Chapter 7 Viruses of Clinical Significance PDF

Summary

This document provides an introduction to viruses of clinical significance, focusing on respiratory viruses. It covers the categorization of viruses by organ/system, and examples like Influenza, RSV, and SARS-CoV-2.

Full Transcript

Chapter 7

Introduction to Viruses of
Clinical Significance

1. Respiratory Viruses

Carina O. Barlongo, RMT
08 October 2024
 Organ / System
Categorization of Viruses

practical approach to understanding the clinical
impact of viruses and the diseases they cause

this method makes it easier to correlate the
viral pathogens with their symptoms, diagnostic
methods, treatments, and preventive measures

for the medical technologists or medical lab
scientists, the association helps in identifying
the appropriate sample specimen and lab tests
 Viruses of Clinical Significance
1. Respiratory Viruses

primarily affect the respiratory tract, causing illnesses
ranging from the common cold to severe pneumonia.
crucial in managing respiratory outbreaks and pandemics

Examples:
Influenza, RSV, and SARS-CoV-2
 Viruses of Clinical Significance
2. Gastrointestinal Viruses

primarily infect the digestive system, leading to
gastroenteritis, diarrhea or hepatitis.

Common examples:
Norovirus and Rotavirus
 Viruses of Clinical Significance
3. Nervous System Viruses

target the central and peripheral nervous systems, causing
neurological diseases like encephalitis or meningitis

Examples:
Rabies virus, Poliovirus, and Herpes Simplex Virus
 Viruses of Clinical Significance
4. Dermatological Viruses

manifest through skin lesions or rashes.

Examples:
Human Papillomavirus (HPV)
Varicella-Zoster virus (VZV)
Molluscum contagiosum
 Viruses of Clinical Significance
5. Hepatic Viruses

primarily affect the liver, leading to conditions such as
hepatitis.

Examples:
Hepatitis A, B, C, D, and E viruses
 Viruses of Clinical Significance
6. Cardiovascular System Viruses

Coxsackie B Virus: Associated with myocarditis and
pericarditis

Enteroviruses: Can cause viral myocarditis, leading to heart
inflammation and damage.
 Viruses of Clinical Significance
7. Reproductive System Viruses

Human Papillomavirus (HPV):
Linked to cervical, anal, and genital cancers, as well as genital warts

Herpes Simplex Virus (HSV-2): Causes genital herpes
 Viruses of Clinical Significance
8. Ocular Viruses

Adenovirus: Can cause viral conjunctivitis (pink eye)

Herpes Simplex Virus:
can lead to ocular herpes, causing keratitis or more severe eye
infections.
 Viruses of Clinical Significance
9. Systemic Viruses

HIV
affects multiple systems but primarily targets the immune system

Cytomegalovirus (CMV)
can cause systemic infections in immunocompromised patients,
affecting the liver, lungs, brain, and gastrointestinal tract.
 Viruses of Clinical Significance
10. Arthropod-borne viruses, or arboviruses
are viruses transmitted by arthropods such as mosquitoes, ticks, and sandflies

typically affect multiple organ systems, depending on the virus, but they are
often categorized based on their primary clinical manifestations

arboviruses can cause a range of diseases, including febrile illness,
encephalitis, hemorrhagic fever, and joint/muscle pain

Examples: Dengue, Zika
1. Respiratory Viruses
 Respiratory viruses primarily target the
respiratory tract (upper and/or lower
airways), leading to a wide range of diseases,
from mild colds to severe pneumonia.

Clinical significance: ability to cause
widespread outbreaks, especially during
colder seasons, and their potential to cause
serious complications, particularly in
vulnerable populations such as young
children, the elderly, and
immunocompromised individuals.

Major routes of transmission:
- airborne droplets
- direct contact and fomites (contaminated
surfaces)
 1. Influenza Virus A, B, C
(Orthomyxoviridae)

1.Orthomyxovirus virions contain a segmented RNA
genome (sdRNA) and have a helical- shaped virion
with an envelope. Size range from 75 to 125 nm.
2.Orthomyxoviruses have hemagglutinin (HA) and
neuraminidase (NA) on their surface.
3.The influenza viruses, A, B, and C, are the only
members of the family Orthomyxoviridae. Influenza A
and B viruses are most clinically significant.
1. Influenza Virus A, B, C
(Orthomyxoviridae)
Hemagglutinin (HA):
A glycoprotein on the surface of the influenza virus that allows the virus to bind to and enter host
cells by attaching to sialic acid receptors on the cell surface. It’s crucial for the virus’s ability to
infect host cells.

Neuraminidase (NA):
Another surface protein that helps the virus to release from the infected host cell after replication.
It cleaves sialic acid, allowing the virus to spread to other cells.

These proteins are the basis for classifying different strains of influenza A virus, such as H1N1 (swine
flu, 2009 pandemic, 1918 Spanish flu) or H3N2 (seasonal flu), where the numbers correspond to
specific subtypes of HA and NA proteins.
1. Influenza Virus (Orthomyxoviridae)
Type: A, B, C
Influenza A: The most virulent and known for causing pandemics (e.g., H1N1, H3N2).
Influenza B: Causes seasonal epidemics but is generally less severe than type A.
Influenza C: Causes mild respiratory illness.

Mode of Transmission: Airborne via respiratory droplets from coughs and sneezes and direct
contact by touching surfaces contaminated with the virus.
Diseases: Causes influenza (trangkaso), characterized by symptoms such as fever, chills,
cough, sore throat, body aches, and fatigue.
Complications: Can lead to pneumonia, bronchitis, sinus infections, and worsening of chronic
health conditions.

Clinical Significance: Influenza has seasonal epidemics with significant morbidity and
mortality, particularly among the elderly, young children, and those with chronic health issues.
Vaccination is critical for prevention.
1. Influenza Virus (Orthomyxoviridae)
Laboratory Diagnosis
Rapid influenza diagnostic tests (RIDTs): Detects
viral antigens, provides results in about 15 minutes
but can be less sensitivity

RT-PCR: Gold standard, highly sensitive, detects
and differentiates between influenza types and
subtypes.

Viral culture: Less commonly used but can be
done for confirmation.
 1. Influenza Virus
(Orthomyxoviridae)
Treatment:
Antiviral medications:
Oseltamivir (Tamiflu): Most common antiviral for influenza.
Zanamivir (Relenza) and Peramivir are alternatives.
Should be administered within 48 hours of symptom onset for
maximum efficacy.

Prevention:
Annual influenza vaccination: Recommended for everyone, particularly
vulnerable groups (children, elderly, healthcare workers).
Hand hygiene and respiratory etiquette
Isolation of infected individuals during outbreaks
 Reconstruction of 1918 Influenza Virus
PCR technology has yielded gene fragments of influenza
virus from archival lung tissue specimens from victims of the
1918 Spanish flu epidemic.
The complete coding sequences of all eight viral RNA
segments have been determined, and the sequences
document that it was an H1N1 influenza A virus.
It appears that the 1918 virus was not a reassortant (not a
combination of the RNA segments) but was derived entirely
from an avian source that adapted to humans.
Source: Jawetz, 28th edition
 2. Rhinovirus (Picornaviridae)
The picornaviruses have a naked virion ranging in size from
20 to 30 nm.
The family Picornaviridae includes a number of viruses such
as the enteroviruses, hepatitis A virus, and the rhinoviruses.
Rhinoviruses
Rhinoviruses are a frequent cause of the common cold.
Other viruses, including coronaviruses, are also
associated with colds.
The rhinoviruses grow better at temperatures just
below core body temperature (e.g., 33°C). This is near
the typical temperature of the nasal passage.
Over 100 serotypes are known, and immunity to one
does not provide immunity to the others. This is why
colds are so common.
 Important Properties of Picornaviruses

2. Rhinovirus
(Picornaviridae)

Source: Jawetz, 28th edition
2. Rhinovirus (Picornaviridae)
Mode of Transmission
Direct contact with infected secretions (e.g.,
touching hands, objects, surfaces)
Inhalation of respiratory droplets

Laboratory Diagnosis:
Typically, clinical diagnosis based on symptoms.
RT-PCR: Can be used for detection in severe
cases, especially in vulnerable populations, but is
not routine.
 2. Rhinovirus
(Picornaviridae)
Treatment
Supportive care: Hydration, rest, over-the-
counter pain relievers (e.g., acetaminophen,
ibuprofen), decongestants.
No specific antiviral therapy for rhinovirus.

Prevention
Hand hygiene and avoidance of close contact
with infected individuals.
Disinfection of surfaces during cold outbreaks.
 3. The Three Major Coronaviruses:
SARS, MERS, and SARS-CoV-2
Coronaviruses are large, enveloped RNA viruses. The
human coronaviruses cause common colds, may cause
lower respiratory tract infections, and have been
implicated in gastroenteritis in infants.
Virus Structure: Enveloped, positive-sense single-
stranded RNA viruses with spike proteins that give
them a crown-like appearance.
Types: Infect humans and animals, causing
respiratory, gastrointestinal, and neurological
diseases.
Very little is known about the epidemiology of
enteric coronavirus infections.
 SARS-CoV
(Severe Acute Respiratory Syndrome Coronavirus)
First Identified: 2002 in Guangdong, China.
Outbreak: Caused a global epidemic in 2002-2003.
Transmission: Respiratory droplets, close contact.
Symptoms: Fever, cough, difficulty breathing, and pneumonia; can
lead to ARDS (Acute Respiratory Distress Syndrome).
Mortality Rate: ~10%.
Diagnosis: RT-PCR, viral culture, serology.
Treatment: Supportive care; no specific antivirals; corticosteroids in
some severe cases.
Prevention: Isolation of infected patients, quarantine, and public
health measures.

Source: WHO, CDC
 MERS-CoV
(Middle East Respiratory Syndrome Coronavirus)
First Identified: 2012 in Saudi Arabia.
Outbreaks: Primarily in the Middle East but also seen in other countries
through travel.
Transmission: Zoonotic transmission from camels to humans; limited
human-to-human spread, mostly in healthcare settings.
Symptoms: Fever, cough, shortness of breath, and gastrointestinal
symptoms; can progress to pneumonia and kidney failure.
Mortality Rate: ~34%.
Diagnosis: RT-PCR, serology, viral culture.
Treatment: Supportive care; investigational antivirals in some cases.
Prevention: Avoiding contact with camels, infection control in healthcare
settings, and travel precautions.

Source: WHO, CDC
 SARS-CoV-2 (COVID-19)
First Identified: December 2019 in Wuhan, China.
Pandemic: ` Global pandemic 2020.
Transmission: Primarily through respiratory droplets, aerosols, and close contact; also via
contaminated surfaces.
Symptoms: Wide range, from asymptomatic to severe pneumonia; common symptoms
include fever, cough, loss of taste/smell, and fatigue. Severe cases may
involve ARDS, multi-organ failure, and death.
Mortality Rate: Varies by region and healthcare capacity; generally lower than MERS but
highly infectious.
Diagnosis: RT-PCR, antigen tests, serology for past infections.
Treatment: Antivirals (e.g., remdesivir), monoclonal antibodies, corticosteroids (e.g.,
dexamethasone), oxygen therapy, and mechanical ventilation in severe
cases.
Prevention: Vaccination (Pfizer, Moderna, AstraZeneca, Janssen, Sinovac), masks,
physical distancing, hand hygiene, and travel restrictions
Source: WHO, CDC
 4. Adenovirus (Adenoviridae)
Adenoviruses can replicate and produce disease in the respiratory,
gastrointestinal, and urinary tracts and in the eye.
Many adenovirus infections are subclinical, and virus may persist in the
host for months
About one-third of the 57 known human serotypes are responsible for
the most cases of human adenovirus disease
A few types serve as models for cancer induction in animals
Adenoviruses are valuable systems for molecular and biochemical
studies of eukaryotic cell processes
They are also useful vectors for gene therapy approaches.
Adenoviruses 1–7 are the most common types worldwide and account
for most instances of adenovirus associated illness
 4. Adenovirus (Adenoviridae)
Adenoviruses belong to the family Adenoviridae. There are
four genera:
Mastadenovirus, Aviadenovirus, Atadenovirus and
Siadenovirus
At present 57 antigenic types of human adenoviruses have
been described.
Human adenoviruses have been classified into seven groups
(A–G) on the basis of their physical, chemical and biological
properties.
All of the human adenoviruses are classified in the
Mastadenovirus genus
Structure and Properties
 Clinical Significance
Infection with one of the many adenoviruses may be
asymptomatic or result in specific syndromes:

1. Respiratory tract infections, especially in young children
2. Urinary tract and gastrointestinal infections, and
pharyngitis
3. Eye infections in newborns, patients who are
immunocompromised,
4. and military recruits (because of close living conditions) are
common.
5. Adenoviruses have been associated with epidemics of
keratoconjunctivitis.
 Gene Therapy
Adenoviruses are being
used as gene delivery
vehicles for cancer
therapy, gene therapy,
and genetic
immunization studies.

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Laboratory Diagnosis
A. Detection, Isolation, and Identification of Virus
Samples should be collected from affected sites early in the illness to optimize virus detection.
Depending on the clinical disease, virus may be found in respiratory samples, conjunctiva, throat,
blood, stool, or urine.
Duration of adenovirus excretion varies among different illnesses
ex: respiratory infection of adults (1–7 days) and children (3–6 weeks)
Virus isolation in a cell culture requires susceptible cell types. Primary human
embryonic kidney cells are most susceptible but usually unavailable.
Polymerase chain reaction (PCR) assays are routinely used for diagnosis of
adenovirus infections in respiratory samples, blood, tissues, or body fluids,
usually by using primers from a conserved viral sequence (eg, hexon and VA I)
that can detect all serotypes.
 Laboratory Diagnosis
B. Serology

The complement-fixation test is an easily applied
method for detecting infection by any member of the
adenovirus group but the test has low sensitivity

If specific identification of a patient’s serologic response
is required, antibody neutralization or hemagglutination
inhibition tests can be used.

The neutralization test is the most sensitive.
 Treatment, Prevention and Control
§ There is no specific treatment for adenovirus infections.
§ Careful hand washing is the easiest way to prevent infections.
§ Environmental surfaces can be disinfected with sodium
hypochlorite.
§ In group settings, paper towels may be advisable because dirty
towels can be a source of infection in outbreaks.
§ The risk of waterborne outbreaks of conjunctivitis can be
minimized by chlorination of swimming pools and waste water.
§ Strict asepsis during eye examinations, coupled with adequate
sterilization of equipment, is essential for the control of
epidemic keratoconjunctivitis.
5. Paramyxo Viruses
(Paramyxoviridae)
Genome:

Non-segmented, negative-sense single-
stranded RNA (ssRNA).

Shape:
Enveloped, pleomorphic (can have various
shapes, typically spherical or filamentous).

Replication:
Occurs in the cytoplasm of the host cell.
5. Paramyxo Viruses
(Paramyxoviridae)
Key Viruses:
Respiratory Syncytial Virus (RSV): A leading cause of
bronchiolitis and pneumonia in infants and the elderly.
Parainfluenza Virus: Causes croup
(laryngotracheobronchitis), especially in children, as well as
bronchiolitis and pneumonia.
Measles Virus: Causes measles, a highly contagious viral
disease characterized by fever, cough, and a widespread
rash.
Mumps Virus: Causes mumps, characterized by fever and
swelling of the salivary glands.
 5. Paramyxo Viruses (Paramyxoviridae)

Diseases:
Paramyxoviruses cause a range of respiratory illnesses, from the common
cold to severe diseases such as bronchiolitis, pneumonia, and croup in
children.
Measles and mumps are also notable systemic diseases caused by
paramyxoviruses.
(both will be discussed in succeeding chapters)

Transmission:
Primarily through respiratory droplets and close person-to-person contact.
 Respiratory Syncytial Virus (RSV)
(Paramyxoviridae)
Mode of Transmission:
Airborne droplets
Direct contact with infected secretions (e.g., saliva, nasal discharge)
Fomites (contaminated surfaces)

Laboratory Diagnosis:
RT-PCR: Highly sensitive and specific for RSV.
Antigen detection tests: Common in pediatric settings but less sensitive than
PCR.
Rapid antigen tests: Can detect RSV in nasopharyngeal swabs or secretions,
commonly used in clinical settings.
Viral culture: Rarely performed due to the slow growth of the virus in culture.
 Respiratory Syncytial Virus (RSV)
(Paramyxoviridae)
Treatment
Supportive care: Hydration, oxygen supplementation, mechanical ventilation in
severe cases.
Ribavirin: Antiviral used in severe cases, particularly in high-risk individuals.
Monoclonal antibody (Palivizumab): Used prophylactically in high-risk infants to
prevent severe RSV infections.

Prevention:
Hand hygiene: Critical in preventing the spread of RSV in hospitals and homes.
Palivizumab: Given to high-risk infants during RSV season as prophylaxis.
Infection control measures: In healthcare settings, isolating RSV patients can
prevent transmission.
 Human Parainfluenza Viruses (HPIV)
(Paramyxoviridae, Respirovirus Genus and
Rubulavirus Genus)
Treatment:
Supportive care:
Management of symptoms such as fever, cough, and breathing difficulty (e.g.,
cool mist humidifiers, hydration). In severe cases, oxygen therapy or intubation
may be required.
Corticosteroids: May be used in severe croup to reduce inflammation and ease
breathing.
Antivirals: No specific antiviral therapy is currently available for HPIV.

Prevention and Control:
Infection control: Hand hygiene, avoiding close contact with infected individuals,
and surface disinfection are key measures.
No vaccine: Unlike measles and mumps, there is no available vaccine for HPIV,
although vaccine development is ongoing.
 Human Parainfluenza Viruses (HPIV)
(Paramyxoviridae, Respirovirus Genus and
Rubulavirus Genus)
Laboratory Diagnosis:
Rapid antigen tests:
Commonly used for detecting HPIV in respiratory specimens.
PCR:
Sensitive and specific detection of HPIV RNA in nasopharyngeal or
throat swabs.
Viral culture:
Occasionally used, though PCR is preferred due to its faster results.
 Knowledge Check
Adenoviruses can cause eye infections that are highly
contagious. Which of the following is least likely to be a means
of transmission during an outbreak of epidemic
keratoconjunctivitis?
A. Swimming pools
B. Hand towels
C. Mosquito bites
D. Hand-to-eye
E. Contaminated ophthalmic equipment