Introduction To Anemias PDF

Summary

This document is a lecture on INTRODUCTION TO ANEMIAS, covering various aspects of classification, clinical presentation, and laboratory diagnosis of different types of anemia. It details learning objectives and readings for the course. The document is likely part of a medical education curriculum.

Full Transcript

INTRODUCTION TO ANEMIAS
Block: Foundations Block Director: James Proffitt, PhD
Session Date: Tuesday, August 06, 2024 Time: 8:00 am - 9:30 am
Instructor: Candace Reveles, MD Department: Department of Pathology
Email: [email protected]

INSTRUCTIONAL METHODS
Primary Method: IM13: Lecture ☐ Flipped Session ☐ Clinical Correlation
Resource Types: RE18: Written or Visual Media (or Digital Equivalent)

INSTRUCTIONS
These lectures will focus on various aspects of classification, clinical presentation, and
laboratory diagnosis of various types of anemia. Some aspects of the topics covered here such
as complete blood cell analysis, peripheral blood morphologic abnormalities, pathophysiology,
clinical presentation and diagnosis have either been already been introduced in previous
lectures or will be discussed in great details in future lectures. The lectures intend to bring
concepts and reinforce and solidify your knowledge on such important aspects of anemia and
expand beyond the topics that have already been discussed.

READINGS
Kumar V, A. A., Aster JC (2021). Anemia section in Red Blood Cells and Bleeding Disorders.
Robbins and Cotran Pathologic Basis of Disease. R. Cotran. Philadelphia, Elsevier: 635-672.

LEARNING OBJECTIVES
1. Define anemia with its signs and symptoms
2. Describe the approach to anemia classification
3. Become familiar with the diagnostic tests in work up of a patient with anemia
a. Red cell incises
b. Reticulocyte count and advanced red cell parameters
c. Peripheral blood smear assessment
4. Describe the morphologic findings and diagnostic work up of:
a. Anemia of inflammation
b. Thalassemia and hemoglobinopathies
c. Hemolysis, immune and non-immune mediated hemolysis
d. Anemia due to RBC membrane structural defects and enzyme defects

CURRICULAR CONNECTIONS
Below are the competencies, educational program objectives (EPOs), course objectives,
session learning objectives, disciplines and threads that most accurately describe the
connection of this session to the curriculum.

Block: Foundations | REVELES [1 of 10]
INTRODUCTION TO ANEMIAS
Related Related
Competency\EPO Disciplines Threads
COs LOs
CO-02 LO-01 MK-05: The altered Pathology N/A
structure and function Hematology
(pathology &
pathophysiology) of the
body/organs in disease
CO-02 LO-02 MK-05: The altered Pathology N/A
structure and function Hematology
(pathology &
pathophysiology) of the
body/organs in disease
CO-02 LO-03 MK-05: The altered Pathology N/A
structure and function Hematology
(pathology &
pathophysiology) of the
body/organs in disease
CO-02 LO-04 MK-05: The altered Pathology N/A
structure and function Hematology
(pathology &
pathophysiology) of the
body/organs in disease

NOTES
ANEMIA
Definition:
Anemia is the most common disorder of blood. It is defined as reduction of total
circulating red cell mass leading to reduced oxygen-carrying capacity and tissue
hypoxia. It can occur when there is decrease of total number of red blood cells
(RBC), amount of hemoglobin in the circulation or circulating red blood cells
mass.

Physiologic compensatory mechanisms for anemia:
1. Increasing cardiac output; patients with limited cardiac reserve (heart failure,
coronary artery disease) may experience anemia at higher hemoglobin
concentration as compared to healthy individuals.
2. Increasing plasma volume; allows remaining RBCs to move more efficiently
due to decrease viscosity.
3. Increasing RBC 2,3-diphosphoglycerate (2,3-DPG) which results in
diminished oxygen affinity for hemoglobin which results in more oxygen
delivery to tissues.

Classification of Anemias
1. Morphologic classification, based on red blood cell size:
a) Microcytic:
i. Defect of hemoglobin synthesis
b) Macrocytic:
i. Megaloblastic: B12, folate, drug-induced
ii. Non-megaloblastic: alcohol, liver disease or hypothyroidism

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INTRODUCTION TO ANEMIAS
c) Normocytic: anemia of inflammation, acute onset of hemolysis or blood
loss, chronic kidney disease
2. Pathophysiologic classification:
a) Increase RBC loss:
i. Hemorrhage, external or internal
ii. Decreased red cell survival, hemolysis (immune, microangiopathic,
intrinsic red cell defects)
b) Impaired red cell production (hypoplastic):
i. Stem cell (acute leukemia, myelodysplastic syndrome, aplastic
anemia)
ii. Nutritional deficiency (iron, B12, folate, copper)
iii. Toxins/drugs (lead)
iv. Lack of growth factors (erythropoietin)
v. Myelophthisic process (metastatic cancer, infection, bone marrow
necrosis)

First Aid for the USMLE Step 1 2020

First Aid for the USMLE Step 1 2020

There is substantial overlap between various types of anemia, both
morphologically and in terms of pathophysiology. A combination of both
approaches is necessary to arrive at an accurate diagnosis.

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INTRODUCTION TO ANEMIAS
Laboratory Evaluation of Anemia
Should focus on (1) determining whether anemia is present and (2) identifying the
underlying cause
1. Complete Blood Count (CBC): includes red and white blood cell and
platelet counts hemoglobin, hematocrit and RBC indices:
a. Hemoglobin (Hb g/dL): main component of RBC
b. Hematocrit (Hct %): packed red cell volume
c. Red blood cell indices:
Mean Cell Volume (MCV fL): the average volume of RBC
Mean Cell Hemoglobin (MCH pg): Hb content (mass) of Hb in
average RBC
Mean Cell Hemoglobin Concentration (MCHC g/dL): average
concentration of Hb in a given volume of packed RBCs.
Red blood cell distribution with (RDW): coefficient of variation of
RBC volume.

2. Reticulocytes: immature non-nucleated RBC that contain RNA; Reflect the
bone marrow proliferative capacity:
i. Percent of RBC: when expressed as % it may
overestimate the red cell production
ii. Absolute number: more adequate representation of bone
marrow production
iii. Immature reticulocyte fraction (IRF %)
iv. Reticulocyte Hb concentration (RET-He pg) – reflects
availability of functional iron

3. Review of peripheral blood smear:
a. Provides key RBC information to create differential diagnosis of
anemia
i. Shape (biconcave, irregular)
ii. Size (microcytic, normocytic, macrocytic)
iii. Color (hypo or normochromic)
iv. Inclusions (Howell-Jolly bodies, malaria parasites)
v. Arrangement

4. Additional studies:
a. Special stains: Heinz bodies, supravital stain highlight inclusion
bodies composed of denatured Hb
b. Complete metabolic panel (CBC) and liver function tests (LFTs)
c. Iron studies: serum iron, % transferrin saturation or total iron binding
capacity (TIBC), ferritin, vitamin B12, and folate
d. Haptoglobin: produced by liver to clear free hemoglobin
e. Direct antiglobulin test (Coombs test): antibodies bound to the RBC
membrane
f. Hemoglobin electrophoresis: measures different types of hemoglobins
in the RBC
g. Genetic testing: hereditary anemias

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INTRODUCTION TO ANEMIAS
Morphologic findings and diagnostic work up of anemia

Anemia of inflammation:
Commonly seen in hospitalized patients
May mimic iron deficiency anemia
Often associated with chronic infections (osteomyelitis, bacterial endocarditis,
lung abscess), chronic kidney disease, immune disorders (rheumatoid
arthritis, systemic lupus), or neoplasms (lymphomas, carcinomas)
Clinical presentation: Symptoms associated with underlying disease
predominate and anemia (usually mild).
Labs: normocytic, normochromic or microcytic, hypochromic anemia with low
reticulocyte count and ⇩ RET-He along with ⇩ serum iron, ⇩TIBC, ⇧ iron
stores and ⇧ ferritin.
Hepcidin is a major iron transport modulator and plays a key role in iron
metabolism. High levels of IL-1, TNF-α, and interferon-γ and other
inflammatory cytokines increase hepcidin synthesis by the liver.
Hepcidin binds ferroportin on the intestinal mucosal cells and macrophages
and inhibits iron release for heme synthesis leading to functional iron
deficiency
Other contributing factors: ⇩ erythropoietin levels, impaired iron transport;
probably due to a defect in the ability to release iron from the storage pool
Treatment: treat the underlying disease; recombinant erythropoietin may be
needed.

Hemoglobinopathies and thalassemia:
Sickle cell disease: homozygous point mutation of the β globin gene leading to
a single amino acid substitution of valine for glutamine. HbS polymerizes and
crystallizes leading to characteristic sickle shape of the RBCs. HbS
polymerization is initially reversible with re-oxygenation, but with repeated cycles
of sickling, the damage becomes irreversible. This leads to secondary
membrane damage, inflexibility, hemolysis and vasoocclusive disease.

Factors precipitating sickling: ⇩ O2 saturation, high altitude, acidosis, infections.
Newborns have high concentration of HbF (2α2γ chains) and low HbS, so
sickling is not seen until fetal hemoglobin levels decline (6-9 months).

Sickle cell trait (carrier): 8% of African Americans carry an HbS allele. Rarely
causes sickling or anemia, except under severe conditions. Sickle cell trait
confers resistance to malaria.

Peripheral blood findings: RBC anisocytosis, poikilocytosis, sickled cells,
reticulocytes; extramedullary hematopoiesis

Complications of sickle cell disease:
Chronic hemolytic anemia
Painful crisis = vaso-occlusive crisis in bones (hand-foot syndrome or leg
ulcers), lungs (acute chest syndrome), penis (priapism), brain (seizure or
stroke), liver or spleen (infarct)

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Aplastic crisis = sudden stop of marrow RBC production (Parvovirus B19
infection)
Sequestration crisis = sudden accumulation of RBCs in the spleen due to
sludging
Autosplenectomy: increase risk of infections (loss of splenic function;
defective complement opsonization). RBC with Howell-Jolly bodies
Microinfarcts expanding to gross infarcts, especially in solid organs (liver,
brain, kidneys), but also in the lungs (cor pulmonale)
Bone marrow expansion with thinning of cortical bone (“crew cut” or “hair-
on-end” appearance of skull x-rays)

Diagnosis: clinical findings, peripheral smear with sickle cells; hemoglobin
electrophoresis; prenatal DNA testing for affected fetus

Thalassemias
Inherited disorder due to decrease of either alpha or beta globin chain
synthesis.
Two types, alpha and beta thalassemia depending on the affected gene
o Alpha thalassemia: deletion of two or more alpha globin genes

o Beta thalassemia: suboptimal or absent beta globin gene expression
Laboratory findings: microcytic anemia with elevated red blood cell count and
no significant anisocytosis. Target cells are characteristic. The degree of
anemia and peripheral blood findings are mild in heterozygotes and more
pronounced in homozygotes.
Β thalassemia minor is associated with ⇧ HbA2 (>3.5%)

Increased Rate of RBC Destruction (Hemolysis)
Anemia can occur when RBC survival is shortened (normal ~120 days) due to
abnormal RBC membrane structure, enzyme deficiency (G-6PD), immune-
mediated, or mechanical red blood cell destruction. The immune-mediated
hemolytic anemias will be covered in a lecture on Red Cell Immunology Immunity
and Infection Block and the discussion here will focus on non-immune mediated
hemolytic anemias.

Common features of hemolytic anemias:
Shortened RBC survival (due to premature RBC destruction)
Elevated erythropoietin levels with compensatory increase in erythropoiesis
▪ Anemia with reticulocytosis
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Accumulation of hemoglobin breakdown products (hemosiderosis)
Jaundice (increased serum bilirubin excreted into urine & feces, pigment
gallstones)
Low serum haptoglobin (scavenger protein clearing free hemoglobin from the
circulation)

Complications unique to patients with chronic hemolytic anemias:
Aplastic crisis (often due to parvovirus B19 infection): lack of RBC production
with continued accelerated destruction can lead to severe prolonged anemia
Hemolytic crisis: super-accelerated destruction seen in response to systemic
problems such as sepsis

Hemolytic anemia due to mechanical trauma of RBC
RBCs exposed to excessive physical stress can break apart. When this
happens, they might completely disintegrate, or they might continue to
circulate as fragments (“schistocytes”). Such damage (macroangiopathic
hemolytic anemia) is most common with intravascular prostheses such as
mechanical heart valves, ECMO, cardio-pulmonary bypass, ventricular assist
devices, or vascular grafts (at the suture line).

It is also typically seen in inflammatory conditions that allow fibrin to deposit
within small vessels. The resulting partial occlusion by the fibrin strands
pinches off pieces of the RBC membrane (microangiopathic hemolytic
anemia). Examples include disseminated intravascular coagulation (DIC),
systemic lupus erythematosus (SLE), and thrombotic thrombocytopenic
purpura/hemolytic uremic syndrome (TTP/HUS).

Clinical presentation: history as described above plus evidence of
hemolysis

Labs: Anemia with fragmented red cells (helmet cells, triangle cells, other
non-specific schistocytes), thrombocytopenia, elevated LDH.

Diagnosis: clinical history and presentation, negative antibody work-up
(excludes immune mediated hemolysis), peripheral smear findings

Anemia due to RBC membrane defects
The unique features of RBCs and membrane skeletal proteins (ankyrin, band 3,
protein 4.2, and spectrin) will be covered in detail by Dr. Marie-Pierre Hasne in
a subsequent lecture in this block. Mutations in these proteins results in an
abnormal, less deformable and rigid membrane with the consequence of shorter
red cell life span due to premature removal by the spleen (hemolysis).

Hereditary Spherocytosis (HS)

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INTRODUCTION TO ANEMIAS
The most common RBC membrane defect. As a result of microvesiculation
and membrane loss, the RBCs appear spherical rather than biconcave.

Genetics: Mutations in the ankyrin gene are most common; defects of band 3
and alpha spectrin are rare. Decreased flexibility makes it hard for the RBC to
pass through small channels. Getting caught in splenic sinusoids leads to
phagocytosis and destruction by splenic
Characteristic triad: Anemia with marked reticulocytosis (bone marrow is
trying to compensate for the anemia), jaundice (hemoglobin degradation
products build up), and splenomegaly (reticuloendothelial system overload).
The severity of anemia is variable from obvious hemolysis at birth to
asymptomatic.

Laboratory findings:
Normochromic normocytic or microcytic anemia with circulating
spherocytes and reticulocytosis
Elevated MCHC >36 g/dL (characteristic finding) due to spherical
shape of the RBCs
Increased LDH
Elevated indirect (unconjugated) bilirubin
Reticulocytosis due to increased bone marrow and extramedullary
erythropoiesis

Diagnosis of HS:
Presence of personal and family history of anemia along with elevated
MCHC = presumptive diagnosis of HS
Increase Osmotic fragility; Note, this test has low specificity and low
sensitivity
Flow cytometric detection of band 3 staining, EMA test, high specificity
and sensitivity for HS
Genetic testing is rarely necessary

RBC enzyme defects, glucose-6-phosphate dehydrogenase (G6PD)
deficiency. More details will be covered in the DMH block.
G6PD deficiency is inherited as a X-linked autosomal recessive
G6PD is a key enzyme in the glycolytic pathway that generates
ATP and glutathione peroxidase necessary in protecting the RBC
from generate free radicals.
Self-limiting anemia: the new RBCs are released into the circulation
with a “full load” of G6PD that is used in during the RBC lifespan
Mature RBC cannot synthesize G6PD and deficiency will lead to
hemolysis if the cells are exposed to oxidative stress such as
chemicals (naphthalene, mothballs), medications (primaquine,
dapsone), acute infections, and certain foods (fava beans)
A majority of deficient individuals are asymptomatic and have no
hemolysis at steady state.

The following Anemias (iron deficiency/nutritional) are for your reference but will
NOT be tested in this block:

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Iron Deficiency Anemia
The most common nutritional deficiency worldwide (including the US).
Causes of iron deficiency:
Insufficient dietary intake (infants, vegetarians, elderly)
Impaired absorption (intestinal disease, gastrectomy, diets rich in
tannates, carbonates and phosphorous)
Increased requirement during pregnancy and children during growth
spurts
Chronic blood loss (peptic ulcers, GI cancer, hematuria, menorrhagia,
gynecologic cancers)
Labs: ⇩⇩ hemoglobin (severe anemia), ⇩ reticulocyte count, ⇩ immature
reticulocyte fraction ⇩ RET-He along with ⇩ serum iron; ⇩ transferrin
saturation (