Blood and Lymphatic Tissue PDF

Summary

These notes cover blood and lymphatic tissue, including the function of blood, the formation of blood, formed elements of blood, and lymphoid organs. The material appears to be lecture notes for an undergraduate course at UNSW.

Full Transcript

Blood and Lymphatic
tissue
ANAT2441: Histology

JOYCE EL-HADDAD

[email protected]
@orientatewithjoyce

Lecture Outline
- Function of blood
- formation of blood
- Formed elements of blood
- Lymphoid organs

Learning Outcomes
1. To identify the cellular components of blood and
understand their functions.
2. To describe the tissue morphology of a lymph node and the
features of the cortex, medulla, trabeculae, medullary cords
and sinusoidal system.

Centrifuged
blood sample

Plasma composition

Plasma
~55%

Water
92%
Transports organic and
inorganic molecules,
cells, platelets, and heat
Plasma proteins 7%
Other solutes

Buffy coat
<1%

1%

Platelets
Blood clot formation
and tissue repair
White blood cells

Neutrophils (60 -70%)

Monocytes (3-10%)
Red blood cells
Eosinophils (1-4%)
Red blood
cells
~45%

Lymphocytes (20 -40%)

Basophils (0 -1%)

LM of bone marrow obtained via
needle biopsy from the medullary cavity

L
typi
Two
are a
(Ba)
stain
lymp
has
cyto
(RBC
elem
a un
and
with
bico
690

Blood
•
•
•

Blood is specialized connective tissue
Consists of cells that circulate in a fluid known as plasma
Average volume of blood ~ 4-6 L depending on body composition

Function of blood is:
o to transport oxygen and nutrients to the lungs and tissues.
o form blood clots to prevent blood loss
o carry cells that are immune in nature
o deliver waste products to the kidneys and liver, which filter and clean the
blood.

168

Blood and Bone Marrow

Blood formation (Haemopoiesis)
Timeline

Main source of Haemopoiesis

PE

RBC

First few weeks of gestation Yolk sac
6 weeks of development

Liver and spleen

6-7 months of fetal life

Bone marrow

LM of a bone marrow smear at low (Above) and high (Right)
magnifications. The smear, made from a bone marrow aspirate, shows
details of hematopoiesis. Hematopoietic cells of the erythroid lineage at
different stages of development in B include a proerythroblast (Pr),
basophilic erythroblast (BE), and early polychromatophilic erythroblast
(PE). Mature erythrocytes (RBC) and two unidentifiable cells (arrows) are
also seen. Above: 8×; Right: 2000×. Wright’s.

Pr

BE

https://radiopaedia.org/articles/yolk-sac

He

Childhood

Bone marrow (most of the skeleton)

Adult life

Bone marrow (axial skeleton,
femur,
LM of a bone marrow biopsy specimen at low (Above) and high
(Right) magnifications. The solid core of tissue contains bone marrow
and humerus)
and bony trabeculae (arrows). Normal bone marrow consists of a heter-

FC

Bo

ogeneous population of cells in various stages of differentiation. Clusters
of tightly packed hematopoietic cells (He) sit between large adipocytes (FC)
and bony trabeculae (Bo). Adipocytes look empty because of lipid extraction
during specimen preparation. Above: 8×; Right: 200×. H&E.

7.11 METHODS OF STUDYING BONE MARROW
Smears and trephine needle biopsy (for preparation of bone

than smears for elucidating cell details but provide a panoramic
view of bone marrow and its normal architecture. They are also

Haemopoiesis
•

Bone marrow is the site of haematopoiesis after birth. Because most blood cells are short-lived, they
need continuous replacement.

•

All mature blood cells derive from pleuripotential stem cells in bone marrow

•

Colony-forming unit (CFUs) committed to erythroid lineage production contain progenitor cells known as
colony-forming unit-erythrocytes (CFU-E). In other words, these are the cells that turn into the
erythrocytes.

•

Granulocyte and monocyte cell lines develop from one progenitor cell known as the colony-forming unitgranulocyte-monocyte (CFU-GM). In other words, these are the cells that turn into the leukocytes.

•

Cells of the lymphocyte lineage are generated from colony-forming unit-lymphocytes (CFU-L).

•

Progenitor cells for megakaryocytes produce colonies that contain colony-forming unit-megakaryocytes
(CFU-Me).

En

Erythrocytes (red blood cells)
•
•

•
•
•
•

Anucleated biconcave discs
A biconcave shape provides a large
surface area for primary functions like
transporting O2 from lungs to tissues and
returning CO2 from tissues to lungs for
elimination
The iron containing protein hemoglobin
in RBCs accounts for their red color
Highly flexible and malleable as they
travel in narrow capillary lumina
99% of formed elements of blood and
have a lifespan in circulation of 120 days
RBCs lose their nucleus at the end stages
of erythropoietic development in bone
marrow.

*
RBC

*

5µm

Electron micrograph (EM) of an erythrocyte in
the lumen of a capillary. The RBC lacks organelles. Its
uniformly granular density is due to the presence of
hemoglobin. An endothelium (En) surrounds the capillary,
sectioned transversely. Note how the RBC completely
fills the lumen. 11,500×.

RBC

2µm

7.3

ULTRASTRUCTURE AND FUNCTION
OF ERYTHROCYTES
RBCs are anucleate biconcave discs that are highly flexible and
malleable as they travel in narrow capillary lumina. They make up
99% of the formed elements of blood and have a lifespan in circulation of about 120 days. Numbers of RBCs per liter of blood
usually average 5 × 1012 in men and 4.5 × 1012 in women. In the
human embryo, RBCs are initially nucleated, up to 7 weeks of
gestation. During final stages of erythropoietic development in
bone marrow, RBCs lose the nucleus and almost all organelles
except the cytoskeleton and then enter the circulation. Because
RBCs lack a nucleus but have a plasma membrane, they are more

containing protein hemo
color. Hemoglobin rapid
jugated protein containi
globin. Heme is a porphy
of hemoglobin in whole
12-16 g/dl for females. S
abnormalities, including
occur in humans.

C
A deficiency of RBCs and
types of which exist. Corr

Immune System

LYMPHOCYTES

Function: provide defense of the body against invasion of foreign material from both outside and
inside the body

A

Neutrophil.

Ne

Neutrophils
•

Neutrophils are the most numerous leukocytes
and constitute 60%-70% of the leukocyte count.

•

The nucleus has a distinctive morphology and
many forms (polymorphonuclear leukocytes),
with a clump-like pattern and three to five
lobes connected by fine chromatin strands.

•

Immature neutrophils show only slight nuclear
lobulation; older cells have more, dark-staining
lobes.
A
Neutrophil.

•
•
•

RBC

Blood and Bone Marrow
B

Neutrophils are actively motile and function
outside the circulation.
After they develop in bone marrow, they stay in
the bloodstream for 8-12 hours.
Neutrophil numbers increase in acute bacterial
infections.

161

Ne
Ne
RBC

*

C

RBC

GC

LMs of neutrophils in blood smears. The young
neutrophil (Ne) in A has a U-shaped, darkly stained
nucleus. The neutrophil in B is more mature; its

*

Eosinophils
•

Eosinophils make up a small proportion of leukocytes in
peripheral blood: 1%-4% of the leukocyte count.

•

Eosinophils circulate in the bloodstream for 6-8 hours; once
they migrate to connective tissues, their lifespan is 8-10
days.

•

Their nucleus is typically bilobed.

•

Cytoplasm extremely eosinophilic.

162

Blood and Bone Marrow

Eosinophil.

•

The cells phagocytose antigen-antibody complexes and
parasites, and elevated cell numbers occur in parasitic
infections and allergic responses such as hay fever and
asthma.

Eo

RBC

LM of an eosinophil in a blood smear.
The distinctive, closely packed eosinophilic
granules fill the cytoplasm of the eosinophil
(Eo). The usually bilobed nucleus has an
irregular shape. This granular leukocyte has a
larger diameter than that of the erythrocytes
(RBC). 1350×. Wright’s.

Basophils
•

The least numerous leukocytes, account for less than 1% of
the leukocyte count

•

The nucleus is often irregular in shape or bilobed.

•

Distinctive specific granules that are intensely basophilic
and fill the cytoplasm.

•

Basophils closely resemble mast cells of connective tissue

•

Basophil.
.The motile basophils are involved in allergic reactions
and
increase in number in many clinical conditions such as hay
fever, urticaria (hives), chronic sinusitis, and some
leukemias.

•

Blood and Bone Marrow

Ba

RBC

An elevated basophil count in peripheral blood rarely
occurs in most benign conditions. An increasing basophil
count can suggest worsening of disease
SG

LM of a basophil in a blood smear.
The easily recognized basophil (Ba) has
many large basophilic specific granules
that are blue. The nucleus, being masked
by the granules, is less evident. The
erythrocytes (RBC) are smaller than the
basophil. 1200×. Wright’s.

Monocytes
•

Monocytes are agranular leukocytes that are
immediate precursors to cells of the monocytemacrophage system (aka Mononuclear
Phagocytic System)

•

They usually circulate in the bloodstream for
only 1-3 days and perform almost all functions
outside the circulation. These actively motile
cells enter connective tissues to become
macrophages (or phagocytes).
Monocyte.

•

Each cell has a nucleus that varies in form and
may have an oval, kidney, or horseshoe shape

Blood and Bone Marrow

LM of a monocyte in a blood
smear. A monocyte (Mo) nucleus is highly
indented and less densely stained than
that of lymphocytes. Throughout the light
blue cytoplasm are many faintly stained
granules, so the cytoplasm looks dusty.
The monocyte is twice as large as the
erythrocytes (RBC). 1350×. Wright’s.

Mo

RBC

1

Platelets

Blood and Bone Marrow

opoiesis

169

Thrombocytopoiesis
(Megakaryocytopoiesis)

poietic
Cell
Cell

Hematopoietic
Stem Cell
CFU-Meg

blast

Megakaryoblast

166

Blood and Bone Marrow

Platelets.
Promegakaryocyte

RBC

hocyte

Thymus

• Platelets are motile cytoplasmic
fragments enveloped by a plasma
membrane
• They arise from megakaryocytes
in bone marrow and appear as
plate-like structures without
nuclei.
• Platelets play a major role in
blood coagulation
Pl

Megakaryocyte

En

1µm

T-Lymphocyte

Platelets

EM of two platelets and part of an erythrocyte
(RBC) in the lumen of a blood vessel. The platelets (Pl)
contain several dense, membrane-bound granules. One
platelet seems to adhere (arrows) to the vessel’s
endothelium (En). 15,000×.

Pl

T-Lymphocyte
Platelets

T-Lymphocyte

nce, main cell types seen in bone marrow smears
topoiesis (center, right), and megakaryocyesemble lymphocytes. Except for megakaryocytes,
es, nuclear density increases, and special features
cific granules (eosinophilic, basophilic, or
on rate and survival and maturation of progenitor

Pl
En

Lymphocytes
Lymphocytes

Organs

B Cells*
T Cells*
NK cells
Dendritic cells (antigen
presenting cell)

Diffuse Lymphatic Tissue (S)
Lymph Nodes (S)
Spleen (S)
Thymus (P)
Bone Marrow (P)
P= Primary lymphatic organ
S = Secondary lymphatic
organ

* Plus different types of these cells.

Lymphocytes
- B cells are more numerous than T cells
- B cells > Plasma cells > production and secrete of antibodies
- T cells recognise invaders, activate the immune response, kill
infected or abnormal cells, coordinate immune functions, and
establish immunological memory to provide long-term protection
against recurring threats.

Take home:
Smooth cytoplasm = low/no activity
Rough/grainy cytoplasm = high activity – protein
synthesis

Lymphocytes
When lymphocytes are active, that is
when their morphology will change

e.g.

Plasma “Clockface” nucleus
• Heterochromatin: tightly packed form of DNA
(dark)
• Euchromatin: loosed packed form of DNA (light)
• Activated B cell > plasma B cells that is secreting
antibodies

B vs T cell

Plasma B cell

Cytotoxic T cell

Lymphoid Organs
qDiffuse Lymphatic Tissue (S)
qLymph Nodes (S)
qSpleen (S)
qThymus (P)

Diffuse Lymphatic Tissue
• Mucosal Associated Lymphoid Tissue (MALT)
• Initiate immune responses to specific antigens
encountered along all mucosal surfaces – enlarge.
• Not enclosed by a connective tissue capsule
• Located in the underlying lamina propria of epithelial
lining
Different locations, different name:
NALT - Nasal Associated Lymphoid Tissue
BALT - Bronchus Associated Lymphoid Tissue
GALT - Gut Associated Lymphatic Tissue

Think about the epithelial lining covering
the nasal cavity, upper resp tract and GIT

Lymphatic follicles in the ileum
Transport gut lumen organisms and particles to immune cells across the
epithelial barrier. Most numerous in the ileum of the small intestine

LYMPH NODES: Function
In lymph vessel pathways “filter” (surveillance) lymph
Immune - detect infections from peripheral tissues
• skin, respiratory tract, gastrointestinal tract, etc.

Return interstitial fluid to circulation
Primary or secondary?

LYMPH NODES: Structure
Location throughout the entire body - concentrated in axilla, groin,
lung, gastrointestinal tract mesenteries
Small (1 mm - 2 cm) encapsulated organ.
In lymph vessel pathways “filter” lymph
• Afferent - towards node (A - arrives at the node)
• Efferent - away from node (E - exits the node)

LYMPH NODES
1

Afferent lymphatic vessel

2

Subcapsular sinus

3

Trabecular sinus

4

Medullary sinus

5

Efferent lymphatic vessel

Afferent lymphatic vessels →
subcapsular sinus → trabecular
sinuses → medullary sinuses →
efferent lymph vessel (hilum)

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• High endothelial venules
(HEVs) are different from
regular blood vessels.
• They have a high endothelial
cell layer with cuboidal or
columnar morphology, as
opposed to the flat
endothelial cells found in
typical capillaries.
• This specialized endothelium
allows for interactions
between lymphocytes and
endothelial cells, which is
essential for lymphocyte
extravasation (leakage).