Chapter 20 Infections of the Respiratory Tract PDF

Summary

This document is a chapter on infections of the respiratory tract, providing an overview of the topic. It covers anatomy, viral and bacterial infections, case studies, clinical presentations, and treatment methods.

Full Transcript

CHAPTER 20
Infections of the Respiratory
Tract

Copyright © 2021 W. W. Norton & Company, Inc.
https://pharmaceutical-journal.com/article/news/monoclonal-antibody-75-effective-against-lower-respiratory-tract-infection-in-infants
https://www.washingtonpost.com/nation/2022/03/04/study-finds-lavender-spray-walmart-killed-sickened-patients/
Infections of the Respiratory Tract
Chapter Objectives
▪ Relate anatomy and physiology of the respiratory tract to the
infectious processes affecting them.
▪ Describe symptoms that can help differentiate upper and lower
respiratory infections caused by different microorganisms.
▪ Explain the mechanisms of pathogenesis for major agents of
respiratory tract infections.
▪ Relate pathogenic mechanisms to disease prevention strategies
for microbes that infect the respiratory tract.

4
The Ominous Cough – 1
Scenario
▪ It was the summer of 1918, and 20-year-old
Floyd, a U.S. army private stationed in Kansas,
began to feel ill. He visited the camp doctor
complaining of a cough, a headache, and some
chills. Within a day, Floyd’s fever reached 40°C
(104°F). He became incoherent and lost
consciousness. When Floyd awoke, he found
himself in a large barracks lying on a cot
among a long line of cots filled with sick
soldiers.

5
The Ominous Cough – 2
Signs and Symptoms
▪ His cough was severe. Floyd
saw dark, purplish brown
spots appear on the face of
the GI lying on the cot next to
his. The soldier began to
cough blood and eventually
his face turned blue from lack
of oxygen—a sign that death
was imminent. Doctors could
do little to help.

6
The Ominous Cough – 3
Resolution
▪ Fortunately, after about 2 weeks,
Floyd started to improve. Many
others were not so lucky and
died. No one knew what caused
the disease raging through the
camp or how to stop it.

7
20.1 Anatomy of the Respiratory Tract – 1
Section Objectives
▪ List the anatomical differences between the upper and lower
respiratory tracts.
▪ Describe the relationship of eyes, ears, and nose with the upper
airways.
▪ Explain the role of the mucociliary escalator in respiratory
infection processes.

8
20.1 Anatomy of the Respiratory Tract – 2
▪ Respiratory infections
Classified by whether
they affect the upper or
lower respiratory tract
Upper respiratory
tract includes
– Upper airways (nasal
passages)
– Oral cavity
– Pharynx
– Larynx

9
20.1 Anatomy of the Respiratory Tract – 3
▪ Lower respiratory tract
Alveoli are small sacs
where oxygen from inhaled
air is exchanged for carbon
dioxide.
All the respiratory tubes
warm, moisturize, and
remove impurities from
inhaled air as it travels to
the alveoli.

10
20.1 Anatomy of the Respiratory Tract – 4
▪ The mucociliary escalator
works to keep the lungs
devoid of microorganisms.
Goblet cells secrete mucin
that combines with water to
create sticky mucus.
Cilia on epithelial cells
remove foreign particles,
including microorganisms,
trapped in the sticky
mucus.

11
20.2 Viral Infections of the Respiratory Tract – 1
Section Objectives
▪ Compare and contrast the signs and symptoms of upper and
lower respiratory tract infections.
▪ Describe the role of mutations in the genesis of influenza
pandemics.
▪ List the risk factors for upper and lower respiratory tract
infections.
▪ Identify the etiology of the major viral respiratory infections on
the basis of their clinical presentation.

12
Case History: Jacob’s Runny Nose – 1
▪ Jacob, a rambunctious 5-year-old boy
brought to the clinic by his mother, was
complaining of a scratchy sore throat, a
nonproductive cough (a cough that does
not produce sputum), rhinorrhea (a runny
nose), nasal congestion (a stopped-up
nose), and a headache that started the
night before. He did not have a fever.

13
Case History: Jacob’s Runny Nose – 2
▪ His complete blood count (CBC)—the
number of platelets and red and white
blood cells in blood, along with its
differential (the different types of red and
white blood cells)—was normal, as was his
chest X-ray. Jacob was diagnosed with the
common cold and advised to rest, drink
plenty of clear liquids, and use
over-the-counter cough suppressants and
either ibuprofen or acetaminophen for
pain.

14
20.2 Viral Infections of the Respiratory Tract – 2
▪ Common cold
The most frequent viral infection of the upper respiratory tract
200 viral subtypes
Rhinoviruses
– The most common cause of colds
Other prominent players include
– Coronaviruses
– Influenza
– Parainfluenza
– Respiratory syncytial virus

15
20.2 Viral Infections of the Respiratory Tract – 3
▪ Viral sinusitis
Infection of the upper airways
Inflammation and congestion of the sinuses
– Impacted narrow sinus passages can then impede the flow of
mucus.
Sinus congestion causes the headache that we feel when our
nose is “stopped-up” from a bad cold.
Resolves on its own

16
Lower Respiratory Tract Viral Infections – 1
▪ Respiratory syncytial virus (RSV) disease
Fusion of adjacent infected cells into a syncytium, a giant cell
containing many nuclei
▪ Transmitted from person to person
▪ Young, around age 2
Most common cause of bronchiolitis and pneumonia among
infants and children younger than 1 year
▪ Infections occur when the virus comes into contact
with mucous membranes of the eyes
with mouth or nose
through the inhalation of droplets from a sneeze or cough 17
Lower Respiratory Tract Viral Infections – 2
▪ Influenza
Based on antigenic determinants
Type A
– Cause of epidemics and occasional pandemics
– Can infect a variety of animals as well as people
– Is constantly changing
Type B
– Found primarily in humans and usually results in a milder illness
– Does not cause pandemics
Type C
– Causes only mild disease
– Does not case epidemics or pandemics
18
Lower Respiratory Tract Viral Infections – 3
▪ Pathogenicity is dependent on three proteins:
Hemagglutinin (HA)
– Transmembrane protein that forms the spikes
on the viral surface
– Binds to N-acetylneuraminic (sialic) acid on
the surface of respiratory cells to gain entry
Neuraminidase (NA)
– On surface releases budding virus from host
cell
M2
– Releases viral genome into host cell cytoplasm
19
Lower Respiratory Tract Viral Infections – 4
▪ Why do some strains cause more severe disease than others?
Influenza can infect humans, pigs, and birds.
– Different viruses can sometimes infect the same cell.
Antigenic shift
– Eight RNA segments of each flu genome will uncoat.
– Mix in the cytoplasm
– Re-sort to form a new influenza virus containing a new form of
the hemagglutinin gene
Antigenic drift
– Smaller mutations in the HA and NA genes

20
Lower Respiratory Tract Viral Infections – 5
▪ Covid-19
SARS-CoV-2
Single-stranded, positive-sense, enveloped RNA virus
Emerged December 2019
Symptoms
– Flu-like
– Cough, fever, shortness of breath
– Severe cases include a cytokine storm
– Many cases are asymptomatic

21
Lower Respiratory Tract Viral Infections – 6
▪ Croup
Also known as laryngotracheobronchitis (LTB)
Infects the larynx
Spreads to the trachea and even bronchi
Children 6 months to 5 years of age are at the highest risk for
contracting the disease.
Symptoms include
– Fever
– Runny nose
– “Barking” cough (caused by the swelling of the larynx)
Parainfluenza viruses types 1 and 2 are the most common cause of
croup.
Treatment depends on severity of symptoms.
22
20.3 Bacterial Infections of the Respiratory Tract
Section Objectives
▪ List the bacterial etiologies of respiratory tract diseases and each
disease’s anatomical location.
▪ Describe the relationships between host and bacteria that
contribute to the pathogenesis of respiratory tract infections.
▪ Compare and contrast clinical presentations of bacterial
infections of the respiratory tract.
▪ Develop a prevention plan for different bacterial respiratory
pathogens.

23
Case History: A Big Pain in a Little Ear
▪ Chloe is a 2-year-old generally healthy child
who was brought to the clinic by her father.
The child had a fever since the previous night,
was irritable, and kept pulling on her left ear.
Chloe also had a runny nose for the past 2
weeks. Her temperature was 38.5°C (101.3°F)
at the clinic and the physical exam showed a
red and swollen ear, an erythematous
(reddened) ear canal, and a bulging tympanic
membrane. Chloe was diagnosed with acute
otitis media and prescribed an antibiotic that
she had to take for 7 days.
24
Upper Respiratory Tract Bacterial Infections – 1
▪ Otitis media
Acute otitis media (AOM)
Most common diagnosis
during a sick child visit to the
pediatrician’s office
Signs and symptoms are wide
ranging and the infections can
be caused by
– Viruses
– Gram-positive and
Gram-negative bacteria
25
Upper Respiratory Tract Bacterial Infections – 2
▪ In infants and young toddlers, the
Eustachian tube is shorter and
almost horizontal, which makes
drainage less optimal.
▪ Bacteria more likely to get trapped
in the middle ear and cause an
infection.
▪ As we get older, the Eustachian tube
lengthens and its path becomes
angled, making drainage of the
middle ear much easier and ear
infections much less likely. 26
Upper Respiratory Tract Bacterial Infections – 3
▪ Otitis media
Three bacterial species are the
most frequent cause of AOM in
otherwise healthy children:
– Streptococcus pneumoniae
– Haemophilus influenzae
– Moraxella catarrhalis
A multivalent polysaccharide
vaccine protects against
S. pneumoniae

27
Upper Respiratory Tract Bacterial Infections – 4
▪ Bacterial sinusitis
Often accompanies middle ear infection in children and
pneumonia in adults
Inflammation and congestion obstructs the sinuses and mucus
flow.
Symptoms include
– Pressure behind the eyes
– Pain in the face
– Foul-smelling nasal discharge or breath
Antibiotics is the usual course of treatment.

28
Case History: The Contagious Football Player with GAS – 1
▪ Dallin, a 16-year-old high school athlete, came to
the clinic complaining of a sore throat. He did not
have a cough or any cold or flu symptoms. His
cervical nodes (lymph nodes in the neck) were
enlarged and tender to palpation, there was an
exudate visible on his tonsils and pharynx
(pharyngotonsilar region), and his temperature
was 39.8°C (103.6°F). The physician assistant
(PA) told Dallin that he probably had a strep
throat but she could not perform a rapid strep test
to confirm because they had run out of the strips.

29
Case History: The Contagious Football Player with GAS – 2
▪ The PA then swabbed the back of Dallin’s throat
and sent the sample to the lab for culture and
antibiotic sensitivity testing. Dallin was given an
antibiotic empirically (based on clinical experience
and in the absence of definitive diagnosis). He was
told that he was contagious and should rest and
avoid contact with others until better. He followed
the recommendations, recovered, and was back
playing football in a few days. The lab isolated
Streptococcus pyogenes, also called group A
streptococcus (GAS), from Dallin’s pharyngeal
swab, confirming the diagnosis.
30
Upper Respiratory Tract Bacterial Infections – 5
▪ Pharyngitis: inflammation of the pharynx
▪ Tonsillitis: inflammation of the tonsils
▪ Laryngitis: inflammation of the larynx
▪ Peritonsillar abscess: abscess in the pharynx
▪ Differential diagnosis for a person complaining of a sore throat
includes a variety of viral and bacterial etiologies, including
infectious mononucleosis and diphtheria.

31
Upper Respiratory Tract Bacterial Infections – 6
▪ Streptococcal pharyngitis
Also known as strep throat
Contagious and spread through
– Person-to-person contact
– Indirect contact with items
contaminated by secretions
Symptoms include
– Sudden onset of high fever and sore
throat
– Tender, enlarged cervical lymph nodes
– Exudate on tonsils
– Absence of a cough
Treatment with antibiotics 32
Upper Respiratory Tract Bacterial Infections – 7
▪ Streptococcal pharyngitis
Some strains of S. pyogenes produce
exotoxins.
– Streptococcal pyogenic exotoxins (SPEs)
– Can cause fever and a red rash called scarlet
fever
Rash starts on the head and neck, then
spreads to the trunk, then to arms and legs.
Some patients may also have a very
distinctive red, bumpy tongue referred to
as a strawberry tongue.
33
Upper Respiratory Tract Bacterial Infections – 8
▪ Streptococcal pharyngitis
Rapid strep test
– Immunoassay
technology
– Highly specific for
S. pyogenes

34
Upper Respiratory Tract Bacterial Infections – 9
▪ Streptococcal sequelae
Pathological conditions result after a primary disease has run
its course.
Sequelae from streptococcal infections
– Caused by the immune response to the bacteria
Antibodies cross-react with host cells in an autoimmune
reaction, resulting in serious sequelae.

35
Upper Respiratory Tract Bacterial Infections – 10
▪ Post-streptococcal sequelae include
Acute rheumatic fever (ARF)
– Young children, 4–9 years of age
– High fever
– Damage to heart, joints, skin, or
nervous system
– Cross reactive antibodies, T cells,
and complement
Glomerulonephritis (a kidney
disease)

36
Case History: The “Bull Neck” – 1
▪ Ramona, a 23-year-old Hispanic mother,
brought her 3-year-old daughter into the
emergency department. The child was
lethargic, had a fever of 40°C (104°F), and
was having trouble breathing. The mother
explained that the family arrived in the
United States from El Salvador the
previous week. The attending physician
noted an extreme swelling of the child’s
cervical lymph nodes, giving the girl a
thick “bull neck” appearance.

37
Case History: The “Bull Neck” – 2
▪ She also noticed the beginnings of a
membranous growth at the back of the
child’s throat that was beginning to
obstruct the trachea. It was grayish in
color and bled when scraped. The
distraught mother admitted that the
child had not received any vaccinations
before arriving in New Mexico.

38
Case History: The “Bull Neck” – 3
▪ Suspecting the nature of the child’s
illness, the physician immediately
admitted the child to the hospital and
ordered administration of penicillin and
a specific antitoxin. The culture results
of a throat swab sent to the
microbiology lab confirmed the
physician’s suspicion. The root of the
child’s disease was Corynebacterium
diphtheriae, which causes diphtheria.

39
Reemerging Upper Respiratory Tract Infections – 1
▪ Diphtheria
Corynebacterium
diphtheriae
Gram-positive rod
Antibiotics and antitoxin
are simultaneously used.
Vaccine is inactivated
diphtheria toxin.
– Diphtheria vaccine is part
of the DTaP series of
vaccinations.
40
Reemerging Upper Respiratory Tract Infections – 2
▪ Whooping cough
Highly contagious
Gram-negative bacillus Bordetella pertussis
Acquired by inhalation of aerosolized droplets coughed by
someone with the illness
Incubation period of 7–21 days. The disease progresses
through
– Catarrhal: symptoms of upper respiratory infection
– Paroxysmal: violent paroxysmal (rapidly repeated) cough,
followed by a struggling deep breath that makes a whooping
noise
– Convalescent: paroxysms gradually disappear during the next 2–3
weeks as patient recovers
41
Reemerging Upper Respiratory Tract Infections – 3

42
Lower Respiratory Tract Bacterial Infections – 1
▪ Bronchitis
Inflammation of the bronchi
Acute and self-limiting
Multiple viral and bacterial etiologies
Productive cough is generally the only presenting symptom.
– Acute bronchitis is suspected when the patient’s cough persists
for more than 5 days.

43
Lower Respiratory Tract Bacterial Infections – 2
▪ Community acquired pneumonia
Acquired outside of a hospital
Pneumonia: an infection that causes inflammation in the lung
Classified as typical or atypical
– Atypical pneumonias affect multiple organ systems, usually
produce a normal WBC count, and produce symptoms that
appear gradually, mimicking upper respiratory infections at the
onset.
– Caused by organisms such as Mycoplasma pneumoniae,
Legionella, and Chlamydophila
Most common cause of typical pneumonia are organisms such
as Streptococcus pneumoniae.
44
Lower Respiratory Tract Bacterial Infections – 3

45
Case History: Night Sweats in a Nursing Home – 1
▪ In March, James, an 80-year-old resident of a New
Jersey nursing home, had a fever accompanied by
a productive cough with brown sputum.
▪ James reported to the attending physician that he
was short of breath, had pain on the right side of
his chest, and suffered from night sweats. Blood
tests revealed that his white blood cell count was
14,000/µl (normal value 4,500–10,000),
composed of 77% segmented forms
(polymorphonuclear leukocytes, PMNs; normal
value 40–60%) and 20% bands (immature PMNs;
normal value 0–3%).
46
Case History: Night Sweats in a Nursing Home – 2
▪ The chest radiograph revealed a right
upper lobe infiltrate. From this
information, the clinician made a
diagnosis of pneumonia. Microscopic
examination of the patient’s sputum
revealed Gram-positive cocci surrounded
by a capsule in pairs and short chains.
Bacteriological culture of his sputum and
blood yielded Streptococcus pneumoniae.

47
Case History: Night Sweats in a Nursing Home – 3
▪ Streptococcus pneumoniae
▪ Occurs mostly among the elderly, smokers,
and immunocompromised individuals
(such as diabetics and alcoholics)
▪ There are 91 serotypes of S. pneumoniae
that frequently colonize our airways.
▪ Humans are the only natural reservoir.
▪ Pneumococcal polysaccharide vaccine
(PPSV)
▪ Protection against 23 of the more than 90
most prevalent polysaccharide types
48
Lower Respiratory Tract Bacterial Infections – 4
▪ Mycoplasma pneumoniae
Atypical pneumonia
Mycoplasma lack a rigid cell wall and usually exist in
filamentous form.
Smallest known species of bacteria
Symptoms include
– Headache
– Malaise
– Progression to a nonproductive cough
– Possible low-grade fever
– Chills
49
Lower Respiratory Tract Bacterial Infections – 5
▪ Legionellosis (legionnaire’s disease)
Legionella pneumophila
Aerobic, Gram-negative bacterium
Causes atypical pneumonia
L. pneumophila contaminates various water sources, ranging
from lakes to the hot-water and air-conditioning distribution
systems of large buildings.
– Transmission via inhalation of contaminated water droplets
Intracellular pathogen
– After phagocytosis, the bacterium prevents the fusion of the
phagosome with the lysosome.
50
Lower Respiratory Tract Bacterial Infections – 6
▪ Hospital acquired pneumonia
HAI or health care–associated infections are acquired during
the course of receiving health care treatment for other
conditions.
Pseudomonas aeruginosa is the most common cause of hospital
acquired pneumonia
– Opportunistic, Gram-negative pathogen
– Large number of virulence factors
– Major contributor to pneumonia and mortality in patients with
cystic fibrosis (CF)

51
Lower Respiratory Tract Bacterial Infections – 7
▪ Tuberculosis
Mycobacterium tuberculosis
Acid-fast
Cases are on the rise in developed nations due to HIV and a
growing indigent population.
Multidrug resistant (MDR) tuberculosis
– Produces rapid onset (fulminant) and fatal disease among
patients with HIV
– Highly infectious even to healthy people without HIV
Spread from person to person (no animal reservoir)
– Aerosolizing of respiratory secretions
52
Lower Respiratory Tract Bacterial Infections – 8
▪ Tuberculosis pathogenesis
Bacteria enter lung, are phagocytized by macrophages, and survive
sheltered within modified phagolysosomes.
A delayed-type hypersensitivity reaction develops.
– Small, hard tubercules (granulomas) form around the site of the infection.
– Tubercules develop into caseous lesions that have a cheese-like
consistency and can calcify into hardened Ghon complexes seen on X-rays.
Latent tuberculosis: bacilli contained by immune system
– Not infectious
Primary disease: characterized by a productive cough that generates
sputum, fever, night sweats, and weight loss
– These patients have active TB and are contagious.
53
Lower Respiratory Tract Bacterial Infections – 9

54
Lower Respiratory Tract Bacterial Infections – 10

55
Pneumonia Caused by Select Agents
▪ Bacillus anthracis
▪ Inhalation anthrax
Spores are inhaled if aerosolized.
Prodromal phase lasts 5 days.
Some may have additional symptoms of hemoptysis (coughing
up blood), dyspnea (shortness of breath), chest pain, and
nausea.
▪ Transmission does not usually occur from person to person.
▪ Rapid diagnosis and antibiotic treatment is critical, as death can
occur within 48 hours.
56
20.4 Fungal and Parasitic Infections of the Respiratory Tract – 1
Section Objectives
▪ Identify the most common etiologies of fungal lower respiratory
tract infections.
▪ Describe the difference between fungal and bacterial lower
respiratory tract infections.
▪ Name the risk factors associated with fungal respiratory tract
infections.

57
Case History: A Boxer’s Fight to Survive – 1
▪ Tyrrell, a 35-year-old male boxer who installs
home insulation for a living, was recently
admitted to a Maryland hospital when he
presented at the emergency department
complaining of difficulty walking, fever, chills,
night sweats, and a recent 10 kg (21 lb) weight
loss. He denied having prior pneumonia, sinus
infection, arthritis, hematuria (blood in urine),
numbness, or muscle weakness. Tyrell also
denied any history of intravenous drug use and
reported to be in a monogamous relationship for
the past 4 years.
58
Case History: A Boxer’s Fight to Survive – 2
▪ There was no history of travel outside the area
for the past year. A review of Tyrell’s past
medical history showed that he had visited the
emergency department 6 months earlier with
flu-like symptoms, a chronic cough that
produced blood-tinged white sputum, shortness
of breath, loss of appetite, and weight loss. One
month prior to current admission, he developed
some painless subcutaneous nodules and
became so short of breath that he could no
longer continue boxing.

59
Case History: A Boxer’s Fight to Survive – 3
▪ At that time, an X-ray taken in the emergency
department showed right upper lobe infiltrate,
indicating pneumonia. A tuberculosis skin test
was negative. He was given a prescription for the
antibiotic azithromycin (a commonly used
antibiotic to treat bacterial infections of the
respiratory tract) and discharged. The cough and
weight loss continued.
▪ Physical exam at the time of current admission
revealed several painful subcutaneous nodules,
one filled with pus, and a tender tibia that
prevented him from walking. A CBC obtained at
the time of current admission showed normal
counts and differential.
60
Case History: A Boxer’s Fight to Survive – 4
▪ Fungal infections of the respiratory tract present with a
constellation of vague and seemingly unrelated symptoms.
▪ The most likely fungal cause of infection in this case are the
endemic mycoses such as histoplasmosis, blastomycosis,
coccidioidomycosis, and cryptococcosis.
▪ Taking into account Tyrrell’s signs, symptoms, and history,
blastomycosis, caused by Blastomyces dermatitidis, seems the
most likely.
▪ Amphotericin B (antifungal) was given, and fever and skin
nodules diminished.

61
20.4 Fungal and Parasitic Infections of the Respiratory Tract – 2
▪ The portal of entry is the
respiratory tract.
▪ Infection is usually associated
with occupational and
recreational activities in wooded
areas along waterways, where
there is moist soil and spores.
▪ Fungal infections are acquired
from the environment and not
person to person.

62
20.4 Fungal and Parasitic Infections of the Respiratory Tract – 3
▪ Fungal infections
Coccidioidomycosis
– Coccidioides immitis
– Endemic in the United States, Valley Fever
Histoplasmosis
– Histoplasma capsulatum
– Flu-like illness, erythema nodosum, arthritis, arthralgia
– In the United States, found mostly in the Ohio and Mississippi
river valleys

63
20.4 Fungal and Parasitic Infections of the Respiratory Tract – 4
▪ Fungal infections
Blastomycosis
– Blastomyces dermatitidis
– Dimorphic fungus
– Found mostly in the Ohio and Mississippi river valleys and
eastern United States
Cryptococcosis
– Cryptococcus neoformans
– Can involve skin, lungs, prostate gland, urinary tract, eyes, bones,
and joints
– The most prevalent clinical form is meningoencephalitis in AIDS
patients.
64
Clicker Question 1
Why are sequelae common after streptococcal infections?

a. Streptococcal infections result in opportunistic infection by the
microbiome.
b. Streptococcal infections increase the risk of secondary
infection by viral pathogens.
c. Streptococcal M proteins mimic human proteins and cause an
autoimmune reaction.
d. Streptococcal infections cause immunodeficiency.

65
Clicker Question 1 – Answer
Why are sequelae common after streptococcal infections?

a. Streptococcal infections result in opportunistic infection by the
microbiome.
b. Streptococcal infections increase the risk of secondary
infection by viral pathogens.
c. Streptococcal M proteins mimic human proteins and cause
an autoimmune reaction.
d. Streptococcal infections cause immunodeficiency.

66
Clicker Question 2
Which of the following viral infections of the respiratory tract is
especially concerning for premature infants?

a. rhinovirus
b. Bordetella pertussis
c. respiratory syncytial virus (RSV)
d. otitis media
e. Pseudomonas aeruginosa

67
Clicker Question 2 – Answer
Which of the following viral infections of the respiratory tract is
especially concerning for premature infants?

a. rhinovirus
b. Bordetella pertussis
c. respiratory syncytial virus (RSV)
d. otitis media
e. Pseudomonas aeruginosa

68
Clicker Question 3
A patient presents with atypical pneumonia, experiencing shortness
of breath, cough, and fever. The patient recently attended a party
with a large indoor water fountain. Several other attendees are also
ill. What is the likely cause?

a. Mycoplasma pneumoniae
b. Legionella pneumoniae
c. Chlamydophila
d. Streptococcus pneumoniae
e. Pseudomonas aeruginosa

69
Clicker Question 3 – Answer
A patient presents with atypical pneumonia, experiencing shortness
of breath, cough, and fever. The patient recently attended a party
with a large indoor water fountain. Several other attendees are also
ill. What is the likely cause?

a. Mycoplasma pneumoniae
b. Legionella pneumoniae
c. Chlamydophila
d. Streptococcus pneumoniae
e. Pseudomonas aeruginosa

70
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Chapter 20.

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