ppt 9

Question 1

Hematology Tests

Answer 1

• White cell count 
• White cell differential 
• Red cell count 
• RBC morphology 
• Hematocrit (HCT) 
• Hemoglobin (Hb) 
• Indices
– MCV
– MCH
– MCHC
• Sedimentation Rate 
• Methemoglobin 
• Iron and Total Iron
Binding Capacity 
• Platelet count

Question 2

Coagulation Tests

Answer 2

• Bleeding Time
• Prothrombin Time 
• Plasma Thrombin Time
• Plasma Fibrinogen
• Fibrin Split Products
• Partial Thromboplastin time
• Activated (Whole Blood)
Clotting Time

Question 3

White Cell Count

Answer 3

• Total number of WBCs (estimated)
– performed by machine
– normal range: 4 -10.5 thousand/cubic millimeter 
• There are five types of WBCs:
- neutrophils 
- lymphocytes 
- monocytes 
- eosinophils 
- basophils

Question 4

Leukocytosis may also occur after:

Answer 4

• epilepsy
• pregnancy and child birth
• anesthesia
• splenectomy (removal of the spleen)

Question 5

Left shift

Answer 5

• is an increase in the number of immature neutrophils (band cells) in the peripheral blood (their normal amount is 2-6% of all neutrophils)
• usually occurs in:
  - inflammation
  - infection
  - cancer

Question 6

Right shift

Answer 6

• in the ratio of immature to mature neutrophils is considered with reduced count or lack of “young neutrophils” (metamyelocytes, and band neutrophils) in blood smear, associated with the presence of “giant neutrophils”
• This fact shows the suppression of bone marrow activity

Question 7

Leukopenia (leukocytopenia or leucopenia)

Answer 7

• is a decrease in the number of white blood cells (leukocytes)
  found in the blood
  • Leukopenia develops due to:
  
  • immunodeficiency disorders
  • chemotherapy
  • radiation therapy
  • some medications (e.g. immunosuppressive drugs)

Question 8

Normal values Neutrophils

Answer 8

= 50 - 65%

2–5 lobes of nucleus

Question 9

Normal values Lymphocytes

Answer 9

= 20 - 35%

Question 10

Normal values Monocytes

Answer 10

= 2 - 8%

Question 11

Normal values Eosinophils

Answer 11

= 1 - 6%

2 lobes of nucleus

Question 12

Normal values Basophils

Answer 12

= 0.5 -1%

2 - 3 lobes of nucleus

Question 13

polymorphonuclear

Answer 13

• more than one lobe of nucleus
• also known as granulocytes
• neutrophils (2–5 lobes of nucleus)
• eosinophils (2 lobes of nucleus)
• basophils (2 - 3 lobes of nucleus)

Question 14

mononuclear

Answer 14

• single nucleus
• also known as agranulocytes
• lymphocytes
• monocytes

Question 15

Function of neutrophils:

Answer 15

• first WBC to enter to the site of acute inflammation
• phagocytosis
  • Their increase is associated with:
• bacterial infection
• fungal infection
• inflammation
  • Lifetime of neutrophils: 6 hours – few days

Question 16

Segmented neutrophils

segs

Answer 16

mature neutrophils Nucleus should have 2-5 lobes

Question 17

Banded neutrophils (band)

Answer 17

• immature neutrophils

- Nucleus are of horseshoe shape

Question 18

Neutrophilia (over 70%)

Answer 18

• Infection (bacterial,
fungal)
• Trauma 
• Inflammatory
diseases 
• Stress

Question 19

Neutropenia (less 45%)

Answer 19

• Bone Marrow depression
  – Aplastic anemia 
  – Megaloblastic anemia
• Viral infection
• Autoimmune
disorders

Question 20

• Functions of eosinophils:

Answer 20

- histaminase locating in cytoplasmic
granules inactivates histamine 
- phagocytosis 
- production of eicosanoids (modulating inflammatory responses)
- physiological role in organ formation
(e. g. postgestational mammary gland development)
• They play roles in:
- allergic reactions 
- bronchial asthma 
- parasitic (worm) infestations
- Lifetime of eosinophils: 8-12 days

Question 21

Increased level(over 6%) eosinophilia

Answer 21

• Allergic reaction 
• Atopic bronchial asthma 
• Parasitic infection (worms):
– flukes, roundworm, nematode, trichenella 
• Skin diseases 
• Leukemia (CML) 
• Hodgkin's disease

Question 22

Decreased level (less 1%) eosinopenia

Answer 22

• Stress
• Cushing’s disease
• Aplastic anemia
• Brucellosis

Question 23

Function: basophils synthesize and store:

Answer 23

= histamine
= anticoagulant heparin (prevents blood from clotting too
quickly)
• They play role in:
- inflammation (due to presence of histamine)
- type I hypersensitivity, or anaphylactic reactions
- ectoparasite infections (e.g. ticks etc.)
- cancer
• Lifetime of basophils: few hours to few days

Question 24

Increased level (over 2%) basophilia

Answer 24

• Chronic myelocytic leukemia
(CML) 
• Hodgkin’s disease 
• Ulcerative colitis 
• Anaphylactic reactions
(allergy) 
• Polycythemia 
• Infection (e.g. TB, chickenpox)

Question 25

Decreased level (less than 0.5%) basopenia

Answer 25

• Hyperthryroidism
• Ovulation
• Pregnancy
• Stress
• Aplastic anemia

Question 26

Functions of lymphocytes:

Answer 26

• are effector cells of the immune system
• B-cells produce plasma cells (for further antibody production)
• participation in regulation of the immune system
• antiviral, antitumor, anti-graft activity
  • Lifetime of lymphocytes: years for memory cells, weeks for all others

Question 27

Increased level (over 45%) lymphocytosis

Answer 27

• Viral infection 
• Autoimmune disorders 
• Infectious mononucleosis
(atypical lymphocytes) 
• Lymphatic (lymphocytic)
leukemia

Question 28

Decreased level (less than 20%) lymphopenia

Answer 28

• Chronic debilitating diseases

* High corticosteroid levels

Question 29

Functions of monocytes:

Answer 29

• phagocytosis (most active of all phagocytic cells)
• mature into macrophages:
  1) Langerhans cells - in epidermis
  2) Alveolar macrophages – in lungs
  3) Microglia – in CNS
  4) Kupffer cells – in liver
• inflammation
  • Monocytes are associated with:
• tissue damage and trauma,
• chronic infectious diseases
• autoimmune diseases,

Question 30

Increased level (over 8%)
monocytosis

Answer 30

- tuberculosis, hepatitis, malaria, typhoid,
leishmaniasis
- diffuse connective tissue diseases 
- subacute bacterial endocarditis 
- myeloma 
- monocytic leukemia

Question 31

Decreased level (less than 2%)
monocytopenia

Answer 31

• acute infections
• stress
• treatment with glucocorticoids
• aplastic anemia
• acute myeloid leukemia

Question 32

Red Blood Cell Count

Answer 32

• Main component of blood
• Helps estimate carrying capacity for oxygen
• Normal range: 4.2 - 6.1 million/cubic millimeter
• Increased count of RBC - polycythemia
• Decreased count of RBC - anemia
• Production is promoted by erythropoetin
• Erythropoetin level is controlled by oxygen level in tissues

Question 33

RBC lifetime

Answer 33

approximately 4 months

Question 34

anisocytosis

Answer 34

• Different size
• means the unequal size of RBC
  
  • macrocytes
  • microcytes

Question 35

poikilocytosis

Answer 35

• Different shape
• abnormal shape of RBC, it represents the
  abnormalities of membrane or Hb of RBC causing remodeling
• types:
  -elliptocytes (oval)
  -tear drop
  -sickle cell
  -schistocytes
  -crenated
  -burr cells
  -spur cells
  -target cells
  -spherocytes

Question 36

macrocytes– increased diameter of RBC, found in:

Answer 36

• megaloblastic anemia -autoimmune hemolytic -anemias
• alcoholism
• chronic liver diseases

Question 37

microcytes – decreased diameter of RBC, found in:

Answer 37

• iron-deficiency anemia -thalassemia
• sickle cell anemia
• spherocytosis

Question 38

elliptocytes (oval) – found in:

Answer 38

• hereditary elliptocytosis (hemolytic anemia)
• thalassemia
• iron-deficiency
  anemia
• myelofibrosis (when bone marrow is replaced by non-hemopoetic tissue, scar tissue)

Question 39

tear-drop – found in:

Answer 39

myelofibrosis

Question 40

sickle cells (drepanocytes) – rod-shaped, boat-
shape, oat-shaped, found in:

Answer 40

sickle cell anemia

Question 41

schistocytes (red cell fragments) – fragments are small, spherical, triangular or irregular, found in:

Answer 41

• hemolytic anemias
  burns
• iron-deficiency anemia
• thrombotic thrombocytopenia purpura

Question 42

crenated

Answer 42

– multiple short symmetric
projection (10-30 spicules of equal length);
not related to any disease

Question 43

burr cells (a.k.a. echinocytes) –irregular asymmetric projections, small cells, found in:

Answer 43

• uremia
• hemolytic anemia
• pyruvate kinase deficiency
• hypomagnesemia,
• hypophosphatemia long-distance runners

Question 44

spur cells (a.k.a.acanthocytes) – with long irregular unequal spicules, found in:

Answer 44

• liver diseases (e.g. liver cirrhosis)
• uremia
• thrombotic thrombocytopenic purpura

Question 45

target cells (a.k.a. codocytes) – that have the appearance of a shooting target, have increased surface
area (due to increased cholesterol and lecithin), found
in:

Answer 45

• obstructive liver diseases
• abnormal hemoglobin diseases (SCD, thalassemia)
• iron-deficiency anemia

Question 46

spherocytes – loss of biconcavity, smaller in

diameter, dark color without central pallor area, found in:

Answer 46

• hereditary spherocytosis
• burns
• after drug toxicity

Question 47

hypochromia – when RBCs are paler than normal due to low hemoglobin concentration, found in:

Answer 47

• iron deficiency
• thalassemia
• sideroblastic anemia

Question 48

hyperchromic - dark red cells due to an increase in the ratio of the weight of hemoglobin to the volume of the RBC, found in:

Answer 48

• hereditary spherocytosis

- megaloblastic anemias

Question 49

basophilic stippling (punctate basophilia) –
aggregates of ribosomes looking like dark blue granules
throughout the cells, found in:

Answer 49

• lead poisoning
• thalassemia
• sideroblastic anemia

Question 50

cabot rings are dark ring-shaped, figure eight structure
(microtubules or remnants of the nuclear membrane),
found in:

Answer 50

• lead poisoning
• pernicious anemia,
• thalassemia

Question 51

Howell-Jolly bodies – DNA nuclear remnants,

single deep purple color, found in:

Answer 51

• megaloblastic anemias
• hemolytic anemia
• post-splenectomy

Question 52

Heinz body - denatured hemoglobin

Answer 52

glucose-6-phosphate dehydrogenase deficiency

Question 53

reticulocytes

Answer 53

– immature red cells with cytoplasmic RNA,
appear as diffusely pale blue color cells
- The number of reticulocytes is a good indicator of bone
marrow activity

Question 54

Rouleaux

Answer 54

• are stacks or aggregations of RBCs
• ## occur when the plasma protein concentration (particularly of fibrinogen and globulins) is high

Question 55

Conditions which cause increased rouleaux formation include:

Answer 55

• infections
• inflammatory diseases
• connective tissue disorders
• malignant tumors (e.g. multiple myeloma)
• diabetes mellitus (diabetic retinopathy)

Question 56

Hematocrit (HCT)

Answer 56

• is a blood test that measures the percentage of the volume of whole blood that is made up of
  red blood cells. This measurement depends on the number of
  red blood cells and the size of red blood cells

Question 57

normal hematocrit

Answer 57

• 45% for men

- 40% for women

Question 58

A high HCT indicates

polycythemia

Answer 58

• polycythemia vera 
• dehydration 
• COPD  (hypoxia) 
• congenital heart disease 
• kidney tumor that
produces excess
erythropoietin

Question 59

A low HCT indicates anemia

Answer 59

• bleeding 
• overhydration 
• nutritional deficiencies such
as iron, folate, vitamin B12 
• bone marrow disorders 
• kidney failure (decreased
production of erythropoietin) 
• excessive destruction of RBC

Question 60

A hematocrit of less than 15% can result in

Answer 60

cardiac failure

Question 61

A hematocrit of over 60% may result in

Answer 61

spontaneous blood clotting

Question 62

Hemoglobin (Hb or HGB)

Answer 62

• Each gram of hemoglobin binds 1.34 ml of O2

* Normal levels 11.6-15.2 g/dl

Question 63

Increased hemoglobin levels indicate:

Answer 63

• polycythemia vera
• dehydration
• cor pulmonale
• pulmonary fibrosis

Question 64

Decreased levels typically found in:

Answer 64

• iron deficiency anemia
• hemolytic anemia, hemoglobinopathies (sickle cell disease, thalassemia)
• renal failure

Question 65

Rule of Three

Answer 65

• RBC count, HGB, and HTC
• The hemoglobin should be three times RBC count.
  -Example: RBC is 5 million/cubic mm. Based on rule of three: 5 x 3 = 15 (this is HGB in g/dl)
• The hematocrit should be three times the hemoglobin.
  -Example: HGB is 15 g/dl. Based on rule of three:
  15 x 3 = 45 (this is HTC in %)
• The hematocrit should be nine times the RBC.
  -Example:
  RBC is 5 million/cubic mm. Based on rule of three: 5 x 9 = 45 (this is HTC in %)
  -This rule of three can be only applied to samples with normal size and shape of erythrocytes

Question 66

Mean Corpuscular Volume (MCV)

Answer 66

-average size of red blood cell
- calculated by dividing the hematocrit by the total number of red blood cells, then multiplied by 10
MCV= (Hct x 10)/RBC
- Normal range is 80-99 femtoliters (fL) – in normocytes
– MCV < 80 fL means smaller cell size (microcytes)
– MCV ≥ 100 fL means bigger cell size (macrocytes)

Question 67

The Mean Corpuscular Hemoglobin (MCH), or “Mean

Cell Hemoglobin”

Answer 67

• the average mass
  of hemoglobin per red blood cell
• MCH = (Hb x 10)/RBC
  -Normal range (normochromic) 27-31 picograms (pg)

Question 68

MCH less than lower limit of normal

Answer 68

• hypochromic anemias:

- e.g. iron deficiency anemia, thalassemia

Question 69

MCH within normal range - normal RBC,

Answer 69

• normochromic anemias:

- e.g. acute blood loss, aplastic anemia, polycythemia vera

Question 70

MCH greater than upper limit of normal

Answer 70

– hyperchromic
anemias:
- e.g. megaloblastic anemia

Question 71

Mean Corpuscular Hemoglobin Concentration (MCHC)

Answer 71

• is a measure of the concentration of hemoglobin in a given volume of packed RBCs
• MCH/MCV or (Hb x 100)/hct
• Normal ranges for blood tests are 32 to 36 g/dl

Question 72

MCHC is diminished

Answer 72

the erythrocytes are hypochromic in microcytic anemias

e.g. iron deficiency anemia, chronic blood loss, thalassemia

Question 73

MCHC is normal

Answer 73

the erythrocytes are normochromic in macrocytic
anemias due to larger cell size, though the hemoglobin
amount (MCH) is high, the concentration remains normal

Question 74

MCHC is elevated

Answer 74

should ONLY occur when spherocytes are present

e.g. hereditary spherocytosis

Question 75

Methemoglobin

Answer 75

• is a form of oxygen-carrying metalloprotein
  that contains ferric (Fe3+)iron not the ferrous (Fe²+) of normal hemoglobin and has a decreased ability to bind O2
  -results from the oxidation of the reduced state
  (ferrous Fe²+) of heme to the trivalent (ferric Fe3+) form
  -This form of hemoglobin cannot combine with oxygen,
  therefore the oxygen transport function is lost, tissue hypoxia
  can occur
  -This form of hemoglobin cannot combine with oxygen,
  therefore the oxygen transport function is lost, tissue hypoxia
  can occur

Question 76

Acquired methemoglobinemia results from:

Answer 76

• carbon monoxide (CO) poisoning
• medication (Tylenol), certain antibiotics
• anesthetics

Question 77

Manifestations of methemoglobinemia:

Answer 77

<10% of MetHb - no clinical manifestations
10-20% - skin discoloration (bluish)
20-30% - headache, dyspnea, anxiety
30-50% - fatigue, dizziness, tachycardia, confusion
50-70% - coma, arrhythmia
>70% - death

Question 78

There are two forms of inherited methemoglobinemia:

Answer 78

-The first form is problem with cytochrome b5 reductase
enzyme
-he second form of inherited methemoglobinemia is
caused by defects in the hemoglobin protein itself

Question 79

the first form is problem with cytochrome b5 reductase enzyme

Answer 79

• type 1 (also called erythrocyte reductase deficiency) occurs when red blood cells lack this enzyme
• type 2 (also called generalized reductase deficiency) occurs when this enzyme doesn’t work anywhere in the body

Question 80

The second form of inherited methemoglobinemia is

caused by

Answer 80

• defects in the hemoglobin protein itself
• This form is called hemoglobin M disease
• Only one parent needs to pass on the abnormal gene for the child to inherit the disease

Question 81

The Erythrocyte Sedimentation Rate (ESR)

Answer 81

• is the rate at which red blood cells sediment in a period of one hour
• Very SENSITIVE but not SPECIFIC
  Normal range:
• males 1-13 mm/hour
• females 1-20 mm/hour

Question 82

Increased ESR:

Answer 82

• inflammatory process
• infection
• neoplasm
• tissue destruction etc.

Question 83

Decreased ESR:

Answer 83

• polycythemia vera
• sickle cell disease
• hyperviscosity syndrome

Question 84

Serum iron

Answer 84

• is a test that measures how much iron is in blood
  • Iron levels are highest in the morning
  • Normal range of the iron in the blood: 60-170 mcg/dL
  • 95% of all iron is complexed with transferrin

Question 85

Higher-than-normal level

Answer 85

• hemochromatosis 
• hemolytic anemia 
• liver tissue issue 
• hemolysis (duo to blood
transfusions)

Question 86

Lower-than-normal levels

Answer 86

• iron deficiency anemia
• pregnancy
• intestinal conditions that cause poor absorption of iron

Question 87

Total Iron Binding Capacity (TIBC)

Answer 87

- is a blood test that
measures  maximum amount of iron that can be bound to
transferrin
- Normal range in the blood:
     - TIBC: 240-450 mcg/dL 
     - transferrin saturation: 20-50%

Question 88

Higher-than-normal TIBC

Answer 88

• when the body’s iron stores
are low:
- iron deficiency anemia - late pregnancy

Question 89

Lower-than-normal

TIBC

Answer 89

when the body's iron stores are high, or function of the liver is low:
    - cirrhosis 
    - hemochromatosis 
    - hemolytic anemia
(e.g. thalassemia,
sickle cells disease) 
    - megaloblastic anemia

Question 90

Ferritin is

Answer 90

-the iron storage protein found in hepatocytes and reticulo-endothelial cells
-Normal value: 20-300 nanograms/ml
- Serum ferritin levels are generally accepted as reliable single
indicators of the presence of iron deficiency

Question 91

High levels of ferritin (Iron Overload)

Answer 91

• hemochromatosis
• liver disease
• iron overload
• leukemia
• infection
• inflammation

Question 92

Low levels of ferritin ( Depletion of Iron )

Answer 92

• iron deficiency

- pregnancy

Question 93

Normal range of platelets

Answer 93

150- 400 thousand/microliter (mcl).

[In microscope 7-10 phf]

Question 94

Count < 50 thousand/mcl platelets results in

Answer 94

spontaneous

bleeding

Question 95

< 5 thousand/mcl platelets

Answer 95

fatal

Question 96

Platelets arise from ____________ in bone marrow

Answer 96

megakaryocytes

Question 97

Elevated platelet levels

Answer 97

• hemorrhage
• infection
• cancer
• iron deficiency anemia
• splenectomy
• pregnancy

Question 98

Decreased platelet levels

Answer 98

• aplastic/hypoplastic marrow 
• infiltrative bone disease
   – neoplasms
   – infection 
• deficiency of:
   – folic acid
   – vitamin B12 
• destruction in:
   – drug reactions
   – Autoimmune
thrombocytopenias

Question 99

Coagulation Tests

Answer 99

• Bleeding Time 
• Partial
Thromboplastin time 
• Prothrombin Time 
• Activated (Whole
Blood) Clotting Time
• Plasma Thrombin
Time 
• Plasma Fibrinogen 
• Fibrin Split Products

Question 100

Bleeding Time

Answer 100

• Duration of bleeding after standardized incision
• Normal 3-6 minutes
• Not be done if platelet count is < 75 thousand/mcl

Question 101

Elevated Bleeding Time (2 x Normal)

Answer 101

• Disorders associated thrombocytopenias
• Hodgkin’s disease
• Leukemia
• Disseminated Intravascular Coagulation (DIC)
• Severe liver disease
• Deficiency of clotting factors
• Uremia
• Drugs (especially NSAIDs)
• Vitamin K deficiency

Question 102

Partial Thromboplastin Time (PTT)

Answer 102

-measures the efficacy of both the intrinsic and
common coagulation pathways
-used to investigate unexplained
bleeding or clotting
-used in conjunction with the prothrombin time which
measures the extrinsic coagulation pathway
-Normal range: 30-50 seconds

Question 103

PTT is used for diagnosis of:

Answer 103

• hemophilia A, B
• liver diseases
• factors I, II, V, VIII, IX, X, XI, & XII deficiency
• disseminated intravascular coagulation
• vitamin K deficiency

Question 104

Prothrombin Time (PT)

Answer 104

• is a blood test that measures extrinsic and common coagulation pathways
  • Normal values (without blood thinning medicines):
  11 – 13.5 seconds
  • 2.5 increase of PT indicates bleeding disorder
  • PT is not used for diagnostics of hemophilia

Question 105

A prothrombin time test can be used to check:

Answer 105

• bleeding problems
• whether medicine to prevent blood clots is working
• presence of clotting factors I, II, V, VII and X
• liver damage (all clotting factors are produced in liver)
• vitamin K status

Question 106

Plasma Thrombin Time (TT)

Answer 106

• The test only detects the activity of fibrinogen and gives
quick estimate of fibrinogen level
• Normal is 10-15 seconds

Question 107

Plasma Thrombin Time Prolonged in:

Answer 107

• fibrinogen abnormalities (congenital or acquired):
  hypofibrinogenemia, afibrinogenemia, dysfibrinogenemia
• deficiency of fibrin formation (disseminated intravascular coagulation, abnormal circulating proteins due to
  amyloidosis or multiple myeloma)
• liver diseases
• heparin therapy

Question 108

Plasma Fibrinogen (Factor I)

Answer 108

• This testing is used to evaluate the fibrinogen level
• Fibrinogen, also known as clotting factor I, is a plasma protein
that can be transformed by thrombin into a fibrin gel (“the clot”)
and is essential for blood clot formation
• Fibrinogen is synthesized in the liver and circulates in the
plasma
• Therefore, fibrinogen deficiency is a serious health problem
• Normal value 200-400 mg/dl

Question 109

Decreased levels of Plasma Fibrinogen (Factor I)

Answer 109

– hereditary absence, deficiency, or defect of fibrinogen 
– abnormal fibrinolysis 
– end-stage liver diseases 
– bone marrow lesions 
– cancer of prostate, pancreas, lungs 
– disseminated intravascular coagulation

Question 110

Increased levels of Plasma Fibrinogen (Factor I)

Answer 110

– cancer of stomach, breast, kidney
– tissue damage/trauma
– inflammation
- pneumonia or glomerulonephritis

Question 111

Plasmin

Answer 111

• is an important enzyme present in blood that
  degrades many blood plasma proteins, including fibrin clots
  (fibrinolysis)
• Normal level 10 mg/L
  • Deficiency in plasmin may lead to arterial thrombosis, especially in young persons (as clots are not degraded adequately)

Question 112

Elevated level in anticoagulant activity and disorders

with excessive bleeding (Plasmin?)

Answer 112

• disseminated intravascular coagulation
• myocardial infarction
• burns or sunstroke
• pulmonary embolism due to deep vein thrombosis