk.
It as slowly progressing nodular, fibrosing pneumoconiosis
( silicotic fibrotic nodules).
 Pathogenesis:
After inhalation the particles
interact with epithelial cells
and macrophages cause
activation and release of
mediators including IL-1,
TNF, fibronectin, lipid
mediators, oxygen-derived
free radicals, and fibrogenic
cytokines.
 Macroscopic
features:

Affected lungs are nodular (small,
discrete nodules) and firm.
Fibrotic lesions may also occur in the
regional lymph nodes and pleura.
 Microscopic features:

The nodular lesions consist
of concentric layers of
hyalinized center.
Surrounded by chronic
inflammatory cells and
stimulate fibroblast
Necrosis and fibrosis take
place.
Silicotic nodules
 Significant and results:

Silica is insoluble in body fluids and is a
powerful irritant, causing extensive
fibrosis which predisposes the lungs to
tuberculosis as silicosis results in a
depression of cell mediated immunity.
Pulmonary tissue become less resistance
to infection.
Alveolar emphysema may develop.
Asbestosis
 Its type of exogenous pigment due to inhalation of asbestos (magnesium silicate).
Asbestos is a Greek word meaning ‘unquenchable’.
In general, if coal is lot of dust and little fibrosis, asbestos is little dust and a lot of
fibrosis.
The gross of diffuse pulmonary fibrosis caused by asbestos exposure and histologic
demonstration of bamboo- like asbestos bodies on asbestos fibers is termed asbestosis.
 Lungs are small, grayish and
firm with cartilage-like
Macroscopic thickening of the pleura.
features: Presence of variable degree of
pulmonary fibrosis, especially in
the subpleural areas and in the
bases of lungs.
 Microscopic features:

▪ There is diffuse pulmonary interstitial
fibrosis.
▪ There is presence of characteristic
asbestos bodies in the involved areas.
▪ These are asbestos fibers coated with
glycoprotein and hemosiderin and appear
beaded or dumbbell-shaped.
▪ The coating stains positively for Prussian
blue reaction.
Diffuse interstitial fibrosis
Asbestos bodies
 Significant and results
Prolonged exposure for several years to asbestos dust
produces three types of severe diseases: asbestosis
of lungs, pleural disease and tumors.
Siderosis
 Def:
Siderosis is deposition of iron in the lungs and pigmentation and cellular reaction
associated with it.
It results from inhalation of iron dust, and occurs in horses, mules, and dogs working in
and around iron mines, smelters, and foundries.

Macroscopically:
Iron dust causes a brown or rusty red pigmentation, which is focal in the beginning due
to the local accumulation of macrophages containing iron dust.
The pigmentation becomes diffuse as more and more dust enters the lungs.
Iron is mildly irritating causing only slight fibrosis.
If silica (silicon) is also present in the dust, extensive fibrosis of the lung occurs.
If tissues containing iron are placed in potassium ferrocyanide solution and hydrochloric
acid (Prussian blue test), the tissues become blue in color.
 Microscopically:
The iron occurs as brown or black irregularly shaped granules (usually
spherical masses) within macrophages.
When Prussian blue test is applied, the granules become blue in color.
There is only mild fibrosis, unless silicon is also present with the iron
dust. Since iron is only slightly soluble in the tissue fluids, it persists in
the tissues for the life of the individual.
Siderosis is usually of no clinical significance.
When iron is present in large amounts or if silicon is also present,
extensive chronic inflammation of the lungs results which may lead to
chronic general passive hyperemia.
 Siderosis in the liver.
Light micrograph of a
section through a liver
affected by siderosis
(hepatosiderosis).
This is a physiological
disorder where excessive
amounts of iron are
deposited in body tissue
 Ingested Pigments:
Chronic ingestion of certain metals may produce
pigmentation.
i) Argyria is chronic ingestion of silver compounds (drugs)
and results in brownish pigmentation in the skin, bowel, and
kidney.
ii) Chronic lead poisoning (plumbism) may produce the
characteristic blue lines on teeth at the gumline.
iii) Melanosis coli results from prolonged ingestion of certain
cathartics.
iv) Carotenaemia is yellowish-red coloration of the skin
caused by excessive ingestion of carrots which contain
carotene.
Ingested pigment
 Injected Pigments
(Tattooing)
Pigments like India ink, cinnabar and carbon are
introduced into the dermis in the process of
tattooing where the pigment is taken up by
macrophages and lies permanently in the
connective tissue.
The examples of injected pigments are prolonged
use of ointments containing mercury, dirt left
accidentally in a wound, and tattooing by pricking
the skin with dyes.
Endogenous pigments
 Def:

Endogenous pigments are
either normal constituents
of cells or accumulate
under special circumstances
e.g. melanin, hemoprotein-
derived pigments, and
lipofuscin
 Melanin
Melanin is the brown-black, non-hemoglobin derived pigment normally
present in the hair, skin, choroid of the eye, meninges and adrenal
medulla.
It is synthesized in the melanocytes and dendritic cells, both of which
are present in the basal cells of the epidermis and is stored in the
phagocytic cells called the melanophores, present in the underlying
dermis.
Melanocytes possess the enzyme tyrosinase necessary for synthesis of
melanin from tyrosine.
 Melanosis
Abnormal deposition of melanin pigment
in various organs especially lung
(pulmonary melanosis) and aorta
resulting in formation of black or brown
spots.
Various disorders of melanin
pigmentation cause generalized and
localized hyperpigmentation and
hypopigmentation.
 Macroscopic
appearance:

The affected organ become
brown or black in color
or have dark-brown spots as
in lungs, heart, liver
 Microscopic
appearance:

Melanin appears as very minute,
uniformly regular dirty-brown,
spherical granules.
The dopa reaction can be used to
determine if certain cells in the skin
or other tissues contain tyrosinase to
produce melanin.
The affected tissue contains
macrophages filled with melanin
(melanophore).
 Generalized hyperpigmentation:
a) In Addison’s disease, there is generalized
hyperpigmentation of the skin, especially in
areas exposed to light and of buccal mucosa.

b) Chloasma observed during pregnancy is the
hyperpigmentation on the skin of face, nipples,
and genitalia and occurs under the influence of
estrogen. A similar appearance may be observed
in women taking oral contraceptives.

c) In chronic arsenical poisoning, there is
characteristic raindrop pigmentation of the
skin.
 Focal hyperpigmentation:

1) Melanosis coli is pigmentation of the mucosa
of the colon.
2) Melanotic tumors both benign such as
pigmented naevi and malignant such as
melanoma, are associated with increased
melanogenesis.
3) Lentigo is a pre-malignant condition in
which there is focal hyperpigmentation on the
skin of hands, face, neck, and arms.
4) Dermatopathy lymphadenitis is an example
of deposition of melanin pigment in
macrophages of the lymph nodes draining
skin lesions.
Generalized hypopigmentation:

Albinism is an extreme degree of generalized
hypopigmentation in which tyrosinase activity of the
melanocytes is genetically defective and no melanin
is formed.
It is congenital absence of melanin.
Albinos have blond hair, poor vision and severe
photophobia.
They are highly sensitive to sunlight.
 Localized hypopigmentation:

a) Leucoderma is a form of partial albinism
and is an inherited disorder.
b) Vitiligo is local hypopigmentation of the
skin and is more common.
It may have familial tendency.
c) Acquired focal hypopigmentation can
result from various causes such as leprosy,
healing of wounds, DLE, radiation dermatitis
etc
Lipofuscin (Wear and Tear Pigment)
 Lipofuscin or lipochrome is insoluble
yellowish-brown intracellular lipid
pigment (lipo= fat, fuscus= brown).
The pigment is often found in atrophied
cells of old age and hence the name ‘wear
and tear pigment’.
It is seen in the myocardial fibers,
hepatocytes, Leydig cells of the testes and
in neurons in senile dementia.
However, the pigment may, at times,
accumulate rapidly in different cells in
wasting diseases unrelated to aging.
 Lipofuscin represents complexes of lipid
and protein that are derived from the free
radical-catalyzed peroxidation of
polyunsaturated lipids of subcellular
membranes.
It is not injurious to the cell but is an
important marker that indicates whether the
cell suffered free radical injury.
Lipofuscin represents the indigestible
residue of autophagic vacuoles (residual
bodies) formed during aging or atrophy.
 Unlike in normal cells, in aging or
debilitating diseases the phospholipid
end products of membrane damage
mediated by oxygen free radicals fail
to get eliminated and hence are
deposited as lipofuscin pigment.
Considered one of age-related disease.
When present in sufficient amounts,
they impart a brown discoloration to
the tissue (brown atrophy).
Mainly in long-lived postmitotic
cells, such as neurons and cardiac
myocytes.
 Macroscopic appearance:

Heart is Brown
shrinkage coloration of
( decrease in heart.
size).
Microscopic appearance:
The pigment is coarse, golden-brown
granular and often accumulates in the
central part of the cells around the nuclei.
In the heart muscle, the change is associated
with wasting of the muscle and is
commonly referred to as ‘brown atrophy’
The pigment can be stained by fat stains but
differs from other lipids in being fluorescent
Lipofuscin is (autofluorescent) and having
acid-fastness.
 By electron microscopy, lipofuscin
appears as intralysosomal
electron-dense granules in
perinuclear location.
These granules are composed of
lipid-protein complexes.
Hemoprotein-derived
Pigments
 Hematogenous pigments are the most
important endogenous pigments derived
from hemoglobin, cytochromes and their
break-down products derived from
erythrocytes.
They include hemoglobin, hematins,
hemosiderin, hematoidin, bilirubin,
biliverdin, and porphyrins.
For an understanding of disorders of
hemoproteins, it is essential to have
knowledge of normal iron metabolism
and its transport.
In disordered iron metabolism and
transport, hemoprotein-derived pigments
accumulate in the body.
 The average life of an erythrocyte is approximately 120 days.
The physiological destruction of red cells occur within the phagocytic cells
of the spleen, liver, and bone marrow and hemoglobin is released.
Three components are formed in the disintegration of hemoglobin:
globin, iron, and heme.
Globin is soluble in the tissue fluids and is removed from the area by the
blood and lymph.
In cells, iron is normally stored in association with a protein, apoferritin,
to form ferritin micelles.
Ferritin forms hemosiderin granules, which are easily seen with the light
microscope.
Thus, hemosiderin pigment represents large aggregates of ferritin
micelles.
Hemosiderosis
 Hemosiderin is a hemoglobin-derived, golden-yellow to
brown granular or crystalline pigment.
Under normal conditions, small amounts of hemosiderin
can be seen in mononuclear phagocytes of the bone
Hemosiderosis marrow, spleen, and liver.
It is greatest in spleen of the horse and least in the dog.
Excess of iron causes hemosiderin to accumulate
within cells, either as a localized process as in
hemorrhage or as a systemic derangement in case of
blood hemolysis.
Excessive storage of hemosiderin occurs when there is
increased break-down of red cells, or systemic overload
of iron due to primary (idiopathic, hereditary)
haemochromatosis, and secondary (acquired) causes
such as in thalassemia, sideroblastic anemia, alcoholic
cirrhosis, multiple blood transfusions etc
 Types of
hemosiderosis
 Localized hemosiderosis:
This develops whenever there is hemorrhage into the tissues.
With lysis of red cells, hemoglobin is liberated which is taken up
by macrophages where it is degraded and stored as hemosiderin.
A few examples are as under :
1) The changing colors of a bruise or a black eye are caused by
the pigments like biliverdin and bilirubin which are formed during
transformation of hemoglobin into hemosiderin.
2) In chronic venous congestion of liver and lung (brown
induration of the lungs) as a result of small hemorrhages as occur
in mitral stenosis and left ventricular failure. Microscopy reveals the
presence of ‘heart failure cells’ which are hemosiderin-laden
alveolar macrophages.
Brown induration of lung
CVC in liver
 Generalized hemosiderosis:
Generalized or systemic overload of iron may occur due to following causes:
i) Increased erythropoietic activity:
In various forms of chronic hemolytic anemia, there is excessive break-down
of hemoglobin and hence iron overload.
The problem is further compounded by treating the condition with blood
transfusions (transfusional hemosiderosis) or by parenteral iron therapy.
The deposits of iron in these cases, termed as acquired hemosiderosis, are
initially in reticuloendothelial tissues but may secondarily affect other organs.
 Generalized hemosiderosis
ii) Excessive intestinal absorption of iron:
A form of hemosiderosis in which there is excessive intestinal absorption of iron even when
the intake is normal, is known as idiopathic or hereditary haemochromatosis.
It is characterized by triad of pigmentary liver cirrhosis, pancreatic damage resulting in
diabetes mellitus, and skin pigmentation. On the basis of the last two features, the disease
has come to be termed as bronze diabetes.
iii) Excessive dietary intake of iron:
A common example of excessive intake of iron is Bantu’s disease in black tribals of South
Africa who conventionally brew their alcohol in cast iron pots that serves as a rich source of
additional dietary iron.
The excess of iron gets deposited in various organs including the liver causing pigment
cirrhosis.
Hemosiderin special
stain

Prussian blue stain

Stain hemosiderin pigment
dark blue in color
Jaundice( Icterus)
 Bilirubin
metabolism
 Bilirubin is the normal non-iron containing pigment
present in the bile.
It is derived from porphyrin ring of the heme of
hemoglobin.
Normal level of bilirubin in blood is less than 1 mg/dl.
Excess of bilirubin or hyperbilirubinemia causes an
important clinical condition called jaundice.
Jaundice is a pathological condition characterized by
yellow discoloration of tissue that is especially in tissue
rich in elastin, such as the aorta, skin , sclera and
mucous membranes.
Hyperbilirubinemia may be unconjugated or
conjugated.
 Hepatic dysfunction is not the only cause of
hyperbilirubinemia and icterus.
Prehepatic causes such as intravascular hemolysis can
cause icterus. It is a common cause in ruminants and
likely occurs more often than hepatic damage.
Horses often manifest icterus with acute hepatic
dysfunction or obstruction, but icterus may or may
not occur in horses with chronic hepatic disease.
Interestingly, “physiologic icterus” is also common in
the horse deprived of feed for several days because
uptake of bilirubin from the plasma by hepatocytes is
decreased.
Icterus in carnivores occurs as a consequence of
hemolysis, hepatic dysfunction, or biliary obstruction.
 Classification of jaundice:

Jaundice may appear in one of the following 3
ways depending on which part affected:
a) Prehepatic or hemolytic, when there is
excessive destruction of red cells.
b) Posthepatic or obstructive, which results
from obstruction to the outflow of conjugated
bilirubin.
c) Hepatic or toxic that results from failure of
hepatocytes.
 ❑Definition:
Hemolytic Jaundice It is a yellow coloration of most body
(prehepatic)
tissues due to excessive hemobilirubin as
a result of excessive systemic hemolysis,
but the liver is normal.
❑Causes:
Blood parasite (anaplasmosis)
Bacterial infection (bacillus anthracis)
viral diseases (equine infectious anemia)
Snake venoms.
Lead poisoning (chronic)
 Toxic Jaundice (intrahepatic):

❑ Definition:
It is characterized by intense yellowish coloration of most body tissues
due to increasing of hemobilirubin & cholebilirubin.
This could be attributed to damaged liver cells resulting in loss of the
liver capacity to extract bilirubin, detoxicate it and secrete it in the bile.

❑ Cause:
Any factors leading to toxic liver → injury of liver cells.
Toxic condition due to some infectious diseases (infectious canine
hepatitis).
 Definition:
Obstructive Jaundice It is a yellowish coloration of most body tissues due
(post-hepatic): to increase of cholebilirubin.
Causes:
Obstruction of bile ducts (cholilithiasis).
Obstruction of gall bladder ( gall stones or presence
of fluke).
Inflammation of bile duct (cholangitis) leading to
stasis of the bile and consequently dilatation of the
bile ducts, and bile canaliculi with the passage of the
bile in the circulation, resulting in
hypercholibilirumiaemia.
Pressure on the wall of bile duct from outside as
tumor, abscess, and enlarged lymph node.
Disturbance in mineral
metabolism
Pathological Calcification
The amount of calcium in bones, tissues, cells,
and fluids of the body ranges constantly.

Its concentration in the blood fluctuates within rather
narrow limits and in general averages about 10 mg per
100 ml of blood (10 mg percent).

The amount of calcium in the blood is associated with
parathyroid activity. When it is low, there is increased
parathyroid activity that causes calcium to be removed from
the skeleton to restore blood calcium to a normal amount.

When calcium content of the blood decreases to 8 mg
percent, excitability occurs, when to 6 mg percent, the
animal goes into tetany, and when it reaches 3 mg
percent, the animal dies.

On the other hand, if the calcium rises to 12 mg
percent or higher, the excess precipitates in various
tissues.
Calcium metabolism
 Pathological Calcification

It is the abnormal deposition of calcium salts mainly Ca.
phosphate and Ca. carbonates together with smaller amounts of
iron, magnesium, and other minerals, in soft tissues other than
the ossified tissue (bone and teeth).
It may be classified as dystrophic and metastatic calcification
 ❑ Definition:

It occur when calcium deposition
Dystrophic occurs in dead (necrotic) or dying
calcification: tissues of any organ.
It occurs in a focal area of the body.
Dystrophic calcification occur in
normal serum levels of calcium, and
in the normal calcium metabolism.

❑ Etiology /Occurrence:
Dystrophic calcification may occur due
to 2 types of causes
Calcification in dead tissue
Calcification of degenerated tissue.
 Calcification in dead tissue:
1. Caseous necrosis in tuberculosis is the most common site for dystrophic
calcification.
2. Liquefaction necrosis in chronic abscesses.
3. Fat necrosis following acute pancreatitis or traumatic fat necrosis in the
breast results in deposition of calcium soaps.
4. Chronic venous congestion (CVC) of the spleen is characterized by
calcific deposits admixed with hemosiderin on fibrous tissue.
5. Infarcts may sometimes undergo dystrophic calcification.
6. Thrombi, especially in the veins, may produce phleboliths.
7. Dead parasites like in hydatid cyst, Schistosoma eggs, and cysticercosis
8. Calcification in breast cancer.
9.Congenital toxoplasmosis.
 Calcification in degenerated tissues:
1. Dense old scars may undergo hyaline degeneration and calcification.
2. Atheromas in the aorta and coronaries.
3. Mönckeberg’s sclerosis shows calcification in the tunica media of muscular
arteries in elderly people
4. Stroma of tumors as uterine fibroids, breast cancer, thyroid adenoma and
goiter.
5. Cysts which have been present for a long time may show calcification of their
walls e.g. epidermal and pilar cysts.
7. Calcinosis cutis is a condition of unknown cause in which there are irregular
nodular deposits of calcium salts in the skin and subcutaneous tissue.
8. Senile degenerative changes such as in costal cartilages, tracheal or
bronchial cartilages, and pineal gland in the brain etc
 Calcinosis Cutis
(Benign Cutaneous
Calcification, Benign
Nodular Calcification)
 Pathogenesis:

Deposition of calcium occurs in two phases:
Initiation phase
Propagation phase
I. Initiation phase:
Initiation can occur intracellularly or extracellularly
Intracellular initiation phase
Damaged cell has increased inflow of calcium into cytoplasm
Calcium that has entered the cell has great affinity for mitochondria and
gets deposited in mitochondria.
 Pathogenesis:
Extracellular initiation phase:
Degenerated cells contain membrane bound vesicles which
contain acidic phospholipids.
Calcium has increased affinity for acidic phospholipids and
thus calcium deposits in vesicles
Once the calcium and phosphate accumulates in vesicles, it
gets budded out of the cell and is released out.
II. Propagation phase:
In the initiation phase tiny crystals of calcium are formed.
Further Calcium deposition and propagation.
Macroscopic features:
Organ becomes hard
and nodular.

Grey/white deposits
in necrosed tissue
looking like honey
comb.

Gritty sound on
cutting

Grossly calcium deposition occurs as fine, white
granules or clumps which are gritty
 Macroscopic features:

In routine H &E-stained sections, calcium
salts appear as deeply basophilic, irregular and
granular clumps.
Calcium deposits can be confirmed by special
stains like silver impregnation method of von-
Kossa producing black color, and alizarin red.
S that produces red staining.
Pathologic calcification is often accompanied
by diffuse or granular deposits of iron giving
positive Prussian blue reaction in Perl’s stain.
 Dystrophic
calcification
Van Zossa stain
stains calcium black
 Metastatic Calcification
Metastatic calcification is characterized by deposition of
calcium salts in soft tissue as a result in apparently normal
tissues and is associated with abnormal calcium metabolism
and hypercalcemia.
 ❑ Since metastatic calcification occurs in normal tissues
due to hypercalcemia, its causes would include one of the
following two conditions:
I. Excessive mobilization of calcium from the bone.
II. Excessive absorption of calcium from the gut.

Etiology: I. Excessive mobilization of calcium from the bone:
These causes are more common and include the following:
1. Hyperparathyroidism which may be primary such as
due to parathyroid adenoma, or secondary such as from
parathyroid hyperplasia, chronic renal failure etc.
2. Bony destructive lesions such as multiple myeloma,
metastatic carcinoma.
3. Prolonged immobilization a patient results in disuse
atrophy of the bones and hypercalcemia.
 Etiology:
II.Excessive absorption of calcium from
the gut:
These causes are as under:
1. Hypervitaminosis D results in increased
calcium absorption.
2. Milk-alkali syndrome caused by
excessive oral intake of calcium in the form
of milk and administration of calcium
carbonate in the treatment of peptic ulcer.
3. Hypercalcaemia of infancy is another
condition in which metastatic calcification
may occur.
 Sites of metastatic calcification:

Metastatic calcification may occur in any normal tissue of the
body but affects the following organs more commonly:
1. Kidneys, especially at the basement membrane of tubular epithelium
and in the tubular lumina causing nephrocalcinosis
2. Lungs, especially in the alveolar walls.
3. Stomach, on the acid-secreting fundal glands.
4. Blood vessels, especially on the internal elastic lamina.
5. Cornea is another site affected by metastatic calcification.
6. Synovium of the joint causing pain and dysfunction.
 Pathogenesis of metastatic calcification

Metastatic calcification at the above-mentioned sites occurs due
to excessive binding of inorganic phosphate ions with calcium
ions, which are elevated due to underlying metabolic
derangement.

This leads to formation of precipitates of calcium phosphate
at the preferential sites.

Metastatic calcification is reversible upon
correction of underlying metabolic disorder.
Lung calcification
 Metastatic
calcification
Lung carbolic acid

Kidney uric acid

Stomach hydrochloric acid
 Gout
(Urates & Uric Acids)
 Def:
It is a type of retrogressive changes (disorder of urate and uric
acid metabolism) characterized by the deposition of crystals of
uric acid and urates (sodium and calcium urates) in the tissues
mainly joints, connective tissues and serous membranes of the
internal organs, intense pain and acute inflammation.
Deposition is due to an increase in the concentration of uric
acid in blood (hyperuricemia) and body fluids.
Gout is mainly a disease of humans and birds and has not
been clearly established in other species.
Clinically, the disease in humans is characterized by
recurrent episodes of painful acute arthritis.
 Etiology:
Gout is usually divided into primary
(unknown cause) and secondary forms (
known causes of hyperuricemia).

Causes :
1) Renal dysfunction.
2) A high protein diet or due to an unusual
type of protein.
3) Vit. A deficiency → due to deficiency
of green food.
4) Insufficient exercise.
5) May be hereditary.
 Pathogenesis:

The uric acid is normal catabolic product of nucleoprotein of food
and body tissues.
It is normally present in blood in small amount 2.5mg/100ml blood
and normally excreted as uric acid in urine.
Excessive retention of uric acids in the blood leads to deposition of its
salts in the tissues in the form of bundles or needles or crystals.
Such salts inside the tissue stimulate foreign body granulomatous
reaction.
Gout pathogenesis
Macroscopic features
In articular form:
The joints and surrounding tissues were covered by white
chalky material known as Tophi which formed mainly from
gouty deposits.
The affected joints are swollen, tender and may be lost their
function.
In visceral form:
Characterized by deposition of urates as a white powder-like
substances (chalky-white, soft plagues) having a metallic
sheen in the kidneys and serous membranes as pericardium.
 Tophi( articular gout)
Articular gout is characterized by tophi.
These are deposits of urates around joints,
particularly those of the feet most commonly
affecting the first metatarsophalangeal joint
(big toe).
The joints are enlarged, and the feet appear
deformed. When these joints are opened, the
periarticular tissue is white due to urate
deposition.
White semi-fluid deposits of urates may be
found within the joints
Articular and visceral gout
 Microscopical findings:
In articular form:
The calcium or sodium urate appeared as needle-shape bundles or
crystals which arranged radically.
The urates stimulate granulomatous reaction as macrophage
aggregations beside foreign body giant cells and connective tissue
proliferation with clusters of sharp a circular crystal or spaces that
left after they dissolved.
These reactions may lead to necrosis and fibrosis.
In visceral form:
Various serous surfaces are covered with finally crystalline or almost
amorphous materials, that does not stain.
▪ Multinucleated
foreign-body type
giant cells
surrounding long,
slender, needle
shaped shadows of
the dissolved urate
crystals.
What is the lesion and stain?