NCM-113-M3-Lesson-1 PDF Nursing Care

Summary

This lesson provides an overview of the anatomy and physiology of the cardiovascular and hematologic systems, focusing on the provision of safe and appropriate care for at-risk and sick adult clients with oxygenation problems. It highlights the importance of using the nursing process in client care.

Full Transcript

Nursing Care of at risk and sick adult clients with
CHAPTER
alterations/problems in oxygenation
3
(Cardiovascular and Hematologic Function)

This chapter will provide an overview of the anatomy and physiology of
the cardiovascular system and hematologic system to give students a better
understanding of the concept. This chapter will also focus on the provision of
safe, appropriate and holistic care which are specific to at risk and sick adult
clients with problems in oxygenation. Also, this chapter will give highlight on
the importance of utilizing the Nursing Process in taking care of the above-
mentioned group.

General objective
At the end of this chapter, the students will have an understanding on
the appropriate nursing care to at risk and sick adult clients with alterations or
problems in oxygenation.

Lesson 1 – Overview of the Anatomy and Physiology,
and the Nursing Process
This lesson will provide students with significant concepts about the
structures of the cardiovascular system and hematologic system with its
functions. Also, this lesson will highlight on the proper assessment skills in
dealing with clients with problems / alterations in the cardiovascular and
hematologic systems.

Lesson objectives:
At the end of the lesson, the students are expected to:
1. describe the parts and functions of the cardiovascular and hematologic
systems;
2. perform the proper techniques in assessing at risk and sick adult clients;
3. differentiate the normal and abnormal assessment findings; and
4. identify the major symptoms of cardiovascular and hematologic alterations
and/or problems.

Overview of the Anatomy and Physiology

Anatomy of the Heart
The heart contributes to homeostasis by pumping blood through blood
vessels to the tissues of the body to deliver oxygen and nutrients and remove
wastes. The heart is located in the mediastinum, the area between the lungs
in the thoracic cavity.
The heart is composed of three layers. The inner layer, or endocardium,

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consists of endothelial tissue and lines the inside of the heart and valves. The
middle layer, or myocardium, is made up of muscle fibers and is responsible
for the pumping action. The exterior layer of the heart is called the epicardium.

The heart is encased in a thin, fibrous
sac called the pericardium, which is
composed of two layers. Adhering to the
epicardium is the visceral pericardium.
Enveloping the visceral pericardium is the
parietal pericardium, a tough fibrous tissue
that attaches to the great vessels, diaphragm,
sternum, and vertebral column and supports
the heart in the mediastinum. The space
between these two layers (pericardial space)
is normally filled with about 20 mL of fluid,
which lubricates the surface of the heart and
reduces friction during systole.

Heart Chambers
- Cardiac muscle tissue, the myocardium, forms the walls of the four
chambers of the heart.
- Endocardium lines the chambers and covers the valves of the heart; is
simple squamous epithelium that is very smooth and prevents abnormal
clotting.

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 - The right and left atria are the upper chambers, separated by the
interatrial septum. The atria receive blood from veins.
- The right and left ventricles are the lower chambers, separated by the
interventricular septum. The ventricles pump blood into arteries.

Heart Valves
The four valves in the heart permit blood to flow in only one direction.
The valves, which are composed of thin leaflets of fibrous tissue, open and
close in response to the movement of blood and pressure changes within the
chambers. There are two types of valves: atrioventricular (separate the atria
from the ventricles) and semilunar (forced to open during ventricular systole
as blood is ejected from the right and left ventricles into the pulmonary artery
and aorta).

Coronary Arteries
- Pathway: ascending aorta to right and left coronary arteries, to smaller
arteries, to capillaries, to coronary veins, to the coronary sinus, to the
right atrium.
- Coronary circulation supplies oxygenated blood to the myocardium.
- Obstruction of a coronary artery causes a myocardial infarction: death of
an area of myocardium due to lack of oxygen.

Myocardium
It is composed of specialized cells called myocytes, which form an
interconnected network of muscle fibers. During contraction, this muscular
configuration facilitates a twisting and compressive movement of the heart that
begins in the atria and moves to the ventricles. The sequential and rhythmic
pattern of contraction, followed by relaxation of the muscle fibers, maximizes
the volume of blood ejected with each contraction. This cyclical pattern of
myocardial contraction is controlled by the conduction system.

Function of the Heart
Cardiac Electrophysiology
The cardiac conduction system generates and transmits electrical
impulses that stimulate contraction of the myocardium. Under normal
circumstances, the conduction system first stimulates contraction of the atria
and then the ventricles.
Both the sinoatrial (SA) node (the primary pacemaker of the heart) and
the atrioventricular (AV) node (the secondary pacemaker of the heart) are
composed of nodal cells. The SA node is located at the junction of the superior
vena cava and the right atrium. The SA node in a normal resting adult heart has
an inherent firing rate of 60 to 100 impulses per minute; however, the rate
changes in response to the metabolic demands of the body. The impulses
cause electrical stimulation and subsequent contraction of the atria.

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 The impulses are then conducted to the AV node, which is located in the
right atrial wall near the tricuspid valve. The AV node coordinates the incoming
electrical impulses from the atria and after a slight delay (allowing the atria time
to contract and complete ventricular filling) relays the impulse to the ventricles.
Initially, the impulse is conducted through a bundle of specialized conducting
tissue, referred to as the bundle of His, which then divides into the right bundle
branch (conducting impulses to the right ventricle) and the left bundle branch
(conducting impulses to the left ventricle). To transmit impulses to the left
ventricle—the largest chamber of the heart—the left bundle branch divides into
the left anterior and left posterior bundle branches. Impulses travel through the
bundle branches to reach the terminal point in the conduction system, called
the Purkinje fibers which are specialized to rapidly conduct the impulses
through the thick walls of the ventricles. This is the point at which the myocardial
cells are stimulated, causing ventricular contraction.
The heart rate is determined by the myocardial cells with the fastest inherent
firing rate. Under normal circumstances, the SA node has the highest inherent
rate (60 to 100 impulses per minute), the AV node has the second-highest
inherent rate (40 to 60 impulses per minute), and the ventricular pacemaker
sites have the lowest inherent rate (30 to 40 impulses per minute).
If the SA node malfunctions, the AV node generally takes over the
pacemaker function of the heart at its inherently lower rate. Should both the SA
and the AV nodes fail in their pacemaker function, a pacemaker site in the
ventricle will fire at its inherent bradycardic rate of 30 to 40 impulses per minute.

Cardiac Action Potential
The cells of the SA node are more permeable to sodium ions and
depolarize more rapidly than any other part of the myocardium. Depolarization
of the SA node spreads to the AV node and to the atrial myocardium and brings
about atrial systole. The AV bundle (bundle of His) is in the upper
interventricular septum; the first part of the ventricles to depolarize. The right
and left bundle branches in the interventricular septum transmit impulses to the
Purkinje fibers in the ventricular myocardium, which complete ventricular
systole.
This relationship changes during cellular stimulation, when sodium or
calcium crosses the cell membrane into the cell and potassium ions exit into
the extracellular space. This exchange of ions creates a positively charged
intracellular space and a negatively charged extracellular space that
characterizes the period known as depolarization. Once depolarization is
complete, the exchange of ions reverts to its resting state; this period is known
as repolarization. The repeated cycle of depolarization and repolarization is
called the cardiac action potential. The cardiac action potential has five
phases:
Phase 0: Cellular depolarization is initiated as positive ions influx into the
cell. During this phase, the atrial and ventricular myocytes rapidly

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 depolarize as sodium moves into the cells through sodium fast channels.
The myocytes have a fast response action potential. In contrast, the cells
of the SA and AV node depolarize when calcium enters these cells
through calcium slow channels. These cells have a slow response action
potential.
Phase 1: Early cellular repolarization begins during this phase as
potassium exits the intracellular space.
Phase 2: This phase is called the plateau phase because the rate of
repolarization slows. Calcium ions enter the intracellular space.
Phase 3: This phase marks the completion of repolarization and return
of the cell to its resting state.
Phase 4: This phase is considered the resting phase before the next
depolarization.

Cardiac Hemodynamics
An important determinant of blood flow in the cardiovascular system is
the principle that fluid flows from a region of higher pressure to one of lower
pressure. The pressures responsible for blood flow in the normal circulation are
generated during systole and diastole. The cardiac cycle refers to the events
that occur in the heart from the beginning of one heartbeat to the next. The
number of cardiac cycles completed in a minute depends on the heart rate.
Each cardiac cycle has three major sequential events: diastole, atrial systole,
and ventricular systole. These events cause blood to flow through the heart due
to changes in chamber pressures and valvular function during diastole and
systole.
Moreover, cardiac output is the amount of blood pumped by a ventricle
in one minute. Stroke volume is the amount of blood pumped by a ventricle in
one beat (average is 60 to 80 mL). Cardiac output equals stroke volume pulse;
average resting cardiac output is 5 to 6 liters. Starling’s law of the heart—the
more cardiac muscle fibers are stretched, the more forcefully they contract.
During exercise, stroke volume increases as venous return increases and
stretches the myocardium of the ventricles (Starling’s law). During exercise, the
increase in stroke volume and the increase in pulse result in an increase in
cardiac output: two to four times the resting level. Cardiac reserve is the
difference between resting cardiac output and the maximum cardiac output;
may be 15 liters or more. The ejection fraction is the percent of its total blood
that a ventricle pumps per beat; average is 60% to 70%.

Assessment of the Cardiovascular System

Health History
- The nurse needs to determine if the patient and involved family members
are able to recognize symptoms of an acute cardiac problem, such as

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 ACS or HF, and seek timely treatment for these symptoms. Responses
to this level of inquiry will help the nurse individualize the plan for patient
and family education.

Common Symptoms
The following are the most common signs and symptoms of CVD, with
related medical diagnoses in parentheses:
- Chest pain or discomfort (angina pectoris, ACS, dysrhythmias, valvular
heart disease)
- Shortness of breath or dyspnea (ACS, cardiogenic shock, HF, valvular
heart disease)
- Peripheral edema, weight gain, abdominal distention due to enlarged
spleen and liver or ascites (HF)
- Palpitations (tachycardia from a variety of causes, including ACS,
caffeine or other stimulants, electrolyte imbalances, stress, valvular
heart disease, ventricular aneurysms)
- Unusual fatigue, sometimes referred to as vital exhaustion (an early
warning symptom of ACS, HF, or valvular heart disease, characterized
by feeling unusually tired or fatigued, irritable, and dejected)
- Dizziness, syncope, or changes in level of consciousness (cardiogenic
shock, cerebrovascular disorders, dysrhythmias, hypotension, postural
hypotension, vasovagal episode)

Past Health, Family, and Social History
In an effort to determine how the patient perceives his or her current
health status, the nurse must ask some of the following questions:
- How is your health? Have you noticed any changes from last year? From
5 years ago?
- Do you have a cardiologist or primary provider? How often do you go for
check-ups?
- What health concerns do you have?
- Do you have a family history of genetic disorders that place you at risk
for CVD? What are your risk factors for heart disease?
- What do you do to stay healthy and take care of your heart?

Physical Assessment

General Appearance
The nurse evaluates the patient’s level of consciousness (alert,
lethargic, stuporous, comatose) and mental status (oriented to person, place,
time; coherence). Patients are observed for signs of distress, which include pain
or discomfort, shortness of breath, or anxiety.
Also. the nurse notes the size of the patient (normal, overweight,
underweight, or cachectic). The patient’s height and weight are measured to

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calculate BMI (weight in kilograms/square of the height in meters), as well as
the waist circumference. These measures are used to determine if obesity (BMI
greater than 30 kg/m2) and abdominal fat (males: waist greater than 40 inches;
females: waist greater than 35 inches) are placing the patient at risk for CAD.

Assessment of the Skin and Extremities
- Six P’s: pain, pallor, pulselessness, paresthesia, poikilothermia
(coldness), and paralysis.
- Affected extremities should be assessed frequently for these acute
vascular changes.
- Hematoma (localized collection of clotted blood in the tissue, may be
observed in patients who have undergone invasive cardiac procedures.
- Edema of the feet, ankles, or legs is called peripheral edema. Sacral
edema can be observed in the sacral area of patients on bed rest. The
nurse assesses the patient for edema by using the thumb to place firm
pressure over the dorsum of each foot, behind each medial malleolus,
over the shins or sacral area for 5 seconds. Pitting edema is the term
used to describe an indentation in the skin created by this pressure.
Pitting edema is graded as absent (0) or as present on a scale from slight
(1+ = up to 2 mm) to very marked (4+ = more than 8 mm). Peripheral
edema is a common finding in patients with HF and peripheral vascular
diseases, such as deep vein thrombosis or chronic venous insufficiency.
- Prolonged capillary refill time indicates inadequate arterial perfusion to
the extremities. Normally, reperfusion occurs within 2 seconds, as
evidenced by the return of color to the nail bed. Prolonged capillary refill
time indicates compromised arterial perfusion, a problem associated
with cardiogenic shock and HF.
- Clubbing of the fingers and toes indicates chronic hemoglobin
desaturation and is associated with congenital heart disease.
- Hair loss, brittle nails, dry or scaling skin, atrophy of the skin, skin color
changes, and ulcerations are indicative of chronically reduced oxygen
and nutrient supply to the skin observed in patients with arterial or
venous insufficiency.

Blood Pressure
A normal BP in adults is considered a systolic BP less than 120 mm Hg
over a diastolic BP less than 80 mm Hg. High BP, or hypertension, is defined
by having a systolic BP that is consistently greater than 140 mm Hg or a
diastolic BP greater than 90 mm Hg. Hypotension refers to an abnormally low
systolic and diastolic BP that can result in lightheadedness or fainting.

Arterial Pulses
The arteries are palpated to evaluate the pulse rate, rhythm, amplitude,
contour, and obstruction to blood flow.

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Pulse Rate
The normal pulse rate varies from a low of 50 bpm in healthy, athletic
young adults to rates well in excess of 100 bpm after exercise or during times
of excitement. Anxiety frequently raises the pulse rate during the physical
examination. If the rate is higher than expected, the nurse should reassess the
pulse near the end of the physical examination, when the patient may be more
relaxed.

Pulse Rhythm
The rhythm of the pulse is normally regular. The pulse rate may increase
during inhalation and slow during exhalation due to changes in blood flow to the
heart during the respiratory cycle. This phenomenon, called sinus arrhythmia,
occurs most commonly in children and young adults.
For the initial cardiac examination, or if the pulse rhythm is irregular, the
heart rate should be counted by auscultating the apical pulse, located at the
PMI, for a full minute while simultaneously palpating the radial pulse. Any
discrepancy between contractions heard and pulses felt is noted. Disturbances
of rhythm (dysrhythmias) often result in a pulse deficit, which is a difference
between the apical and radial pulse rates. Pulse deficits commonly occur with
atrial fibrillation, atrial flutter, and premature ventricular contractions. These
dysrhythmias stimulate the ventricles to contact prematurely, before diastole is
finished.

Pulse Amplitude
The pulse amplitude, indicative of the BP in the artery, is used to assess
peripheral arterial circulation. The nurse assesses pulse amplitude bilaterally
and describes and records the amplitude of each artery. The simplest method
characterizes the pulse as absent, diminished, normal, or bounding. Scales are
also used to rate the strength of the pulse. The following is an example of a 0-
to-4 scale:
0: Not palpable or absent
+1: Diminished—weak, thready pulse; difficult to palpate; obliterated with
pressure
+2: Normal—cannot be obliterated
+3: Moderately increased—easy to palpate, full pulse; cannot be
obliterated
+4: Markedly increased—strong, bounding pulse; may be abnormal

Palpation of Arterial Pulses
To assess peripheral circulation, the nurse locates and evaluates all
arterial pulses. Arterial pulses are palpated at points where the arteries are near
the skin surface and are easily compressed against bones or firm musculature.
Pulses are detected over the right and left temporal, common carotid, brachial,
radial, femoral, popliteal, dorsalis pedis, and posterior tibial arteries.

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Jugular Venous Pulsations
If the internal jugular pulsations are difficult to see, pulsations of the
external jugular veins may be noted. These veins are more superficial and are
visible just above the clavicles, adjacent to the sternocleidomastoid muscles.
In patients who have normal blood volume (euvolemia), the jugular veins
are normally visible in the supine position with the head of the bed elevated to
30 degrees. Obvious distention of the veins with the patient’s head elevated 45
to 90 degrees indicates an abnormal increase in CVP. This abnormality is
observed in patients with right-sided HF, due to hypervolemia, pulmonary
hypertension, and pulmonary stenosis; less commonly with obstruction of blood
flow in the superior vena cava; and rarely with acute massive pulmonary
embolism.

Heart Inspection and Palpation
A systematic approach is used to examine the precordium in the
following six areas.
1. Aortic area—second intercostal
space to the right of the sternum.
To determine the correct
intercostal space, the nurse first
finds the angle of Louis by
locating the bony ridge near the
top of the sternum, at the junction
of the sternum and the
manubrium. From this angle, the
second intercostal space is
located by sliding one finger to the left or right of the sternum.
Subsequent intercostal spaces are located from this reference point by
palpating down the rib cage
2. Pulmonic area—second intercostal space to the left of the sternum
3. Erb’s point—third intercostal space to the left of the sternum
4. Tricuspid area—fourth and fifth intercostal spaces to the left of the
sternum
5. Mitral (apical) area—left fifth intercostal space at the midclavicular line
6. Epigastric area—below the xiphoid process

Heart Auscultation
Normal Heart Sounds
S1—First Heart Sound. Tricuspid and mitral valve closure creates the first
heart sound (S1). The word “lub” is used to replicate its sound. S1 is usually
heard the loudest at the apical area. S1 is easily identifiable and serves as the
point of reference for the remainder of the cardiac cycle.

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S2—Second Heart Sound. Closure of the pulmonic and aortic valves produces
the second heart sound (S2), commonly referred to as the “dub” sound. The
aortic component of S2 is heard the loudest over the aortic and pulmonic areas.
However, the pulmonic component of S2 is a softer sound and is heard best
over the pulmonic area.

Abnormal Heart Sounds
Abnormal sounds develop during systole or diastole when structural or
functional heart problems are present. These sounds are called S3 or S4
gallops, opening snaps, systolic clicks, and murmurs.

S3—Third Heart Sound. An S3 (“DUB”) is heard early in diastole during the
period of rapid ventricular filling as blood flows from the atrium into a
noncompliant ventricle. It is heard immediately after S2. “Lub-dub-DUB” is used
to imitate the abnormal sound of a beating heart when an S3 is present. It
represents a normal finding in children and adults up to 35 or 40 years of age.
In these cases, it is referred to as a physiologic S3. In older adults, an S3 is a
significant finding, suggesting HF. It is best heard with the bell of the
stethoscope. If the right ventricle is involved, a right-sided S3 is heard over the
tricuspid area with the patient in a supine position. A left-sided S3 is best heard
over the apical area with the patient in the left lateral position.

S4—Fourth Heart Sound. S4 (“LUB”) occurs late in diastole. S4 heard just
before S1 is generated during atrial contraction as blood forcefully enters a
noncompliant ventricle. This resistance to blood flow is due to ventricular
hypertrophy caused by hypertension, CAD, cardiomyopathies, aortic stenosis,
and numerous other conditions. “LUB lub-dub” is the mnemonic used to imitate
this gallop sound. A right-sided S4, although less common, is heard best over
the tricuspid area with the patient in supine position. There are times when both
S3 and S4 are present, creating a quadruple rhythm, which sounds like “LUB
lub-dub DUB.” During tachycardia, all four sounds combine into a loud sound,
referred to as a summation gallop.

Opening Snaps and Systolic Clicks. Normally, no sound is produced when
valves open. However, diseased valve leaflets create abnormal sounds as they
open during diastole or systole. Opening snaps are abnormal diastolic sounds
heard during opening of an AV valve. For example, mitral stenosis can cause
an opening snap, which is an unusually high-pitched sound very early in
diastole. Timing helps to distinguish an opening snap from the other gallop
sounds. It occurs too long after S2 to be mistaken for a split S2 and too early in
diastole to be mistaken for an S3. The high-pitched, snapping quality of the
sound is another way to differentiate an opening snap from an S3. Hearing a
murmur or the sound of turbulent blood flow is expected following the opening

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snap. An opening snap is heard best using the diaphragm of the stethoscope
placed medial to the apical area and along the lower left sternal border.
In a similar manner, stenosis of one of the semilunar valves creates a
short, high-pitched sound in early systole, immediately after S1. This sound,
called a systolic click, is the result of the opening of a rigid and calcified aortic
or pulmonic valve during ventricular contraction. Mid- to late systolic clicks may
be heard in patients with mitral or tricuspid valve prolapse as the malfunctioning
valve leaflet is displaced into the atrium during ventricular systole. Murmurs are
expected to be heard following these abnormal systolic sounds. These sounds
are the loudest in the areas directly over the malfunctioning valve.

Murmurs. Murmurs are created by turbulent flow of blood in the heart. The
causes of the turbulence may be a critically narrowed valve, a malfunctioning
valve that allows regurgitant blood flow, a congenital defect of the ventricular
wall, a defect between the aorta and the pulmonary artery, or an increased flow
of blood through a normal structure (e.g., with fever, pregnancy,
hyperthyroidism). Murmurs are characterized and consequently described by
several characteristics, including their timing in the cardiac cycle, location on
the chest wall, intensity, pitch, quality, and pattern of radiation.

Friction Rub. A harsh, grating sound that can be heard in both systole and
diastole is called a friction rub. It is caused by abrasion of the inflamed
pericardial surfaces from pericarditis. Because a friction rub may be confused
with a murmur, care should be taken to identify the sound and to distinguish it
from murmurs that may be heard in both systole and diastole. A pericardial
friction rub can be heard best using the diaphragm of the stethoscope, with the
patient sitting up and leaning forward.

Assessment of Other Systems

Lungs
Findings frequently exhibited by patients with cardiac disorders include
the following:
- Hemoptysis
- Cough
- Crackles
- Wheezes:

Abdomen
For the patient with a cardiovascular disorder, several components of
the abdominal examination are relevant:
- Abdominal distension
- Hepatojugular reflux
- Bladder distention

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Structure and Function of the Hematologic System

Blood
Blood is the river of life that surges within us. Blood contributes to
homeostasis by transporting oxygen, carbon dioxide, nutrients, and hormones
to and from your body’s cells. It helps regulate body pH and temperature, and
provides protection against disease through phagocytosis and the production
of antibodies.
The general functions of blood are transportation, regulation, and
protection.

Characteristics of Blood
Amount - 4 to 6 liters; 38% to 48% is cells; 52% to 62% is plasma
Color - arterial blood has a high oxygen content and is bright red;
venous blood has less oxygen and is dark red.
pH - 7.35 to 7.45; venous blood has more CO2 and a lower pH than
arterial blood.
Viscosity - thickness or resistance to flow; due to the presence of cells
and plasma proteins; contributes to normal blood pressure.

Plasma
- 91% water
- Plasma transports nutrients, wastes, hormones, antibodies, and CO2 as
HCO3–.
- Plasma proteins: clotting factors are synthesized by the liver; albumin is
synthesized by the liver and provides colloid osmotic pressure that pulls
tissue fluid into capillaries to maintain normal blood volume and blood
pressure; alpha and beta globulins are synthesized by the liver and are
carriers for fats and other substances in the blood; gamma globulins are
antibodies produced by lymphocytes.

Blood Cells
- Formed elements are RBCs, WBCs, and platelets.
- After birth the primary hemopoietic tissue is the red bone marrow, which
contains stem cells. Lymphocytes mature and divide in the lymphatic
tissue of the spleen, lymph nodes, and thymus, which also have stem
cells for lymphocytes.

Red Blood Cells
- Biconcave discs; no nuclei when mature.
- RBCs carry O2 bonded to the iron in hemoglobin.
- RBCs are formed in the RBM from hemocytoblasts (stem cells, the
precursor cells).

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 - Hypoxia stimulates the kidneys to produce the hormone erythropoietin,
which increases the rate of RBC production in the RBM.
- Immature RBCs: normoblasts (have nuclei) and reticulocytes; large
numbers in peripheral circulation indicate a need for more RBCs to carry
oxygen.
- Vitamin B12 is the extrinsic factor, needed for DNA synthesis (mitosis) in
stem cells in the RBM. Intrinsic factor is produced by the parietal cells of
the stomach lining; it combines with B12 to prevent its digestion and
promote its absorption.
- RBCs live for 120 days and are then phagocytized by macrophages in
the liver, spleen, and RBM. The iron is returned to the RBM or stored in
the liver. The heme of the hemoglobin is converted to bilirubin, which the
liver excretes into bile to be eliminated in feces. Colon bacteria change
bilirubin to urobilinogen. Any urobilinogen absorbed is converted to
urobilin and excreted by the kidneys in urine. Jaundice is the
accumulation of bilirubin in the blood, perhaps due to liver disease.
- ABO blood types are hereditary. The type indicates the antigen(s) on the
RBCs; antibodies in plasma are for those antigens not present on the
RBCs and are important for transfusions.
- The Rh type is also hereditary. Rh positive means that the D antigen is
present on the RBCs; Rh negative means that the D antigen is not
present on the RBCs. Rh-negative people do not have natural antibodies
but will produce them if given Rh positive blood.

White Blood Cells
- Larger than RBCs; have nuclei when mature; produced in the red bone
marrow, except some lymphocytes produced in the thymus.
- Granular WBCs are the neutrophils, eosinophils and basophils.
- Agranular WBCs are the lymphocytes and monocytes.
- Neutrophils and monocytes phagocytize pathogens; monocytes become
macrophages, which also phagocytize dead tissue.
- Eosinophils detoxify foreign proteins during allergic reactions and
parasitic infections; they phagocytize anything labeled with antibodies.
- Basophils contain the anticoagulant heparin and histamine, which
contributes to inflammation.
- Lymphocytes: T cells, B cells, and natural killer cells. T cells recognize
foreign antigens and destroy them. B cells become plasma cells, which
produce antibodies to foreign antigens. NK cells destroy foreign cell
membranes.
- WBCs carry out their functions in tissue fluid and lymphatic tissue, as
well as in the blood.

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Platelets
- Platelets are formed in the RBM and are fragments of megakaryocytes;
the hormone thrombopoietin from the liver increases platelet production.
- Platelets are involved in all mechanisms of hemostasis (prevention of
blood loss)
- Vascular spasm - large vessels constrict when damaged, the myogenic
response. Platelets release serotonin, which also causes
vasoconstriction. The break in the vessel is made smaller and may be
closed with a blood clot.
- Platelet plugs - rupture of a capillary creates a rough surface to which
platelets stick and form a barrier over the break.
- Chemical clotting involves platelet factors, chemicals from damaged
tissue, prothrombin, fibrinogen and other clotting factors synthesized by
the liver, and calcium ions. The clot is formed of fibrin threads that form
a mesh over the break in the vessel.
- Clot retraction is the folding of the fibrin threads to pull the cut edges of
the vessel closer together to facilitate repair. Fibrinolysis is the dissolving
of the clot once it has served its purpose.
- Abnormal clotting (thrombosis) is prevented by the very smooth
endothelium (simple squamous epithelium) that lines blood vessels;
heparin, which inhibits the clotting process; and antithrombin
(synthesized by the liver), which inactivates excess thrombin.

Assessment

Health History
Careful attention to the onset of a symptom or finding (e.g., rapid vs.
gradual; persistent vs. intermittent), its severity, and any contributing factors
can further differentiate potential causes. Of equal importance is assessing the
impact of these findings on the patient’s functional ability, manifestations of
distress, and coping mechanisms.

Physical Assessment
The physical assessment should be comprehensive and include careful
attention to the skin, oral cavity, lymph nodes, and spleen.

Lymph Node Assessment
Assess lymph nodes symmetrically and take note of location, size (in
centimeters), degree of fixation (e.g., movable, fixed), tenderness, and texture.
Examine superficial lymph nodes with light palpation. Ordinarily, lymph nodes
are not palpable in adults. If a node is palpable, it should be small (0.5 to 1 cm),
mobile, firm, and nontender to be considered a normal finding. A node that is
tender, hard, fixed, or enlarged (regardless if it is tender or not) is an abnormal

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finding and needs further investigation. Tender nodes are usually a result of
inflammation. Hard or fixed nodes suggest cancer.

Palpation of Liver or Spleen
The liver and spleen are normally not detectable by palpating the
abdomen. An enlarged liver or spleen may be detectable by percussion or
palpation. Measure the degree of liver enlargement by the number of
fingerbreadths it extends below the rib border. The spleen may be harder to
detect because of its deep location in the left abdomen.

Skin Assessment
Skin assessment may be a valuable source of information about the
hematologic system. In patients with RBC disorders, the skin may be pale or
pasty or it may have a cyanotic tinge in severe anemia. Erythrocytosis often
causes small vessel occlusions causing a purple, mottled appearance of the
face, nose, fingers, or toes. Color changes in dark-skinned persons are best
assessed in the sclera, conjunctiva, buccal mucosa, tongue, lips, nail beds, and
palms. Clubbing of the fingers can be seen with chronic anemia.
WBC disorders may cause infectious or cancerous skin lesions. Look for
findings that can indicate bleeding disorders. Assess for petechiae (small
purplish red pinpoint lesions), ecchymoses (bruising), and spider nevus (a
form of telangiectasia). Petechiae are more likely to occur where clothing
constricts the circulation.

Summary
Because of the prevalence of CVD, nurses practicing in any setting
across the continuum of care, whether in the home, office, hospital,
long-term care facility, or rehabilitation facility, must be able to assess
the cardiovascular system. Key components of assessment include a
health history, physical assessment, and monitoring of a variety of
laboratory and diagnostic test results.
This assessment provides the data necessary to identify nursing
diagnoses, formulate an individualized plan of care, evaluate the
response of the patient to the care provided, and revise the plan as
needed.
Patients with hematologic disorders often have significant
abnormalities in blood tests but few or no symptoms. Therefore, the
nurse must have a good understanding of the pathophysiology of the
patient’s condition and the ability to make a thorough assessment that
relies heavily on the interpretation of laboratory tests.

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