Pharmacotherapy of Hematologic Disorders PDF

Summary

This document provides an overview of pharmacotherapy approaches for treating hematologic disorders, focusing on anemia. It details various types of anemia, their classifications, and associated treatments.

Full Transcript

Pharmacotherapy Our Lady of Fatima
University
of Hematologic College of Pharmacy

Disorders PHCP 311
Objectives

☐ To explain the pathophysiology of the
Anemia
☐ To identify the factors that may induce and
potentiate the disease
☐ To discuss the clinical presentation as well
the diagnosis and laboratory evaluation.
☐ To create a therapeutic outcome.
Anemia

▪ Anemia is a group of diseases characterized
by a decrease in either hemoglobin (Hb) or the
volume of red blood cells (RBCs), resulting in
decreased oxygen-carrying capacity of blood.
▪ The World Health Organization defines
anemia as Hb less than 13 g/dL (130 g/L;
8.07 mmol/L) in men or less than 12 g/dL
(120 g/L; 7.45 mmol/L) in women.
Functional classification of anemias
Common causes of Diseases Causing Anemia of
Inflammation

Chronic infections: Tuberculosis, Other chronic
lung infections (eg, lung abscess, bronchiectasis,
Human immunodeficiency virus, Subacute
bacterial endocarditis, Osteomyelitis, Chronic
urinary tract infections,
Chronic inflammation: Rheumatoid arthritis,
Systemic lupus erythematosus, Inflammatory
bowel disease, Inflammatory osteoarthritis, Gout,
Other (collagen vascular) diseases, Chronic
inflammatory liver diseases
Malignancies: Carcinoma, Lymphoma,
Leukemia, Multiple myeloma
Morphologic classifications are based on cell
size.
☐ Macrocytic cells are larger than normal
and are associated with deficiencies of
vitamin B12 or folic acid.
☐ Microcytic cells are smaller than normal
and are associated with iron deficiency
☐ Normocytic anemia may be associated
with recent blood loss or chronic disease
Iron-deficiency anemia (IDA), characterized
by decreased levels of ferritin (most sensitive
marker) and serum iron, and decreased
transferrin saturation, can be caused by
inadequate dietary intake, inadequate
gastrointestinal (GI) absorption, increased iron
demand (eg, pregnancy), blood loss, and
chronic diseases.
Vitamin B12– and folic acid–deficiency anemias,
macrocytic in nature, can be caused by inadequate dietary
intake, malabsorption syndromes, and inadequate
utilization.
☐ Deficiency of intrinsic factor causes decreased
absorption of vitamin B12 (ie, pernicious anemia).
☐ Folic acid–deficiency anemia can be caused by
hyperutilization due to pregnancy, hemolytic anemia,
myelofibrosis, malignancy, chronic inflammatory
disorders, long-term dialysis, or growth spurt.
☐ Drugs can cause anemia by reducing absorption of
folate (eg, phenytoin) or through folate antagonism (eg,
methotrexate).
Anemia of inflammation (AI) is a newer term
used to describe both anemia of chronic disease
and anemia of critical illness.
☐ A diagnosis of exclusion, AI is an anemia that
traditionally has been associated with
malignant, infectious, or inflammatory
processes, tissue injury, and conditions
associated with release of proinflammatory
cytokines.
☐ Serum iron is decreased but in contrast to IDA,
the serum ferritin concentration is normal or
increased
▪ Age-related reductions in bone marrow
reserve can render elderly patients more
susceptible to anemia caused by multiple
minor and often unrecognized diseases (eg,
nutritional deficiencies) that negatively affect
erythropoiesis.
▪ Pediatric anemias are often due to a primary
hematologic abnormality.
☐ The risk of IDA is increased by rapid
growth spurts and dietary deficiency.
▪ Rapid diagnosis is essential because anemia
is often a sign of underlying pathology.
▪ Severity of symptoms does not always
correlate with the degree of anemia.
▪ Initial evaluation of anemia involves a
complete blood cell count (CBC), reticulocyte
index, and examination of the stool for occult
blood.
Clinical Presentation

Signs and symptoms depend on rate of
development and age and cardiovascularstatus of
the patient.
Acute-onset anemia is characterized by
cardiorespiratory symptomssuch as palpitations,
angina, orthostatic light-headedness, and
breathlessness.
Chronic anemia is characterized by weakness,
fatigue, headache, orthopnea, dyspnea on
exertion, vertigo, faintness, cold sensitivity, pallor,
and loss of skin tone.
IDA is characterized by glossal pain, smooth
tongue, reduced salivary flow, pica (compulsive
eating of nonfood items), and pagophagia
(compulsive eating of ice).
Neurologic effects (eg, numbness and
paraesthesisas) of vitamin B12 deficiency may
precede hematologic changes. Psychiatric
findings, including irritability, depression, and
memory impairment, may also occur with vitamin
B12 deficiency.
Anemia with folate deficiency is not associated
with neurologic symptoms
Diagnosis based on MCV
Diagnosis based on MCV
Diagnosis based on MCV
Treatment

Goals of Treatment:
The goals are to return hematologic
parameters to normal, restore normal function
and quality of life, and prevent long-term
complications.
IRON-DEFICIENCY ANEMIA

▪ Oral iron therapy with soluble ferrous iron salts,
which are not enteric coated and not slow or
sustained release, is recommended at a daily dosage
of 150–200 mg elemental iron in two or three divided
doses
▪ Iron is best absorbed from meat, fish, and poultry.
▪ Administer iron at least 1 hour before meals because
food interferes with absorption, but administration
with food may be needed to improve tolerability.
▪ Consider parenteral iron for patients with iron
malabsorption, intolerance of oral iron therapy, or
nonadherence.
Oral Iron Products

Iron dextran, sodium ferric gluconate, iron sucrose, ferumoxytol, and ferric
carboxymaltose are available parenteral iron preparations with similar efficacy but
different molecular size, pharmacokinetics, bioavailability, and adverse effect profiles
VITAMIN B12–DEFICIENCY ANEMIA

▪ Oral vitamin B12 supplementation is as effective as
parenteral, even in patients with pernicious anemia,
because the alternate vitamin B12 absorption pathway is
independent of intrinsic factor. Initiate oral cobalamin at 1–2
mg daily for 1–2 weeks, followed by 1 mg daily.
▪ Parenteral therapy acts more rapidly than oral therapy and
is recommended if neurologic symptoms are present.
▪ A popular regimen is IM cyanocobalamin, 1000 mcg
daily for 1 week, then weekly for 1 month, and then
monthly for maintenance therapy. Initiate daily oral
cobalamin administration after symptoms resolve.
▪ Continue vitamin B12 for life in patients with pernicious
anemia.
FOLATE-DEFICIENCY ANEMIA

▪ Oral folic acid, 1 mg daily for 4 months, is
usually sufficient for treatment of folic
acid–deficiency anemia, unless the etiology
cannot be corrected.
▪ If malabsorption is present, a dose of 1–5 mg
daily may be necessary.
▪ Parenteral folic acid is available but rarely
necessary.
ANEMIA OF INFLAMMATION

▪ Treatment of AI is less specific than that of
other anemias and should focus on correcting
reversible causes.
▪ Reserve iron therapy for an established IDA;
iron is not effective when inflammation is
present. RBC transfusions are effective but
should be limited to episodes of inadequate
oxygen transport and Hb of 7–8 g/dL (70–80
g/L; 4.34–4.97 mmol/L).
Erythropoiesis-stimulating agents (ESAs) can
be considered, but response can be impaired
in patients with AI.
The initial dosage for epoetin alfa is 50–100
units/kg three times weekly and darbepoetin
alfa 0.45 mcg/kg once weekly.
Iron, cobalamin, and folic acid
supplementation may improve response to
ESA treatment.
Potential toxicities of exogenous ESA administration
include increases in blood pressure, nausea,
headache, fever, bone pain, and fatigue. Hb must be
monitored during ESA therapy.
☐ An increase in Hb greater than 12 g/dL (120 g/L;
7.45 mmol/L) with treatment or a rise of greater
than 1 g/dL (10 g/L; 0.62 mmol/L) every 2 weeks
has been associated with increased mortality and
cardiovascular events.
In patients with anemia of critical illness, parenteral
iron is often used but is associated with a theoretical
risk of infection.
ANEMIA IN PEDIATRIC POPULATIONS

▪ Infants aged 9–12 months: Administer ferrous
sulfate 3–6 mg/kg/day (elemental iron) divided
once or twice daily between meals for 4
weeks.
▪ Continue for two additional months in
responders to replace storage iron pools.
▪ The dose and schedule of vitamin B12 should
be titrated according to clinical and laboratory
response. The daily dose of folic acid is 1
mg.
EVALUATION OF THERAPEUTIC OUTCOMES

IDA: Positive response to oral iron therapy is
characterized by modest reticulocytosis in a
few days with an increase in Hb seen at 2
weeks.
☐ Reevaluate the patient if reticulocytosis
does not occur.
☐ Hb should return to normal after 2 months;
continue iron therapy until iron stores are
replenished and serum ferritin normalized
(up to 12 months).
▪ Megaloblastic anemia: Signs and symptoms
usually improve within a few days after starting
vitamin B12 or folic acid therapy.
▪ Neurologic symptoms can take longer to improve
or can be irreversible, but should not progress
during therapy.
▪ Reticulocytosis should occur within 3–5 days. Hb
begins to rise a week after starting vitamin B12
therapy and should normalize in 1–2 months.
▪ Hct should rise within 2 weeks after starting folic
acid therapy and should normalize within 2
months.
ESAs: Reticulocytosis should occur within a
few days. Monitor iron, TIBC, transferrin
saturation, and ferritin levels at baseline and
periodically during therapy. The optimal form
and schedule of iron supplementation are
unknown. Discontinue ESAs if a clinical
response does not occur after 8 weeks
Pediatrics: Monitor Hb, Hct, and RBC indices
4–8 weeks after initiation of iron therapy.
Monitor Hb or Hct weekly in premature
infants.
Sickle Cell Anemia
Sickle Cell Anemia

▪ Sickle cell syndromes, which can be divided
into sickle cell trait (SCT) and sickle cell
disease (SCD), are hereditary conditions
characterized by the presence of sickle
hemoglobin (HbS) in red blood cells (RBCs).
▪ SCT is the heterozygous inheritance of one
normal β-globin gene producing hemoglobin
A (HbA) and one sickle gene producing HbS
(HbAS) gene. Individuals with SCT are
asymptomatic.
▪ SCD can be of homozygous or compounded
heterozygous inheritance.
▪ Homozygous HbS (HbSS) has historically
been referred to as sickle cell anemia (SCA),
which now also includes HbSβ0-thal due to
similarities in clinical severity.
▪ Heterozygous inheritance of HbS with
another qualitative or quantitative β-globin
mutation results in sickle cell hemoglobin C
(HbSC), sickle cell β-thalassemia (HbSβ+-thal
and HbSβ0-thal), and some other rare
phenotypes.
PATHOPHYSIOLOGY

Clinical manifestations of SCD are due to
impaired circulation, RBC destruction, and stasis
of blood flow and ongoing inflammatory
responses.
☐ These changes result from disturbances in
RBC polymerization and membrane damage.
☐ In addition to sickling, other factors
contributing to the clinical manifestations
include functional asplenia (and increased risk
of infection by encapsulated organisms),
deficient opsonization, and coagulation
abnormalities
▪ Polymerization allows deoxygenated
hemoglobin to exist as a semisolid gel that
protrudes into the cell membrane, distorting
RBCs into sickle shapes. Sickle-shaped
▪ RBCs increase blood viscosity and encourage
sludging in the capillaries and small vessels,
leading to local tissue hypoxia that
accentuates the pathologic process.
Repeated cycles of sickling, upon
deoxygenation, and unsickling, upon
oxygenation, damage the RBC membrane
and cause irreversible sickling.
☐ Rigid, sickled RBCs are easily trapped,
resulting in shortened circulatory survival
and chronic hemolysis.
CLINICAL PRESENTATION
Cardinal features of SCD are hemolytic anemia and
vasoocclusion.
Symptoms are delayed until 4–6 months of age when
HbS replaces fetal hemoglobin (HbF). Common
findings include pain with fever, pneumonia,
splenomegaly, and, in infants, pain and swelling of the
hands and feet (eg, hand-and-foot syndrome or
dactylitis).
Usual clinical signs and symptoms of SCD include
chronic anemia; fever; pallor; arthralgia; scleral icterus;
abdominal pain; weakness; anorexia; fatigue; enlarged
liver, spleen, and heart; and hematuri
Acute complications of SCD include fever and
infection (eg, sepsis caused by encapsulated
pathogens such as Streptococcus
pneumoniae), stroke, acute chest syndrome,
and priapism.
Acute chest syndrome is characterized by
pulmonary infiltration, respiratory symptoms,
and equivocal response to antibiotic therapy.
Acute episodes of pain can be precipitated by
fever, infection, dehydration, hypoxia,
acidosis, and sudden temperature changes.
The most common type is vasoocclusive
pain, which is manifested by pain over the
involved areas without change in Hb.
Aplastic crisis is characterized by acute
decrease in Hb with decreased reticulocyte
count manifested as fatigue, dyspnea, pallor,
and tachycardia.
Acute splenic sequestration is the sudden
massive enlargement of the spleen due to
sequestration of sickled RBCs.
☐ The trapping of sickled RBCs by the spleen
leads to hypotension and shock, and can
cause sudden death in young children.
☐ Repeated infarctions lead to
autosplenectomy; therefore, incidence
declines as adolescence approaches.
▪ Chronic complications involve many organs
and include pulmonary hypertension, airway
inflammation and hyperresponsiveness, bone
and joint destruction, ocular problems,
cholelithiasis, cardiovascular abnormalities,
depression, hematuria, and other renal
complications.
▪ Children experience delayed growth and
sexual maturation.
▪ Patients with SCT are usually asymptomatic,
except for rare painless hematuria.
▪ Other reported complications associated with
SCT are delayed hemorrhage after eye
trauma, venous thromboembolism,
particularly pulmonary embolism, and chronic
kidney disease.
DIAGNOSIS

SCD is usually identified by routine neonatal
screening programs using isoelectric
focusing, high-performance liquid
chromatography, or electrophoresis.
Laboratory findings include:
☐ low hemoglobin; increased reticulocyte,
platelet, and white blood cell counts; and
sickled red cell forms on the peripheral
smear.
Prophylactic penicillin is recommended until
at least 5 years of age.
An effective regimen is penicillin V
potassium, 125 mg orally twice daily until 3
years of age and then 250 mg orally twice
daily until age 5 years.
DISEASE-MODIFYING THERAPIES

▪ HbF directly affects polymer formation.
▪ Increases in HbF correlate with decreased
RBC sickling and adhesion.
▪ Patients with low HbF levels have more
frequent pain and higher mortality.
▪ HbF levels of 20% or greater reduce the
risk of acute sickle cell complications.
▪ Hydroxyurea, a chemotherapeutic agent,
stimulates HbF production and increases the
number of HbF-containing reticulocytes and
intracellular HbF.
▪ It is indicated for patients 2 years of age and
older with recurrent moderate to severe
painful crises to reduce the frequency of pain
crises and the need for blood transfusions.
▪ The recommended single daily dose for adults
is 15 mg/kg and 20 mg/kg for children
l-Glutamine is approved for SCD patients age
5 and older to reduce the acute complications
of SCD.
☐ Dose is weight-based: 5 g twice a day for
65 kg.
▪ Chronic RBC transfusions are indicated for
primary and secondary stroke prevention and
amelioration of organ damage.
▪ Transfusions are usually given every 3–4 weeks or
as needed to maintain desired HbS levels.
▪ The optimal duration of primary prophylactic
transfusion therapy in children is unknown.
▪ Risks include alloimmunization, hyperviscosity,
viral transmission (requiring hepatitis A and B
vaccination), volume and iron overload, and
transfusion reactions
▪ Allogeneic hematopoietic stem cell
transplantation is the only curative therapy
for SCD.
▪ The best candidates are younger than 16
years, have severe complications, and
have human leukocyte antigen–matched
donors.
▪ Risks must be carefully considered and
include mortality, graft rejection, and
secondary malignancies.
TREATMENT OF COMPLICATIONS

▪ Educate patients to recognize conditions that
require urgent evaluation.
▪ Balanced fluid status and oxygen saturation
of at least 92% are important to avoid
exacerbation during acute illness.
▪ RBC transfusions are indicated for acute
exacerbation of baseline anemia (eg, aplastic
crisis, hepatic or splenic sequestration, or severe
hemolysis), severe vasoocclusive episodes, and
procedures requiring general anesthesia.
Promptly evaluate fever of 38.5°C (101.3°F) or
higher. Empiric antibiotic therapy should
provide coverage against encapsulated
organisms (eg, ceftriaxone for outpatients
and cefotaxime for inpatients; clindamycin
for cephalosporin-allergic patients).
For acute chest syndrome:
☐ initiate incentive spirometry; appropriate
fluid therapy; broad-spectrum antibiotics,
including a macrolide or quinolone; and, for
hypoxia or acute distress, oxygen therapy.
☐ Other potential therapies include steroids
and nitric oxide.
Priapism has been treated with analgesics,
antianxiety agents, and vasoconstrictors to
force blood out of the corpus cavernosum
(eg, phenylephrine and epinephrine), and
vasodilators to relax smooth muscle (eg,
terbutaline and hydralazine).
Treatment of aplastic crisis is primarily
supportive. Blood transfusions may be
indicated for severe or symptomatic anemia.
Hydration and blood transfusions are
indicated to treat hypovolemia associated
with splenic sequestration.
☐ Manage recurrent episodes with
observation and splenectomy.
☐ Consider chronic transfusions in children
younger than 2 years of age to delay
splenectomy until the age of 2 years.
☐ Splenectomy is an option for chronic
hypersplenism.
Hydration and analgesics are mainstays of
treatment for vasoocclusive (painful) crisis.
☐ Administer fluids IV or orally at 1–1.5 times
the maintenance requirement; monitor
closely to avoid volume overload.
☐ Consider an infectious etiology and initiate
empiric therapy if indicated
Tailor analgesic therapy to the individual
because of the variable frequency and
severity of pain.
☐ Pain scales should be used to quantify the
degree of pain.
☐ Use nonsteroidal anti-inflammatory
drugs (NSAIDs) or acetaminophen for
mild to moderate pain. Consider adding an
opioid if mild to moderate pain persists.
(eg, codeine or hydrocodone).
Treat severe pain aggressively with an opioid,
such as morphine, hydromorphone, fentanyl,
or methadone.
☐ Avoid meperidine due to accumulation of
the normeperidine metabolite, which can
cause neurotoxicity, especially in patients
with impaired renal function.
▪ Treat severe pain with an IV opioid titrated to
pain relief and then administered on a
scheduled basis with as-needed dosing for
breakthrough pain
▪ Patient-controlled analgesia is commonly
utilized.
▪ Treatment of chronic pain in SCD requires an
interprofessional team approach.
▪ Guidelines for chronic pain management are
available.
EVALUATION OF THERAPEUTIC OUTCOMES

▪ Evaluate patients on a regular basis to establish
baseline symptoms, monitor changes, and provide
age-appropriate education.
▪ Evaluate CBC and reticulocyte counts every 3–6
months up to 2 years of age, then every 6–12 months.
▪ Screen HbF level annually until 2 years of age.
▪ Evaluate renal, hepatobiliary, and pulmonary function
annually. Screen patients for retinopathy.
▪ Assess efficacy of hydroxyurea by monitoring the
number, severity, and duration of sickle cell crises.