Advanced Bedside Assessment PDF

Summary

This document provides learning objectives, terminology, and common symptoms related to bedside assessment of patients with cardiopulmonary disease. It emphasizes the importance of patient interviews and physical examinations in identifying the need for further diagnostic tests.

Full Transcript

Bedside Assessment of the
Patient
RC 1 M 3
Professor Barrette, MBA, RRT-
ACCS, NPS, RPFT

1
 Learning Objectives
Describe why patient interviews are necessary and the
appropriate techniques for conducting an interview.
Differentiate between signs and symptoms.
Identify abnormalities in lung function associated with
common pulmonary symptoms.
Identify breathing patterns associated with underlying
pulmonary disease.
Differentiate between dyspnea and breathlessness.
Identify terms used to describe normal and abnormal lung
sounds.
 Learning Objectives (cont.)
Describe the mechanisms responsible for normal and abnormal
lung sounds.
Explain why it is necessary to examine the precordium,
abdomen, and extremities in a patient with cardiopulmonary
disease.
Describe some of the common abnormalities found during the
exam of the precordium, abdomen, and extremities in patients
with cardiopulmonary disease.
Identify the three main tests used to diagnose coagulation
disorders.
Describe how the sputum Gram stain and culture are used to
diagnose patients with pulmonary infections.
 Learning Objectives (cont.)
Describe what a critical value is and state its
importance in clinical practice.
Define the following terms related to clinical lab
tests: leukocytosis, leukopenia, anemia,
polycythemia, and thrombocytopenia.
Identify which electrolyte disturbances interfere
with normal respiratory function.
Describe clinical tests used to identify cardiac
stress and myocardial infarction.
 Why Build Assessment Skills?
Decisions regarding when to initiate, change, or
discontinue therapy (tx) depend on accurate
clinical assessments.
RTs often play a vital role in clinical decision
making and must therefore develop competent
bedside assessment skills.
RT must assume responsibility for gathering and
interpreting relevant bedside patient data.

5
Why Build Assessment Skills? (cont.)
Bedside assessment:
1. Process of interviewing and examining a patient
for signs and symptoms of disease
2. Evaluating the effects of treatment

Very often bedside assessment techniques provide initial
evidence that something is wrong AND are of little risk to
the patient
6
Why Build Assessment Skills? (cont.)
Two key sources of patient data:
The patient’s medical history
Physical examination

Data gathered during the initial patient interview and physical
examination help identify the need for subsequent diagnostic
tests.
After a tentative diagnosis is made, these assessment skills are
used repeatedly to monitor the patient’s response to therapy,
monitor the patient’s response to therapy, and make any
necessary adjustments.

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 Patient Assessment
Life functions – getting O2 from the air to all the
cells of the body
(4) Critical Life Functions
1. Ventilation – moving air in and out of the
lungs
2. Oxygenation – getting O2 into the blood
3. Circulation – moving the blood through the
body
4. Perfusion – getting oxygen into the
tissues/cells
 Patient Assessment (Cont.)
We measure these (4) life functions in many ways, one
of which is using vital signs
Ventilation – RR, VT, Chest Movement, Breath sounds,
PaCO2 , ETCO2
Oxygenation – HR, Color, Sensorium, PaO2 , SpO2
Circulation – HR and strength, cardiac output
Perfusion – BP, sensorium, temperature, urine output,
hemodynamics
Assessment and treatment should be based on life
functions because almost every part of assessment
relates to one of these 4 life functions
 Patient Assessment (Cont.)
If assessment of the life functions identifies problems, they must
be treated or corrected right away
If any of these life functions are absent (i.e., no breathing, no
pulse, no blood pressure) then there is an emergency, which may
require resuscitation
When there is an emergency:
1. 1st priority is ventilation*
2. 2nd priority is oxygenation
3. 3rd priority is circulation
4. 4th priority is perfusion
The most common problem is with oxygenation
 Basic Terminology
Diagnosis (Dx:) is the process of identifying the nature and cause of
illness
A disciplined, systematic approach based on careful history taking, physical
examination, and testing (primarily performed by a physician)
Differential diagnosis (Diff Dx:) is the term used when signs and
symptoms are shared by many diseases and the exact cause is unclear
(i.e., cough)
Is the list of all possible causes of a sign or symptom
Signs refer to the objective manifestation of illness (i.e., increased RR,
HR, BP)
Symptoms refer to the sensation or subjective experience of some
aspect of an illness
Symptoms must always be stated by the patient and NEVER assumed from
observed signs.

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 Basic Terminology (cont.)
Chief Complaint (CC) – is a concise statement by the patient or
family member relating to his/her reason for seeking medical
attention.
“Why are you here?” or “What medical problem brought you
to the hospital?”
The patient’s primary symptom described in his/her OWN
words!
Identification of the CC is the 1st step in determining the
admitting diagnosis.
Provides a starting point with which to guide the patient
history, physical, and diagnostic testing.
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 Basic Terminology (cont.)
History of the present illness (HPI) – is a detailed description of the
symptoms, chronology of events, and resultant impact on the
patient’s health
Each symptom is fully described in terms of the nature of the
symptom, its location, and its severity
Rule out (R/O) - means to eliminate as a possibility. (i.e., a doctor
may have a patient's blood pressure tested to rule out high blood
pressure. That is, the doctor wants to know if the results from the
test will eliminate the possibility that the patient has high blood
pressure.
Status post (S/P) - “condition after” means that the client has
had the procedure or event in the past. (s/p appendectomy)

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14
 Interviewing
Interviewing for Cardiopulmonary Symptoms:
Dyspnea
Cough
Sputum production
Chest pain
Fever and/or sweating
Pedal edema
Syncope (dizziness and fainting) - temporary loss of
consciousness caused by reduced blood flow and
therefore a reduced supply of oxygen and nutrients to
the brain.
 Common Cardiopulmonary
Symptoms
Dyspnea
Sensation of breathing discomfort by patient (subjective feeling)
Cannot be inferred from observing a pt.’s breathing pattern
Most important symptom RT is called upon to assess and treat
Often perceived as life-threatening and may provoke a profound sense
of dread
During the interview, RT should pay attention to whether or not the
patient can speak in full sentences
Pt.’s with severe dyspnea often cannot speak more than a few words at a
time
If this is the case, interview should be condensed and treatment initiated
ASAP
When possible, questions should be brief and limited to yes or no responses
in severe dyspnea
Quality and intensity of dyspnea? Onset? Duration?

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 Common Cardiopulmonary
Symptoms (cont.)
Dyspnea (cont.)
Thought to be derived from the interaction of various
physiological, psychological, social, and environmental
factors.
Underlying cause may be pulmonary, cardiac,
hematologic, neurologic, psychogenic, metabolic, or
mechanical.
Treatment should be aimed at the underlying cause
Pt.’s may describe as an increased WOB, chest tightness,
or “air hunger”
“I feel short of breath.” “I’m having difficulty breathing.” “I can’t catch my
breath.”

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 Common Cardiopulmonary
Symptoms
Dyspnea cont.
3 complex factors influence the perception of breathing:
1. The neural drive to breathe coming from the
respiratory centers in the brain
2. Tension developed in the respiratory muscles
3. The corresponding displacement of the lungs and
chest wall

When the neuronal signals in charge of these sensations
become unbalanced, breathing is perceived to be
abnormal.
 Psychogenic Dyspnea
When a patient with normal cardiopulmonary
function complains of dyspnea or suffocation it is
referred to as psychogenic hyperventilation
syndrome.
Normally associated with panic disorders and
anxiety.
Resultant hyperventilation (low CO2 ) mat
present alongside chest pain, anxiety,
palpitations, and paresthesia.
Can be sporadic or chronic and is self-
 Treatment of Dyspnea
RT must ALWAYS approach any situation
involving hyperventilation or dyspnea as if it had
a pathogenic basis!
1st priority is to measure vital signs, including
SaO2/SpO2 , 12-lead ECG, arterial blood gas
(abg).
A psychogenic source is to be considered only
AFTER a pathogenic source has been ruled out.
 Common Cardiopulmonary
Symptoms
Breathlessness
Sensation of unpleasant urge to breathe
Can be triggered by acute hypercapnia,
acidosis, or hypoxemia
Is believed to be the conscious perception of
intense neural discharge from the brainstem to
the respiratory muscles
Anxiety is often accompanied by
breathlessness and hyperventilation.
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 Positional Dyspnea
Orthopnea: dyspnea that is triggered when the
patient assumes the reclining position
Common in patients with CHF, mitral valve disease,
and superior vena cava syndrome
Platypnea: dyspnea triggered by assuming the
upright position
Typically occurs in patients following
pneumonectomy and in those with chronic liver
disease
Sometimes observed during hypovolemia and in
some neurologic diseases.
 Positional Dyspnea (Cont.)
Orthodeoxia: oxygen desaturation on assuming
an upright position.
Accompanies platypnea
Trepopnea: when lying on one side relieves
dyspnea
Usually associated with either CHF or pleural
effusion.

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 Language of Dyspnea
RT should try to categorize each sensation according to a
particular aspect of breathing:
inspiration, expiration, respiratory drive, or lung
volume
Ask patient about quality and characteristics of dyspnea
Patients with cardiopulmonary disease frequently
experience several unpleasant breathing sensations
simultaneously
Different lung diseases evoke different sensations (i.e.,
asthma vs interstitial lung disease)
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 Intensity of Dyspnea

These scales are used to document the patient’s perceived intensity of
dyspnea, as well as provide a way to assess the patient’s response to
treatment over time
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 Common Cardiopulmonary
Symptoms (cont’d)
Cough
Most common, nonspecific symptom observed in patients with
pulmonary disease
Cough occurs when cough receptors in airways are stimulated by
inflammation, mucus, foreign material, or noxious gases.

Cough history: Onset and duration
Characteristics
Time of day (i.e., day or night)
Frequency
Dry vs. Loose; productive or non-productive
Acute vs. Chronic; weak or strong
A chronic cough is one lasting 8 weeks or longer
 Common Causes of Chronic Cough
Upper airway cough syndrome (UACS)*
Asthma*
Gastroesophageal reflux disease (GERD)*
Chronic bronchitis associated with cigarette smoking
ACE-1 Cough
* Restrictive diseases may result in dry, nonproductive
coughs (i.e., pulmonary fibrosis, CHF)
*Obstructive diseases may result in loose, productive
coughs (i.e., CBABE)

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Less Common Causes of Chronic
Cough

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 Basic Terminology
Phlegm - Mucus from tracheobronchial tree not contaminated by oral
secretions
Sputum - Mucus from lower airways that passes through the mouth as
it is expectorated
Fetid - Foul-smelling sputum; associated with long-term infections
i.e., bronchiectasis, lung abscess, CF, aspiration, pseudomonas
Purulent – sputum that contains WBCs (thick, colored, and sticky)
Sputum purulence occurs when inflammatory or sloughed (dead
tissue) mucosal epithelial cells are present (i.e., viral or bacterial
infection)
Mucopurulent sputum – thicker, white, or yellow in color and sticky
Mucoid – clear and thick (i.e., asthma)

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 Common Cardiopulmonary
Symptoms (cont.)
 Sputum
Excessive sputum production is generally associated with acute or chronic
infection or inflammation of the respiratory mucosa. (Common in pulmonary
disease)

Respiratory care clinician should directly observe and record the appearance
and characteristics of sputum produced: often signs of infection and must be
documented and reported to the physician

Amount (quantity i.e., tsp (5mL), tbsp. (15 mL)., or portion of a cup)
Color – (i.e., clear, cream, white, yellow-green, rust, yellow, red, and brown)
– cellular debris and WBCs can affect sputum color
Consistency (viscosity) – partly a function of the sputum’s water content
Odor
 Common Cardiopulmonary
Symptoms (cont.)
Hemoptysis
Coughing up blood or blood-streaked sputum
from the lungs
Blood-tinged sputum is associated with a large
number of pulmonary disorders
Massive (Frank)
More than 300 ml of blood expectorated over 24 hours
Common causes: bronchiectasis, lung abscess, and acute
or chronic tuberculosis

31.

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Common Cardiopulmonary
Symptoms (cont.)
 Chest Pain
Location
Description
Chest wall
Pleuritic
Non-pleuritic

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 Chest pain
Pleuritic chest pain—located laterally or posteriorly
Sharp, and increases with deep breathing (i.e., pneumonia and
pulmonary embolism)
Usually described as a sharp, stabbing type of pain
Nonpleuritic chest pain—located in center of chest and may radiate
to shoulder or arm; it is not affected by breathing
Often caused by angina (pressure sensation with exertion or
stress that results from CAD), gastroesophageal reflux,
esophageal spasm, chest wall pain, and gall bladder disease
Usually described as a dull ache or pressure type of pain
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 Fever
Fever is an elevated body temp >38.3 o C (101o F)
Normal temp for adults:
Oral: 97.6-99.6 degrees F or 36.5-37.5 degrees C
Rectal: 98.7-100.5 degrees F or 37.1-38.1 degrees
C
Axillary: 96.7-98.5 degrees F or 35.9-36.9 degrees
C
Tympanic: similar to rectal
Temperature elevation caused by disease
is called fever and the patient is said to
be febrile
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 Fever (cont.)
Fever and/or Sweating (>38.3 C; 101°F)
Increases metabolic rate, O2 consumption, CO2
production

– Clinical presentation:
Diaphoresis
Hot sweats
Night sweats
Cold sweats

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 Fever (cont.)

Fever with illness of at least 3 weeks duration:
temperatures > 38.3°C (101°F), and no diagnosis
reached following three or more clinic visits or
three or more days in the hospital is the
definition of fever of unknown origin (FUO).

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 Hypothermia
Body temperature normally decreases at night and normal values may
be as low as 35.0° C (95.0° F) during sleep.
Hypothermia can and most commonly occurs due to exposure
to environmental cold.
Reduces the metabolic rate and tissue demand for oxygen.
Because of the reduction in metabolic rate, hypothermic patients may
exhibit slowed or shallow breathing.
When hypothermia is observed due to non-environmental causes, the
clinician should suspect involvement of the hypothalamus.
Low body temperature should alert the clinician to a possibly
significant neurological incident, such as head trauma, stroke,
or evolution of a mass.
 Pain
 Patients with cardiopulmonary disease may experience generalized pain
and discomfort or localized pain due to specific injury or disease.
Chest pain is a common symptom in patients with a wide variety of

cardiopulmonary problems ranging from heart disease to pneumonia, pleurisy, rib
fracture, pneumothorax, and tumor.

Abdominal pain can be caused by many different disease states and conditions

including gastric or intestinal disease, reflux disease, appendicitis, and
diverticulitis.

Acute, intense abdominal pain with hemodynamic instability represents a

medical emergency requiring immediate attention.
 Pain (cont.)
 A common method is to ask the patient to rate his or her pain on a scale of
0 to 10, where 0 indicates no pain and 10 indicates the worst possible
pain.
In patients who are semiconscious, unconscious, or unable to otherwise
communicate, the presence of the physical signs of pain should be
noted:
Grimacing
Writhing
Tachycardia
Hypertension
Tachypnea
Diaphoresis
Piloerection
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Critical Care Pain Observation Tool
(CPOT)
The CPOT is based on
observation of the
patient’s facial
expression, body
movements, muscle
tension, and compliance
with the ventilator for
intubated patients or
vocalization for extubated
patients. Total CPOT scores
range from 0 to 8.
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 Pedal Edema
Swelling of lower extremities; most often due to heart failure
Two subtypes:
1. Pitting edema—indentation mark left on skin after applied pressure
2. Weeping edema—small fluid leak occurs at point where pressure
applied
 Venous congestion is caused by the heart’s reduced ability to effectively pump
blood. The increased hydrostatic pressure from blood pooling in gravity-
dependent lower extremities causes fluid to leak into the interstitial spaces.
Patients with chronic hypoxemic lung disease usually develop
right heart failure (cor pulmonale) due to pulmonary
hypertension
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Pedal Edema (cont’d)

Can be classified from 1-4 depending on severity
”1” = trace of heart failure with rapid refill
“4” = severe pitting with refill time > 2 minutes
44
 Syncope
A temporary loss of consciousness caused by
reduced blood flow
Reduction in blood flow leads to a reduced
supply of oxygen and nutrients to the brain
Reduced cerebral blood flow may be localized or
generalized

45
 Common causes of syncope
Drugs
Valsalva maneuver
Prolonged coughing
Hypoxia
Hypocapnia
Vasovagal (most common)
Results from a loss of peripheral venous tone
Physical/emotional stress, pain, venipuncture, prolonged
standing, anxiety
The vagus nerve is the longest cranial nerve. It contains motor
and sensory fibers and, because it passes through the neck
and thorax to the abdomen, has the widest distribution in the
body.

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 Height and Weight (BMI)
(18.5-24.9)
In adult patients, clinicians typically utilize the height
and weight measurements to calculate Body Mass Index
(BMI).
BMI is a way of measuring a person’s weight relative
to his or her height
Allows healthcare professional to discuss a pt.’s
weight objectively on a standardized scale
Helpful for risk stratification for a variety of chronic
and acute disease processes.
Overweight or obese patients are at risk for the
development of heart disease, high blood pressure,
stroke, cancer, osteoarthritis, sleep apnea, and
diabetes.
47
 BMI = Weight(lb)/[Height (in)]2 X 703)
ht or obese patients are at risk for the development of heart disease, high blood pressure, stroke
osteoarthritis, sleep apnea, and diabetes. 48
 Format for Obtaining a Medical
History
Chart review
Review of patient’s chart for current medical problems
Chief Complaint (CC)/History of present illness (HPI) – explains current medical
problems
Review past medical history (i.e., pack years, advance directives)
(i.e., DNR, DNI) - information in the patient’s medical record indicating any limits on
the extent of care to be provided in the event of cardiac or respiratory arrest
Review family, social/environmental history
Review systems
Patient interview
Physician and nursing consultations
Objective: Take the time to know your patients!!!
 The Physical Examination

Essential for evaluating patient’s problem and
determining ongoing effects of therapy

50
 Introduction to the Physical Exam
RCP must be able to integrate the results of the
patient history, physical examination, and diagnostic
tests in confirming the diagnosis and creating an
effective treatment plan.
Accurate and effective physical exam is completed
using an organized and systematic approach by body
system, which may include:
Vital signs, skin, HEENT, neck, back and spine,
heart and blood vessels, thorax and lungs
Abdomen/GI, extremities, musculoskeletal,
neurologic
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 General Appearance
Done during first few seconds of patient encounter
If pt.'s general appearance indicates an acute condition,
examination may be postponed until condition stabilizes.
Indicators to assess pt.’s overall appearance:
Level of consciousness
Facial expression (i.e., pain, anxiety)
Level of anxiety or distress
Body positioning (i.e., tripodding – pulmonary
hyperinflation)
Personal hygiene

52
 General Appearance
Cachexia (cachetic)/Emaciated: Weakness and
emaciation are are signs of general ill health and
malnutrition
Patients with prolonged illnesses may have severe
weight loss and muscle wasting.
Common chronic illnesses that are associated with
cachexia are: congestive heart failure, chronic
respiratory illnesses, such as COPD; and chronic renal
failure.
Diaphoresis (Diaphoretic): (Sweating) can indicate
fever, pain, increased metabolism, or increased anxiety.
The respiratory clinician should note the patient’s
color and if the patient is sweating excessively.
53
 Level of Consciousness
Sensorium: term used when evaluating a patient’s
cognitive functioning and orientation to time, place,
person, and situation (i.e., oriented × 4)
Is the patient aware of his/her current
circumstances?
Reflects oxygenation status of brain
Affected by poor cerebral blood flow (hypotension)
If patient NOT alert—standard rating scale is used
to objectively describe patient’s level of
consciousness
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 Level of Consciousness Rating
Scales
Confused
Exhibits slight decrease of consciousness
Slow mental responses
Decreased or dulled perception
Incoherent thoughts
Delirious
Easily agitated; irritable; exhibits hallucinations
Lethargic
Sleepy; arouses easily; responds appropriately
when aroused
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 Level of Consciousness (cont’d)
Obtunded
Awakens with difficulty
Responds appropriately when aroused
Stuporous
Does not awaken completely
Decreased mental & physical activity
Responsive to pain
Responds slowly to verbal stimuli
Semi-comatose
Patient responds only to pain.
56
 Level of Consciousness (cont’d)
Comatose
Unconscious
Does not respond to stimuli
Does not move voluntarily
Exhibits possible signs of upper motor neuron
dysfunction (i.e., Babinski reflex)
Loses reflexes with deep or prolonged coma

57
 Level of Consciousness (Scales)
A number of scales and scoring systems have
been developed to quantify level of
consciousness or levels of sedation.
The Glasgow Coma Scale ranges from 3 points
(brain death) to 15 points (fully conscious).
Both the Ramsay Sedation Scale and the
Richmond Agitation Sedation Scale (RASS)
have been developed to rate patients’
agitation and level of sedation.
58
Level of Consciousness (GCS)

Mild impairment: 13-15
Moderate impairment: 9-12
Severe impairment: ≤ 8 (coma)

GCS 4
cm above sternal angle
Most common cause is cor pulmonale (i.e., chronic hypoxemia)

75
Physical Examination

76
 JVP may increase due to right heart failure (e.g., cor
pulmonale), left heart failure, constrictive pericarditis, pleural
effusion, obstructed vena cava, and other cardiopulmonary
disorders.

77
JVD

78
Examination of the Extremities

Clubbing
Capillary refill
Cyanosis
Pedal edema

79
 Clubbing
Painless enlargement of the
terminal phalanges of the
fingers and toes
Angle of the fingernail to the
nail base increases and the
base of the nail feels “spongy”
Causes: lung disease, various
cancers, congenital heart
disease, bronchiectasis,
chronic liver disease,
inflammatory bowel disease

80
 Examination of Extremities

COPD alone, even when hypoxemia is present, does not lead to clubbing.
Clubbing of the digits in a patient with COPD indicates that something
other than obstructive lung disease is occurring.
81
 Capillary Refill
Assessed by pressing briefly and firmly on the
patient’s fingernail until the nail bed is blanched.
When pressure is released, the speed at which
the blood flow and color return should be 2
seconds or less.
Decreased C.O. and poor digital perfusion =
slow capillary refill (>2 seconds)

82
 Lung and Chest Topography
Surface Landmarks/ Imaginary Lines
Used to describe an anatomic region of the
chest
Anterior
Midsternal line – located in the middle of the
sternum and equally divides anterior chest into
left/right hemithoraces.
Midclavicular line (left and right) – run parallel to
the sternum, traditionally down through the male
nipple.
83
Lung and Chest Topography (cont.)
Posterior
Midspinal (Vertebral) line – runs along spinous processes of
the vertebrae
Scapular lines (left and right) - runs through the middle of
either the left or right scapula, parallel to the vertebral line
Lateral
Anterior axillary line – originates at the anterior axillary fold
and runs down through the anterolateral aspect of chest
Midaxillary – divides lateral chest into 2 equal halves
Posterior axillary – runs parallel to the midaxillary line
along the posterolateral wall of the thorax
84
Anatomy of the thorax. (A) Thoracic landmarks and
Imaginary lines of the chest
Anatomy of the thorax. (B) Topographic landmarks of
the chest and imaginary lines
Thoracic Landmarks
– Anterior
Suprasternal notch
Clavicles
Sternum
Angle of Louis
Costal angle
– Ribs
– Posterior
Scapulae
Vertebrae
– Cervical;
Thoracic
Ribs

87
 Lung Borders
Anteriorly
Apex of the lung extends approx. 2-4 cm above the
clavicle
Normally, lungs extend down to about the level of the
6th rib
Posteriorly
Superior portion of lung extends to approx. the level of
T-1 and down to approx. T-10
Laterally
Lungs extend to the 8th rib
88
 Lung Fissures
Right Lung – separated into the upper, middle, and
lower lobes by:
Horizontal fissure – separates the right anterior
upper lobe from the middle lobe
Oblique fissure
Anteriorly- divides the lower lobe from the lower border of the
middle lobe
Posteriorly – separates the upper lobe from the lower lobe
Left lung – separated into the upper and lower lobes
by the oblique fissure
89
Anatomy of the thorax. (A) Thoracic landmarks. (B) Topographic landmarks of the
chest. (C) Surface anatomy of the thorax.

90
 Examination of the Thorax and
Lungs
Consists of four steps:
1. Inspection (visually examining)
2. Palpation (touching)
3. Percussion (tapping)
4. Auscultation (listening with stethoscope)

91
 Physical Examination

Inspection  Breathing pattern
Thoracic configuration Normal I:E ratio
Increased with
A – P Diameter Restrictive
Pectus Carinatum / Decreased with
Obstructive
Excavatum  Breathing effort
Barrel Chest (i.e., WOB
emphysema) Accessory muscle use
Spinal Deformities Retractions

92
 Pectus Excavatum (Funnel Chest)
Pectus excavatum (PE) is an
abnormal development of the rib
cage where the breastbone
(sternum) caves in, resulting in a
sunken chest wall deformity.
Often present at birth (congenital)
and can be mild or severe.
Researchers believe that the
deformity is caused by excessive
growth of the connective tissue
(cartilage) that joins the ribs to the
breastbone (also known as the
costochondral region), which
causes an inward defect of the
sternum.

93
 Physical Examination
Barrel chest—seen w/ emphysema;
indicates poor lung recoil;
hyperinflation

When the AP diameter increases, the normal 45-degree angle of
articulation between the ribs and spine is increased, becoming more
horizontal.
94
 Breathing Pattern and Effort
Abnormal breathing pattern—broken into two
broad categories:
1. Those directly associated with
cardiopulmonary or chest wall diseases that
increase work of breathing
2. Those associated with neurologic disease

95
 Breathing Pattern and Effort (Cont.)
Common causes of an increase in WOB (effort)
include:
Narrowed airways (e.g., COPD, asthma)
“Stiff lungs” (e.g., acute respiratory distress
syndrome, cardiogenic pulmonary edema,
pulmonary fibrosis)
Rapid, shallow breathing
A stiff chest wall (e.g., ascites, anasarca, pleural
effusions)
One sign of severely increased work of breathing is
visible distortions in chest wall, called retractions
96
 Retractions
An inward sinking of the chest wall during inspiration
Intercostal (between the ribs)
Supraclavicular (above the clavicles)
Subcostal (below the rib cage)
Occurs when inspiratory muscle contractions generate
very large negative intrathoracic pressures
Retractions can be caused by upper airway obstruction
(supraclavicular), decreased lung compliance (intercostal
and/or xiphoid), or inadequate gas flow to the
mechanically ventilated patient.
97
 Use of the Accessory Muscles of
Inspiration
Scalene (anterior, medial, and posterior)
Sternocleidomastoid (SCD)
Pectoralis major/minor
Trapezius

98
Accessory Muscles of Inspiration
Scalene SCD

Pecs Trapezius

99
The way a patient may appear when using the pectoralis
major muscles for inspiration.

100
 Use of the Accessory Muscles of Expiration

Rectus abdominis
External oblique
Internal oblique
Transverse abdominis
Serratus (anterior, posterior)
Lattisimus dorsi

101
 Rectus
External Oblique
Abdominis

Transverse
Internal Oblique
Abdominis

Accessory muscles of expiration
102
Accessory muscles of expiration (cont.)
103
 Diaphragmatic Fatigue
Found in many types of chronic and acute
pulmonary diseases
Signs of acute fatigue:
Tachypnea
Diaphragm and rib cage muscles take turns
powering breathing (respiratory alternans)
Abdominal paradox occurs with complete
diaphragmatic fatigue
Abdomen moves inward on inspiration and outward on expiration

104
 Flail Chest
The chest should be inspected for scars and/or
trauma.
Flail chest occurs when there are double
fractures of multiple adjacent ribs with
resulting instability of the chest wall.
Leads to a paradoxical movement of the
affected area (chest paradox)—in upon
inspiration and out upon expiration.

105
 Physical Examination
Palpation - Touching the surface of the chest wall to evaluate
underlying lung structure and function
Thoracic Expansion - Chest/abdomen should expand synchronously
during inspiration
Skin
– Temperature
– Crepitation
– Fremitus
Vibration felt on palpation
– Tactile fremitus
– i.e., 99
– Vocal fremitus
Physical Examination

Estimation of thoracic expansion
107
 Skin Turgor
Skin turgor is the skin's elasticity
It is the ability of skin to change shape
and return to normal
Is a sign of fluid loss (dehydration)
The HCP grasps the skin between two
fingers so that it is tented up. The skin is
held for a few seconds then released.
Normal turgor = skin “snaps” back
rapidly
Poor turgor = skin takes time to return to
its normal position

108
 Tactile and Vocal Fremitus
Vocal fremitus refers to vibrations created by the
vocal cords during speech
Vibrations are transmitted down the
tracheobronchial tree and through the lung to the
chest wall
When these vibrations are “felt” on the chest wall, it
is referred to as Tactile fremitus
Rhonchial fremitus is commonly caused by gas
flowing through thick secretions that are partially
obstructing the large airways.

109
 Tactile and Vocal Fremitus (Cont.)
Air is a poor transmitter of sound waves and
vibration, therefore:
Conditions that increase the ratio of air to lung
tissue or increases fluid in the pleural space
will DECREASE fremitus (i.e., pneumothorax,
emphysema, pleural effusion, asthma)
Vocal and tactile fremitus is also reduced with
obese or overly muscular patients

110
 Tactile and Vocal Fremitus (Cont.)
Conditions that decrease the ratio of air to lung
tissue will INCREASE fremitus: (i.e.,
consolidation)
Pneumonia, Atelectasis
Consolidation of the lung is simply a
“solidification” of the lung tissue due to
accumulation of solid and liquid material in the
air spaces that would have normally been filled
by gas
111
 Subcutaneous
Emphysema
(Crepitus)
Crepitus is a classic sign of
barotrauma.
Occurs when air escapes from
the thorax and enters the
subcutaneous tissue (i.e.,
CMV with high PAP, trauma)
Air bubbles create a
“crackling sound” when
palpated.
Frequently collects in the
chest, neck, and eyes.

112
 Physical Examination
Percussion
Tapping on the chest wall to
evaluate the underlying lung
fields.
Avoid breast and boney
structures
With hand on chest tap middle
finger with middle finger of
other hand in short, sharp
blows
Compare both sides for
intensity, quality, and pitch 113
 Percussion (cont.)
Reserved for those patients suspected of
pneumothorax or lung consolidation
Rapid bedside assessment of chest abnormalities
Increased lung tissue or pleural space density =
decreased resonance or a dull note (i.e.,
pneumonia, pleural effusion)
Hyperinflated lungs or air in the pleural space
(pneumothorax, emphysema) = increased
resonance or a hyperrresonate note
114
Findings should be labeled as:
normal, increased, or decreased
resonance
115
-Chest percussion of a normal lung – loud, low in pitch, and long in duration (resonant/tympanic)
-Similar to the sound produced when knocking on a watermelon
Resonant – deep, clear, and continuing to sound or ring

116
A short, dull, or flat percussion note is typically produced over areas of alveolar
consolidation.
i.e., pleural effusion, empyema, atelectasis, pneumonia, tumors

117
Percussion becomes more hyperresonant/tympanitic with alveolar
hyperinflation.
i.e., pneumothorax, asthma, emphysema, gastric air bubble

118
Auscultation of Lung/Breath Sounds
 Auscultation of the Lungs
The process of listening for bodily sounds.
Performed over the thorax to identify normal
and abnormal lung sounds and to evaluate the
effects of therapy.
Provides info relating to the status of the
airways and lung parenchyma.
Should be carried out in a systematic manner.

120
Bell – used to listen to heart sounds (low-pitched sounds)
Diaphragm – preferred for auscultation of the lungs (high-frequency)

*Always ensure the room is as quiet as possible when listening to breath
sounds. 121
Auscultation of the Lungs
(Technique)
Patient sitting in upright
position (when
possible)
Breathe a little more
deeply than normal
through an open mouth
Exhalation should be
passive. NOT
FORCED!!!
Systematically evaluate
at least one FULL
ventilatory cycle at
each position
Evaluate ALL lobes of
the anterior, posterior,
& lateral chest.
122
 What Am I Listening For?
Key Features of Breath Sounds:
1. Duration – length of inspiratory and expiratory
phases (I:E)
2. Intensity – loudness
3. Pitch – vibration frequency

123
Auscultation of Lung Sounds

ERRORS CORRECT TECHNIQUE

Listening thru patient’s Place diaphragm directly
gown/robe against the chest wall
Tubing rubbing against Keep tubing away from
bed rails or gown objects
Auscultating in a noisy Turn television or radio
room off
Auscultating only in Ask patient to sit up, roll
convenient areas comatose patient onto
side*
124
Mechanism and Significance of Lung
Sounds
Normal breath sounds
Lung sounds are audible vibrations primarily
generated by turbulent airflow in the larger
airways
Sounds are altered as they travel through the
lung periphery and chest wall
Normal lung tissue acts as a low-pass filter
It preferentially passes low-frequency sounds

125
 Normal Lung/Breath Sounds
TYPE LOCATION DESCRIPTION
Tracheal Over trachea Loud, high pitch,
hollow, harsh,
inspiration equals
expiration or expiration
may be slightly longer
than inspiration
Broncho-vesicular Near main stem Softer, lower in pitch
bronchi (anteriorly) than bronchial;
between scapulae inspiration equals
(posteriorly) expiration

Vesicular Peripheral lung Soft, low-pitched,
primarily heard
during inspiration;
exhalation is approx.
1/3 the duration of
Under normal conditions, vesicular breath sounds are auscultated over most lung
inhalation
fields both anteriorly and posteriorly 126
 Bronchial Breath Sounds
Are considered abnormal when they are heard
over peripheral lung fields
Replace vesicular lung sounds when lung-tissue
density increases
When normal air-filled lung tissue becomes
atelectatic or consolidated (i.e., pneumonia), the
sounds auscultated are similar to tracheal breath
sounds, which is considered ABNORMAL.
The location at which bronchovesicular breath
sounds (A) and vesicular breath sounds (B) are
normally auscultated.
128
 ABNORMAL/ADVENTITIOUS BREATH
SOUNDS
are atypical, or uncharacteristic, lung sounds that are not
normally heard over a specific area of the thorax.

129
 Abnormal/Adventitious Breath
Sounds
How to describe breath sounds:
1. Pitch: high, moderate, or low (i.e., “high-pitched
wheezes were auscultated.”
2. Intensity (loudness): faint, soft, mild, moderate, or
loud (i.e., “loud bronchial breath sounds were
auscultated.”
3. Part of the respiratory cycle: (i.e., inspiration,
expiration or both)
4. When it occurs: (i.e., late-inspiratory crackles.”)
5. Location

130
 Abnormal/Adventitious Breath
Sounds (cont.)
Always record the precise LOCATION over the
chest the abnormal breath sound is auscultated
(i.e., expiratory wheezes were noted over the
anterior chest, right lower lobe)
Ex: High-pitched, faint, late-inspiratory wheezes
were noted over the right anterior lower lobe

131
 Abnormal/Adventitious Breath
Sounds (cont.)
Two varieties:
1. Discontinuous
Intermittent, crackling, or bubbling sounds of short
duration
Referred to as “crackles” or “rales”
2. Continuous
Referred to as “wheezes” – quasi-musical sound
When heard over the upper airway is called “stridor”
Heard over larynx and trachea during inspiration
Common in infants and small children; sign of obstruction or
edema (i.e., LTB)
132
 Crackles
 Occurs when airflow moves through excessive secretions or fluid in the
airways.
 HOWEVER, Coarse crackles (rhonchi) are CONTINUOUS
Coarse crackles (rhonchi)
heard during inspiration & expiration
Can clear with suctioning or cough
low-pitched, CONTINOUS sound that is associated with secretions in the larger airways
 Fine crackles: Can be heard LATE or EARLY in the Inspiratory Phase
LATE INSPIRATORY CRACKLES: Sudden opening of small peripheral airways; usually LATE in the
inspiratory phase; MAY CLEAR WITH SEVERAL DEEP INSPIRATIONS or CHANGE IN POSTURE
Heard with pulmonary fibrosis and atelectasis, pneumonia, pulmonary edema

Faint or Low intensity crackles are often referred to as fine crackles; more
pronounced or more intense crackles are referred to as coarse crackles

133
 Crackles (Discontinuous)
Early inspiratory crackles
Larger, more proximal bronchi may close during
expiration
Loud or faint
Not silenced by cough or a change in position
Frequently occur in pt.’s with: COPD (bronchitis,
emphysema, or asthma)
Indicate severe airway obstruction
134
 Wheezes and Stridor (cont.)
Inspiratory stridor = narrowing above the glottis
(supraglottic)
Expiratory stridor = narrowing of the lower
trachea (subglottic)
In adults, stridor most often occurs from laryngeal
or subglottic edema secondary to airway trauma
after prolonged intubation
GIVE RACEMIC EPINEPHRINE QUICK!!!!

135
 Wheezes and Stridor
(Continuous)
Vibrations of airway wall caused when air flows at a high velocity
through narrowed airways.
Airway diameter can be reduced by: bronchospasm, mucosal
edema, inflammation, tumors, foreign bodies, pulmonary edema
Wheezing may be described as a high-pitched, whistling sound
during breathing
Expiratory wheezes = obstruction of intrathoracic airways (i.e.,
bronchitis, asthma)
Monophonic – single airway partial obstruction; may be heard
during either part of the respiratory cycle (inspiration or
expiration)
Polyphonic – multiple airways obstructed; expiration only (i.e.,
asthma, bronchitis, chf)

136
 Whistling, Wheezing, and Chest
Tightness
Recurrent wheezing, chest tightness, difficulty in
breathing, or a cough that may be worse at night are
associated with asthma.
Asthma is characterized by airway inflammation,
hyperreactive airways, and reversible airway obstruction.
Patients should be asked about their breathing using
open-ended questions
And direct questions to determine any changes in the
frequency, duration, or related circumstances associated
with wheezing, chest tightness, SOB, or cough

137
 Whistling, Wheezing, and Chest
Tightness (cont.)
A change in symptoms and what factors are
associated with that change should be noted.
(i.e., EIA)
Paroxysmal nocturnal dyspnea – acute shortness
of breath at night
Associated with congestive heart failure (CHF)
CHF causes edema of the airways and may
lead to wheezing and SOB (also known as
Cardiac Asthma)
138
 Abnormal/Adventitious Breath
Sounds (cont’d)
Diminished breath sounds
Occur when sound intensity at site of
generation (larger airways) is reduced due to
shallow or slow breathing, OR
When sound transmission through lung or
chest wall is decreased (COPD or asthma)
Other causes: mucus plugs, hyperinflation of
lung tissue, air/fluid in the pleural space,
anasarca (extreme edema), obesity
140
 Pleural Friction Rub
A “creaking or grating” sound that occurs when the
parietal/visceral linings become inflamed (i.e.,
pleurisy)
Pleurisy is an inflammation of the pleurae, the
membranes of the pleural cavity surrounding the
lungs.
May be heard during inhalation or exhalation
Sounds similar to coarse crackles but is NOT cleared
with coughing
Intensity may increase with deep breathing

141
 Abnormal Breath Sounds (Cont.)
Recommended terminology for ALS are the
following:
Fine crackles
Medium crackles, or coarse crackles
Wheezes
Bronchial breath sounds
Stridor, pleural friction rub
Diminished breath sound
Whispering pectoriloquy (i.e., 1,2,3)
142
 Voice Sounds
Auscultation while patient vocalizes
Resonance is produced during vocalization
Normal lungs:
Voice sounds are filtered by air-filled lung
tissue which reduces intensity and clarity of
words
Abnormal lungs:
Transmission of voice sounds is
altered/enhanced
143
 Voice Sounds (cont’d)
Term Vocalization Clinical Diagnosis
Bronchophony “99, 99, 99” increases in Increased consolidation,
intensity & clarity over pneumonia
the lung periphery

Egophony “E-E-E” spoken becomes Heard over compressed
“A-A-A” (E to A lung as in pleural
egophony) effusion; consolidation

Whispered Pectoriloquy “1,2,3” whispered Consolidation
results in increased
clarity
Bronchophony or Whispered Pectoriloquy is an increased
intensity and clarity of vocal resonance produced by enhanced transmission
of vocal vibrations through consolidated lung tissue.

144
Adventitious Breath Sounds and
Disorders

145
Adventitious Breath Sounds and
Disorders (cont.)

146
General location and source of abnormal lung sounds.

147
Heart Sounds
 Heart Sounds
Cardiac Examination
Inspection and palpation
Normal/abnormal pulsations
Point of maximal impulse (PMI) – a visible,
palpable pulsation generated by left
ventricular contraction
Palm of the right hand is placed over the lower left sternal
border
Shifts away from a pneumothorax but towards lobar
collapse
Auscultation of heart sounds – patient should be
 Heart Sounds (cont.)
Cardiac Examination (cont.)
Identifies heart sounds created by closure of heart valves
S1: closure of atrioventricular valves (mitral and tricuspid)
during ventricular contraction
S2: closure of pulmonic and aortic valves (semilunar) – end of
systole (ventricles relax)
S3: abnormal – produced by rapid ventricular filling (i.e., CHF)
S4: abnormal – may be a sign of heart disease
Gallop rhythm – patient with heart disease who has an S3 and
S4 heart sound
 Cardiac Murmurs
Are created by:
1. Backflow of blood through an incompetent valve
(systolic)
2. Forward flow of blood through a stenotic valve
(diastolic)
3. Rapid blood flow through a normal valve
When caused by incompetent or stenotic heart valve are
classified as diastolic or systolic.
Incompetent AV Valve = Systolic murmur
Obstructed flow through a stenotic Semilunar valve =
Diastolic murmur

151
 Abdominal Exam
Patient should be placed comfortably in the
supine position with table extended so patient’s
legs are parallel to the ground.
Typically, the abdomen is separated into (4)
quadrants:
R and L upper & R and L lower quadrants,
utilizing the umbilicus as the landmark for
differentiation of the various quadrants

152
Abdominal Quadrants
 Abdominal Examination (cont.)
Abdomen should be inspected and palpated for
evidence of distention and tenderness.
Abdominal distention and pain impair
diaphragmatic movement possibly contributing
to respiratory insufficiency.
Abdominal dysfunction may inhibit deep
breathing and coughing and promote atelectasis.

154
Components of the Abdominal Exam
1. Inspection – the 1st component of the
abdominal exam; room should be well lit
Abdomen observed for general shape and
contour, skin color, distention, ascites, scars,
pulsation, or ecchymoses (subcutaneous
blood)
2. Auscultation – should be performed prior to
percussion or palpation
Performed using the diaphragm of the
stethoscope 155
Components of the Abdominal Exam
(cont.)
Auscultation should be performed over all 4
anatomic locations (15 or 20 sec.)
Bowel sounds should be evaluated for frequency
and quality
Descriptors include the following:
Hyperactive bowel sounds: Loud, gurgling rushed sounds
Hypoactive bowel sounds: Soft, low, widely separated sounds,
(i.e., 1 or 2 occurring in 2 minutes)
Absent sounds: Sounds are not heard for 3 to 5 min of
auscultating in each quadrant
Decreased or absent bowel sounds may be caused by a decrease or
absence of peristalsis (i.e., mechanical bowel obstruction, inadequate
blood supply)

156
Components of the Abdominal Exam
(cont.)
3. Palpation – used to assess organ size and location
of masses or abdominal pain (liver, spleen,
kidneys)
If masses or tenderness are noted, RT should note
quadrant and begin thinking of possible causes
Average patient should have a soft, nonrigid
abdomen
4. Percussion – base finger pressed firmly on the
patient’s bare skin while the dominant hand
delivers 2 blows to the finger

157
Components of the Abdominal Exam
(cont.)
All 4 quadrants should be percussed, noting
the quality of the note elicited
Most areas of the abdomen will have a
tympanic quality due to the gas located within
the bowel
Important finding: excessive gas, pain,
pneumoperitoneum caused by abdominal
trauma or perforation

158
 Abdominal Examination (cont.)
Intraabdominal hypertension is defined as intraabdominal pressure
>12 mm Hg.
Common in pt.’s with:
Blunt or penetrating abdominal trauma
Ruptured aortic aneurysm
Bowel infarction
End-stage liver failure
Suspected when abdominal exam reveals pronounced distention.
Hepatomegaly (enlarged liver) is a frequent cause of right lower
lobe atelectasis and pleural effusion
Common finding in pt.’s with liver disease and cor pulmonale

159
 Abdominal Examination (cont.)
Intraabdominal pressure >20 mm Hg results in
Abdominal compartment syndrome
Requires emergency decompressive surgery
Causes profound atelectasis, hypotension,
hypoxemia, and renal failure

160
 Rib Fractures
Painful, limit deep breathing and effective
coughing, leading to atelectasis and retained
secretions that increase the risk of pneumonia.
When extensive, cause chest wall instability
(paradoxical chest movement) that limits
effective ventilation and heightens the risk for
respiratory failure.
Cigarette smoking and alcohol abuse further
increase the susceptibility to pneumonia.
161
 Rib Fractures (cont.)
First priority is to increase O2 therapy to achieve
adequate oxygenation while conducting
examination.
Worsening oxygenation, despite doubling O2
therapy, suggest refractory hypoxemia
Administer high concentration O2, continuous
pulse-ox, close hemodynamic monitoring
Should be alert for signs of respiratory
distress/increased WOB
162
 Rib Fractures (cont.)
Acute pulmonary embolism is another
consideration.
Especially if the patient also suffered any leg or
pelvic fractures and was immobilized or has
redness and swelling of the lower extremities.
Chest should be inspected for possible
pneumothorax (i.e., subcutaneous emphysema)
Further workup: CXR, ABG, Blood work

163
CLINICAL LABORATORY
TESTS

164
 Laboratory Medicine
Studies tissue and fluid specimens from patients and consists of (5)
disciplines:
1. Clinical biochemistry – analyzes blood, urine, and other bodily
fluids for electrolytes and proteins
2. Hematology – analyzes cellular components of blood i.e, RBC,
WBC, Platelet count, Hb, HCT
3. Clinical microbiology – tests blood and other bodily fluids for
infectious agents i.e., bacteria (bacteriology), viruses (virology),
fungi (mycology), and parasites (parasitology)
4. Immunology – focuses on autoimmune and immunodeficiency
diseases i.e., Type 1 Diabetes, Lupus, Multiple sclerosis (MS)
5. Anatomic pathology – helps diagnose diseases by analyzing tissue
samples
 Clinical Laboratory Tests
Performed to:
Evaluate general health and baseline status of
the patient
Identify organ system dysfunction
Detect the presence of infection
Determine the effects of therapy

166
 Critical Test Value
Result significantly outside reference range
Represents pathophysiologic condition
May represent potentially life-threatening
situation

167
 Complete Blood Count (CBC)
Common test measuring formed elements of blood
Counts and examines:
Leukocytes (white blood cells)
Made up of five different types of cells reported under the
differential
Erythrocytes (red blood cells)
Evaluated for size and hemoglobin content
Thrombocytes (platelets) – (150 – 400,000)
Evaluated by the number present
< 150,000 = thrombocytopenia

168
 White Blood Cell Count

White Blood Cell (WBC) Count
Reference range: 5-10 × 103/mcL (5,000-
10,000)
Leukocytosis—WBC count above normal
Common with infection, stress, and trauma.
Degree of leukocytosis depends on severity of
infection
Severe infection with mild leukocytosis may
represent poor prognosis
169
 White Blood Cell Count (Cont.)
Leukopenia—WBC below normal
Occurs with overwhelming infections and when
immune system is depressed due to disease or
certain cancer therapies (chemotherapy)
Diseases of bone marrow (e.g., leukemia)
Neutrophilia—Elevation of the absolute value of
neutrophils (sign of severe infection)
Neutropenia – a reduced number of circulating
neutrophils (i.e. Lymphoma, leukemia, autoimmune
disorders, HIV, chemo)
170
 Differential of WBC Count
Determines the number of each type of WBC present in the
blood
Most circulating WBCs are either neutrophils or lymphocytes
White blood cells come in five varieties
1. Neutrophils* - 1.8-6.8 X 109/L
2. Lymphocytes* - 1.0-3.4 x 109/L
3. Eosinophils – 0-0.4 x 106/L
4. Basophils – 0-0.1 x 106/L
5. Monocytes – 0.2-0.8 x 106/L
Elevation of the WBC count usually is caused by an increase in
either neutrophils or lymphocytes in response to infection.
171
 Red Blood Cell Count
Red blood cell (RBC) count
Reference range: Men : 5 million/mm 3
Women: 4.5 million/mm3
Reduced RBC is called anemia < 4 million/mm3
Due to either blood loss or reduced RBC production by bone
marrow
Anemia reduces oxygen-carrying capacity of blood
Several types of anemia exist with different causes (dietary
deficiencies, chronic inflammatory disease, hereditary)
Severe anemia is treated with transfusion (Hb < 7)

172
 Red Blood Cell Count (Cont.)
Polycythemia—Abnormal elevation of RBC, Hb, or
HCT count
Hb of > 18 gm/dl
HCT of > 55%
Secondary polycythemia occurs when bone marrow
is stimulated to produce more RBCs in response to
chronically low blood oxygen levels
Common in people who live at an elevated
altitude and in patients with chronic hypoxemic
lung disease

173
 Red Blood Cell Count (Cont.)
RBC count includes hemoglobin and hematocrit
levels
Hemoglobin (Hb)
Plays role of bonding with oxygen
Reference range: Men 13.3-17.7 g/dl
Women 11.7-15.7 g/dl
The recommended threshold for blood
transfusion is a hemoglobin < 7.0 g/dL or
hematocrit of 21%
174
 Red Blood Cell Count (Cont.)
Hematocrit Levels
Ratio of RBC volume to that of whole blood
Proportion of sample represented by packed
cells
Reference range : Men 40%-52%
Women 35%-47%
Low levels occur with anemia or overhydration
High levels occur with polycythemia and
dehydration
175
 Electrolyte Test
Basic Concepts
Normal cellular function depends upon
homeostasis of fluid, electrolytes, and acid-
base balance
Electrolytes are ions that influence functioning
of enzymes
Enzymes are proteins regulating all chemical
reactions occurring within cells (metabolism,
protein synthesis)
176
 Basic Chemistry Panel
Also called a basic metabolic panel (BMP)
Predominant electrolytes measured in lab:
Sodium (Na+) – 135-145 mEq/L
Potassium (K+) – 3.5-5.0 mEq/L
Chloride (Cl−) – 98-106 mEq/L
Glucose (GL) – 70-110 mg/dl
Excretion of renal-mediated waste products is included in panel:
Creatinine (Cr) = 0.5-1.5 mg/dL
Blood urea nitrogen (BUN) = 6-20 mg/dL

177
 Cardiac Enzymes
CPK (22-198 U/L)
Creatine phosphokinase (CPK) or creatinine kinase, is found
mainly in heart, brain, and skeletal muscle tissue.
Levels will be elevated during sustained ischemic damage
to the tissues (i.e., heart, brain, skeletal muscle)
CPK-2 (MB) is the most common CPK test and is released
from the heart after Myocardial infarction
Levels increase 4-6 hrs. and peak 12-24 hrs. after injury.
Monitored in pt.’s with suspected MI, cardiac contusion,
open heart surgery, or myocarditis
178
 Cardiac Enzymes (cont’d)
Troponin
Complex protein that helps regulate skeletal and
cardiac muscle contractility.
More commonly used than CPK-2
Troponin I Levels will peak 12-16 hrs. after MI.
(>0.05 ng/L)
B-Type Natriuretic Peptide (BNP) is used to
evaluate patients for heart failure ( 300 = mild HF; >600 = moderate HF; >900
= severe HF 179
 Enzyme Tests (Cont.)
Coagulation Studies
The process by which the blood forms clots to
stop bleeding and repair blood vessels
Thrombocytopenia (low platelets 400,000)
Causes excessive clotting
180
 Enzyme Tests (Cont.)
Coagulation studies used to measure function
Prothrombin Time (PT) – seconds it takes plasma to
form a clot
Partial Thromboplastin Time (PTT) – used to
evaluate abnormalities in blood clotting and
monitor the effects of anticoagulation tx
PT is accompanied by an additional measurement—
International Standardized Ratio (INR) 0.9-1.3…values
of 5 indicate high likelihood of bleeding…values of 0.5
associated with increased clotting
These tests assess 2 different pathways by which fibrin clots are formed
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Enzyme Tests (Cont.)

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 Enzyme Tests (Cont.)
Sweat Chloride
Cystic Fibrosis (CF)
CF patient’s have elevated level of sweat Cl−
40-60 mmol/L is borderline
< 40 mmol/L are unlikely to be diagnosed
Must be accompanied by other tests to
confirm diagnosis

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 Microbiology
Sputum Gram Stain
Suspected infection in lungs or airways may benefit from
analysis of sputum sample
The first test used in evaluating sputum samples
Gram stain can determine if offending organism is gram
positive or gram negative and its shape
Legitimate sputum sample will have numerous pus cells
(leukocytes) and few epithelial cells (If saliva is expectorated,
sample is invalid)
Although a gram stain can be helpful in identifying an
invading organism so antibiotics can be quickly started, a
definitive diagnosis is made only by culture of the specific
organism over several days
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 Microbiology (cont.)
Sputum Culture (C &S)
If the gram stain reveals an adequate sample,
the lab technician prepares a portion of the
sputum for culture.
Sample is placed in a medium permitting
growth of the organism
When the organism has matured, it is
examined microscopically to determine its
exact type and sensitivity to antibiotic therapy
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 Sputum Culture for AFB/PCP
Acid-fast testing for AFB
Identifies acid-fast bacterium
Mycobacterium tuberculosis causes pulmonary
tuberculosis
Pneumocystis pneumonia (PCP) is a serious infection caused
by the fungus Pneumocystis jirovecii.
Most people who get PCP have a medical condition that
weakens their immune system or take medicines that
lower the body’s ability to fight germs and sickness (i.e.,
HIV/AIDS*)
Symptoms include: fever, cough, difficulty breathing,
chest pain, chills, fatigue