Y1S1 Myeloid Tissue Histology PDF

Summary

This document provides detailed notes on myeloid tissue histology, covering yellow and red marrow, their functions, and hematopoiesis within the bone marrow. The role of stem cells, progenitor cells, and precursors in hematopoiesis is also described within these tissues.

Full Transcript

(MICRO LEC) – (MICROSCOPIC HUMAN STRUCTURAL BIOLOGY 1A)
(MYELOID TISSUE HISTOLOGY & Dr. Dennis Ivan Bravo)
(Y1S1_Week 7_Sept/2024) DIMAYACYAC - SALAMANCA - SALAS - SAMSON - SANCHEZ - SANTIAGO - SAROCA - SICAT - TABBILOS - TALOSIG
- TAWASIL - TEOPENGCO - ULANG - UMALI - VENDIVIL

OUTLINE
Introduction FAT STORAGE
Histology and Structure
○ Yellow Marrow Storage of adipose tissue (yellow marrow)
○ Red Marrow
Hematopoiesis ○ Aside from hematopoiesis, the bone marrow is also a
○ Erythropoiesis storage site for triglycerides. Adipose tissue can be
○ Thrombopoiesis found in the bone marrow particularly in the yellow
○ Granulopoiesis
○ Monocytopoiesis marrow.
Clinical Relevance
Summary BONE MARROW STRUCTURE
REFERENCES
Myeloid Tissue Histology PPT and Recorded Lecture
RED MARROW: THE BLOOD-MAKING MAESTRO

Active hematopoietic: stem cells, progenitor cells, and
INTRODUCTION
precursors: erythroblasts, myeloblasts and megakaryoblasts
○ Primarily responsible for hematopoiesis
Functions of the Bone ○ Active in hematopoiesis
Support for soft tissues and tendon attachment ○ Stem cells, progenitor cells, and precursor cells in
○ Protection for internal organs varying stages of development are found here.
The bone is an important organ that protects vital ○ This will include the precursors:
internal organs like the brain and heart. Erythrocytes or Red Blood Cells- ERYTHROBLASTS
○ Movement in combination with skeletal muscle Leukocytes or White Blood Cells- MYELOBLASTS
Thrombocytes or Platelet- MEGAKARYOBLASTS
It is responsible for locomotion so whenever skeletal
muscles would contract by themselves, this would not
YELLOW MARROW: THE FAT-STORING STEWARD
create any movement unless of course that skeletal
muscle is attached to the bone.
Adipose cells, varies with age and activity
Store and release minerals (Calcium) ○ The yellow marrow is composed of adipose so
○ Bones also have other functions aside from its its main function is to store triglycerides.
mechanical function. They store and release minerals
like calcium and phosphate.
YELLOW MARROW & RED MARROW

Functions of the Bone Marrow
The blood factory
○ Deep within the bone is the bone marrow and it is
actually a factory or some of the formed elements of the
blood.
Soft, spongy tissue found inside bones
Primary site of hematopoiesis
○ The bone marrow is a soft spongy tissue found inside
the core of the bone and this is their primary site for
blood production which we call hematopoiesis.

HEMATOPOIESIS

Production of blood cells (red blood cells, white blood cells,
and platelets)

IMMUNE FUNCTION Yellow Marrow
○ Located in long bones of adults (Femur, Humerus)
Housing of immune cells (B and T lymphocytes) in the initial ○ Highly infiltrated with adipocytes
stages of development
○ NOT hematopoietic, BUT has potential to become
○ The red marrow has immune function because it
houses the immune cells which include the B and the T one if necessary
lymphocytes at least in the initial stages of
development.

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Red Marrow red marrow are the erythroid precursor cells, myeloid
○ Found in flat bones (e.g., sternum, ribs, pelvis) and in precursor cells,, and lymphoid progenitors.
the proximal ends of long bones (e.g., femur,
humerus)
○ Highly cellular and actively involved in Schematic Histology of a Typical Red Marrow
hematopoiesis

Histology of the Yellow Marrow

The bone marrow is highly vascular and contains sinuses
through which red blood cells pass after their maturation
process. These sinuses are lined by endothelial cells.
Red - Bony trabechular The marrow is composed of erythroblastic cells in different
Spaces - occupied largely by triglyceride by lipid droplets; stages of development.
Adipocytes with signet ring appearance The myeloid area is occupied by cells that will eventually
give rise to various local sinuses. Additionally, the marrow
contains large adipocytes that store triglycerides.
Cellular components of red marrow
Hematopoietic Cells: The Stars of the Show
Blood cell precursors at various stages of development
Precursors include erythroid, myeloid, and lymphoid
progenitors

Histology of a Red Marrow

It is typical to observe that 50% of the tissue should be
filled with adipocytes in adults. Additionally, there are
hematopoietic cells at different stages of development.
Some cells are larger than others, indicating that they are
in earlier stages of development.

Sinus: are capillaries that would provide blood supply to
the red marrow
Marrow is a highly vascular organ
Adipocytes / Fat cells are the normal component of the red
marrow present in red marrow but the main cells in the

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Cellular Components of Red Marrow
Red Marrow
Stromal Cells: The Supporting Players
Support and regulate hematopoiesis:
○ Endothelial cells that lines the sinusoids
○ Fibroblasts that produces fibers like collagen and
reticular fibers
○ Adipocytes that stores triglycerides
○ Macrophages that would phagocytose defective
hematopoietic cells
○ Reticular cells

Histology of the Red Marrow

Spaces (white circle structures) were filled with
adipocytes, followed by the presence of hematopoietic
cells in varying stages of development.
The large cells seen are known as the megakaryocytes,
which are located inside the pink circles.

Bone Marrow

The bone marrow is highly vascular due to the presence of
numerous sinusoids that branch off from arteries to supply
it.
The internal environment of the marrow is lined by
reticuloendothelial cells, which are depicted as green
structures in the image above.
The tissue is highly vascular, containing numerous ○ Hematopoietic stem cells occupy this space, and they
sinusoids through which red blood cells pass. Some red are in various stages of development.
blood cells are being released from the marrow.
The large cells are megakaryocytes, which are
responsible for producing platelets. Structural Components of Red Marrow
The spaces in the tissue are occupied by different cell
stacks, and the remaining cells are hematopoietic cells in Extracellular Matrix: The Set Design
various stages of development. Provides structural support and regulates cell-cell
interactions
Components: collagen, laminin, fibronectin

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Microenvironment of red bone marrow HEMATOPOIESIS

The Growth Factors and Cytokines: The Stagehands of
Hematopoiesis
○ Substances orchestrating the production of blood cells
○ Promote cell proliferation, differentiation, and survival
○ Examples: erythropoietin (EPO), colony-stimulating
factors (CSFs), thrombopoietin (TPO)

Red marrow composition with age

Amount of hematopoietic cells varies with patient’s age:
○ Child: Red BM is 100% hematopoietic and present in
virtually every bone
very few adipocyte
○ Adults: Red BM is 50% hematopoietic and 50%
adipocyte and present in the sternum, ribs, pelvis and
skull
○ 70 y/o: Hematopoietic cell is reduced to 30%
mostly occupied by adipocytes

Hematopoiesis

Hematopoiesis: Process of blood cell formation
Importance: Essential for maintaining a healthy blood
supply and supporting various physiological functions
Starts with Hematopoietic Stem Cells (HSCs)
End products: Erythrocytes, leukocytes, platelets

Illustration of Hematopoiesis Starts with Hematopoietic Stem Cells (HSCs)
HSC gives rise to various progenitor cells
Progenitors develop to precursor cells
○ Erythropoiesis: Proerythroblast to RBC
○ Thrombopoiesis: Megakaryoblast to platelet
○ Granulopoiesis: Myeloblast to neutrophil
○ Monocytopoiesis: Monoblast to monocyte

Hematopoiesis gives rise to hematopoietic stem cells. These
cells are capable of cellular division or mitosis to replenish
itself. Then it will differentiate into progenitor cells. And those
progenitor cells will develop into cells committed to develop
into different cell lines, we referred to those committed cells as
precursor cells.

So in the erythropoiesis of the precursor, is the proerythroblast
that will differentiate to become the RBCs.
In thrombopoiesis the committed precursor is the
Everything starts with hematopoietic stem cells and will megakaryoblast.
differentiate to different progenitor In granulopoiesis the committed precursor is the myeloblast.
○ Myeloid progenitor cells —> RBC, Platelets, In monocytopoiesis the committed precursor is the
Leukocytes monoblasts.
○ Lymphoid progenitor cells —> T cells and B cells
So it starts with the hematopoietic stem cells. We can refer to it
as the “Great granddaddy” of all the cells in the blood.

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Characteristics of Hematopoiesis
and leukocytes (with exception of lymphocytes). While the
Self-renewal: capable of producing more HSCs
common lymphoid progenitor will give rise to the B and T
Multipotent: can differentiate into all types of blood cells
lymphocytes.

DIAGRAM HEMATOPOIESIS The common myeloid progenitor (CMP) will give rise to
granulocyte-monocyte progenitor, which is the daddy for both
the monocyte and neutrophils.

The eosinophil-basophil progenitor is the daddy for both the
eosinophil and basophil.

The megakaryocyte-erythrocyte progenitor is the common
ancestor for both platelets and RBC.

HEMATOPOIESIS

Everything starts with the multipotent hematopoietic stem cell.
It is characterized as capable of self renewal and it doesn’t go
through mitosis and replenishes itself. Because it is multipotent
and can give rise to all cell types in the bone marrow. It can be
differentiated by common myeloid progenitor and also the
common lymphoid progenitor.
The great grand daddy HSC gives rise to progenitor cells
(grand daddies): The common myeloid progenitor is the ancestor of
○ Common Myelocyte Progenitor erythrocytes, platelets, granulocytes, and monocytes. While
It gives rise to erythrocytes, granulocytes, the common lymphoid progenitor is the ancestor for
monocytes, and platelets B-lymphocyte, T-lymphocyte, and NK cell. We’ll only focus on
○ Common Lymphocyte Progenitor the common myeloid progenitor.
Gives rise to B lymphocytes, T lymphocytes, and
natural killer cells

HSC will undergo division and differentiation to ultimately give
rise to all the cells in the blood. This will include the
reticulocytes, leukocytes, and the platelet.

So everything starts with the HSC. We can refer to it as the
“great granddaddy” of all the cells in the blood. It will
differentiate to give rise to myeloid and lymphoid progenitors.
The myeloid progenitor will give rise to the RBCs, platelets,

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ERYTHROPOIESIS

The common myeloid progenitor will further give rise to the
granulocyte-monocyte progenitor which is the ancestor for
granulocyte and monocyte. The eosinophil-basophil progenitor
will give rise to eosinophil and basophil. CMP can also be
differentiated to the megakaryocyte-erythrocyte progenitor
which is the ancestor for erythrocyte and platelet.

Process of RBC production
Hematopoietic Stem Cell (HSC) to Common myeloid
progenitor (CMP) to Megakaryocyte-erythrocyte
progenitor (MEP) to Proerythroblast
Proerythroblasts (The first committed progenitor that will
give rise to RBC) mature through several stages to
become erythrocytes
The maturation process is characterized by volume loss,
loss of organelle and nucleus, HgB synthesis
Regulated by erythropoietin (EPO)

Now let us take a look at the development of the
megakaryocyte-erythrocyte progenitor which is the ancestor for
both the RBCs and platelets.

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ERYTHROPOIETIC CELLS PROERYTHROBLAST

Sometimes known as Pronormoblast
First committed erythroid progenitor
A large, nucleated cell with an abundant cytoplasm
Undergoes mitotic divisions to produce more erythroid
progenitors
Basophilic cytoplasm (RNA)
Start of Hemoglobin synthesis
But the level of hemoglobin here is still low that it doesn’t really
contribute to the staining character of proeryhtroblast

BASOPHILIC ERYTHROBLAST

Basophilic Normoblast
Intensely basophilic because of ribosomes
Synthesizes hemoglobin
Nucleus starting to condense
Continues to undergo mitotic divisions to continue
How do we distinguish erythropoietic cells? replenishing the RBC precursor cells
○ No visible granules in contrast to granulopoetic cells
that do not contain granules all throughout their
development POLYCHROMATIC ERYTHROBLAST
○ Round nucleus
How do we determine the stage of development? Based When the level of RNA and hemoglobin are almost equal, the
cell would now have A mix of red and blue staining, showing
on:
both hemoglobin and ribosomes so now we can refer to the
○ Cell size cell as polychromatic erythroblast or polychromatic normal
○ Condensation of nucleus blast
○ Cytoplasm color Nucleus becomes smaller
Begins to expel organelles
Hemoglobin synthesis has intensified (and hemoglobin
synthesis will continue until orthochromatic erythroblast)

ORTHOCHROMATIC ERYTHROBLAST

Characterized by condensed pyknotic nucleus
○ nucleus is at its smallest size and ready to be extruded
out
Last stage with nucleus (we would find the nucleus)
Primarily stains red due to abundant hemoglobin
Continues to expel organelles
Intensified hemoglobin synthesis

ORTHOCHROMATIC ERYTHROBLAST

When they are younger, they are larger. As they become
more mature the cytoplasm becomes relatively smaller.
The more mature cells are smaller until they become
biconcave in shape.
When they are young, they are predominantly basophilic
because of the abundance of RNA, and as they continue
to produce hemoglobin, the basophilic character
disappears and is going to be replaced by eosinophilic
character attributed to abundance of hemoglobin.

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We have here an orthochromatic erythroblast, we can see that ERYTHROPOIESIS
it is expelling out the condensed pyknotic nucleus after this
stage the nucleus will not disappear, it will now be known as
reticulocyte or polychromatic erythrocyte

POLYCHROMATIC ERYTHROCYTE

Reticulocyte
Enucleated, residual ribosomes and organelles
Hemoglobin synthesis has halted
Mature into fully developed erythrocyte within 1-2 days

Here some ribosomes are still present, but will eventually
disappear. At this point, hemoglobin synthesis has stopped.
Hemoglobin synthesis is no longer possible for this stage. So this
reticulocyte will mature into a fully developed RBC within 1-2
days.

orthochromatophilic
POLYCHROMATIC ERYTHROBLAST

Reticulocyte
Number is good indicator of BM activity
High number: chronic or severe loss of mature RBC
Low number: chemotherapy, aplastic anemia, pernicious
anemia, bone marrow malignancies

The level of reticulocyte that reaches the maturation is a good
clinical indicator for bone marrow activity. Excessive number of Erythropoiesis chain of events
reticulocytes that reach the circulation may be indicative of ○ Proerythroblast - largest cell; As it matures, 3 things
chronic or severe loss of mature red blood cells, that even the
young ones being extruded out in the circulation. Like young can be observed:
soldiers being called out to serve because the more experienced Cell volume begins to decrease
ones have already died. Other one is the reticulocyte lower than Shift from basophilic color to eosinophilic color due
the normal. This indicates depression of the bone like what to abundance of RNA to Hgb
happens in chemotherapy, in aplastic anemia, pernicious anemia, The nucleus is condensing and will be ejected at
or other bone marrow malignancies. the orthochromatic erythroblast
The precursor initially has a high amount of
ERYTHROCYTE RNA that eventually goes down. This will be
replaced with hemoglobin.
Final stage Primary regulator:
Biconcave shape ○ Erythropoietin (EPO)
Abundant hemoglobin Produced in kidneys in response to low O2 levels
Circulates in the bloodstream for approximately 120 days Stimulates erythropoiesis by:
before being destroyed in the spleen Promoting proliferation and differentiation of
erythroid progenitor cells
SUMMARY OF ERYTHROPOIESIS Increasing Hgb synthesis
Other factors influencing erythropoiesis:
Proerythroblast: Committed erythroid progenitor ○ Iron availability
Basophilic erythroblast: Synthesizes hemoglobin; ○ Vitamin B12 and folic acid (deficiency results to halted
presence of ribosomes maturation = megaloblast)
Polychromatic erythroblast: Red and blue staining (due to ○ Hormones: Testosterones, cortisol, thyroid hormones
the presence of both the RNA and Hgb)
Orthochromatic erythroblast: Pyknotic nucleus
Reticulocyte: Enucleated residual ribosomes
Mature erythrocyte: Fully developed

PNEMONIC:

Proper Blood Needs Oxygen Really Bad!

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THROMBOPOIESIS THROMBOPOIESIS

Process of platelet formation.
Hematopoietic stem cel to Common myeloid progenitor
to Megakaryocyte-erythrocyte progenitor (MEP) to first
identifiable immediate precursor Megakaryoblast
MEP is the origin of both RBC and platelet precursors
(they are siblings!)
Thrombopoiesis is characterized by endocytosis and
pseudopod fragmentation.

MEGAKARYOBLAST

A large, nucleated cell with abundant cytoplasm
Contains granules and organelles that will eventually
become platelets

Megakaryoblast, the earliest identifiable immediate precursor, it is
a large, nucleated cell with abundant cytoplasm.
The RBC and platelets do have a common ancestor and that
PROMEGAKARYOCYTE
would be the Megakaryocyte-erythrocyte progenitor.

Continues increase in size
Undergo endomitosis (resulting polyploid
chromosomes)
Cytoplasm becomes filled with granules and organelles

Megakaryoblast will give rise to Promegakaryocyte, which will
continue to increase in size. It will undergo endomitosis where
there is doubling of chromosome; it is not gonna be followed by
actual cellular division and this result to polyploid chromosome.

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MEGAKARYOCYTE

The result of endomitosis of a promegakaryocyte
Very large, multinucleated cell with a polyploid nucleus
due to endomitosis
Cytoplasm contains numerous granules and organelles
Extends cytoplasmic processes (pseudopodia) into the
bone marrow sinusoids

THROMBOCYTE

Platelets
Formed from megakaryocytes pseudopod fragmentation
Small, disk-shaped anucleated cells Diagram that shows megakaryocytes where they are extending
Play a crucial role in blood clotting their pseudopods or proplatelets into the sinusoids.
Pseudopods/proplatelets that would fragment to give rise to the
thrombocytes/platelets.
The platelets that are going to be formed from the fragmentation
of megakaryocytes is a small, disk-shaped anucleated cells which
play a crucial role in blood clotting. THROMBOPOIESIS - SUMMARY

Promegakaryoblast: Committed thrombocyte progenitor
○ Give rise to megakaryoblast
Megakaryoblast: Undergo endomitosis
○ Give rise to a large cell called megakaryocyte
Megakaryocyte: Gives rise to platelets via fragmentation
Platelets: Anucleated cells important for clotting
○ Initiates the process of clotting

PNEMONIC:

“Please Make My Tea!”

THROMBOPOIESIS

So, let’s look for megakaryocyte here, the large cells we see
here which is considered to be larger than hematopoietic
precursors is the megakaryocyte

In thrombopoiesis, we start with myeloid stem cell that will give
rise to megakaryoblast, undergoing endomitosis, to give rise to
megakaryocyte that will fragment to give rise to platelets.
The Megakaryocyte pseudopod will start to bud off and that
would give rise to the platelets

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THROMBOPOIESIS

Primary regulator:
○ Thrombopoietin (TPO)
Produced by the liver and kidney
Stimulates megakaryocyte production and
maturation in the bone marrow
Primary stimulant
Negative feedback loop:
○ Increased platelet count leads to decreased TPO
production in the liver

Granulocyte-monocyte progenitor is a common ancestor for
both neutrophil and monocyte.

GRANULOPOIESIS
Common myeloid progenitor: give rise to erythrocytes,
granulocytes, platelets, and monocytes

Megakaryocyte-erythrocyte progenitor: give rise to RBC
and platelet Process of neutrophil formation.
Granulocyte-monocyte progenitor: give rise to neutrophils HSC to CMP to GMP to Myeloblast
and monocytes ○ From hematopoietic stem cell to common myeloid
progenitor to granulocyte-monocyte progenitor to
myeloblast
GMP is the origin of both neutrophil and monocyte

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Development characterized by change in nucleus shape
Appearance of granules (primary followed by specific
secondary)

MYELOBLAST

Earliest identifiable committed precursor
Blast: young
First committed granulocyte progenitor
Large, nucleated cell with abundant cytoplasm
Mitotic divisions to produce more granulocyte
progenitors
○ Always capable of mitosis so that it replenish
When the first granules appear, it is called
itself and other granulocyte precursor promyelocyte.
When the secondary granules start to appear, it is
PROMYELOCYTE referred to as myelocyte.
When the secondary granules are predominant, it is
Pro: before, cyte: cell now referred to as metamyelocyte.
Contains primary granules (azurophilic granules)
These granules contain lysosomal enzymes and other
proteins involved in phagocytosis
Undergoes mitotic divisions to replenish itself and other
granulocyte precursor

MYELOCYTE

Contains secondary granules (specific granules)
Secondary granules determines the granulocyte subtype
(neutrophil, eosinophil, or basophil) Aside form the appearance of the secondary granules, the
Nucleus undergoes morphological changes and development from promyelocyte to band neutrophil, it is
becomes indented characterized by flattening of the nucleus. it becomes
horseshoe shaped until it becomes segmented.
METAMYELOCYTE

Summary
Meta: beyond
Nucleus becomes more indented, resembling a
○ Myeloblast: First committed granulocyte progenitor
horseshoe shape
○ Promyelocyte: Contains primary granules
Cytoplasm becomes more abundant replete with
○ Myelocyte: Contains secondary granules
secondary granules (becoming predominant)
○ Metamyelocyte: Nucleus becomes indented
○ Band neutrophil: Nucleus becomes horseshoe-shaped
BAND NEUTROPHIL
○ Mature segmented neutrophil: Developed neutrophil
with a multilobed nucleus
Nucleus becomes fully horseshoe shaped
Cytoplasm contains numerous granules (secondary)
PNEMONIC:
Ready to enter the bloodstream
“My Phone Memory Might Be MicroSoft!”
MATURE SEGMENTED NEUTROPHIL

Fully developed neutrophil with a multilobed nucleus
Contains abundant granules for phagocytosis
Circulates in the bloodstream for a few days before
entering tissues to fight infections

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GRANULOPOIESIS

Regulators are group of proteins that stimulate the growth
and differentiation of granulocytes:
○ Granulocyte-colony stimulating factor (G-CSF)
○ Granulocyte-macrophage colony-stimulating factor
(GM-CSF)
○ Interleukin-3 (IL-3)
Produced by various cells: macrophages, T cells, and
endothelial cells
Regulate granulopoiesis in response to infection or
inflammation

MONOCYTOPOIESIS

Process of monocyte formation.
HSC to CMP to GMP to Monoblast
○ From hematopoietic stem cell to common myeloid
progenitor to granulocyte-monocyte progenitor to
monoblast
GMP is the origin of both neutrophil and monocyte

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Monocytopoiesis KEY POINTS

Monoblast: First committed monocyte progenitor Bone marrow is a vital tissue involved in:
○ earliest identifiable precursor and the one committed ○ Hematopoiesis
to the pathway ○ Immune function
Promonocyte: A larger cell with a more indented nucleus ○ Fat storage.
Mature monocyte: Fully developed monocyte with a
kidney-shaped nucleus and abundant cytoplasm Hematopoiesis is the process of blood cell production,
Monocytes migrate from the bone marrow into the involving hematopoietic stem cells and their differentiation
bloodstream. into various blood cell lineages.
Circulate in blood for a few days before entering tissues. Hematopoiesis: occurs primarily in the bone marrow.
Upon entering tissues, monocytes differentiate into Hematopoietic stem cells (HSCs): progenitor cells that give
macrophages. rise to all blood cell lineages.
Macrophages are larger and more phagocytic than HSCs: self-renew and differentiate into various blood cell
monocytes.
types:
○ Common myeloid progenitor (CMP)
Summary
○ Common lymphoid progenitor (CLP)
Monoblast: First committed monocyte progenitor
Promonocyte: Large indented nucleus
Monocyte: Kidney shaped nucleus Erythropoiesis is the process of red blood cell production,
Macrophage: Active phagocytic in tissues regulated by erythropoietin (EPO).
○ Proerythroblast is earliest identifiable precursor
MONOCYTOPOIESIS ○ Development involves
Synthesis of hemoglobin
Regulation: Loss of organelles
○ Colony-stimulating factors (CSFs): Extrusion of nucleus (normoblast)
○ Granulocyte-macrophage colony-stimulating factor ○ Mature erythrocyte is extruded unto circulation
(GM-CSF)
○ Macrophage colony-stimulating factor (M-CSF) Granulopoiesis is the process of white blood cell
Interleukins production, regulated by colony-stimulating factors (CSFs).
○ Can also stimulate monocytopoiesis, in response to ○ Myeloblast is the earliest identifiable precursor
infection or inflammation ○ Process involves appearance of secondary
○ Interleukin-3 (IL-3) specific granules and nuclear segmentation
○ Interleukin-4 (IL-4) ○ Band neutrophil migrates to the circulation
○ Interleukin-5 (IL-5) ○ Mature segmented neutrophil

CLINICAL RELEVANCE Thrombopoiesis is the process of platelet production,
regulated by thrombopoietin (TPO).
BONE MARROW DISORDERS: ○ Megakaryoblast is the earliest identifiable
precursor
Anemia ○ Promegakaryocyte undergoes endomitiosis
Deficiency in red blood cells, leading to fatigue, ○ Megakaryocyte undergoes proplatelet
weakness, and shortness of breath fragmentation
manifested in circulation, this is in general deficiency of ○ Thrombocyte/platelet
RBC

Leukemia
Malignant proliferation of white blood cells, affecting their
function and leading to various symptoms

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