1 - SCIE2020 Harmening Chapter 1.pptx

Transcript

RECAP: SCIE1440

(Intro to Immunology & Hematology)

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 “hema” – blood

“ology” – study of
Hematology

The study of blood & blood-
forming organs, centering on
the blood cells & coagulation
factors

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Blood Volume
Average blood volume in an adult is
4-6L
Average male has 5-6L

Average female has 4-5L

Blood is composed of

~55% plasma (liquid portion)

~45% cells (WBCs, RBCs, &
PLTs)

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Plasma portion of blood:

Mainly Water (90-92%)

Proteins and other solutes
Proteins (~7%) – Albumin, globulin, fibrinogen
Organic constituents – urea, creatinine, glucose
Inorganic constituents – Na, K, Ca, Cl
Respiratory gases
Internal secretions – enzymes, hormones, antibodies
(immunoglobulins)

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 Blood Cells

Red Blood Cells White Blood Cells

Platelets
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 Blood Cells

Erythrocytes Leukocytes Thrombocytes
100
50
0
1s
Qtr
t 4t
Qt
h
r
E
W
N
a
e
o
st
s
rt
t
h

Granulocyt Lymphocyt
Monocytes
es es

Basophils Eosinophils Neutrophils

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 Hematopoietic Cell Function

Cell Function
Granulocytes Fight infection / trigger immune response

Neutrophils = ______________________________

Neutrophils
Monocytes = _______________________________

Eosinophils
Eosinophils = _______________________________

Basophils
Basophils = _________________________________
Lymphocytes Cellular & humoral immunity (antibody production)
Monocytes
Lymphocytes = __________
Erythrocytes
Phagocytosis & secrete cytokines
Platelets
Respiratory gas exchange (O2 and CO2)
Hemostasis

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In healthy individuals, there is a constant balance between the rates of
formation and aging/destruction/removal of these cells

Disturbance of this critical balance may result in changes in:

 Rates of formation
 Disordered formation
 Increased utilization and/or destruction

The above changes can be responsible for a subsequent pathological
condition(s)

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Ready? …
Let’s begin! 

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Hematology I
(SCIE2020)

Harmening Chapter 1
Hematopoiesis
Battlement Pattern for Slide Morphology & Differentials

Used for assessment of morphology (WBCs, RBCs
and PLTs)

Used for performing a WBC Differential

L
A
B
E
L

Source: Harmening Fig 5-1, p. 96
Three Zones of Wedge Preparation

L
A
B
E
L

Head Region Body Region Tail Region
Harmening
Chapter 1
 Reading Assignment:

Chapter 1  Morphology of Human Blood
and Marrow Cells: Hematopoiesis
OBJECTIVES
2.1 Define the term hematopoiesis
2.2 Name organs responsible for hematopoiesis in the fetus
2.3 Define the term erythropoiesis
2.4 List the proper cell maturation sequence of the erythroid series
2.5 Recognize each cell in the erythrocytic series
2.7 Describe the process of hematopoiesis
2.9 Name the most common skeletal sites for hematologic studies
 Harmening p. 8

Hematopoiesis
Define  The dynamic processes of blood cell
hematopoiesis production and development of the
various cells of the blood
 Harmening p. 8

Hematopoiesis
 Current evidence indicates that all blood
cells are derived from a hematopoietic
stem cell.
 Hematopoiesis is characterized by a constant
Hematopoiesis turnover of cells.
 The normal hematopoietic system
continuously maintains a cell population of
erythrocytes, leukocytes, and platelets
through a complex network of tissues,
organs, stem cells, and regulatory factors.
 Harmening p. 8

 This network of organs is responsible
for the maturation and division of
hematopoietic stem cells into various
cell lines, that are committed to carry
out various functions
 Examples:
 Transport oxygen and excrete
carbon dioxide (RBCs)
Hematopoiesis
 Fight infection (granulocytes)
 Perform immune functions
(lymphocytes)
 Maintain hemostasis, a process in
which blood clots and bleeding is
halted (platelets)
 Source: Harmening p. 9

There are descriptions of these cells at the beginning of Chapter 1, p. 1-8

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 Harmening p. 8

 Hematopoietic stem cells duplicate themselves during division

 The hematopoietic stem cell has the capacity for continuous
self-replication and proliferation, together with the ability to
differentiate into committed progenitor cells of lymphoid and
myeloid lineages

 Under the influence of growth factors (cytokines), such as colony-
stimulating factors (CSFs) and interleukins (ILs), progenitor cells divide
and differentiate to form the mature cellular elements of the peripheral
blood

 (see diagram Fig 1-15 next slide)
Source: Harmening Fig 1-15, p. 9
Harmening p. 9
 Harmening p. 36

Note: Hematopoetic stem cell

Colony-
stimulatin
g factors
(CSFs)

Interleukin
s (ILs)

Source: Harmening Figure 1-62
 Harmening p. 8

The Hematopoietic System

 The hematopoietic system is orchestrated by the following:
 (a) Organs
 (b) Pluripotent stem cells
 (c) Regulatory factors (aka. Growth factors)

 These features enable the hematopoietic system to respond to stimuli
such as infection, bleeding or hypoxia, by increasing hematopoiesis
with emphasis on the particular cell type needed.
 Harmening p. 8

The Hematopoietic System

 The hematopoietic system consists of the following (a) organs, which are
are involved in the production, maturation, and destruction of blood cells:
 Bone marrow
 Liver
 Spleen
 Lymph nodes
 Thymus.
 The entire process of hematopoiesis evolves from the (b) stem cells that
support hematopoiesis, the progenitor cells that are committed to particular
cell lines, and the (c) regulatory factors (growth factors) to which the
hematopoietic system responds.
 These features enable the hematopoietic system to respond to stimuli such as
infection, bleeding or hypoxia, by increasing hematopoiesis with emphasis on
the particular cell type needed.
Summary
HEMATOPOIESIS IN PREGNANCY
Origin of Hematopoiesis: Also, see illustration next slide
Period Age Site(s) Comments
Mesoblastic Embryo (3rd- Blood islands Primitive erythroblasts produce
12th) week of of Yolk Sac embryonic hemoglobin (Gower I,
gestation Gower II, Portland)
Hepatic Fetus Liver, spleen, The liver is the primary site of RBC
(Beginning fifth thymus, lymph production until the sixth month and
week of nodes may continue to produce blood
gestation) cells to a lesser degree until 1-2
weeks after birth. In the adult, the
liver and spleen may be reactivated
for RBC production if the bone
marrow fails to keep up with
demand (extra-medullary
hematopoiesis). The spleen,
thymus, and lymph nodes produce
lymphocytes through-out life.
Myeloid Approximately Bone Marrow By 3 weeks of age, the bone
7th month of marrow is the only normal site of
gestation and RBC production. In the child, all
continuing marrow is active. In the adult, fat
throughout fills the shafts of the long bones,
adulthood and the only active hematopoietic
sites are the pelvis, vertebrae, ribs,
sternum, skull, and proximal
extremities of the long bones. Fatty
marrow may be reactivated to
compensate for anemia.

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 Hematopoiesis
(Source: Harmening p. 10, fig. 1-16)
(Summarized in a table, previous slide)
a. Tissues and organs At birth, BONE
MARROW (BM) is
major site of blood
cell development

Hematopoiesis
begins At 18-20 years, hematopoietic marrow is found

Location of active marrow growth in the fetus & adult: 2-3 exclusively in the sternum, ribs, pelvis,
months vertebra & skull
Birth
Source: Harmening p. 10, fig. 1-16
Active marrow
in all bones

Moves
to

At 4years, fat cells begin to
appear in long bones

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 Red Marrow- active
Yellow Marrow - inactive

By adulthood, BM is
Source: Harmening p. 10, fig. 1-16 50% fat & 50% cells

As the growth rate slows, there is less
At birth, 90% of BM shows red
demand for active marrow; fat infiltration
marrow indicating very active blood
begins ~ 4 yrs
cell development
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Hematopoiesis involves the production of stem cells, progenitor cells and precursor cells.

b. Stem cells
All blood cells are derived from a pod of

multi potential stem cells or pluri potential stem cells
↓
Unipotential (committed) myeloid and lymphoid
↓
Colony forming units (CFU’S)

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 Hematopoiesis
Harmening Fig. 1-17 p.10

Shows different cell pools according to their activity:

2 pools: storage & functional

Pluripotential CFU’s Stored for Along
stem cell later vessel
PPSC’s release wall
into blood

Origin of all
blood cells

Source: Harmening Fig 1-17, p. 10 spleen

BM 100% functional
BM PB
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c. Controlling Factors/Growth Factors

Colony Stimulating Factors (CSFs)
 human hematopoietic growth factors

Interleukins (IL’s)
 proteins/glycoproteins; they regulate and differentiate of precursor cells;
they act on cell surface receptors & either stimulate or inhibit proliferation
and differentiation e.g. Interleukin 1 (IL-1), Interleukin 2 (IL-2)

Controlling Factors:
 regulate blood cell development by mediating proliferation, differentiation
and maturation of progenitor cells

 regulate survival and function of mature blood cells

 are produced by macrophages, activated T-lymphocytes, fibroblasts and
endothelial cells and have factors to regulate their production and growth

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Erythropoietin (EPO) - a growth factor that stimulates the erythroid
precursors

 Hormone produced primarily by kidney

 Critical in RBC growth and differentiation

 EPO test can be ordered; low EPO (anemia or kidney disease/dysfunction); high
EPO (secondary polycythemia)

 EPO stimulating drugs (such as Epoetin, Procrit, etc.) can be given as therapy

See Harmening p. 34, Table 1-16 (Progenitor cells)

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 Harmening p.
36
Note: stem cell

EPO = erythropoietin
a growth factor that stimulates the erythroid
precursors

Source: Harmening Figure 1-62 Regulation of hematopoiesis by cytokines. BFU-E = burst-forming unit-erythroid; CFU-Bas = colony-
forming unit-basophil; CFU-E = colony-forming unit-erythroid; CFU-Eo = colony-forming unit-eosinophil; CFU-G = colony-forming
unit-granulocyte; CFU-GEMM = colony-forming unit-granulocyte, erythroid, monocyte macrophage, megakaryocyte; CFU-M =
colony-forming unit-monocyte; CFU-Meg = colony-forming unit-megakaryocyte; EPO = erythropoietin; G-CSF = granulocyte colony-
stimulating factor; M-CSF = monocyte-colony-stimulating factor.
 Harmening p. 34

Hematopoietic Progenitor Cells - stem cells
These cells develop into morphologically recognizable cell lines with distinctive features

Committed cells
that develop into
a single cell line

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 Harmening p. 43

Hematopoietic Tissue

Cells have their own “territory” in the bone marrow

Intramedullary hematopoiesis – Production within the bone marrow
Developing cell lines in hemopoietic cords of the BM cross over the walls of the sinuses (vascular spaces) & enter the blood via sinusoids

A layer of endothelium
lines these sinusoids

Cells moves across
theses walls & enter
Source: Harmening, fig. 2-1, p. 43

blood via sinusoids

Granulocytes
begin here and
then move
closer to
sinusoid

Platelets directly
released into
sinusoidal blood

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Internal Structure of Bone Marrow

RBC’s in clusters, often around iron laden macrophages

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General Cellular Characteristics to Consider as Cells
Mature

(Summary Slide, ahead):

Overall Cell Size
 WBCs + RBCs + PLTs all decrease ( ) in size as the cells mature
 The EXCEPTION are megakaryocytes (aka. Immature platelet precursor)
 Megakaryocytes get bigger and bigger until they burst open with platelets!

Nuclear : Cytoplasmic Ratio
 Definition: The amount of space occupied by the nucleus of a cell in relationship to the
space occupied by the cytoplasm of that cell
 The size of the nucleus generally decreases as the cell matures ( )
 The nucleus gets smaller and smaller, while the cytoplasm becomes larger and larger as
cells mature

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37
General Cellular Characteristics to Consider as
Cells Mature (see Summary Slide ahead):

Nuclear Characteristics
 Chromatin patterns - in general, the overall pattern progresses from a loose-looking arrangement to a
more clumped pattern as the cell matures. Some terms used to describe various patterns include:
smooth or homogeneous, fine, delicate, lacy or thready, smudged, clumped, or pyknotic (dense or
compact). Usually, the chromatin is dense and clumped with distinct lighter areas of parachromatin.

 nuclear shape - round or oval usually in young cells; as they mature, nuclear shapes become very
distinctive for particular cell types

 presence of nucleoli - present in earliest cell stages (blast). As cell matures, nucleoli are usually not
visible. These changes in the appearance of nucleoli are related to the rate of synthesis of ribosomal
RNA. The number of nucleoli varies depending on cell type. The part of the nucleus that contains
nucleoli is called euchromatin.

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The chromatin is
dense and clumped with distinct
lighter areas of parachromatin.
Nucleoli
With hematologic stains, nucleoli may appear as pale spots
in a darker nuclear background

40
Chromatin

Early stage chromatin –
The content of the nucleus is
fine, delicate

As blood cells mature,
chromatin becomes clumped,
resulting in a distinctive dark
pattern see solid black arrows
of this basophilic erythroblast

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Pyknosis

Definition: Extreme
condensation of nucleus

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Cytoplasmic Characteristics, as Cells
Mature
 Staining color and intensity decreases (e.g. basophilia decreases)

 Granulation - if present it varies in size (fine to coarse), in color, in
amount per cell. Blasts do not have granules. Those cells that
develop them go from no granules to non-specific granulation to
specific granulation

 Cytoplasmic shape (or outline)

 Quantity of cytoplasm - may increase with age

 Vacuolization - may normally be found in monocytes; abnormally -
serious infection, old cells, as artifacts in stored blood

 Inclusion bodies - may aid in cell identification, can indicate specific
diseases, some require special staining techniques
43
Summary

General Changes During Cell Maturation*- Summary

Size Becomes smaller
N:C ratio Becomes smaller

Cytoplasm Less basophilic due to loss of RNA.
Granulocytes produce granules.
Erythrocytes produce hemoglobin (pink
color)
Nucleus Becomes smaller. Nuclear chromatin
condenses. Nucleoli disappear. In
granulocytic series, nucleus indents, then
segments. In erythrocytic series, nucleus
is extruded.

* Note: exceptions
Plasma cells - increased RNA and protein synthesis produces a deep basophilia
Megakaryocytes - they grow larger as cytoplasm accumulates (will study this line next semester)

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 Blood Cells
Site of
Cell Production Primary Function Life Span
Bone
Erythrocytes Oxygen transport 120 days
marrow
Granulocytes
Bone Defense against Variable;
marrow bacterial infection 9-10days
B-Lymphs
Lymphocytes
Lymphoid Cellular and humoral 1-5 days
tissue immunity T-Lymphs
60-530 days
Bone
Platelets
marrow Coagulation/hemostasis 7-10 days

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Erythropoiesi
s
 The term erythropoiesis identifies the
Erythropoiesi entire process by which erythrocytes
are produced in the bone marrow
s
 Harmening p.
11

Erythropoiesis (cont’d)

 In response to erythropoietin (EPO), a growth
factor that stimulates the erythroid precursors,
erythropoiesis occurs in the central sinus beds of
medullary marrow over a period of about 5 days
through at least three successive reduction-divisions
from pronormoblast to basophilic normoblast to
polychromatophilic normoblast, and finally to
orthochromatic normoblast.
 Harmening p.
11

Erythropoiesis (cont’d)

 With successive developmental stages the following
changes occur: reduction in cell volume,
condensation of chromatin, decrease in N:C ratio,
loss of nucleoli, decrease in ribonucleic acid (RNA)
in the cytoplasm, decrease in mitochondria, and
gradual increase in synthesis of hemoglobin (see p
11).
 You will need to memorize the following developmental stages from
immature to mature erythrocyte:
 pronormoblast (rubriblast) to basophilic normoblast (prorubricyte)
to polychromatophilic normoblast (rubricyte) to orthochromatic
normoblast (metarubricyte)

 The nucleus of the orthochromatic normoblast is eventually extruded,
leaving a non-nucleated polychromatophilic (diffusely basophilic)
erythrocyte (reticulocyte), which is released into the circulating blood
to mature in 1 to 2 days

 Progressive cellular divisions of one pronormoblast results in
production of 14 to 16 erythrocytes
Dietary Requirements for RBC Maturation

 protein (source of amino acids)
 iron
 Vitamin B12
 Folic acid
 Vitamins B6, B12
 trace metals (e.g. cobalt, copper, zinc)
NOTE: The more common abnormalities of erythropoiesis arise due to a lack of any one or more of these factors.

51
 Harmening p.
 List the proper cell 11

maturation sequence of the
erythroid series

 Know names/terminology

Source: Harmening Fig 1-18 p. 11
 Harmening p.
15

Source: Harmening p. 15
 Harmening p. 11

Pronormoblast (Rubriblast, Proerythroblast)

 Pronormoblast:
 Earliest recognizable cell of the erythrocytic series
 Has a round, primitive nucleus with visible nucleoli and chromatin
strands that are distinct and dispersed. There is no evidence of clumped
chromatin
 The nucleus stains reddish-blue with Wright's stain.
 The cytoplasm stains a deep blue (royal blue) owing to the presence of
RNA
 The nuclear-to-cytoplasmic (N:C) ratio in a pronormoblast is 8:1 to 6:1
 Note these cells in the slides ahead   
 Harmening p. 11

Pronormoblast (Rubriblast, Proerythroblast)

 Pronormoblasts
 Range in size between 14 and 24 µm
 Usually slightly larger than a myeloblast and has more cytoplasm, which stains a
deeper blue
 Constitute ~1.5% or less of the cells observed in normal bone marrow
 Pronormoblasts usually divide within 12 hours to make “daughter cells” (aka.
basophilic normoblasts)
 Harmening p. 12

Recognize the two prononoblasts below:

Source: Harmening Fig. 1-19a p.
12

Harmening Figure 1-19
A. Two pronormoblasts (note the perinuclear
halo)
B. Two polychromatophilic normoblasts
C. Neutrophilic band
D. Segmented neutrophil
E. Smudge cell
 Harmening p. 12

Recognize the pronormoblast below:

Harmening Figure 1-20
A. Pronormoblast – may have a round to slightly oval
shaped nucleus
B. Orthochromatic normoblast
C. Two polychromatophilic normoblasts
 Harmening p. 12

Harmening Figure 1-22
center: pronormoblast
lower center: lymphocyte
 Harmening p. 13

Source: Harmening Fig. 1-23 p.
13

Harmening Figure 1-23
A. Pronormoblasts
B. Neutrophilic myelocyte
C. Neutrophilic metamyelocyte
D. Segmented neutrophil
 Flash
Card
Pronormoblast Side 1
Rubriblast

List some characteristics

________________________

________________________

________________________

________________________

________________________
 Flash
Card
Pronormoblast Side 2
Rubriblast

Earliest morphologically recognizable RBC precursor.
14-24 microns.
8:1-6:1 N:C ratio.
Small-to-moderate amount of deep blue cytoplasm; pale area next
to nucleus may be seen (referred to as perinuclear halo).
1-3 nucleoli possibly; reddish purple nucleus: homogeneous lacy
chromatin.
0-1.5% in BM
 Harmening p. 11-
12

Basophilic Normoblast (Prorubricyte, Basophilic Erythroblast)

 Basophilic normoblasts, the daughter cells of pronormoblasts,
 Require about 20 hours to develop
 In normal bone marrow, there are about four times (4x) as many basophilic
normoblasts as pronormoblasts
 The basophilic normoblast is differentiated from the pronormoblast by the
coarsening of the chromatin pattern and the nucleoli, which are ill
defined or not visible under light microscopy.
 Harmening p. 11-
12

Basophilic Normoblast (Prorubricyte, Basophilic Erythroblast)

 As the basophilic normoblast matures, it accumulates more RNA and hemoglobin
 The predominant color of the cytoplasm is blue due to the staining of RNA, but
there may be a pinkish tinge reflecting the presence of varying amounts of
hemoglobin.
 The N:C ratio in the basophilic normoblast is 6:1 to 4:1.
 A basophilic normoblast is somewhat smaller than a pronormoblast with a size of
12 to 17 µm.
 Normal bone marrow contains 1% to 5% basophilic normoblasts.
 The division of the basophilic normoblasts forms polychromatophilic normoblasts,
which are smaller than basophilic normoblasts but have twice the amount of
hemoglobin.
 Harmening p.
13

Recognize the basophilic normoblasts below:

Source: Harmening Fig. 1-24 p.
13

Harmening Figure 1-24 Basophilic normoblasts.
 Harmening p.
14

Source: Harmening Fig. 1-26 p.
14
Harmening Figure 1-26
Left: Basophilic normoblast;
center: plasmacyte.
 Flash
Card
Basophilic Normoblast Side 1
Prorubricyte

List some characteristics

________________________

________________________

________________________

________________________

________________________
 Flash
Card
Basophilic Normoblast Side 2
Prorubricyte

2nd stage; 12-17 microns.
6:1-4:1 N:C ratio. Deep blue-purple cytoplasm with
occasional small patches of pink.
Irregular cell boarders and perinuclear halo may be
present.
Nucleus has indistinct nucleoli with coarsening
chromatin that is deep purplish-blue.
 Harmening p.
12

Polychromatophilic Normoblast (Rubricyte,
Polychromatophilic Erythroblast)

 Polychromatophilic normoblasts are smaller than basophilic
normoblasts (10 to 15 µm), having relatively more cytoplasm
and a smaller nucleus than basophilic normoblasts.
 Nuclear chromatin is thicken and irregularly condensed, light-
staining parachromatin areas are visible among the dark blue-
staining irregular pyknotic masses. Nucleoli are no longer visible.
 The cytoplasm contains a varying mixture of pink due to
hemoglobin and blue due to RNA; in the late polychromatophilic
normoblast, the pinkish color is usually predominant.
 Maturation time in the bone marrow is about 30 hours
 Not normally present in the peripheral blood of adults (but may
appear in small numbers in the PB of normal newborns)
 Harmening p.
14

Recognize the polychromatic normoblasts below:

Source: Harmening Fig. 1-28 p.
14

Harmening Figure 1-28
Polychromatophilic normoblasts: early and late
stages.
 Harmening p.
14

Source: Harmening Fig. 1-29 p.
14

Harmening Figure 1-29
A. Polychromatophilic
normoblasts.
B. Lymphocyte.
C. Segmented neutrophil.
 Flash
Card
Polychromatophilic Normoblast Side 1
Rubricyte

List some characteristics

________________________

________________________

________________________

________________________

________________________
 Flash
Card
Polychromatophilic Normoblast Side 2
Rubricyte

Nucleus: low N:C ratio due to condensation of
nuclear chromatin (increased clumped chromatin)

Cytoplasm: less basophilic than earlier stages;
described as blue-pink (or light purple)
 Harmening p.
13

Orthochromatic Normoblast
(Metarubricyte, Orthochromatic Erythroblast)

 Orthochromatic normoblasts are formed from polychromatophilic
normoblasts and are recognized by the solid, blue-black,
degenerated (pyknotic) nucleus with a nonlinear clumped chromatin
pattern

 The cytoplasm is predominantly pink (or reddish) because of
increasing hemoglobin synthesis, but there may remain minimal
amounts of blue cytoplasm due to the presence of RNA.
 Harmening p.
13

Orthochromatic Normoblast
(Metarubricyte, Orthochromatic
Erythroblast)

 The nucleus is called pyknotic because there is no
parachromatin (white areas) present. The
orthochromatic normoblast nucleus is incapable of
further DNA synthesis, and therefore, cannot divide.
 The degenerated nucleus of the orthochromatic
normoblast is destined to be extruded and will
be phagocytized.
 The N:C ratio in an orthochromatic normoblast is 1:1
to 1:2.
 Harmening p.
13

Orthochromatic Normoblast
(Metarubricyte, Orthochromatic
Erythroblast)
 The maturation time for the orthochromatic
normoblast is 48 hours.
 The number of orthochromatic normoblasts in
normal bone marrow varies between 5% and 10%
 Orthochromatic normoblasts are not observed in
the normal peripheral blood of adults, but they
can be found in the blood of normal newborn
infants.
 The orthochromatic normoblast is the smallest of
the nucleated erythrocyte precursors (8 to 12 µm).
 Harmening p.
14

Source: Harmening Fig. 1-27 p.
14

Harmening Figure 1-27
Center: Basophilic normoblast;
right: Orthochromatic
normoblast.
 Flash
Card
Orthochromic Normoblast Side 1
Metarubricyte

List some characteristics
________________________________

________________________________

________________________________

________________________________

________________________________
 Flash
Card
Orthochromic Normoblast Side 2
Metarubricyte

4th stage
Size: 10-15um.
Nucleus: pyknotic, eccentric
Cytoplasm: full complement of Hb
N:C: 1:1-1:2 ratio
 Reticulocyte
(Diffusely Basophilic Erythrocyte, Polychromatophilic Erythrocyte)

 The condensed, pyknotic nucleus of an orthochromatic
normoblast is extruded, leaving a diffusely basophilic or
polychromatophilic cell. The membrane of the erythrocyte seals itself.
 Some of the bluish-staining color remains because of the presence of
RNA. The erythrocyte contains approximately two-thirds of its total
hemoglobin content by the time the nucleus is lost. The RNA content
soon begins to decrease.
 Referred to as “retic” or “reticulocyte”
 Flash
Card
Reticulocyte Side 2

Young/immature RBC
Normally 1-2% of circulating blood
No nucleus -Maturation into RBC in ~1 day
Absolute Count: per cell field,
Corrected: takes into account whether anemic or
not

The polychromatophilic stage of erythrocyte that
still contains ribosomal material which can be
identified by new methylene blue stain which
forms an artifact of network or reticulum within
the cytoplasm.
 Flash
Card
Reticulocyte Side 1

List some characteristics

_______________________________

______________________________

______________________________

______________________________

______________________________
Erythrocyte
(Red Blood Cell)

 A mature erythrocyte is not able to
synthesize hemoglobin, because it is without
a nucleus, mitochondria, or ribosomes, but it
has a unique, yet limited, metabolism to
sustain itself while traversing the
microvasculature.
 The erythrocyte carries oxygen from the
lungs to the tissues where it is exchanged for
carbon dioxide.
 Erythrocytes are pliable or flexible and
deformable, making them capable of unusual
changes in shape that are necessary for the
passage through the microcirculation to
transport oxygen.
 Harmening p.
16

Recall: Reticulocyte (Diffusely Basophilic
Erythrocyte, Polychromatophilic Erythrocyte) and
supravital stain

Source: Harmening Fig. 1-30 p.
16

Harmening Figure 1-30
Reticulocytes. New methylene blue stain of peripheral blood. Note reticulocytes with varying amounts of stained reticulum
(RNA). Reticulocytosis is associated with increased erythropoietic activity reflected by polychromasia on the Wright's stain
of the peripheral blood.
 Harmening p.
15

 Begin to recognize each cell in the erythrocytic series
 Name the characteristics of each red cell in the
erythrocytic series
 At this point, know the
characteristics/morphology of the
following MATURE white blood cells:

 (Segmented) Neutrophil
The following objectives relate  (Band) Neutrophil
to white blood cells – We will  Eosinophil
cover this next semester!   Basophil
 Lymphocyte
 Monocyte.
 2.6 : List the proper cell
sequence for myelopoiesis
(granulocytopoiesis) We’ll look at these during our next
lecture as well as in-lab.
SOME SUMMARY POINTS

▪ Blood is composed of 55% plasma, the liquid portion, and 45% cells, the formed elements
(RBCs, WBCs, and platelets).
▪ The average blood volume in an adult is 4 to 6 L.
▪ Plasma contains mainly water (91.5%), proteins (7%), other solutes (1.5%).
▪ The plasma proteins are albumin, globulin, and fibrinogen.
▪ Erythrocyte morphology is evaluated in the “body” area of every stained smear where red
blood cells are evenly distributed, do not overlap, yet are close together.
▪ Blood smears should be well made and well stained in order to properly differentiate
leukocytes, platelets, and erythrocytes
SOME SUMMARY POINTS

▪ Hematopoiesis is defined as the dynamic processes of production and development of the
various blood and marrow cells.
▪ Hematopoiesis begins in the yolk sac and, after 2 months, migrates to the liver and spleen,
where it remains until the seventh month, before finally shifting to the bone marrow, which
becomes the major site of blood cell development in the fetus and after birth.
▪ Erythropoiesis identifies the entire process by which erythrocytes are produced in the
marrow and develop from pronormoblasts (rubriblasts) to diffusely basophilic cells and finally
into a mature erythrocyte.
▪ A pronormoblast (rubriblast) differs little from a myeloblast: both have a round primitive
nucleus, visible nucleoli, and chromatin strands that are distinct and dispersed; however, the
pronormoblasts (rubriblast) is slightly larger than a myeloblast and has more cytoplasm, which
stains a deeper blue.
▪ An orthrochromic normoblast (metarubricyte) is recognized by the solid, blue-black,
degenerated nucleus with nonlinear clumped chromatin and cytoplasm that is predominately
pinkish because of increasing hemoglobin synthesis; however, there may remain a minimal
amount of bluish cytoplasm due to RNA.
 SOME SUMMARY POINTS

▪ Normal neutrophil segmented cells contain from two to five lobes (usually three) connected by a
threadlike filament(s); Segmented neutrophils constitute 50% to 70% of total leukocytes in an adult.
▪ Normal neutrophil band cells have a horseshoe-shaped nucleus without evidence of a filament;
Band neutrophils make up only 2% to 6% of the leukocytes in an adult.
▪ Normal eosinophil granules are large, round, and stain orange to reddish-orange; Eosinophils are
found in 0 to 4% of leukocytes in an adult.
* Normal basophil granules are large, round, and stain dark blue to purple; Basophils are found in
0 to 2% of the leukocytes in an adult.
▪ The majority of lymphocytes on an adult blood smear are small, have a relatively round nucleus
with clumped chromatin and a small amount of pale blue cytoplasm; Lymphocytes comprise 20%
to 44% the leukocytes in an adult.
▪ A monocyte is larger than the mature neutrophil; has abundant gray blue cytoplasm with fine,
reddish or purplish, evenly distributed granules; and has a nucleus with folds or brain-like convolutions,
and lacy, often delicate, chromatin. Monocytes comprise 2% to 9% of the leukocytes in an adult.
LAB THIS WEEK:
 Safety in the Clinical Laboratory

 “The Great Chocolate Pudding Self-Assessment”


My Additional Notes
Harmening Chapter 1
My Additional Notes
Harmening Chapter 1