Hematology 1 PDF

Summary

This document provides a detailed outline on hematology, focusing on erythropoiesis, red blood cell characteristics, and related anomalies. Topics include erythrocyte indices, hemoglobinopathies, and different types of anemia. The content is presented in an outline format.

Full Transcript

HEMATOLOGY 1
By: RJAR Dinglasan, RMT | 1

TOPIC OUTLINE Thalassemia → MICROCYTIC,
A. Erythropoiesis HYPOCHROMIC
B. Reticulocytes Sideroblastic anemia→ MICROCYTIC,
1. Reticulocyte count HYPOCHROMIC ANEMIA
i. Methods of counting reticulocytes ○ INSUFFICIENT ERYTHROPOIESIS → Decrease in
ii. Methods of reporting reticulocyte counts
the number of rbc precursors in the bone marrow
C. Erythrocytes
1. RBC count
(resulting in low rbc production = ANEMIA)
2. RBC Metabolic Pathways Examples of conditions:
D. Red Blood Cell Anomalies iron deficiency → MICROCYTIC,
1. Anisocytosis HYPOCHROMIC ANEMIA
2. Anisochromia renal disease → NORMOCYTIC,
3. Poikilocytosis NORMOCHROMIC ANEMIA
4. RBC inclusion bodies acute leukemia → NORMOCYTIC,
E. Hemoglobin NORMOCHROMIC ANEMIA
1. Hemoglobinometry
○ PROGENITOR CELLS → immature hematopoietic
2. Hemoglobin electrophoresis
3. Hemoglobin Synthesis
cell that is committed to a cell line but CANNOT be
4. Hemoglobin derivatives identified morphologically (makikita pero hindi
F. Hematocrit and ESR makikilala)
1. Hematocrit determination EX. BFU-E, CFU-E
G. Related Topics ○ PRECURSOR CELLS → immature hematopoietic
1. Rule of Three cells that is morphologically IDENTIFIABLE as
2. Erythrocyte Indices belonging to a given cell line (makikita mo na,
3. Erythrocyte sedimentation rate makikilala mo pa)
H. General Overview of Anemia
EX. Rubriblast, Prorubricyte
1. Morphologic Classifications
2. Pathophysiologic Classification
○ CD71→ EARLIEST marker of erythroid
I. Hemoglobinopathies differentiation; transferrin receptor (in the
J. ThalassemiaS erythroid cells)
○ CD34→ classical marker of the HEMATOPOIETIC
ERYTHROPOIESIS STEM CELLS
ERYTHROPOIESIS → process of RBC formation (takes
place inside the bone marrow) HORMONES RELATED TO ERYTHROPOIESIS
50% red marrow, 50% yellow marrow HORMONE REMARKS
Site of formation: red marrow Erythropoietin Chief stimulatory cytokine for
Related terms: (EPO) RBCs
○ ERYTHRON → Total mass of rbc circulating in the Major hormone that stimulates
peripheral blood and the bone marrow rbc the production of erythrocytes
precursors Thermostable, non dialyzable,
○ RBC MASS → erythrocytes in the circulation, total glycoprotein hormones
population present inside the circulation (blood Primary cell / organ source:
vessel only) ○ Organ: KIDNEYS
○ ERYTHROKINETICS → a term that describes the ○ Cells: Peritubular interstitial
dynamics of rbc creation and destruction cells
Lifespan of RBC: 120 days EXAMPLE BOARD EXAM QUESTION:
○ INEFFECTIVE ERYTHROPOIESIS What do you call the hormone
Production of defective erythroid precursor produced by the kidneys for RBC
cells (These defective RBC precursors often production?
undergo apoptosis (programmed cell death) A) Erythropoiesis
in the bone marrow before they have a B) ---
chance to mature to the reticulocyte stage.) C) ---
Happens inside the RED BONE MARROW, no D) Erythropoietin
longer circulate in the blood vessel = patients Primary target cells: BFU-E and
suffer anemia CFU-E
Examples of conditions include ○ Affected by erythropoietin
Vitamin B12 deficiency → MACROCYTIC, Normally, EPO is released from the
NORMOCHROMIC ANEMIA kidney into the blood in response
Folate deficiency → MACROCYTIC, to hypoxia (too little tissue oxygen)
NORMOCHROMIC ANEMIA Three major effects:
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○ Allowing early release of CFU-E → colony forming unit-erythroid
reticulocytes from the bone NTR:
marrow BFU-E & CFU-E are committed erythroid progenitor
○ Reducing the time needed for cells (makikita pero di makikilala)
cells to mature and the bone It takes about 18 to 21 days for the BFU-E to mature to
marrow an erythrocyte, of which approximately 6 days are
○ Preventing apoptotic death spent recognizable precursors in the bone marrow.
(note: apoptosis rescue is the
MAJOR way in which EPO NOMENCLATURE SYSTEMS
increases rbc mass) RUBRI NORMOBLAST ERYTHROBLAST
Some of the current or potential Rubriblast Pronormoblast Proerythroblast
therapeutic applications: Pro rubricyte Basophilic Basophilic
○ Anemia of chronic renal Normoblast OR erythroblast OR
disease Early normoblast Early erythroblast
○ Autologous donation blood Rubricyte Polychromatophi Polychromatophili
collection lic normoblast c erythroblast OR
○ Anemia and hiv infection to OR Intermediate Intermediate
permit use of zidovudine Normoblast Erythroblast
(AZT) Metarubricyte Orthochromatic Orthochromatic
“BLOOD DOPING” → Some normoblast OR erythroblast OR
athletes illegally use epo injections Late normoblast Late erythroblast
to increase oxygen carrying Reticulocyte Reticulocyte Reticulocyte
capacity of their blood
Mature Mature Mature
○ To enhance endurance and
erythrocyte erythrocyte erythrocyte
stamina * not a precursor
○ can lead to deadly arterial *for as long you’re using supravital stain, Reticulocyte will be
and venous thrombosis called the same; it will differ in name when using Wright’s stain
GROWTH Produced by: Pituitary gland
HORMONE Stimulates erythropoiesis directly NTR:
in the BM 5 RBC Precursors under RUBRI: Rubriblast, prorubricyte,
TESTOSTERONE Produced by: Testes rubricyte, metarubricyte, reticulocyte
Stimulates erythropoiesis indirectly 3 nomenclature: Rubriblast, Normoblast, Erythroblast
(stimulates kidneys to produce Polychromatic and polychromatophilic are the same
more erythropoietin in the BM) When reticulocytes are found in a Wright-stained smear:
Male hormone Polychromatophilic erythrocytes
PROLACTIN Produced by: Pituitary gland Diffusely basophilic erythrocytes
Stimulates erythropoiesis directly -------------------------------------------------------------------------------
ESTROGEN Produced by: Ovaries PRO = “before”
Inhibits erythropoiesis indirectly META= “after”
(pinipigilan ang process of RBC
production; has an effect on
kidneys - inhibits the production of
more erythropoietin = BM of
women less stimulated to produce
RBC)
Bakit magkaiba RBC COUNT in
males and females?
○ Because of estrogen hormones
in females (inhibits
erythropoiesis) = lower RBC ct. STAGES
○ Testosterone stimulates 1. RUBRIBLAST (PRONORMOBLAST)
kidneys to stimulate BM to This cell (rubriblast) gives rise to 2 prorubricyte.
produce MORE red cells Earliest recognizable erythroid precursor using the
Female hormone light microscope
Capable of mitosis= produces 2 prorubricyte each
RBC STAGES OF MATURATION Moderately basophilic with nucleoli
BFU-E → burst forming unit-erythroid Additional information: N:C RATIO → 8:1
 HEMATOLOGY 1
By: RJAR Dinglasan, RMT | 3

○ A morphological feature used to identify and 3. RUBRICYTE (POLYCHROMATIC/ INTERMEDIATE
stage RBC and WBC precursors NORMOBLAST)
○ A visual estimate of what area of the cell is Each of this cell (rubricyte) gives rise to 2
occupied by the nucleus compared with the metarubricyte
cytoplasm “POLY” = many; many colors (CHROMA)
○ If the areas occupied by the nucleus and the May be confused with the lymphocyte
cytoplasm or approximately equal the N:C ratio is ○ LYMPHOCYTE
1:1 Nucleus → CRUSHED VELVET
○ If the nucleus takes up < 50% of the area of the Cytoplasm → SKY BLUE/ “ROBIN EGG”
cell, the ratio is lower ( eg. 1:5 or less than 1) BLUE
○ Is the nucleus takes up > 50% of the area of the ○ RUBRICYTE
cell, the ratio is higher (eg. 3:1 or 3) Nucleus → CHECKERBOARD
Basophilia → pertains to the blueness (BUGHAWWW) Cytoplasm → MUDDY or GRAY
of a particular part of the cell and is due to the acidic LAST stage capable of mitosis
components that attract the basic stain (example: First stage in which the cytoplasm becomes PINK
methylene blue) ○ Cytoplasm of rubricyte = GRAY (because of the
○ Degree of cytoplasmic basophilia correlates with mixture of pink and blue)
the quantity of ribosomal rna SIZE NUCLEOLI NUCLEUS CYTOPLASM
Eosinophilia or acidophilia → pertains to the 10-12 um none Round and Basophilic to
pinkness of a particular part of the cell and is due to smaller, pick diffusely lilac
the accumulation of more basic components that nuclear in color
attract the acid stain eosin membrane, (muddy or
○ As the rbc matures, the eosinophilia of the eccentric gray),
nucleus depending on
cytoplasm correlates with the accumulation of
hemoglobin
hemoglobin. NC ratio= 4:1 content
SIZE NUCLEOLI NUCLEUS CYTOPLASM 4. METARUBRICYTE (ORTHOCHROMATIC/ LATE
12 to 20 um 1 to 2 Round or Small and
NORMOBLAST)
slightly oval, amount,
thin nuclear moderately Nucleus is extruded at this stage, and the cell
membrane, basophilic, becomes a reticulocyte.
central or homogeneous Last stage that the RBC has its nucleus
slightly NC ratio= 8:1 ORTHO- “the same”
eccentric ○ Mature red blood cell = cytoplasm: saHmon pink
2. PRORUBRICYTE (BASOPHILIC NORMOBLAST) Other names: (total number of names: 7)
The prorubricyte gives rise to 4 rubricyte ○ Nucleated RBC
Capable of mitosis= produces 4 prorubricyte ○ Pyknotic erythroblast
No nucleoli and has cell chromatin ○ Acidophilic normoblast
The color of the cell is BLUE PYRENOCYTE
Most helpful criteria in distinguishing the
prorubricyte from the rubriblast
○ 1) Coarser chromatin
○ 2) Absence of nucleoli (pertains to the material
found inside the nucleus)
Last stage with nucleolus
First stage of hemoglobinization (Hb synthesis) ○ Enveloped extruded nucleus
○ Hemoglobin -> eosinophilic material (pink) ○ Engulfed by bone marrow macrophages
○ Although it starts to creates Hb, it cannot be ○ Frequently, small fragments of the nucleus are
seen under the microscope because of small left behind if the projection is pinched off before
amount the entire nucleus is enveloped
SIZE NUCLEOLI NUCLEUS CYTOPLASM The fragments inside the cell are called
10-15 um 0-1 round, thin Appears more HOWELL-JOLLY BODIES when seen in the
nuclear abundant RBCs in the circulation
membrane, than in
Howell-Jolly bodies are typically removed
smaller, normal blast
slightly because of from the rbcs by the splenic macrophage
eccentric smaller pitting crosses once the enter the
NC ratio= 6:1 nucleus circulation
Pag nawala spleen = more HJ bodies in
circulation
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SPLENECTOMY- surgical removal of the SIZE NUCLEOLI & CYTOPLASM
spleen NUCLEUS
SIZE NUCLEOLI NUCLEUS CYTOPLASM 7-8 um None Salmon pink (with a central
8-10 um none Pyknotic salmon pink pallor occupying ⅓ of the
(dense mass cell’s diameter)
of the
degenerated NC Ratio = 1:2 RETICULOCYTES
chromatin) RETICULOCYTE COUNT
5. RETICULOCYTE (DIFFUSELY BASOPHILIC RETICULOCYTE
ERYTHROCYTE) ○ Immature, non-nucleated RBC which contains >2
blue stained, granulofilamentous materials
(RETICULUM) after staining (supravital stains)
In Wright stain, reticulum CANNOT be seen
that’s why it’s called Diffusely basophilic
erythrocytes
○ Continues to generate hemoglobin (last stage)
○ Normal maturation time for reticulocytes in blood:
1 DAY
○ Production of reticulocytes: 50x10^9/L/day

*wright-stained
Last young stage of RBC that appear in the circulation
Last stage of hemoglobin synthesis
Young RBCs containing residual RNA (last immature
erythrocyte stage)
Spends 2-3 days in the bone marrow and 1 day in the
peripheral blood before developing into a mature RBC
Shift Cells (POLYCHROMATOPHILIC MACROCYTE)
○ Seen in cases of increase RBC production
Stress Reticulocytes (MACRO RETICULOCYTES) RETICULOCYTE COUNT
○ Seen in more severe conditions (ex. Hemolytic ○ Permits effective assessment of RBC production by
anemia the bone marrow
SIZE NUCLEOLI & CYTOPLASM ○ A measure of EFFECTIVE ERYTHROPOIESIS
NUCLEUS REFERENCE RANGES:
8-10 um None Cytoplasm still with small ○ Adults: 0.5 to 1.5%
amounts of RNA = ○ Newborns: 1.8 to 5.8% (by 1-2 weeks of age,
polychromasia (mixed pink and reference values are the same as for adults)
blue staining with Golgi ○ Increased (↑) reticulocyte counts (reticulocytosis)
apparatus remnants and aka: POLYCHROMASIA or POLYCHROMATOPHILIA
residual mitochondria that Considered as the first sign of accelerated
allows continued aerobic erythropoiesis and observed in hemolytic
metabolism and hemoglobin
anemias (RBCs are continually lysed in
generation
circulation), individuals with iron deficiency
6. MATURE ERYTHROCYTE
anemia receiving iron therapy, thalassemia,
Shape: biconcave disk sideroblastic anemia, and in acute and
Thickness: 1.5 to 2.5 um chronic blood loss.
Average life span: 120 days When RBC mass is lessened, the BM is
Number of erythrocytes produced from each stimulated to produce more RBCs at a faster
rubriblast: 16 rate (accelerated erythropoiesis) = manifest
Normal ratio of RBCs to WBCs is approximately 600:1 as increased retics (young rbc)
and the normal ratio of RBCs to Platelets is approx. ○ Decreased (↓) reticulocyte counts
15:1 (reticulocytopenia):
Adult RBC contains no mitochondria (no protein or Hb Observed in aplastic anemia and and
synthesis) conditions in which the bone marrow is NOT
producing RBCs
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MATERIALS FLOW CYTOMETRY
SUPRAVITAL STAINS MILLER DISK Most rapid, accurate, and precise method of
1. New Methylene blue reticulocyte count
-More preferred for In this method, the reticulocytes are counted on the
staining retics basis of optical scatter or fluorescence after treatment
-Composed of: with fluorescent dyes or nucleic acid stains
i. Sodium oxalate- The test values in this method or reported in absolute
prevents and in relative terms
coagulation Example: Sysmex R-3500
ii. Sodium Chloride- Calibrated disk placed in ○ Uses auramine O (a supervital fluorescent dye)
provides the ocular of the ○ Reticulocytes fall into low-fluorescence, middle
isotonicity microscope fluorescence or high fluorescence regions, with
Large Square (A) less mature reticulocytes showing higher
2. Brilliant Cresyl blue ○ Is used for counting fluorescence.
-Provides inconsistent RETICULOCYTES ○ Immature Reticulocyte Fraction (IRF) → Sum of
staining results (not Small Square (B) the middle fluorescence, or high fluorescence
preferred) ○ Is used for counting ratios
-Composed of: RBCs Demonstrates an early indication of
i. Sodium citrate- ○ Minimum # of cells erythropoiesis (sensitive index of bone
prevents that should be marrow erythropoietic activity)
coagulation counted: 112 The quantity of reticulocytes with the highest
ii. Sodium Chloride- ○ 1/9th of square A content of RNA
provides Indicates the ratio of immature reticulocytes
isotonicity to total reticulocytes in a blood sample
Used together with ARC to distinguish types
METHODS OF COUNTING RETICULOCYTES of anemia
ROUTINE LIGHT MICROSCOPE METHOD
1. Combine equal amounts of blood and supravital stain NTR: IMPORTANT
(2-3 drops or around 50 uL each), and allow to incubate New methylene blue is chemically different from
at room temperature for 3 to 10 minutes. methylene blue
2. Remix the preparation Brilliant cresyl blue also stains reticulocyte but shows
3. Prepare the two blood smears. too much unpredictability and staining for routine use
4. In the region and which cells are near each other but If a patient is very anemic or polycythemic, their
NOT touching, count to 1,000 RBCs under the oil proportion of dye to blood should be adjusted
immersion objective lens (1000x total magnification). accordingly. For the best results, a larger proportion of
NTR: blood should be added to the stain when the patient
Reticulocytes are included in the total RBC count hematocrit is low. add a smaller amount of blood to
Reticulocytes are counted as both an rbc and a the stain when the patient has a very high hematocrit.
reticulocyte The time allowed for staining of the reticulocyte is NOT
5. To increase accuracy, have another medtech count the critical. it should not, however, be less than 10
other blood smear; count should agree within 20%. minutes.
6. Calculation: Increased blood glucose or the use of heparin as
𝑁𝑜. 𝑜𝑓 𝑅𝑒𝑡𝑖𝑐𝑠 𝑜𝑏𝑠𝑒𝑟𝑣𝑒𝑑 anticoagulant may cause the reticulocytes to show fail
𝑅𝑒𝑡𝑖𝑐 (%) = 1,000 𝑅𝐵𝐶𝑠 𝑜𝑏𝑠𝑒𝑟𝑣𝑒𝑑 𝑥 100
staining.
The blood and stain should be mixed well prior to
making smears. The reticulocytes have a lower specific
CALIBRATED MILLER DISK METHOD gravity than mature erythrocytes and, therefore, settle
Count a minimum of 112 RBCs in a small square (b). on top of the red blood cells in the mixture.
Reticulocyte in square be is counted as both an
erythrocyte and reticulocyte. OTHER RBC INCLUSIONS STAINED BY NMB:
At this point, theoretically, the number of retics and INCLUSIONS COLOR (NMB) REMARKS
1008 RBCs has been counted. Howell-Jolly Deep purple Nuclear
Computation fragments
𝑇𝑜𝑡𝑎𝑙 𝑟𝑒𝑡𝑖𝑐𝑠 𝑖𝑛 𝑆𝑞𝑢𝑎𝑟𝑒 𝐴
𝑅𝑒𝑡𝑖𝑐𝑠 (%) = (𝑇𝑜𝑡𝑎𝑙 𝑅𝐵𝐶𝑠 𝑖𝑛 𝑆𝑞𝑢𝑎𝑟𝑒 𝐵 𝑥 9) 𝑥 100 Heinz bodies Light blue green -Usually present
at thePeripheral
edge of the red
cell
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-Denatured and ○ IRF is high because BM is starting to accelerate
precipitated RBC production
hemoglobin CORRECTED RETICULOCYTE COUNT
Pappenheimer Purple -Generally appear Sometimes referred to as:
bodies as several ○ Reticulocyte index (RI)
granules in a ○ Hematocrit correction
small cluster ○ Poor man's bone marrow aspirate
-A wright-stained The percentage of reticulocytes may appear increased
or prussian blue because of early reticulocyte release into the
stained smear circulation or because of a decrease in the number of
may be examined mature cells in circulation. (ANEMIA may cause falsely
to confirm their ↑ reticulocyte count)
presence The CRC corrects the observed reticulocyte count to a
-Hemosiderin in normal Hct of 0.45 L/L (average normal for both
the mitochondria genders) to allow correction for the degree of patient’s
Hemoglobin H Greenish-blue -Multiple small anemia.
bodies dots in and form Formula:
𝐻𝑐𝑡 𝑖𝑛 𝐿/𝐿
of alpha 𝐶𝑅𝐶 = 𝑅𝑒𝑡𝑖𝑐𝑠 (%) 𝑥 0.45 𝐿/𝐿
thalassemia
SAMPLE CASE
METHODS OF COUNTING RETICULOCYTES Patient: Male, 29 y.o.
ABSOLUTE RETICULOCYTE COUNT (ARC) Lab results:
Actual number of reticulocytes in 1 liter of whole blood Hct = 28% (0.28 L/L) - anemia = low rbc mass
Helps us determine what kind of anemia is present Retic ct. = 5% (MAY BE high bc of accelerated
Computation: erythropoiesis or falsely elevated bc of anemia)
12
𝑅𝐸𝑇𝐼𝐶𝑈𝐿𝑂𝐶𝑌𝑇𝐸𝑆 (%) 𝑥 𝑅𝐵𝐶 𝐶𝑂𝑈𝑁𝑇 (𝑥10 /𝐿)
○ NV: 0.5-1%
𝐴𝑅𝐶 = 100
𝑥 1000 BM should produce RBC at a faster rate; accelerating
Reference range: 25 to 75 X10^9/L erythropoiesis
Used together with IRF to distinguish types of
anemias:

CONDITION ARC IRF
CRC = 3.11% -> HIGH (truly ↑)
Hemolytic Anemia (an anemia ↑ ↑
with ↑ marrow erythropoiesis)
Hemorrhage ↑ ↑ RETICULOCYTE PRODUCTION INDEX
RPI (Also known as SHIFT CORRECTION) provides a
Chronic Renal Disease ↓ ↓
further refinement of the CRC.
Early Response to therapy in Normal ↑
A general indicator of the rate of erythrocyte
nutritional anemias to ↓
production increase above normal in anemias.
Hemolytic anemia and Hemorrhage have increased:
Calculation:
○ ARC → BM is compensating for the loss of RBCs in 𝐶𝑂𝑅𝑅𝐸𝐶𝑇𝐸𝐷 𝑅𝐸𝑇𝐼𝐶𝑈𝐿𝑂𝐶𝑌𝑇𝐸 𝐶𝑂𝑈𝑁𝑇
the circulation by creating more RBCs in an 𝑅𝑃𝐼 = 𝑀𝐴𝑇𝑈𝑅𝐴𝑇𝐼𝑂𝑁 𝑇𝐼𝑀𝐸 𝐼𝑁 𝑇𝐻𝐸 𝑃𝐸𝑅𝐼𝑃𝐻𝐸𝑅𝐴𝐿 𝐵𝐿𝑂𝑂𝐷
accelerated rate
○ IRF → BM is actively producing RBC (an increased HEMATOCRIT (%) MATURATION TIME (Days)
IRF means BM is creating erythrocytes, because 40-45 1.0
IRF is the younger form of reticulocytes) 35-39 1.5
Chronic Renal Disease → BM of patient is not 25-34 2.0
producing enough RBC anymore (↓ ARC) 15-24 2.5
○ Take note: Kidneys create erythropoietin, the 3 ADEQUATE BM RESPONSE
also no longer stimulated to produce more RBCs.
RPI 8.0 um) RBCs (diameter ⅓ of diameter spherocytosis
Usually microcytic
GRADING OF HYPOCHROMIA (HARMENING) POLYCHROMATOPHILIC ERYTHROCYTES
1+ Area of central pallor = ½ of diameter
2+ Area of central pallor = ⅔ of diameter
3+ Area of central pallor = ¾ of diameter
4+ Thin Rim of Hb (ANULOCYTE)
ANULOCYTE
○ A.k.a. “PESSARY CELL or GHOST CELL”
○ RBC with thin rim of hemoglobin and a large, clear
center When Wright’s stain is used it is called DIFFUSELY
○ May be observed in iron deficiency anemia BASOPHILIC ERYTHROCYTE
Larger than normal red cells with bluish tinge (wright’s
HYPERCHROMIC CELLS stain)
Bluish tinge →Caused by the presence of residual RNA
Large numbers: associated with decreased RBC
survival, hemorrhage or erythroid hyperplastic marrow.
GRADING OF POLYCHROMASIA
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Grade Percentage of Polychromatophilic RBCs deficiency, hepatic
Slight 1% hemangioma, neonatal
hepatitis, after heparin
1+ 3%
administration, post
2+ 5% splenectomy, cirrhosis
3+ 10% of the liver with
4+ >11% associated hemolytic
anemia.

BURR CELL RBCs with regularly Uremia - characterized
“ECHINOCYTES” spiculated surface by:
marked ↑ in
plasma urea and
POIKILOCYTOSIS other nitrogenous
Increased number of red cells with variation in SHAPE waste products
Acidemia
RED CELL DESCRIPTION EX. OF CONDITIONS
electrolyte
SPHEROCYTE Almost spherical in Hereditary
imbalance (K+
shape; lacks the spherocytosis,
elevation)
central pallor autoimmune hemolytic
normocytic,
anemia, burns, ABO
normochromic
HDN, and following
anemia
transfusion of stored
uremic frost (dirty
blood
skin)
NTR:
generalized
Hyperchromic Spherocytes me be
edema
wrongly reported if one
foul breath
examines the feathered
urine-like sweat
edge of the blood film
Pyruvate kinase
because the RBCs in
deficiency
the said area lack
OVALOCYTE Oval-shaped RBCs Hereditary Ovalocytosis
central pallor
“SOUTHEAST
Natural rbc death can ASIAN
result to spherocytic OVALOCYTOSIS”
RBC ELLIPTOCYTE Elliptical -Hereditary
Rh Deficiency (cigar-shaped) RBC Elliptocytosis
STOMATOCYTE Elongated RBCs with
syndrome, Alcoholism, -Thalassemia “Hered.
“MOUTH CELL” the slit like central Leptocytosis,
pallor (may be electrolyte imbalance,
severe liver diseases, Mediterranean
considered as an Anemia”
overhydrated More oval than that
artifact) hereditary
of ovalocyte
stomatocytosis

Dehydrated hereditary DACRYOCYTE Pear-shaped or Primary Myelofibrosis
stomatocytosis “TEARDROP teardrop shaped (PMF) (previously
(HEREDITARY CELLS” RBCs known as myelofibrosis
XEROCYTE: with myeloid
XEROCYTOSIS)
→ Most common form metaplasia, chronic
of stomatocytosis idiopathic
→ Characterized by the myelofibrosis,
presence of xerocytes agnogenic
XEROCYTES: myelofibrosis)
- a dehydrated form of - an example of an
a stomatocytes MPN
- appears to have (myeloproliferative
puddled at one hand neoplasm)
(half-dark, half-light) some of the
Abetalipoproteinemia characteristics:
ACANTHOCYTE RBCs with irregularly
“BASSEN-KORNZWEIG -splenomegaly
“THORN CELL or spiculated surface
SYNDROME and -in the marrow:
SPUR CELL”
HEREDITARY hypercellularity,
ACANTHOCYTOSIS” increased
→ Characterized by megakaryocytes, and
defective apo B fibrosis
synthesis - in the PBS: immature
→ VLDL, LDL, granulocytes,
chylomicron: NOT normoblasts,
found in plasma dacryocytes, and other
bizarre RBC shapes
McLeod syndrome,
Pyruvate kinase Megaloblastic Anemia,
myelophthisic anemia,
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after Heinz body DREPANOCYTE Sickle- or Sickle cell anemia,
formation induced by “SICKLE CELLS or crescent-shaped Hemoglobin SC disease,
drug ingestion, MENISOCYTES” RBCs etc.
tuberculosis, tumor
metastasized to the
Two forms of drepanocytes:
bone marrow, 1.) ISC (Irreversible sickle cells)
thalassemia, and some Crescent shaped with long
hemolytic anemias projections
When reoxygenated: may
SCHISTOCYTE Fragmented RBCs Patients with artificial undergo fragmentation
“SCHIZOCYTE” heart valves, uremia,
severe burns, MAHAs
(microangiopathic 2.) OAT-SHAPED CELLS
hemolytic anemias): Less pronounced projections
-group of disorders When oxygenated, they return to
characterized by RBC the original biconcave disk shape
fragmentation and
thrombocytopenia
-major MAHAs: TTP,
LEPTOCYTE RBCs which show a -Liver disease Certain
HELLP, HUS, and DIC
“CODOCYTE, centrally stained hemoglobinopathies
-characterized by
PLATYCYTE, area with a thin Thalassemia (Hered.
narrowing or
GREEK HELMET Leptocytosis &
obstruction of small outer rim of
CELL, MEXICAN Mediterranean
blood vessels by fibrin hemoglobin Anemia)
HAT CELL,
or platelet aggregates
BULL’S EYE CELL, -LCAT deficiency
resulting in the
TARGET CELL” “Lecithin Cholesterol
fragmentation of RBCs
acyltransferase
-Helmet cell = helmets
(“lecithin cholesterol
shaped schistocyte that
acyltransferase”)
may appear in MAHA

TTP (thrombotic
thrombocy-
BITE CELL Demonstrate a Glucose-6-Phosphate
topenic purpura)
“DEGMACYTE” semicircular defect Dehydrogenase
HELLP syndrome
in their edge (G-6-PD) deficiency
(hemoly- sis,
elevated liver (resembles a bite
BOARD EXAM reg.
enzymes, low mark) G6PD
platelet count)
Poikilocyte → Bite cell
HUS (hemolytic
Inclusion → Heinz
uremic syndrome)
Bodies
-associated with
BISCUIT CELL Folded RBCs Hemoglobin SC disease
Escherichia coli
serotype SEMILUNAR -As large as Frequently seen in
O157: H7 infection BODIES leukocytes malaria and in other
-characterized by: -Pale-pink staining conditions causing
renal failure, overt hemolysis
ghost of the red cell
thrombocytopenia, HbsC
(the membrane
schistocytes (PBS), and
remaining after the
severe mucocutaneous
Hemorrhage contents been
DIC (disseminated released)
intravas- cular -Folded RBCs
coagulation) BRONZE -Bipolar/ Central Sickle cell anemia
*Additional information about DIC ELLIPTOCYTE distribution of Hgb
“DEFIBRINATION SYNDROME and CONSUMPTION
COAGULOPATHY” RBC INCLUSION BODIES
Generalized over-activation of the coagulation and INCLUSION CONTENT VISUALIZATION ASSOCIATED
fibrinolytic systems CONDITIONS
Not a disease but a result of a particular disease OR BASOPHILIC Aggregated Wright stain -Lead
manifestation of an underlying disease STIPPLING RNA (deep blue to poisoning
Some of the tests: D-dimer test and PF 1+2 (Prothrombin “PUNCTATE purple) (PLUMBISM)
Fragment) BASOPHILIA” Supravital stain -Arsenic
related conditions: T O M A S A poisoning
-Pyrimidine-5’-
○ Tissue Trauma
nucleotidase
○ Obstetric complication deficiency
○ Mucus-secreting tumor -Anemias with
○ Acute infections (ex: Malaria, Gram neg. septicemia) impaired
○ Snake bites hemoglobin
○ Acute Promyelocytic Leukemia synthesis (ex:
 HEMATOLOGY 1
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Thalassemia) severe
-Refractory hemolytic
anemias episode)
-Alcoholism -expected
-Megaloblastic inclusion
anemias bodies in
Two forms of basophilic stippling: favism: HEINZ
a.) Fine stippling – usually observed when there is increase BODIES
polychromatophilia -Drug-induced
b.) Coarse stippling – may be observed in plumbism or other disorders hemolytic
with impaired Hb synthesis, in megaloblastic anemia, and in other Anemias
forms of severe anemia (DIHA)
SIDEROTIC Intraerythrocyt Iron stains: -Sideroblastic -Unstable
GRANULES ic collections of -Perls’ reagent Anemias hemoglobin
“PAPPENHEIM iron through =characterized disease
ER BODIES“ Prussian Blue by a dimorphic (congenital
Rxn peripheral Heinz body
(described as -Called: blood picture hemolytic
multiple dark SIDEROTIC (presence of anemia)
blue irregular GRANULES BOTH examples of Unstable Hemoglobin Variants: 1.) Hb Köln 2.) Hb
granules [in normochromic Casper/Southampton 3.) Hb Genova 4.) Hb Gun Hill 5.) Hb M-Saskatoon
Prussian blue New and 6.) Hb Bristol 7.) Hb Torino 8.) Hb Seattle
iron staining]) Methylene hypochromic HEMOGLOBIN Precipitated Hb Supravital Hb H Disease (a
(described as Blue and RBCs in the H INCLUSION H (Hb H – an stain: (subtype of
pale blue Wright stain: same blood BODY abnormal Hb - NMB alpha
clusters [in -Called: smear) composed of 4 - BCB thalassemia)
Wright PAPPENHEIME -Thalassemia (described as β (beta) globin
staining]) R BODIES -Hemochromat small, multiple, chains) NOTE:
osis or evenly (denatured Appearance of
Hemosiderosis distributed β-globin RBCs with Hb H
HOWELL-JOLLY Remnants of -Wright stain -Megaloblastic throughout the chains) Bodies:
BODIES nuclear New anemias red cell, -NOT “PITTED GOLF
(description: chromatin -Methylene -After granular, demonstrated BALL”
frequently (DNA) Blue splenectomy greenish-blue using Wright’s
appears singly -Feulgen -Thalassemia bodies) stain
in a cell (only reaction (+)
one per cell), (*histochem.
usually round, staining PARASITES -Protozoa/Prot Wright stain Parasitic
and 10
cells/Greek helmet cells/ (Pappenheimer
platycytes) bodies)
Rouleaux formation “PSEUDO
AGGLUTINATION” HEMOGLOBIN
Aggregation of RBCs REFERENCE RANGE
Caused by a serum AGE GROUP CONVENTIONAL SI UNIT
protein abnormality UNIT
(↑ fibrinogen or ↑ Children (8 to 13 y.o.) 12 to 15 g/dL 120 to 150 g/L
globulins) Adult (male) 14 to 18 g/dL 140 to 180 g/L
Often seen in Adult (female) 12 to 15 g/dL 120 to 150 g/L
MULTIPLE
MYELOMA(now HEMOGLOBIN
called: PLASMA Main component of the red blood cell (approximately
CELL MYELOMA) 95% of the cytoplasmic content of RBCs)
also known as the: RESPIRATORY PIGMENT
“STACKS OF COINS”
concentration of Hb within RBCs: approximately 34
appearance of red cells
g/dL
Rouleaux may be wrongly molecular weight: approximately 64,000 Daltons
reported if one examines the Felix Seyler identified the respiratory protein
thick part of the blood film Hemoglobin (in 1862)
because the red blood cells in About 65% of cytoplasmic hemoglobin is produced
the said area are overlapping. before the nucleus is extruded, and the remaining 35%
Sickle cells Basophilic stippling Whenever present, grade as is synthesized in the early reticulocyte
Pappenheimer bodies POSITIVE ONLY Single most common complex organic molecule in
Howell-Jolly bodies vertebrates
1 gram of hemoglobin can carry 1.34 mL of O2.
SAMPLE CRITERIA FOR RBC MORPHOLOGY EVALUATION 1 gram of hemoglobin can carry a constant 3.47 mg
MORPHOLOGY WNL 1+ 2+ 3+ 4+ IRON
CHARACTERISTICS +
Macrocytes > 9 0-5 5-10 10-20 20-50 >50
um
COMPLETE ADULT Hgb MOLECULE IS COMPOSED OF 4
Microcytes 50 DIFFERENT CONSTITUENTS:
Hypochromia 0-2 3-10 1052 50-75 >75 1.) A protein component (globin) composed of two sets of
0 two different polypeptide chains.
Poikilocytes 0-2 3-10 10-20 20-50 >50 Globin (protein) is made out of amino acids
(generalized 2.) Four molecules of the nitrogenous protoporphyrin IX
variations in with hole (ring) in the middle.
shape) 3.) Four iron atoms in the ferrous form (Fe+2) that combine
Burr cell 0-2 3-10 10-20 20-50 >50 with protoporphyrin IX to create the four heme molecules
Acantohocytes 50 or FERROPROTOPORPHYRIN IX.
Schistocytes 50 4.) One 2,3-BPG molecule as a transient resident in the
Teardrop 0-2 2-5 5-10 10-20 >50 center of the hemoglobin unit.
poikilocytes
(dacryocytes)
GLOBIN CHAIN IN HEMOGLOBIN
Target cell 0-2 2-10 10-20 20-50 >50
GREEK GREEK NAME NUMBER OF AMINO ACIDS
(codocytes)
DESTINATION
Spherocytes 0-2 2-10 10-20 20-50 >50
Alpha 141
Ovalocytes 0-2 2-10 10-20 20-50 >50
Stomatocytes 0-2 2-10 10-20 20-50 >50 Beta 146
Sickle cell A Report as 1+ to indicate
(drepanocytes) presence; do not quantitate
Delta 146
Polychromatophili 20
a (ADULT) YA Gamma A 146 (position
Polychromatophili 1-6 7-15 15-20 20-50 >50 136: alanine)
a (NB) YG Gamma G 146 (position
Basophilic 0-1 1-5 5-10 10-20 >20 136: glycine)
stippling E Epsilon 146
Howell-jolly A 1-2 2-5 5-10 >10 Z Zeta 141
bodies
 HEMATOLOGY 1
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Theta Unknown Resolved through: Centrifuge
reagent-sample solution,
then the supernatant is
PRIMARY FUNCTION OF HEMOGLOBIN measured
1. Delivery of oxygen to the tissues
2. To carry waste product CO2 away to the lungs Lipemia (Turbidity) Caused by fatty foods
3. Binding, inactivation, and transport of NO (Nitric Oxide)
Add 0.01 mL of the patient’s
plasma to 5 mL of the
cyanmethemoglobin reagent
and using this solution as the
reagent blank
PROTEIN STRUCTURE OF HEMOGLOBIN
Fasting is not a requirement
PROTEIN STRUCTURE REMARKS Cells containing HB S and HB C Abnormal hemoglobin that
PRIMARY describes the amino acid cause turbidity in sample if
sequence of the polypeptide not lysed
chains Make a 1:2 dilution with
SECONDARY describes the chain distilled water (1 part diluted
arrangements in helices and sample plus 1 part water)
nonhelices. and multiplying the results
TERTIARY describes the arrangement of from the standard curve by 2.
the helices into a pretzel-like Abnormal globulins (such as Can easily precipitated in the
configuration or formation those found in patients with solution
QUATERNARY (TETRAMER) describes the complete plasma cell myeloma or Add 0.1 gram of potassium
hemoglobin molecule Waldenstrom carbonate to the
(complete hemoglobin macroglobulinemia) may cyanmethemoglobin reagent.
molecule is spherical, has precipitate in the reagent. Commercially available
four heme groups attached cyanmethemoglobin reagent
to four polypeptide chains, has been modified to contain
and may carry up to four KH2PO4 salt, so this problem
molecules of oxygen) is NOT likely to occur.
Reminders:
HEMOGLOBINOMETRY (HEMOGLOBIN DETERMINATION) ○ Cyanmethemoglobin reagent is sensitive to light
Measurement of hemoglobin (should be stored in a brown bottle or in a dark
Reference method: Cyanmethemoglobin (HiCN) place)
Method (standard, best and most widely used) ○ Another technique that has been used in some
○ Principle: Hemoglobin (Fe2+) + K3Fe (CN)6 → automated instruments involves the use of
methemoglobin (Fe3+) + KCN → sodium lauryl sulfate (SLS) to transform
cyanmethemoglobin hemoglobin to SLS-methemoglobin. This method
○ Ideal specimen: Fasting blood specimen (but not does NOT produce toxic wastes.
required) ○ HemoCue –an example of a commercially
○ Uses Drabkin’s reagent - major components: available handheld system to measure the
Potassium ferricyanide (K3Fe(CN)6) hemoglobin concentration
converts the hemoglobins into Parameter: ONLY hemoglobin
methemoglobin Screen potential donors → BB section
Potassium cyanide (KCN) In here, hemoglobin is converted to
Provides cyanide ions azidemethemoglobin and is read
HiCN is measured at 540 nm (spectrophotometer) (All photometrically at two wavelengths (570
types of Hb may be measured through this method, nm and 880 nm).
EXCEPT: SULFHEMOGLOBIN - cannot be converted to
cyanmethemoglobin HEMOGLOBIN ELECTROPHORESIS
○ Turbid = falsely elevated Electrophoresis - movement of charged particles in an
Possible source of error: electric field
SOURCE OF ERROR (FALSE CORRECTION CELLULOSE ACETATE (pH 8.4-8.6)
ELEVATED Hb) Considered as the primary screening procedure to
High WBC count Values of High WBC (>20 x detect variant (abnormal) hemoglobins
High platelet count 10^9) and High PLT ct (>700 x In an alkaline buffer (8.4 to 8.6) hemoglobin is a
10^9/L) negatively charged molecule
 HEMATOLOGY 1
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During electrophoresis, the Hb molecules travel
toward the anode (+) because of their net negative
charge
○ Positive pole - anode
○ Negative pole - cathode
○ Positively charged ions - cations
○ Negatively charged ions - anions
The difference in the net charge of the Hb molecule Complementary procedure to cellulose acetate Hb
defines its mobility and reveals itself by the speed electrophoresis (something that completes)
with which it migrates to the positive pole. Hemoglobin exposed to acidic environment →
FASTEST = Hb H (an abnormal hemoglobin; composed different charges
of 4 beta globin chains; not found in normal
individuals; exist in circulation of individual with
Hemoglobin H disease)
○ In normal individuals, the fastest si Hb A1
○ If ever coexisting happens (both Hb A and Hb H
present), Hb H is still faster than Hb A
SLOWEST = Hb C, HbA2, Hb E, Hb CHarlem, Hb OArab
○ same migration pattern → cannot identify what Some are negative charge, some are positive charge
type of hemoglobin present ○ F,A,A2 might be positively charged while S and C
NOTE: Hb S, Hb D and Hb G migrate to the same area might be negatively charged
at cellulose acetate electrophoresis → difficult to Used to confirm variant hemoglobins and further
identify what type of hemoglobin present differentiates hemoglobin S from D and G, and
hemoglobin C from hemoglobins E, OArab, CHarlem
○ Ex. Patient 4 in Cellulose acetate develop band in
S portion and also developed band in S portion of
Citrate agar → confirmed na Hb S

HEMOGLOBIN SYNTHESIS
HEME SYNTHESIS
HEME a.k.a. Ferroprotoporphyrin IX
Belongs to class of pigments known as porphyrins
Site of heme synthesis: Mitochondrion
Heme biosynthesis:
○ occurs in all metabolically active cells containing
mitochondria
○ most prominent in bone marrow and liver.
○ Erythroid marrow is the MAJOR heme-forming
tissue, generating 85% of the daily heme
requirement.
Ferrochelatase - aka: Heme synthetase - enzyme needed to
insert the Ferrous form of iron to the center of
protoporphyrin IX

Numbers: Patient sample
Letters: Legend
Bottom to top orientation
Patient 2: hemoglobin exposed in alkaline buffer →
develop a net negative charged→ hb A (same as Hb
A1)
Patient 4: develop a net negative charged (migrate
toward the anode) → Hb S (possible but not finally) →
same migration pattern as Hb D and Hb G

CITRATE AGAR (pH 6.0-6.2)
 HEMATOLOGY 1
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FUNCTIONAL Hgb
OXYHEMOGLOBIN DEOXYGENATED Hgb
Symbol: HbO2 Hb w/ Fe2+, NOT
Hb w/ Ferrous form of bound to oxygen
iron + Oxygen Found in venous
Found in arterial blood blood (Dark Red)
(bright red) Conformation of
Conformation of Hb in Hb in the
the oxygenated state: R deoxygenated
state (relaxed) state: T state
MedTech does not (Tense)
perform arterial puncture
Glycine + Succinyl-CoA → within the mitochondrion
Aminolevulinic Acid → Cytosol DYSHEMOGLOBINS
Protoporphyrin IX (ring form) + Ferrous form of iron CARBOXYHEMOGLOB METHEMOGLOBIN SULFHEMOGLOBIN
(FE) = heme IN
Must be ferrous form Symbol: HbCO Symbol: Hi Symbol: SHb
Hb w/ Fe2+ Other names: Mixture of
(Ferrous ferrihemoglob oxidized,
GLOBULIN SYNTHESIS form), bound in, partially
Site: ribosomes in the normoblast cytoplasm to CO (carbon hemoglobin denatured
Chromosome 16 = dictates the production of A and Z monoxide) Hb w/ Fe3+ forms of Hb
Chromosome 11 = dictates the production of B,E,D and Carbon (ferric form), Causes:
G globin chains monoxide - NOT bound to Prolonged
FORMS OF HEMOGLOBIN (ACCORDING TO STAGE OF LIFE) form of O2 constipation,
poison, can Color of enterogenous
HgB MOLECULAR PROPORTION PROPORTION lead to death blood cyanosis,
STRUCTURE (%) IN NB (%) IN ADULTS in large (methemoglo bacteremia
(older than 1 quantity binemia): (caused by C.
yr) CO gas Chocolate perfringens)
- Has 240 times brown Color of
Portland ζ2γ2 0 0
greater affinity blood:
2 zeta, 2
to Hb than O2 Mauve-Laven
gamma
- Tasteless, der
Gower I ζ2ε2 0 0
colorless and
2 zeta, 2
odorless gas NOTE:
epsilon
- Color of blood In-vitro,
Gower II α2ε2 0 0
and skin in HbCO sulfhemoglobin
2 apha, 2
poisoning: forms when
epsilon
(SHERRY) cherry hydrogen sulfide is
F (Fetal Hb) α2γ2 80 37 mm/h has higher samples are then left to sediment for a specific period
incidence of disease progression and death 18-degree slant of the tubes with respect to the
○ In coronary artery disease: ESR >22 mm/h in vertical axis: causes acceleration in sedimentation,
white men had high risk of CAD allowing results comparable to those of Westergren at
○ In patients with known cancer: when value the 1st hour to be obtained in only 25 minutes, while
exceeds 100 mm/h, metastases are usually those comparable to Westergren at the 2nd hour
present. require only 45 minutes
○ ESR - indicated in establishing the diagnosis and The optoelectronic sensors automatically read the RBC
in monitoring polymyalgia rheumatica and sedimentation level.
temporal arteritis (rate typically exceeds 90 REFERENCE RANGE
mm/hr) AGE GROUP MODIFIED WINTROBE
○ Moderate elevations - common in active WESTERGREN
inflammatory disease like rheumatoid arthritis, Adult (male) 0 to 10 mm/hour 0 to 9 mm/hour
chronic infections, collagen disease, and Adult (female) 0 to 15 mm/hour 0 to 20 mm/hr
neoplastic disease (NOTE: ESR has little diagnostic Female - mas mabilis magfall ang RBC
value in these disorders, but can be useful in STAGES OF RBC SEDIMENTATION
monitoring disease activity) FIRST 10 MINS NEXT 40 MINS LAST 10 MINS
REMINDERS: Lag Phase Decantation Final settling
Rouleaux phase phase
ESR is prone to technical errors.
formation occurs Rapid and RBC
ESR has low specificity and sensitivity. Therefore, it is
○ Rouleaux constant sedimentatio
NOT recommended as a screening test to detect formation - RBC n is slower
inflammatory conditions in asymptomatic individuals.
 HEMATOLOGY 1
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aggregation sedimentati Diabetes mellitus
of RBC on End-stage renal
○ Increased failure
Fibrinogen Hepatitis
or Globulins Gout
→ bibilis Malignancy
bagsak RBC Menstruation
→ mas Multiple
mabilis ESR Myeloma
APRs (acute Waldenstrom’s
phase reactants) macroglobulinemia
→ proteins that Myocardial
increase in infarction
inflammation Rheumatic fever
○ Fibrinogen, Rheumatoid
Globulins arthritis
Syphilis
DYSHEMOGLOBINS Temporal arteritis
FACTORS ESR INCREASED ESR DECREASED Nephrosis
Proteins and lipids ↑ cholesterol ↑ albumin Tuberculosis
in the blood ↑ fibrinogen ↑ glucose Adults over 60
↑ gamma globulins ↑ bile salts years of age
↓ albumin ↑ phospholipids (frequently have
↓ fibrinogen a slightly higher
↓ gamma globulins ESR value due
primarily to
Red blood cells Anemia Polycythemia
decreased
(decreased RBC) (increased RBC)
concentrations of
Macrocytosis Anisocytosis
plasma albumin)
(marked)
Pregnancy
Microcytosis
Acanthocytosis Technique Refrigerated Clotted blood
Hemoglobin C sample NOT sample
Sickle cells returned to room Delay in testing
Spherocytosis temperature Bubbles in ESR
Thalassemia High room column
temperature Low room
White blood cells Leukemia Leukocytosis
Vibration temperature
(marked)
Tilted ESR tube Narrow ESR
Drugs Dextran Adrenocorticotro
column diameter
Heparin pic hormone
Penicillamine (corticotropin)
Procainamide Cortisone NTR:
Theophylline Ethambutol Tilted ESR tube- “A tilt of as little as 30 from the vertical can
Vitamin A Quinine cause error of up to 30 → Place on a flat surface ; tubes
Salicylates must be placed in a separate stable surface/table → vibrate
Clinical conditions Inflammatory Cachexia will accelerate yung pagbaba ng RBC sa bottom
conditions Congestive heart
(associated with failure
CASE STUDY
increased plasma Newborn status
proteins, Because of lack of space in the laboratory, the rack of
particularly, sedimentation rate tubes was placed directly on top of a
fibrinogen, alpha small refrigerator. What are the three possible effects on
globulins, and beta the ESR results?
globulins) 1. A falsely decreased (↓) ESR– because of lower
Infections (acute temperatures from air rushing out on opening the
and chronic) refrigerator or freezer
Subacute
2. A falsely increased (↑) ESR – because of vibrations from
bacterial
endocarditis
opening and closing the refrigerator and freezer doors
Acute heavy 3. A falsely increased (↑) ESR – because of heat released
metal poisoning from the refrigerator motor
Collagen vascular Must be at room temp
diseases
GENERAL OVERVIEW OF ANEMIA
 HEMATOLOGY 1
By: RJAR Dinglasan, RMT | 23

ANEMIA ○ Described as a rare but potentially deadly bone
Manifestation of the diseases marrow failure
defined as the decrease below normal of one or more ○ Characteristic features:
of the following: Pancytopenia (marked decrease in the
○ Number of red blood cells number of RBCs, WBCs, and platelets in the
○ Hemoglobin blood)
○ Volume of packed red cells (hematocrit) Reticulocytopenia
○ Bone marrow hypocellularity
MECHANISM OF ANEMIA: Depletion of hematopoietic stem cells
HEMORRHAGE ○ May be classified as:
Loss of erythrocytes through bleeding must always be Acquired aplastic anemia
the INITIAL FOCUS in any patient with anemia and Approximately 80% to 85% of aplastic
must prompt an evaluation of the hemostatic system. anemia cases
Bleeding - may be secondary to trauma, surgery, or a 2 categories
disease ○ Idiopathic acquired aplastic
Gastrointestinal tract - a common site for clinically anemia - no known cause
significant bleeding ○ Secondary acquired aplastic
Menstruation – a significant source of blood loss in anemia
women Associated with an
○ Automatic ba na nagkaka anemia during identified cause
menstruation? Some causes include
NO especially if you are eating well (iron Chemicals (insecticides,
rich food) benzene)
HEMOLYSIS Viruses (Epstein-Barr
shortened erythrocyte survival time NOT explained by virus)
bleeding Drugs
average survival time of RBCs after leaving bone (Chloramphenicol) -
marrow: 120 days most frequently
implicated in acquired
DECREASED PRODUCTION OF ERYTHROCYTES aplastic anemia
Nutritional deficiencies (iron, vitamin B12, or folic acid) Inherited Aplastic Anemia
are common and readily correctable causes of Approximately 15% to 20% of aplastic
hypoproliferative anemia. anemia cases
Kidney disease may be associated with decreased Associated diseases:
production of EPO ○ Dyskeratosis congenita
○ Shwachman-Bodian-Diamond
MORPHOLOGIC CLASSIFICATION syndrome
More commonly used