HEM-210 Faculty of Medicine – Sohag University PDF

Summary

This document is a course outline for HEM-210, a medical course offered by the Faculty of Medicine at Sohag University, covering various medical fields like anatomy, histology, biochemistry, physiology, microbiology, parasitology, pathology, and pharmacology. This section is on the lymphatic system.

Full Transcript

HEM-210

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- Title Page
1 Anatomy 3

2 Histology 13

3 Biochemistry 43

4 Physiology 58

5 Microbiology 92

6 Parasitology 109

7 Pathology 137

8 pharmacology 165

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1 The lymphatic system

Lymphatic system

it is the overflow system that provides drainage of tissue fluids and leaked plasma
proteins to the blood stream as well as removal of debris from cellular decomposition
and infection (figure 1).
It is formed of: 1-Lymph vessels, 2- lymph nodes, 3- lymphoid organs that produce
lymphocytes (tonsils, spleen, thymus gland, red bone marrow and lymphoid
follicles at wall of intestine and appendix).

Figure 1: lymphatic system and its componenets (nodes and vessles)

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Lymph

it is colorless fluid which circulates between cells and tissues to remove dead cells,
waste products and toxins. That It runs inside thin walled vessels called the
lymphatics, which accompany the veins but not seen by naked eyes.
In small intestine, fats are absorbed by intestinal epithelium and packed to form milky
opaque lymph which is called chylomicrons; here the lymph is termed chyle.

Lymphatic vessels (Lymphatics):
1- Extensive and complex interconnected network channels.
2- It is distributed all over the body (figure 1).
3- Thin-walled and have abundant lymphatic valves, so the beaded appearance.
4- It collect fluid from capillary beds during nutrients exchange processes and
deliver it back to the venous side of the vascular system
5- It begins as lymphatic capillaries (figure 2)

Figure 2: Lymphatic capillary (fine structure)

6- Lymphatic capillaries in turn drained by small lymph vessels which unite to
form large lymph vessels which connected with large veins in the root of the
neck.
7- It present in the most areas in the body except brain, bone marrow,
epidermis, eyeball and cartilage.

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8- Lymphatic vessels that carry lymph to a lymph node are referred to as
afferent vessels; those that transport it away from a node are efferent vessels
(figure 3).

Figure 3: Cut section in lymph node

N.B

Movement of lymph is controlled by the
action of adjacent muscle especially
the skeletal muscles and pulse of
arteries.
Unidirectional flow maintained by the
presence of valves in the lymphatics.

Lymph nodes:

These are several small masses of lymphoid tissue present at the pathway of
lymphatic vessels, small and encapsulated (0.1 to 2.5 cm long).
It contains elements of body defense systems like lymphocytes and macrophages.
It presents in certain groups which may be superficial to skin at areas and deep in
other areas (figure 4).
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1- Axillary lymph nodes which drain upper limb and breast
2- Cervical lymph nodes which drain head and neck
3- Mediastinal lymph nodes which drain thoracic organs
4- Aortic lymph nodes which drain abdominal organs
5- Inguinal lymph nodes which drain groin and lower limbs.

Figure 4: Groups of lymph nodes

N.B

Because lymph nodes are efficient filter and flow through it
is slow, cells that metastasize or migrate from primary
tumor and enter the lymphatic vessels are often lodged in
and stagnate at it.
So, lymph nodes are considered as secondary tumor; here
it becomes palpable and enlarged.
Also, Infection or inflammation could enlarge it (figure 5).
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Figure 5: Enlarged lymph node

Lymphatic trunks and ducts:
1- All lymphatic vessels coalesce together to form larger trunks and ducts.
2- Trunks and ducts are drained into venous system at sides of the neck where
the internal jagular veins join the subclavian veins to form the
brachiocephalic veins.
3- Lymph from the right side of head and neck, right upper limb, right side of
the thorax and right upper abdominal wall is drained to right lymphatic duct
(figure 6).

Figure 6: Showing right and left lymphatic ducts and its drainge site

4- Lymph from the left side of the body is drained to the thoracic duct (figure 6).
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Thoracic duct:

1- It is the largest lymphatic duct in the
body

2- It drains lymph from the lower limbs,
pelvis, perineum, abdomen, left
side of the neck and left upper limb.

3- Length = 45 cm.

4- Course: it takes origin from the upper
end of the abdominal lymph trunks or
cisterna chyli in front of the lower
border of the last thoracic vertebra (
figure 7); it reaches the thorax by
ascending through the aortic opening of
the diaphragm between thoracic aorta
and azygos vein. It ascends at the
posterior the mediastinum in front the
anterior longitudinal ligament of the
vertebral column and in front of right
aortic posterior intercostal arteries and
terminal part of hemiazygos vein. Later
on, it crosses gradually from right to left
side of the median plane of the body in
front the fifth thoracic vertebra. It
continues upward behind the esophagus
at the superior mediastinum. Later on, it Figure 7: Showing course of thoracic duct
becomes at the left side of the
esophagus with the aortic arch. At level
of the seventh cervical vertebra, its 5- At termination site, thoracic duct
cervical part curves behind the carotid contains two competent valves
sheath to terminate in the angle of to prevent reflux of venous blood
junction between left internal jagular and to it.
left subclavian vein where it is drained to
venous system (figure 7).
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Lymphoid organs:
Parts of body that produce lymphocytes such as:
1- Thymus gland
2- Tonsils
3- Spleen
4- Red bone marrow
5- Lymphoid follicles at wall of alimentary tract and appendix..
1-Thymus gland:

It is a central lymphoid organ which involved in early development of the immune
system, it is well developed at birth and grows until puberty, and later on it is
diminished at size nd replaced by fibrous and adipose tissue.
It has unequal 2 pyramidal lobes which are bound together by loose connective tissue
(figure 8).

Figure 7: Thymus gland

Position: it presents at the most anterior part of superior mediastinum,
immediately posterior to manubrium of the sternum; its upper part extends to the neck,
its lower part extends in the anterior mediastinum over the pericardial sac, it overlaps
the great vessels of the heart (figure 8).
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2-Tonsils:

Collection of lymphoid tissue at the mucosa of pharynx surrounding the openings
of nasal and oral cavities forming distinct masses called tonsils.
1-Pharyngeal tonsils: it lies at midline on the roof of the nasopharynx (figure 9),
when it is enlarged it is called (adenoid).

Figure 8: Sagittal section showing sites of tonsils

2-Palatine tonsils: it lies at the side of the oropharynx between palatoglossal and
palatopharyngeal aches just posterior to oropharyngeal isthmus.
3-lingual tonsils: it presents at the posterior part of the tongue.

3-Spleen:

It is considered as the largest lymphoid organ in the body, it is reddish brown in
colour.
Position: it lies in the left hypochondrium between stomach and diaphragm under
the 9th, 10th and 11th ribs, its weight is about 200gm.
Shape: pyramidal and has 2 ends: medial and lateral; with 2 borders; upper and
lower. It has 2 surfaces; diaphragmatic (related to the diaphragm which separate it
from ribs) and visceral (related to stomach, left kidney and left colic flexure) (figure
10).
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Figure 9: Spleen

Functions of the spleen:
Formation of some blood cells
Storage of blood cells
Formation of antibodies
Formation of bile pigments
Removal of toxins, dead cells and bacteria from blood.

N.B

Reticulo endothelial system: it includes
spleen, lymph nodes, tonsils, blood leucocytes
and other phagocytic cells scattered in liver,
lungs, and endothelium of blood vessels for
protection against bacteria, toxins and foreign
bodies.

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 Hematology
HEM-210

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Hematology
Block HEM-210

‫إعداد و تأليف‬
‫قسم الهستولوجيا‬
2023-2024

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‫الرؤية والرسالة‪:‬‬

‫‪1-4‬الرؤية‪:‬‬

‫تسعي كلية الطب بجامعة سوهاج أن تكون مركزا للريادة والتفوق والتميز في مجال‬
‫العلوم الطبية علي الصعيدين اإلقليمي والعالمي‬
‫‪2-4‬الرسالة‪:‬‬
‫تلتزم كلية الطب البشرى بجامعة سوهاج بتقديم برامج طبية متميزة وتبني آليات‬
‫التعليم الطبي المستمر وإجراء بحوث علمية متميزة وخدمات مجتمعية بما يضمن‬
‫تطوير المهنة وتخريج أطباء قادرين على تلبية احتياجات سوق العمل وتنمية المجتمع‬
‫المحلى واالقليمي والدولي فى ضوء المعايير األكاديمية القومية وقيم المجتمع النبيلة‪.‬‬

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1 THE LYMPHTIC SYSTEM

Learning objectives:
A1- Describe the cytological A2- Define & classify lymphatic
characteristics of lymphocytes tissue; diffuse and nodular

A3- Describe the structure of
lymphatic organs.

Lymphocytes (Fig.1):

Accounting for 20-35%, of the circulating W.B.Cs.

Structure:
L.M. E.M.
deep stained nucleus small Golgi
thin rim of clear blue cytoplasm a pair of centrioles
no specific granules but contain few Many free ribosomes but no
small azurophilic granules endoplasmic reticulum
one or two mitochondria

Types of lymphocytes:

- On the basis of cell diameter, they are divided into
small (4-7 um),
medium sized (7-11 um)
Large lymphocytes (11-15 um).

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- According to the presence of distinct surface markers determined by
immunohistochemical methods small lymphocytes are divided into ;
B lymphocytes,
T lymphocytes
Null cells.

Fig. ( 1): L.M & EM of lymphocyte

B lymphocytes:

1-Origin: in mammals they arise from the stem cells in the bone
marrow.
2-Life span: B lymphocytes have a short life span (few weeks) and
during this time they circulate and recirculate through the blood,
lymph nodes, spleen and lymph for many times.
3-Activation: B lymphocytes when activated, they differentiate into
large lymphocytes then to lymphoblasts to plasma cells that produce
immunoglobulins. Some of activated lymphocytes remain as B
memory cells. This type is called humeral response.

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T lymphocytes:
1-Origin: Stem cells originate in the bone marrow that is carried
through the blood to the thymus where they proliferate and
differentiate to T lymphocytes. At the cortico-medullary
region they become mature T lymphocytes, then they leave
the thymus through post capillary venules to the spleen then
to the circulating pool of lymphocytes.

2-Life span: T lymphocytes have a long life span for several months.

- T lymphocytes have a long life span for several months.
3-Activation:
- T lymphocytes when activated by antigen, they soon differentiate
into four types of cells producing cellular immune response. These
cells are:
T killer or rejection cells: Those reject transplanted organs or skin
grafts.
T memory cells: They are programmed to react with the same
antigen on entering the body for another time.
T helper cells: They help B lymphocytes producing humoral
immunity.
T suppressor cells: They inhibit the activity of both B and T
lymphocytes triggering the end of the immune response.

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THE LYMPHOID TISSUE

- Lymphatic tissue is defined as reticular connective tissue that is
infiltrated with lymphocytes.
- This includes discrete organs as well as more diffuse aggregations of
lymphocytes.

The lymphoid organs are either primary or secondary.

Primary organs Secondary organs
where lymphocytes are formed where lymphocytes are activated
and mature as bone marrow and as lymph nodes, spleen and
thymus. mucosa associated lymphoid
tissue (MALT).

MALT is numerous scattered
non-capsulated lymphoid nodules
distributed in the mucosa of the
digestive, respiratory and urinary
systems collectively.

The lymphoid nod
:ule
- It is a spherical mass of lymphocytes.

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Sites of the nodule:
1- Lymphatic organ as spleen, lymph node and tonsil.
2- In lamina propria of digestive and respiratory system.
3- Payer’s patch of ilium
4- appendix

Types of the nodule

A.Primary lymphoid nodules :
They represent the unstimulated follicles. They are formed of closely
packed small lymphocytes.
B. Secondary lymphoid nodules :
- When the primary nodules are stimulated by antigen (any foreign
protein), they become secondary nodule.
- This secondary nodule consists of two zones.
The outer zone (mantle), also called peripheral zone contains small
lymphocytes with less cytoplasm so it stains dense.
The inner zone, also called germinal center or central zone contains
large and medium lymphocytes, lymphoblast, plasma cells and
macrophages. It stains pale due to these cells have more cytoplasm and
euchromatic nuclei.

1- THYMUS

- The thymus is a primary lymphoid organ situated in the superior
mediastinum.
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Lymphoblast differentiates into T-lymphocytes within the special
microenvironment of the thymus, independent of antigenic
stimulation.
After differentiation, the thymus populates T-lymphocytes to the
peripheral lymphoid organs.
The thymus is well developed at birth and during early childhood,
then it begins to involute.
- Histological Organization (Fig. 2):
The thymus is composed of stroma and parenchyma.
- The Stroma: is formed of
Thin capsule.
Trabeculae of loose C.T divide the gland into incomplete lobules.
Supporting network of epithelial reticular cells.

- The parenchyma: is formed of thymic lobules.
Each lobule has a dark-staining peripheral zone, the cortex and a
lighter-staining inner zone, the medulla.
At the cortex, the lymphocytes (thymocytes) are numerous and
densely packed, causing the intense basophilia of this region.
At the medulla, the lymphocytes are fewer and the epithelial reticular
cells with their abundant eosinophilic cytoplasm are more prominent.

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- Thymocytes:
Represent the main cellular population of the thymus.
These include small, medium and large lymphocytes.

Epithelial Reticular Cells or cytoreticular cells:

These are branched cells form a network that carry lymphocytes and is
referred to as cytoreticulum.
The cells have several processes that joined together by desmosomes.
According to E.M. structure, location and histochemical characters they
are of 6-types.

- Hassall's corpuscles (Fig. 3) :
They are acidophilic with hyalinized centers.
It is formed by type 6 reticular cells in the medulla.
These cells are flattened and tend to wrap around one another and
joined together by many desmosomes and contain abundant bundles of
keratin filaments. The cells in the central portion of the corpuscle lose
their nuclei and cytoplasm is full of keratin.

Fig.(2) A diagram showing the histological structure of thymus
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Fig (3): A diagram showing the cortex and medulla of the thymic lobule

- The blood-thymus barrier (Fig. 4)
It prevents antigenic macromolecules of the blood from reaching the
thymus.

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Fig (4): A diagram showing the blood thymic barrier
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2- LYMPH NODES

- There are 500-600 lymph nodes (lymph glands) in the body.
A lymph node is capsulated round, ovoid, or bean-shaped and varies in
size from less than 1 mm to 2-3 cm.

Structure (Fig. 5)
The lymph node is formed of stroma and parenchyma.

- The stroma :
C.T. capsule that greatly thickened at the hilum.
Branching trabeculae extend from the deep surface of the capsule
inwards to divide the organ into relatively regular compartments in the
outer part (cortex) and more irregular compartments in the inner part
(medulla) of the gland.
Between the trabeculae, the lymphoid tissue is supported by a network
of reticular fibers and reticular cells.

- The parenchyma
1) The cortex
It is formed of three zones; outer, mid and deep cortical region.
The lymphoid nodules are of primary and secondary types.
They form the great bulk of the outer cortex while the diffuse
lymphoid tissue makes up the bulk of the mid and deep cortex.
B-lymphocytes are the predominant cells in the outer cortex while T-
lymphocytes are the predominant cells in the mid and deep cortical
zones.
The mid and deep zones are called thymus dependent zones of the
lymph nodes.
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They contain an antigen presenting cells known as dendretic cells.

2) Medulla
1. The medullary cords consist of aggregations of lymphoid tissue
organized around small blood vessels. They are formed of small
lymphocytes, plasma cells and macrophages.
2. The lymph sinuses are channels lined with a layer of thin squamous
cells without basal lamina and supported by a thin layer of reticular
C.T.
3. All the sinuses contain macrophages which remove particulate matter
and degenerating cells from the lymph and filter it from bacteria or
malignant cells.

3-THE SPLEEN

- The spleen is a large lymphoid organ present in the left upper quadrant
of the abdominal cavity.
Histological Organization of the Spleen:
The spleen is formed of stroma and parenchyma.
- The stroma: It is formed of
Capsule
Thick trabeculae
N.B.
Delicate reticular fibers framework that Both the capsule and the
occupies the interior of the organ and holds trabeculae consist of
dense C.T. rich in elastic
in its meshes the free cells of the fibers. In human, they
contain few smooth
parenchyma. muscle cells

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- The Parenchyma (Fig.6) :
A-The white pulp:
1. The periarterial lymphoid sheaths (PALS):
2. It consists of a central artery (a branch of the splenic artery) that
surrounded by a sheath of lymphoid tissue
3. Malpigian corpuscle (lymphoid follicle):
4. the central artery is located at the periphery of nodule.
B-The marginal zone :
1. It is the transitional zone between the white pulp and the red pulp of the
spleen.
C-Red pulp :
1. Pulp cords (cords of Billroth) are consist of large number of RBCs,
macrophages, lymphocytes dendritic cells, plasma cells and
granulocytes.
2. The splenic venous sinuses.

Fig. (6): A diagram showing the structure of the spleen
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2 THE BLOOD

A1- Describe the cytological
characteristics of blood elements

A2-Define & classify A3- Describe formation
bone marrow types of blood elements

- Blood is considered as a special type of C.T composed of: Formed
elements: erythrocytes, leucocytes and blood platelets, suspended in an
extracellular fluid matrix (the blood plasma).

RED BLOOD CORPUSCLES (RBCs), (ERYTHROCYTES)

At L.M. level:
They appear acidophilic non-nucleated cells (not true cells so called
corpuscles) and have biconcave shape to increase surface area (Fig. 1)
seen as central pallor of staining.
The erythrocytes form aggregates that resemble stacks of coins called
rouleaux. This happens only in stagnant blood in vitro
Abnormalities in the shape of RBCs e.g. sickle cell anemia (Fig. 2).

Fig. (1): Scanning electron microograph of Fig. (2): Scanning electron micrograph of an
erythrocytes showing their Biconcave shape. erythrocyte in sickle cell anaemia.

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Ultrastructure of Erythrocy
tes
Cell organelles are lacking. Hb molecules form dense homogenous
content of a granular texture.
Immediately beneath the membrane, there is a network of membrane
cytoskeleton: which makes R.B.Cs. to be quite pliable when flowing
through narrow capillaries.

Characters of RBCs:

- Size:
Normal R.B.Cs varies from 6-9 um in diameters and about 1.9 um in
thickness. These are called normocytes.

- Color:
The normal color of R-B.Cs is greenish or orange yellow. When they
condense, the color is red.
The normal color of R.B.Cs is called normochromic.
The decrease in amount of Hb content resulted in hypochromic
R.B.Cs occurs in iron deficiency anemia.
The increase in the amount of Hb result in hyperchromic R.B.Cs.

WHITE BLOOD CELLS (W.B.Cs) (LEUKOCYTES)

Differences between WBCs and RBCs
Leucocytes are colorless do not contain pigment
they contain granules.
Leucocytes are capable of amoeboid movement.
They perform their function in the C.T.
They are larger in diameter.
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Number

The total leukocyte count in the circulation ranges from 5000 to
9000/cu mm.

Classification of Leucocytes

Leucocytes are classified as granular and non-granular depending on
weather they do or do not contain specific granules in their cytoplasm.
note: Both types contain non-specific granules in their
cytoplasm(Azurophilic non-specific granules are primary lysosomes)

1 -Granular leucocytes are; neutrophils, eosinophils and basophils
2 -Non-granular leucocytes include lymphocytes and monocytes

N.B
Neutrophils constitute 60-70%
The relative number of
eosinophils 2-5% each type of leucocyte is
basophils 0-1% called the differential
lymphocytes 20-35% leucocytic count.
Monocytes 3-7%.

Clinical notes:
An increase in the number of leucocytes is called leukocytosis while its
decrease is called leucopenia.

Neutrophil Leucocytes:
Diameter of granular leukocytes about 10-12 um.
They are called polymorphs, polymorpho-nuclear leucocytes or
tissue microphages.
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they increase in acute pyogenic infection for defence against
invasion of bacteria by phagocytosis and.
- By L.M
1. The nucleus: multilobed (more than 2lobes connected by
chromatin thread).
2. The cytoplasm is stippled with very fine specific granules stain
faintly pink.
- By E.M. (Fig.3)
The cytoplasmic granules of neutrophils are of two main types :
1. Azurophilic primary non-specific granules or lysosomes are
large, dense vesicle
2. Specific secondary granules are smaller and less dense ,

Fig. (3): micrograph of
neutrophil LM, E.M.

Eosinophil Leucocytes:
By L.M :
The nucleus is bilobed.
The cytoplasm contains large eosinophilic refractile granules.
By E.M. (Fig. 4):
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The specific granules contain dense crystalloid core included in
amorphous matrix.
The granules contain major basic proteins which control parasites
and control allergy.
In chronic inflammation: Eosinophils are particularly abundant in
connective tissue of the intestinal lining and at sites of chronic
inflammation

Fig. (4): eosinophil by LM, E.M

Basophil Leucocytes:
- By L.M.
The nucleus is U or S shape.
The specific granules are relatively few, large and basophilic Which
may obscure the nucleus.
- By E.M(Fig.5).: The cytoplasm contains;
The specific granules are large dense rounded and they contain
histamine and heparin like mast cells.
On degranulation release of basophilic mediators(histamine) from
specific granules causing allergic reaction or anaphylactic shock.
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U shape
nucleus

Fig. (5): basophil by LM, E.M

Lymphocytes

- Previously discussed in lymphatic system- see fig
Monocytes

- Measure about 12-20 um. in diameter in stained blood film (largest
cell in blood film).
- BY L.M.
The nucleus is eccentric kidney shapes.
The cytoplasm is pale blue contains few azurophilic granules.
- BY E.M. Fig:)7(.
Function:
1- capable of developing into macrophage after they migrate into the
C.T.
2- They also act as antigen presenting cells.

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Fig. (7): Diagram of a monocyte by L.M. E.M.

BLOOD PLATELETS, (Fig.8)
- minute, colorless, non-nucleated corpuscles found in the blood of all
mammals. Their number ranges from 150,000-350,000 /c mm. Their
life span is 9-10 days.
- By L.M.
They appear in stained blood film thin biconvex fusiform disc 2-3 um
diameter (smaller than RBCS).
They are having thin, pale blue peripheral zone called hyalomere and
a thicker granular central region called the granulomere
- By E.M.
The hyalomere contains a circumferential bundle of microtubules for
maintaining shape.
The granulomere contains;
1. scattered glycogen granules, dense granules (ADP), lysosomes.
2. membrane bounded canaliculi that open to the surface (surface-
connected canalicular system): for discharge of secretory products
upon activation of platelets.
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3. Dense tubular system: not connected to the surface
4. mitochondria

Fig. (8): A diagram of a platelet by E.M

- Functions:
1-Initiating blood clotting upon injury of the endothelium.
2-Platelet derived growth factor: secreted on platelet activation and help in
repair process.

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3 BONE MARROW

- Bone marrow is soft, gelatinous tissue that fills the medullary cavities.
Types

Red bone marrow, known as myeloid tissue, consists of a delicate,
highly vascular fibrous tissue containing hematopoietic stem cells.
These are blood-forming stem cells. It is called red because of the
presence of a vast number of red blood corpuscles.
Yellow bone marrow is made mostly of fat and contains
mesenchymal stem cells which produce fat, cartilage, and bone.
Sites
Bone marrow remains red in all body until around the age of 7 years,
as the need for new continuous blood formation is high. As the body
ages, it gradually replaces the red bone marrow with yellow bone
marrow.
In adult’s highest concentration of red bone marrow is in bones of the
vertebrae, hips (ilium), (sternum) as well as at the metaphyseal and
epiphyseal ends of the long bones

Fig. 9: red marrow
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Hematopoiesis

- The process of formation of different blood cells from pluripotent
hematopoietic stem cells

Site of Hematopoiesis
Red bone marrow produces all blood elements
The small lymphocytes destined to be T cells leave the bone marrow,
and undergoing maturation in the thymus

Histological structure of the bone marrow

1-Stroma

it is formed of a network of reticular C.T. that supports the cells.

2- The vascular sinuses of the marrow are
50-75 um in diameter.
They are lined with a layer endothelial cells joined together by junctional
complexes. Transendothelial migration of blood cells involves temporary
channel formation through the endothelial membrane. As the blood cell
completes its passage through the aperture, the endothelial cell “repairs
itself,” and the aperture disappears. A discontinuous basal lamina is seen.
3-Free cells
these are the free stem cells, immature and mature cells of all blood
elements.

4-Fixed cells
these are the reticular cells, fibroblasts, adipocytes and macrophages.
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Fig. (10): A diagram of bone marrow

Histological structure of the bone marrow

- These are pluripotential cells that can generate all of blood cell types.
They give rise progenitor cells.

Progenitor cells
1- Common myeloid progenitors
give rise to either:
megakaryocyte/erythrocyte
progenitors
granulocyte/monocyte
progenitors

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2- Common lymphoid progenitors give rise to lymphocytes

Fig. 11: Hemopoietic stem cells
Development of erythrocytes (erythropoiesis)

1.Pluripotential stem cells

Colony forming unit erythropoietin sensitive cells (CFU-e) (from commn
myeloid progenitor).

2.Proerythroblasts

3.Basophil erythroblasts

large number of ribosomes that start to synthesize hemoglobin.

4.Polychromatophil erythroblasts

contain hemoglobin in their cytoplasm

5.Orthochromatophil erythroblasts or normoblasts

have pink cytoplasm with only faint ting of blue.

6.Polychromatophil erythrocytes or reticulocytes
these are immature R.B.Cs result from extrusion of the nucleus of
normoblast and contain a small number of ribosomes

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- It can be seen in the Peripheral blood but not more than 1%.
Its number is clinically useful in estimation of the rate
of erythropoiesis in patients suffering from anemia or
recovering from blood loss.

Granulopoesis( fig. 13)

1. Pluripotential stem cells - commn myeloid
progenitor. granulocyte monocyte progenitor
2. Myeloblasts: devoid of granules.
3. Promyelocytes contains numerous azurophilc
granules.
4. Myelocytes and metamyelocyte: contain specific
cytoplasmic granules
5. Band cells or stab cells: the nucleus is elongated
and curved.

Fig. 13: Granulopoesis Fig. 12 :(erythropoiesis)
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Development of non-granular
leucocytes

Lymphopoiesis
steps of Development of lymphocytes from hematopoetic stem cell

Monopoiesis
Steps of Development of monocytes from hematopoetic stem cell

Development of blood platelets (thrombopoiesis)

Thrombopoiesis refers to the development of either thrombocytes (in
lower vertebrates) or platelets. It passes through steps till become
Megakaryocytes (fig. 14)

Fig. 14: thrombopoiesis

Megakaryocytes (fig. 15)

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These are giant cells (50-70 um) with single, large, lobulated polyploid
nucleus (due to increase their DNA content without undergoing late stages
of mitosis)

Fig. 15: Megakaryocytes

Mechanism of platelet formation (fig. 16)
- Cytoplasmic extensions from megakaryocytes called proplatelets
processes develop.
- The proplatelet processes pierce through sinusoidal endothelium
(transendothelial) extend into the sinusoidal blood and at transverse
constrictions appear throughout the proplatelet called Platelet
demarcation membranes release platelets.

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Fig. 16: Platelet formation

References:
-Alan Stevens, James S.Lowe. 3rd edition
--Illustrated Interactive Q&A: L Illustrated
Q&A
-Review of Histology. Guiyun Zhang, Bruce A.
Fenderson

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1 Hemoglobin

Definition

It is an example of chromo- and metallo-conjugated proteins. It is
formed of a tetramer of polypeptides of two types that differ
according to its developmental stage of expression to meet
specific requirements. It fills up the entire space of RBCs where it
carries several functions as follow

Function

1-Carrier of oxygen from its high tension in the lung to its low tension
in the peripheral tissues.
2- Carrier of carbon dioxide as carbonium with amino groups of its
amino acids from tissues to the lung.
3- Strong buffer that is essential for pH maintenance in RBCs and
affect O2 transport (Bohar's effect).
4- Its genetic and/or metabolic abnormalities cause serious diseases.

Structure of heme

- Heme is a complex of iron (in ferrous state, F ) and one of porphyrins called:
protoporphyrin IX. Iron is held in the centre of heme molecule by bonds to
the 4 nitrogen atoms of pyrrole rings of protoporphyrin
- Heme containing proteins are called hemoproteins, metallo and chromoproteins.
They include :
1-Hemoglobin and myoglobin.
2- Respiratory cytochromes and microsomal cytochrome P450
3-Catalase, peroxidase and tryptophan oxygenase

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The role of the heme
group in each protein is:

1- In hemoglobin and myoglobin: Acts as oxygen carrier.
2- In cytochromes: Acts as an electron carrier for hydroxylation reaction s and
energy production.
3- In catalase and peroxidase: Acts as a part of active site of the enzyme that
catalyzes the breakdown of hydrogen peroxide (H2O2 ).

Hemoglobin:
Hemoglobin: Globin:
- It is formed of a it is a basic protein formed
protein part, globin, of 4 polypeptides
and a non-protein (tetramer) of two types
part, heme prosthetic -At the center of
group, bound each polypeptide there is a
together; therefore, it heme group. Thus each
is a type of polypeptide binds an O2
conjugated metallo- Hemoglobin is
and chromo-protein. classified structurally
according to the types of
these polypeptides as
follows.

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Structural types of normal hemoglobin
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A) Hemoglobin A (HbA ):

- It is the major hemoglobin in adults (90_95%)
- Its globin compromise 4 polypeptide chains two -chains (141 amino acids )
and two -chains (146 amino acids ) The globin is abbreviated 22.
- The iron of each heme group is bound by coordination bonds to nitrogen atoms
of imidazole rings of histidine amino acids number 58 and 87 in -chains and
number 63 and 92 in  chains.
- When hemoglobin is oxygentaed , the bonds between iron and histidine
residues number 87 in  chains and number 92 in  chains are displaced by
oxygen

B) Hemoglobin A (HbA2 ):
It is the minor adult hemoglobin accounting for about 2.5% of adult
human hemoglobin. Its globin consists of 2  chains and 2 delta
chains(): 22.

C) Fetal hemoglobin (HbF):

-This is hemoglobin present in fetus during intrauterine fetal life. It consists of 2
 chains and 2 gamma chains. (22).
-Hemoglobin F accounts for about 1% of adult human hemoglobin. Unlike HbA1
it resists denaturation by alkalis.
-It binds 2,3-diphosphoglycerate weaker than HbA and therefore has higher
affinity to O2.

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D) Embryonic or growing
hemoglobin (HbG):

- It is formed in erythrocytes of the first three intrauterine life of baby. It
consists of 2 alpha  chains and  chains, 22.

Abnormal hemoglobin

Hemoglobin A1c ( Glycated hemoglobin ) :
- Hemoglobin A, reacts non-enzymatically with glucose to form a derivative
known as glycated hemoglobin or HbA1c.
- Normally the concentration of HbA1c is very low(5-8%) but in diabetes
mellitus,where blood suger level is high,the concentration of HbA1c may reach
12% or more of total hemoglobin
- It is used for long-term (several weeks) surveillance of diabetes mellitus.

NOTE

- Normal vallue of Hb:
Blood hemoglobin content is
12-18 g/dL in females and 13-
20 g/dL in males

Synthesis of hemoglobin:

Three components are required:

Protoporphyrin IX:.
Globin: Produced by the usual mechanisms of protein
synthesis.
Iron.

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In addition to the actual constituents of haemoglobin, certain vitamins
and other factors are also required
Pantothenic acid Pyridoxal-P
Copper Vit C (ascorbic acid
Intrinsic factor: It is necessary for vit B12 absorption.
Vit B12 and folic acid: Erythropoietin

Heme synthesis

δ-ALA synthetase enzyme is very unstable, low in concentration in
tissues, Main rate-limiting enzyme in the synthetic pathway
Synthesis of Hb appears to proceed concurrently with the maturation of
erythrocytes. The primitive red cells contain free porphyrins rather than Hb.
As the red blood cells mature, the content of free porphyrin decreases and
that of Hb rises. These biochemical changes are correlated with the
alterations in the staining properties of the cells.

PORPHYRIAS

When the blood levels of coproporphyrins and uroporphyrins are increased
above normal level and excreted in urine/faeces, the condition is called
porphyria..

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HMP SHUNT

Definition

- It is an alternative minor pathway for glucose oxidation that does not produce
ATP nor utilize it. It aims at producing NADPH.H+ and ribose. It is considered
as a shunt from the main stream of glycolysis.

Biomedical Importance:

Though it is oxidation of glucose, but it is not meant for energy
Provides NADPH which is required for various reductive synthesis
in metabolic pathways.
Provides pentoses required for nucleic acid synthesis.
Deficiency of a particular enzyme leads to haemolytic anaemia,
which is of great clinical importance.

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Location

intracellular location: Organ location
cytoplasm

Organ location

a) its active where NADPH.H+ is needed in:
-Adipose tissue & liver : for lipogenesis
-Adrenal cortex ,ovaries&testis : for steroid biosynthesis
-RBCs : for production of reduce glutathione
-retina : for reduction of retinal into retinol
b) In many tissues it supplies ribose for nucleotides

NOTE

HMP never occur in :
-non lactating mammary gland
-skeletal muscles.

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Steps of HMP Shunt

Clinical Aspects

Haemolytic Anemia due to G6PD Deficiency

Amutation present in some populations causes a deficiency of the enzyme-
G-6-PD with impairment of generation of NADPH that is manifested as red cells
haemolysis when the susceptible individuals are subjected to oxidant group of
drugs such as antimalarials, like primaquin and aspirin, etc.
Inheritence:
Generally transmitted by a sex-linked gene of intermediate dominance.
Race:
Defect has a high incidence in Negroes. Also found in non-Negro races and
seen most frequently in Mediterranean peoples, namely Italians particularly
Sardinians and some Greeks. Other races known to be affected include:
Indians, Chinese, Malayan and Thais

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Clinically
Anaemia
Fall in blood Hb↓
May be jaundice and
Blackenning of urine.
- This type of haemolysis is “selflimiting”; older cells are destroyed whereas the
younger cells are resistant.
Mechanism of Haemolysis

Red cells abnormalities associated are as follows:
G-SH-low or low normal
G-SH stability-low
Catalase-low
O2 consumption-low

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Micro-minerals
2
(Trace elements)

Sources:

Liver Heart Kidney Organ meats Spleen

NOTE
Other sources are egg yolk, fish, nuts, dates and beans.
Spinach is a poor
Functions of Iron source,because of its lower
content of iron and some iron
Iron plays a number of important roles in the body: is bound to phytate.
As a component of :

hemoglobin and myoglobin, it is required for O and
CO2 transport.

cytochromes and non-heme iron proteins, it is required
for oxidative phosphorylation.

the essential enzyme, (lysosomal) myeloperoxidase, it
is required for phagocytosis and killing of bacteria by
neutrophils.

⚫ Lactoferrin binds iron in milk, it facilitates the transfer of iron to
intestinal receptor in the infant. It also inhibits microbial growth.

Body Iron
The total body iron of an adult male is 3-5g.
It is distributed as follows:
RBCs iron(hemoglobin):66%

Tissue iron :33%

Plasma iron :1%
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Tissue iron ; It includes:

1.Ferritin :it is the main 2.Hemosidren :When
storage form of iron. A- Available content of iron is high
Its protein is called forms Or more than the capacity
apoferritin, which can Non-haem of apoferritin, some of
carry 24 atoms of iron to iron(29%) iron is found in granules
form ferritin.It presents in called hemosiderin.
iron stores, e.g., liver, Can be used by tissues These granules are
spleen, bone marrow and or there is body need composed of iron,protein
intestine. (polymerized ferritin)
and
polysaccharides. It is an
aging sign.

1.Myoglobin : 2.Respiratory cytochromes
(b ,c1 ,c ,a , and a3 ) :
It is hemoprotein
formed of a single
haem ring attached These are components
to one long of respiratory chain in
polypeptide chain. It mitochondria. They act as
is present in muscles electron carriers
and heart. It acts as B-Non available forms
oxygen reserve for (4%)
quick utilization by
contracting muscles. that can not be used
even if there is body
needs. It is in the form
of hemoproteins, i.e.,
contained in haem ring

5.Microsomal and
Mitochodrial non
respiratory
3.Catalase and peroxidase cytochromes:
These are a specific group
These are two enzymes 4.Tryptophan oxygenase of enzymes that present in
that act on the toxic (Pyrrolase) liver, lung, kidney, gut,
hydrogen peroxide(H2O2 ) adrenal cortex, heart and
converting it into H2O. This enzyme is important for brain. They act as electron
tryptophan metabolism. carrier.

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Mechanism of iron
absorption:

Absorption of iron occurs in duodenum and the proximal part of the
jejunum.

Alterations of
plasma iron:

a) Iron deficiency anemia:

Deficient intake

Causes: Impaired absorption: e.g. Steatorrhea, abdominal surger

Excessive loss e.g. menstrual loss, gastrointestinal bleeding,
bleeding due to some parasites (anchylostoma).

Biochemical changes:

Plasma iron is decreased.
Plasma TIBC is increased.
Plasma ferritin is decreased.
RBCs are hypochromic and microcytic.

b) Iron overload:
Note
Repeated blood transfusion. Hemochromatosis :This is
a rare hereditary disease
characterized by
Causes: Intravenous administration of iron. abnormal increase of iron
absorption.

Hemochromatosis (hemosiderosis, Bronz diabetes)

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Iron is deposited in the form of hemosiderin in:
⚫ Liver: Causing liver cirrhosis.

⚫ Pancreas: Causing fibrosis and diabetes mellitus.

⚫ Skin: Causing Bronz discoloration of skin.

Biochemical changes:

Plasma iron is increased.

Plasma TIBC is decreased.
Plasma ferritin is increased
Requirements:

✓ Adults :10 mg/day

✓ Pregnant and lactating women :30 mg /day.

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1 Introduction

Blood is a connective tissue in fluid form. It is considered as

‘Fluid of life’

it carries oxygen from lungs to all parts of the body and carbon dioxide from all parts
of the body to the lungs.

‘Fluid of growth’

it carries nutritive substances from the digestive system and hormones from
endocrine gland to all the tissues.

‘Fluid of health’

it protects the body against the diseases and gets rid of the waste products and
unwanted substances by transporting them to the excretory organs like kidneys.

1) Blood Functions

Respiratory
Homeostasis

Nutrition

Haemostasis
Excretion
Functions

Defense Regulation of
metabolism

Regulation of
body temperature

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1. Respiratory function
Blood carries O2 from lungs to tissues and carries CO2 from tissues to lungs.

2. Nutritive function
Blood carries nutrients (glucose, amino acids, fatty acids......) to the tissues.

3. Excretory function
Blood carries the waste products (urea, uric acid, creatinine, lactic acid) from
the tissues to be excreted by excretory organs as (the kidneys, lungs & skin).

4. Regulation of metabolism
Blood carries hormones and vitamins or other physiologically active
substances which regulate body metabolism.

5. Regulation of body temperature
Blood carries heat from the internal organs to the superficial organs and skin, so
excess heat can be lost by conduction, radiation and convection and also by
evaporation.

6. Defense function; Through:

White blood cells (cellular immunity) which is capable of Phagocytosis.
Antibodies (humoral immunity) against foreign proteins.

7. Haemostasis (prevention of blood loss)
Through blood platelets & coagulation factors.

8. Homeostasis
Regulation of water balance.
Regulation of acid-base balance: by chemical buffers in blood.

2) Blood physical properties

Color

Blood is red in color.
Arterial blood is scarlet red because it contains more oxygen.
Venous blood is purple red due to presence of reduced Hb.

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Specific Gravity
1030
for plasma
1060
While the specific gravity of water is 1000 it is
for Whole Blood 1090
for erythrocytes

Osmotic pressure

the colloidal O.P is (25-30mmHg)
It is greatly due to albumin which has the highest concentration of all plasma
proteins.

Viscosity

Taking viscosity of water unity

The viscosity of the plasma is about 2 (due to presence of plasma proteins
mainly fibrinogen.
Viscosity of whole blood is about 5 (due to presence of R.B.Cs).
So it is in polycythemia or dehydration

in anemia or Hypoproteinemia.

Volume
Average volume of blood in a normal adult is 5 L.
In a newborn baby, the volume is 450 ml.
In females, it is slightly less and is about 4.5 L.
It is about 8% of the body weight in a normal young healthy adult, weighing
about 70 kg.

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NOTE

Blood volume is higher in
males due to genetic and
body-built difference.

3) Blood Components

Cellular Component Fluid Part (Plasma)
Represents 55% of blood volume
Red blood cells (RBCs) or Erythrocytes
90% Water
White blood cells (WBCs) or Leucocytes 7-8% plasma proteins
0.9% Electrolytes
Blood Platelets or Thrombocytes
1-2% Others: nutrients, Waste
products, hormones, blood gases,
dugs….etc.

2 Plasma Proteins
100 cc of plasma contain 7-8 gm plasma proteins which are
Albumin 4.5gm
Globulins 2.7gm
Albumin/Globulin ration (A/G ratio) Fibrinogen 0.4gm

It is about 1.2-1.6
It decreases in

I. Liver diseases: due to
a) ↓ formation of albumin
b) ↑ formation of globulin
Formed
By liver
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II. Renal diseases
due to loss of albumin in urine.

Dynamic state of plasma proteins
Plasma proteins are dynamic structure.
They are continuously formed from amino acids in the liver.
They are continuously destroyed into amino acids which are used by the tissues.
Rate of formation 6-10% = rate of destruction 10%

Site of synthesis of plasma proteins
Albumin and fibrinogen: formed only by the liver.
Globulins: formed not only in the liver but also by the cells of the
reticuloendothelial system which are present in the liver, spleen,bone marrow
and lymph glands.

 So, in liver diseases albumin and fibrinogen levels decrease but globulins are
compensatory increased.

1) Sources of plasma Proteins

Diet proteins
high biological value proteins (containing all essential amino acids) produce more
plasma proteins than those of a low biological value.

Tissue proteins
the plasma proteins could be regenerated from tissues even in complete starvation of
animal, they are classified into

Labile protein
immediately added from liver and tissues to the plasma.

Reserved protein
slowly regenerated and moved from liver and tissues to plasma this occurs at the
expense of tissue proteins.

Fixed cell proteins
form apart of the cell membrane and cannot be changed into plasma protein at
all.

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2) Functions of plasma Proteins
1. Maintenance of plasma colloidal osmotic pressure
Achieved by plasma proteins mainly Albumin
About (25-30 mmHg)
Important for regulation of blood volume

2. Defense function
Because the antibodies are mainly gamma-globulins

3. Clot formation
Fibrinogen plays an important role in clot formation

4. Viscosity
Plasma proteins mainly fibrinogen give viscosity to the plasma which is
important for maintenance of peripheral resistance and hence arterial B.P.

5. Carriers
Plasma proteins act as carriers for Hormones, Metal ions, Fatty acids & amino
acids or Drugs.

6. Buffers
If acids is added (e.g. lactic acid as during muscular exercise)
Lactic acid + Na proteinate → Na lactate + Proteinic acid.
If an alkali is added:
NaOH + Proteinic acid → Na proteinate + H2O

7. CO2 carriage
in the form of carbamino protein.

8. Capillary permeability regulation
by blocking the pores of the capillaries.

9. Diet reserve
Plasma proteins are dynamic structure i.e. continuously destroyed into
amino acids which are used by the tissues.
Can be utilized during starvation.

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Red Blood Corpuscles (RBCs)
6 Erythrocytes

Shape
circular, biconcave, non-nucleated discs.

 Biconcavity of RBCs is achieved by the presence of Ankyrin and Spectrin proteins
in the cell membrane of RBCs.
 Lack of these proteins leads to spherical shaped RBCs, a condition that called
"spherocytosis".

Normal Count

In males 4.6:6.2 million / mm3 (average 5.4 million / mm3).
In females 4.2:5.4 million / mm3 (average 4.8 million / mm3).

Wall

Semipermeable
Plastic (i.e. can be momentary deformed when squeezed in narrow capillaries
then it regains its original form)
Not elastic (i.e. doesn’t elongate on stretch, so when absorbs some water it
ruptures) !

Haemoglobin

It is a chromoprotein in which four haem groups are
attached to a protein part (globin).
Each haem group contains an iron atom which can
carry one O2 molecule.
Globin keeps iron of haem in ferrous state whether
in oxy Hb or reduced Hb.
If oxidized to ferric state by oxidizing agents, it is
converted into methemoglobin which isn’t capable of
carrying oxygen. !

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Types of normal Haemoglobin
The haem molecule of haemoglobin doesn’t vary in composition, but the globin
molecule is the responsible for the different types of haemoglobin.

Globin is formed of 2 identical halves each half consists of 2 polypeptide chains:

Hb A (normal adult Hb representing 97%)
formed of 2α & 2β chains
Hb A2 (normal minor adult Hb only 3%)
formed of 2α & 2δ chains
Hb F (normal fetal Hb)
formed of 2α & 2γ chains
Gower I Hb (formed of 4ε) & Gower II (formed of 2α & 2ε)
Both are the embryonic Hb

1) Functions of RBCs

Functions of the content
1. Haemoglobin
Has a respiratory function, It transports O2 from lungs to tissues & CO2 from
tissues to lungs
Has a buffer action (i.e. helps in keeping the blood PH constant)
2. Carbonic anhydrase
Important in CO2 carriage.
3. Histaminase enzyme
for destruction of histamine.
4. Glucose-6-phosphate dehydrogenase
protect RBCs from toxic H2O2

Functions of the wall
1. Allows the RBCs to pass through the narrow capillaries due to its plasticity
2. The biconcavity of the membrane gives the RBCs a large surface area which
helps the exchange of gases.
3. It is semipermeable (i.e. it regulates the passage of electrolytes to the inside and
the outside of the cell)
4. Permits the passage of HCO3- and Cl- but doesn’t allow the passage of H+ and
K+.
5. keeps the content inside the RBCs protecting carbonic anhydrase enzyme from
being lost in urine & protect Hb from being free in plasma.
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2) Origins of RBCs

Erythropoiesis
the process of the origin, development and maturation of erythrocytes

Site
Beginning from the 4th week of pregnancy and all over the 1st six
months of fetal life
it occurs in the stem cells of yolk sac, liver and spleen.

In the last 3 months
bone marrow becomes the most active site.

In infants & young children
bone marrow becomes the only site for erythropoiesis.

In adults
erythropoiesis is limited to the red bone marrow (which is present
in the ends of long bones, vertebrae & flat bones).

Stages of formation

Basophil Polychromatophil Acidophil
Heamocytoblast Pro-erythroblast Reticulocyte RBCS
erythroblast erythroblast Erythroblast

During maturation
The nucleus becomes smaller until it disappears from the mature RBCs.
There’s progressive ↓ in the size of the whole cell.
Appearance of hemoglobin
Change in the staining properties of the cytoplasm

LIFE SPAN OF ERYTHROCYTES
Erythrocytes live for about 120 days.
The number of red cells is kept nearly constant by a balance between the rate of
destruction & the rate of regeneration.

FATE OF OLD ERYTHROCYTES
The old red cells at the end of their life are taken up by the phagocytic cells of the
RES then:
Hb molecule is broken into haem + globin.
Globin is used by the body or stored for future use
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Haem losses its iron and is converted into bile pigments which then excreted by
the liver to the small intestine then excreted with stool
Iron is used by the body for reformation of RBCs or stored in the liver as ferritin
for future use.
NOTE
Bile Pigments are
responsible for the
brown coloration of the
stool.

3) Factors affecting erythropoiesis

1. Oxygen tension of arterial blood
Oxygen tension of arterial blood is the main stimulus for erythropoiesis, as
Lowering of oxygen tension stimulate bone marrow to produce more RBCs
Doesn’t act directly on bone marrow but through the release of Erythropoietin
hormone

 Conditions that decrease O2 supply to the tissues increases the rate of
production of erythrocytes as occurs in:
High altitude
Increase demands for O2 in athletes.
Chronic respiratory disease (e.g. COPD)
Anemia
Prolonged heart failure

2. Kidney
As a result of O2 lack, the endothelium of peritubular
capillaries of the kidney release a substance called
erythropoietin hormone.
The kidney secretes 85% of erythropoietin.
The liver secretes the remaining 15%.
Erythropoietin hormone stimulates bone marrow to produce more RBCs
 Explain: anemia in renal failure

3. Hormones
Specific → Erythropoietin
Non-specific → thyroxin, testosterone
 Explain: number of RBCs in male is more than that in females

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4. Liver
Produces → globin of haemoglobin & 15% of erythropoietin.
Stores → iron &vitamin B12
 Explain: anemia in liver failure.

5. Bone marrow
Healthy bone marrow is essential in erythropoiesis.
If bone marrow is destroyed by prolonged exposure to X-rays, atomic
radiations or drugs → results in aplastic anemia !

6. Food factors

I. Iron
essential constituent of Hb molecule.
Iron deficiency results in anemia
Absorption of iron:
o Iron absorption takes place in the upper part of the duodenum
o Most of inorganic iron in food is in ferric state.
Iron is reduced to ferrous iron in the stomach by vitamin C in
the presence of HCl
o Mucosal cells manufacture a protein called (apoferritin) which
combines with iron to form (ferritin)
o when all apoferritin is converted to ferritin, iron absorption is
stopped, and the excess iron will be excreted in feces
Ferritin is in equilibrium with iron in the plasma so; fall of iron
concentration in the plasma is followed by separation of iron from
ferritin and is transported by beta globulin into circulation in the form of
Transferritin

II. Vitamin B12
Important for nuclear maturation & normal development of RBCs
Deficiency of Vit. B12 results in failure of nuclear maturation and cell
division in bone marrow → megalocytes appear in peripheral blood
which is larger in size than normal RBCS, Oval in shape, less in
number, large amount of Hb, and of shorter life span.
Absorption
o It is absorbed from the terminal ileum
o Vit B12 is called the extrinsic factor.
It combines with intrinsic factor secreted by parietal cells of the
o stomach.to protect Vit. B12 from digestion.
It is stored in the liver
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III. Folic acid
Folic acid, like Vit. B12 is needed for maturation of RBCs
Its deficiency leads to megaloblastic anemia
Absorbed from jejunum

IV. Proteins
Proteins of high biological value are needed for synthesis of
haemoglobin.

V. Trace elements
Copper and Cobalt act as catalyst for the synthesis of Hb but do not
enter in the formation of Hb.
Copper deficiency leads to anemia.
Cobalt enters in the formation of Vit. B12 and stimulate Erythropoietin
formation. So, excess cobalt may produce polycythemia

NOTE
Absorption of:
Iron Duodenum
Vit B12 Ileum
Folic Acid Jejunum

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8 Anaemia

Anemia
1-normal level of haemoglobin
It’s a decrease in the quality or
Males: 16grams/dl
quantity of RBCs.
Females:14grams/dl
Blood count: when No. of RBCs is
If the haemoglobin level drops
below 5 millions.
below normal, the condition is
Hb estimation: when Hb level is
called Anaemia.
below 12 gm / dl.

Causes of Anemia
A. Antigen-Antibody reaction as in incompatible
blood transfusion.
B. Bacterial toxins and malaria.
1. Excessive
C. Chemicals: as in lead poisoning.
destruction of D. Drugs: as sulfa.
RBCs E. Enzyme deficiency: as in favism there ↓ in G6PD
(haemolysis) enzyme.
F. Snake venom.
G. Blood diseases: as spherocytosis or sickle cell.anaemia

This is may be due to:
A. Prolonged exposure to X-rays.
2. Aplastic B. Exposure to atomic radiations.
anaemia C. Malignant diseases infiltrating the bone marrow..D. Drugs as chloramphanicol

3. After haemorrhage

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This is may be due to:
Defective intake, Defective absorption or
4. Iron deficiency increased iron requirements.
anaemia
The RBCs are small in size and pale in colour

This is may be due to:
5. Vitamin Stomach diseases or its removal :
B12deficiency Lack of intrinsic factor.
(pernicious anaemia) Disease or removal of lower ileum.

This is may be due to:
6. Folic acid Increase its requirements in the pregnant
deficiency women in the first 3 months of pregnancy.

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9 Blood groups
The surface of the RBCs contains many antigens (agglutinogen) the most important
of these antigens are the A and B antigens

Blood groups

According to the presence or absence of these antigens, people are divided into
4 groups:
42% group A contain A antigen on R.B.Cs and anti-B in plasma
9% group B contain B antigen on R.B.Cs and anti-A in plasma.
3% group AB contain both A & B antigens and no anti Bodies in plasma.
46% group O contain neither A or B antigen and both anti-A, anti-B in plasma
This is important in blood transfusion

Blood transfusion

Donor
A B AB O
Recipient
Group A ✔ ✖ ✖ ✔
Anti B
Group B ✖ ✔ ✖ ✔
Anti A
Group AB ✔ ✔ ✔ ✔
No
antibodies
Group O ✖ ✖ ✖ ✔
Anti A
&Anti B

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Each blood group can donate and receive blood from persons with the same
blood group (after cross matching test)
Blood group AB is a universal reciepient as there are no antibodies in their
plasma.
Blood group O is a universal donor as their RBCs don’t contain antigens on
their surfaces.
It is rare that the transfused blood (from the same group if it contains foreign
antigens or from group O) causes agglutination of the recipient’s blood
because the plasma of donor’s blood immediately becomes diluted by
recipient’s plasma. And this can be avoided by the cross matching test.

Determination of blood groups: By using anti A and anti B antibodies

RH Factor

There is another antigen on the surface of R.B.Cs called Rh.Factor.
It is determined by the presence of the D antigen.
It is firstly discovered in rhesus monkey and present in 100% of
these monkeys (all are RH +ve).
In people, D antigen is found in 85% of persons and are said to be
(Rh+ve). But 15% have no D antigen on their R.B.Cs and are said
To be (Rh -ve).
The plasma of either Rh +ve or Rh –ve persons doesn’t contain
antibodies against Rh. factor naturally.

Importance of RH Factor

1) Blood transfusion 2) in marriage

If Rh–ve person receives Rh +ve blood When an Rh-ve woman is married to an
for the first time antibodies are Rh +ve man, the fetus genetically almost
developed in his plasma but no will be Rh +ve like his father.
agglutination occur.

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If second transfusion of Rh +ve blood Small amount of fetal blood may leak
occurs → serious agglutination and into the maternal circulation during
haemolysis occurs delivery when the placenta is separated
from the uterus so anti-D antibodies will
be formed.

When Rh–ve blood is transfused to Rh– During the next pregnancy these
ve or Rh +ve blood no harm occur. antibodies cross the placenta and reach
the fetus causing agglutination and
haemolysis of his R.B.Cs.
The condition is called erythroblastosis
fetalis and the baby is born usually dead.

Note

If the baby is born alive he will suffer from anaemia, jaundice
and may be kernictrus.
Erythroblastosis fetalis can occur in the 1stpregnancy if the
mother receives Rh +ve blood before pregnancy.
Rh incompitability may not occur in Rh–ve mothers if the
previuos babies were Rh–ve or due to different blood groups so,
fetal RBCs destructed by maternal antibodies

Treatment and prevention

Treatment: If the baby is born alive with erythroblastosis fetalis can be treated by
blood exchange by a blood group O Rh–ve
Prevention: Rh-ve women must not receive Rh +ve blood even before marriage.
If Rh-ve woman marries Rh +ve man she must be given anti D antibodies within
72 hours after any delivery or abortion

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Cross matching test

It is performed prior to a blood transfusion, to determine if the donor's blood is
compatible with the blood of an intended recipient or not even if they have the
same blood group and the same Rh factor to avoid:
1)Subgroup incompatibility.
2)High concentration of antibodies in the donor's blood. (As in case of
giving group O blood to a group A recipient)

3) blood transfusion

1) indication of blood trasfusion 2) complication of blood transfusion

RBCs loss: as in massive What are the causes of death with
haemorrhage, haemolysis. incompatible blood transfusion?
Plasma loss: as in severe burns. Anuria and renal failure.

Thrombocytopenia or deficiency in Arrhythmia. Due to K+ release
coagulation factors.
Shock. Due to allergy and histamine
Severe anaemia. release.

10 White blood cells (leucocytes)

( Normal count 4000-11000 mm3 )

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According to the presence or absence of
1) Types of leucocytes granules in their cytoplasm, leucocytes
can be classified into

1) granular 2) Non granular leucocytes
leucocytes(granulocytes) (agranulocytes)
Neutrophils 60- 70% Contain fewer granules

Eosinophils 2- 5% Lymphocytes 15-25%

Basophils 0- 1% Monocytes 2-8%

Granulocytes and monocytes are formed only in bone marrow
Lymphocytes are formed mainly by lymphatic tissue but also in
Origin bone marrow to a lesser extent.

2) Function of leucocytes

Eosinophils : Basophils :
Weak phagocytes Not phagocytic
Attack parasites. They secrete histamine and contain
They collect at sites of allergic about half the amount present in the
reactions. It may destruct histamine body.
released in allergic conditions (it They secrete (anticoagulant)
contains histaminase enzyme). heparin
release plasminogen needed for
lysis of blood clots

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Neutrophils : Lymphocytes
They have a defensive action The small lymphocytes have 2 types:
against invasion of microorganisms
They have highly phagocytic
(microphages)

A. Diapedesis: They migrate from
blood stream by passing through the
pores between endothelial cells of
capillaries to reach the tissue
spaces.
B. Movement: They move through
the tissue spaces by amoeboid
movement
C. Chemotaxis: They attracted to
bacteria by chemical agents known
as leucotaxin.

leucotaxin is bacterial products
interact with plasma factors.

D. Phagocytosis: Finally
neutrophils ingest and digest
bacteria by their proteolytic.enzymes as myeloperoxida

Monocytes :
Highly phagocytic
(macrophages): It can engulf large
sized particles as R.B.Cs, tissue
debris, malaria or large No. of
bacteria (about 100).
Have role in tissue repair after
inflammation by removing the
tissue debris & supply proteins and
lipids necessary for healing

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Life span &
Fate
Life span:
Neutrophils: 1-2 days.
Lymphocytes: few hours up to years according to type.
Monocytes and macrophages: months or year
Fate:
Phagocytosed by cells of the RES

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11 Lymphatic system

Introduction:
Homoeostatic mechanisms are required to maintain the constancy
of the fluid around each body cell.
Many substances that cannot enter or return through the
capillary walls, including protein molecules, are returned to the
blood as lymph.
Lymphatic system is a closed system of lymph vessels,
through which lymph flows, it's a one way system.
It's consists of lymph vessels, ducts, nodes and other tissues

1) Lymph

Lymph is derived from blood as filtrate and circulates around the body
(including lymph nodes, liver and spleen) in lymph vessels

Factors increasing the flow of lymph

Flow of the lymph is promoted by the increase of lymph

Blood capillary pressure
Interstitial fluid pressure
Permeability of lymph capillaries
Surface area of lymph capillary by means of dilatation

Functional activities of tissue

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Function of the lymph
Important function of lymph is to return the proteins from tissue spaces into blood
Bacteria, toxins and other foreign bodies are removed from tissues via lymph
Maintenance of structural and functional integrity of tissue obstruction of the
lymph flow affects various tissues, particularly myocardium, nephrons and hepatic
cells
Important route for intestinal fat absorption this is why lymph appears milky after
fatty meal
It's play an important role in immunity by transport of lymphocytes

2) Lymph nodes

Lymph nodes are small glandular structure located in the course of lymph vessels,
the lymph node also called lymph gland

Function of the lymph nodes
Lymph node work as filters to filter bacteria, viruses, parasites, other foreign
materials (even cancer cells) that are brought to the node via lymphatic vessels

Antibodies production

Trapping antigens by phagocytes

Lymphopoiesis: LN is the site of maturation of some lymphocyte and monocytes

3) Spleen

The spleen is the largest lymphoid organ in the body
The spleen has a very rich blood supply and may contain more than 500ml of blood

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Function of spleen:
Formation of RBCs in early fetal life
Destroys old, damaged and abnormal RBCs and storage the iron
found in hemoglobin for future use. (RBCs undergo extreme
,deformation during passage from the cords into the sinusoids. Old
damaged and abnormal RBCs have ↓ elasticity, so entrapped in
)cords & phagocytosed by cordal macrophages

Reservoir for monocytes, which can quickly leave the spleen to
help repair damaged tissue anywhere in the body during an
emergency
Reservoir for blood that can be returned to the cardiovascular
system when needed
Defensive function:

1-Macrophages of spleen engulf bacteria and other infectious agents
2-Lymphoid cells of the spleen react against infections by formation
of antibodies. Contains about 25% of T & 15% of B lymphocytes

4) Reticuloendothelial System

It is a general phagocytic system located in all tissues, especially
in those tissues where large number of organisms, particles and
toxins are to be destroyed.

Origin: almost all these cells originate from monocytic stem cells
therefore, the RES is almost synonymous with the monocyte macrophage system..
RES consist of:

2-mobile tissue 3- Fixed tissue
1- monocytes
macrophage macrophage

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Function of RES

Phagocytic Function: Bacteria, other foreign bodies and
tissue debris are engulfed and digested by the lysosomes of the macrophages

Destruction of senile red cells

Storage and metabolism of iron

Formation of bile pigments

Fixed tissue macrophage: (Known by different names in different sites)

Liver: Kupffer CNS: Microglia Bones: Osteoclasts
cells
Lungs: Alveolar macrophages Connective tissue: Histiocytes

Spleen/Bone marrow/Lymph nodes: Reticular or Dendritic cells

Skin: Langerhans cells

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12 Blood platelet(thrombocytes)
(thrombo = clots ; cytes = cells )
Count and formation:
Count = ¼ - ½ million / mm3
They are formed from mother cell in bone marrow called megakarocyte
(one megakarocyte gives 4000 platelets)
Life span = 8-12 days (removed by RES specially spleen) so
splenectomy causes an increase in platelet count

Structure of platelets:

1-Platelet Membrane invaginates inside the platelets forming.
canaliculi and also contains:
Receptors for collagen, vessels wall, thrombin, Von Willebrand.Factor (vWF) and fibrinogen
Coat of glycoproteins: that prevents platelets adherence to
normal endothelium but help the platelets adhesion to injured.vessels

2-platelet cytoplasm: that contains
Microfilaments (actin and myosin for clot retraction) and microtubules

Two types of granules:

1- Alpha granules: contains vWF, fibrinogen, platelet factor
4(PF4),beta thromboglobulin,and platelet derived growth factor (PDGF)
2-Dense granules (delta granules): contains ADP & serotonin

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Prevention of blood coagulation in normal vascular system:

1-Endothelial surface factors: By

1- Smoothness of the endothelium: This prevents platelet.aggregation or activation of clotting factors

2-Presence of negatively charged protein on the inner surface
,Of endothelium: This repels clotting factors and platelets so
Prevent activation of clotting factors

3- Healthy vascular endothelium secretes Nitrous Oxide (NO)
and prostacyclin (PGI2) that inhibit platelet aggregation

4- presence of a protein bound with the endothelial membrane
called thrombomodulin,which act as antithrombin factor

2- Presence
of
1-Anti thrombin III: activated by heparin and removes
Activated thrombin

2-Alpha 2-macroglobulin: has the same function as
antithrombin III but not activated by heparin

3- Thrombomodulin

4-Heparin: anticoagulant secreted by basophils and mast cells
in connective tissue around the capillaries

5-Prostacyclin: released from endothelium and inhibits
platelet aggregation

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3-Lysis of blood clots by
fibrinolysin (plasmin):

Released from eosinophils in an inactive form (plasminogen)

Activated by:
1-Tissue plasminogen activator (tPA) which released very
slowly from the injured vessel
2-Urokinase-type plasminogen activator: originally isolated from
human urine, and it is also present in the blood
3- Active factor XII and thrombin
4 - Thrombin
3 - Active factor XII

It causes lysis of blood clot and destruction of many clotting
factors, as fibrinogen, prothrombin, factors V, VIII & XII

It removes the remaining unnecessary blood clot & reopens
many small blood vessels in which blood flow has been blocked
by clots

4- Presence of coagulation factor in an active form:

In addition to removal of some activated coagulation factors by circulating
blood and their inactivation in the liver.

5- Normal dynamic circulatory state
Because slowing of the blood flow helps in accumulation of the activated
factors and enhances intravascular clotting.

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13 Hemostasis

Definition: stoppage of bleeding
Hemostasis can be divided into two stages :-
Primary hemostasis: includes the platelet and vascular response
to vessel injury

Secondary hemostasis includes the coagulation factors response to such
injury
Together, platelets, vessels, and coagulation factors combine to
stop bleeding and allow for vessel repair through formation of a stable
fibrin-platelet plug at the site of injury.

Steps of hemostasis:

1-Local vasoconstriction of the injured vessel by:

1-Myogenic mechanism: contraction of smooth muscles in the
blood vessel wall as a result of the trauma

2-Neurogenic mechanism: by nervous reflexes initiated by pain
sensation that activate sympathetic fibers leading to
vasoconstriction.

3-Chemical mechanism: by serotonin released from activated
platelets

P