Lecture3 Diagnosis and Control of Infection PDF

Summary

This lecture covers the diagnosis and control of different infections, including epidemiology, reservoirs of infectious organisms, emerging diseases, and different types of disease transmission. The lecture was possibly delivered by Dr. Monica Agromayor, from King's College London's Faculty of Life Sciences and Medicine.

Full Transcript

Diagnosis and control of infection

Dr. Monica Agromayor
Department of Infectious Diseases
Faculty of Life Sciences and Medicine
Principles of disease transmission
Epidemiology
Science that studies when and where diseases occur and how they are transmitted in a population.
Epidemiologists collect information to determine:

Aetiology: identification of the pathogen causing the disease
Predisposing factors: age, sex, lifestyle, etc. – identify susceptible populations
Incidence: number of individuals acquiring disease in a given time period.
Prevalence: number of individuals with disease in a given time period.
Mode of transmission
Public health policy and prevention
Disease development and transmission
Disease development and transmission
Chain of infection is a concept used to explain how a patient can acquire an infection from
another person

It is used by epidemiologists and clinical
microbiologists to develop strategies to
prevent and control epidemics.
The components of the chain will vary
depending on the microbe and the disease it
causes.
Transmission of any given infection is
stopped by breaking one or more of the
links.
Disease development and transmission
The spread of infection is the final requirement for a successful pathogen.

Two main factors affect the spread of infection:
Reservoirs of infectious organisms - places where pathogens can grow
and accumulate
Modes of transmission – the various ways in which pathogens move
from place to place
Reservoirs
Habitat in which an infectious
agent normally lives, grows,
RESEVOIR
and multiplies.
Usually source from which it
is transmitted to a
susceptible host.
Zoonotic diseases spread NON
HUMAN ANIMAL
between animals and people. LIVING

The natural reservoir of some
diseases remains unknown.

CASE CARRIER
Reservoirs
Habitat in which an infectious
agent normally lives, grows,
RESEVOIR
and multiplies.
Usually source from which it
is transmitted to a
susceptible host.
Zoonotic diseases spread NON
HUMAN ANIMAL
between animals and people. LIVING

The natural reservoir of some
diseases remains unknown.

CASE CARRIER
Reservoirs
Habitat in which an infectious
agent normally lives, grows,
RESEVOIR
and multiplies.
Usually source from which it
is transmitted to a
susceptible host.
Zoonotic diseases spread NON
HUMAN ANIMAL
between animals and people. LIVING

The natural reservoir of some
diseases remains unknown.

CASE CARRIER
Reservoirs
Habitat in which an infectious
agent normally lives, grows,
RESEVOIR
and multiplies.
Usually source from which it
is transmitted to a
susceptible host.
Zoonotic diseases spread NON
HUMAN ANIMAL
between animals and people. LIVING

The natural reservoir of some
diseases remains unknown.

CASE CARRIER
Emerging disease
Unrecognized infection, or a previously recognized infection that has expanded into a new
ecological niche, often accompanied by a significant change in pathogenicity.
Many emerging diseases are zoonotic - an animal reservoir incubates the organism, with
only occasional transmission into human populations.
Emerging disease
Unrecognized infection, or a previously recognized infection that has expanded into a new
ecological niche, often accompanied by a significant change in pathogenicity.
Many emerging diseases are zoonotic - an animal reservoir incubates the organism, with
only occasional transmission into human populations.

Can be caused by:
Newly identified species (e.g. HIV and AIDS)
Newly identified strains that have evolved from a known infection (e.g. influenza)
Ecological changes that alter the composition and size of reservoirs (e.g. Lyme disease)
Spread to a population in a new area of the globe (e.g West Nile fever)
Re-emerging infections like drug resistant tuberculosis
Nosocomial (hospital-acquired) infections, such as Methicillin-resistant S. aureus
Emerging disease
Disease transmission

Main modes of transmission:
Contact transmission
Indirect transmission –
vehicle or vector
Horizontal (vs vertical)
Contact transmission
A healthy person is exposed to pathogens by either touching or being close to an infected
person or object.

Direct Contact Transmission: Person-
to-person transmission (touching,
kissing, sexual intercourse). No
intermediate object is involved

Examples: Hepatitis A, Smallpox, Staphylococcal infections,
mononucleosis, sexually transmitted diseases such as syphilis or HIV/AIDS.
Contact transmission
A healthy person is exposed to pathogens by either touching or being close to an infected person or object.

Indirect Contact Transmission: The microbe is
transferred via a nonliving object or fomite, such as
towels, eating utensils, thermometers, stethoscopes,
bedding, clothes, money, and needles.

Examples: Herpes simplex virus, Cytomegalovirus, Giardia, Impetigo
Contact transmission
A healthy person is exposed to pathogens by either touching or being close to an infected person or object.

Droplet Transmission: Microbes are spread in
mucus droplets that travel short distances (less
than 1 meter).
It can occur through sneezing, coughing, or
talking.

Typical of respiratory viruses (e.g., influenza, adenovirus, respiratory
syncytial virus, human metapneumovirus), Bordetella pertussis,
Pneumococci, Diphtheria and Rubella.
Vehicle transmission
Transmission of disease via medium such as water, food, air, blood, body fluids, and intravenous fluids.

Waterborne Transmission: Usually caused by
water contaminated with sewage.
Airborne Transmission: Not to be confused
with droplet transmission, is due to inhalation
of small pathogens and particles (e.g. bacterial
and fungal spores) that are suspended in air
and can travel long distances.
Foodborne Transmission: Typically due to bad
sanitation practices leading to contamination
of food with pathogens

Examples: Anthrax, tuberculosis, salmonella, cholera, typhoid, legionella
Vector transmission
Transmission of disease via animals that carry disease from one host to another. Insects
are most important animal vectors.

Mechanical Transmission: Passive
transport of pathogens on vector’s body.
Flies are the most common vector. Most of
the diseases can also be contracted
more directly through contaminated food,
water, air, hands and person-to-person
contact

Examples include enteric infections (dysentery, diarrhoea, typhoid or cholera) and eye
infections (trachoma and conjunctivitis)
Vector transmission
Transmission of disease via animals that carry disease from one host to another. Insects
are most important animal vectors.
Biological Transmission: Pathogen
spends part of its life cycle in the
vector and transmission to the host is
through a bite.

Examples include malaria, Zika virus,
Dengue fever, schistosomiasis and
rabies
Horizontal vs vertical transmission
Transmission from mother to child is called vertical transmission and can occur in utero
across placenta, at the time of delivery or during breast feeding. Person-to-person
transmission that is not between mother and offspring is called horizontal transmission.

Examples include HIV, Rubella and toxoplasmosis
Detection and diagnosis
Koch’s postulates Diseased animal Healthy animal..
1. The microorganism must be found in
abundance in all organisms suffering from.
1. Observe sample....
under microscope
the disease, but not in healthy organisms.
Suspected pathogen
Red blood cells
2. The microorganism must be isolated from
a diseased organism and grow in pure No pathogen
culture. 2. Culture sample
from diseased or
present

healthy animals

3. The cultured microorganism should cause Cultured pathogen

disease when introduced into a healthy 3. Inoculate healthy animal
with suspected pathogen
organism.

Diseased animal
4. The microorganism must be reisolated
from the inoculated, diseased experimental
host and identified as being identical to the 4. Culture

original specific causative agent.
Koch’s postulates today
Koch’s principles do not apply to all diseases:

Exceptions to the first postulate: Asymptomatic or
subclinical infection carriers are a common feature of many
infectious diseases
e.g. cholera or typhoid fever and viral infections such as polio, herpes simplex,
HIV and hepatitis C
Exceptions to the second postulate: Some microbes cannot
be grown in vitro or there are no susceptible animal species
e.g. Treponema pallidum (syphillis), Mycobacterium leprae (leprosy) and wart
viruses
Exceptions to the third postulate: not all organisms exposed
to an infectious agent will acquire the infection
e.g. resistance to malaria conferred by possessing at least one sickle cell allele.

Koch’s postulates continue to inform the approach to microbiologic diagnosis but
fulfillment of all four postulates is no longer required to demonstrate causality
Laboratory diagnosis
Two main methods are used in a diagnostic laboratory to confirm infection:

Direct detection methods – clinical
specimen is examined for the presence
of a microbe or its products. These
include culture, microscopy and
molecular methods
Indirect detection (serological)
methods – blood and other body fluids
are examined for the presence of
antibodies against a pathogen
The specimen to be collected from the patient needs to be selected taking into
account the pathogenesis of the infection.
Direct methods: culture of bacteria
Method used to propagate microorganisms by allowing them to grow in predetermined culture media
under controlled laboratory conditions (e.g. temperature, air supply, light, pH).
Depends on culture of microorganism mainly on solid nutrient media (agar plates) to produce colonies.
A colony is composed of thousands of bacteria growing on the surface that originate from a single cell.
Direct methods: culture of bacteria
Method used to propagate microorganisms by allowing them to grow in predetermined culture media
under controlled laboratory conditions (e.g. temperature, air supply, light, pH).
Depends on culture of microorganism mainly on solid nutrient media (agar plates) to produce colonies.
A colony is composed of thousands of bacteria growing on the surface that originate from a single cell.
Types of medium:
Defined medium: if the exact chemical composition is known.
Direct methods: culture of bacteria
Method used to propagate microorganisms by allowing them to grow in predetermined culture media
under controlled laboratory conditions (e.g. temperature, air supply, light, pH).
Depends on culture of microorganism mainly on solid nutrient media (agar plates) to produce colonies.
A colony is composed of thousands of bacteria growing on the surface that originate from a single cell.
Types of medium:
Defined medium: if the exact chemical composition is known.
Enrichment medium: contains some component that permits the
growth of specific types or species of bacteria, usually because they
alone can utilize the component from their environment.
Selective medium: Culture media designed to support the growth of
only specific microorganisms (e.g. selection done by adding antibiotics
or lacking amino acids).
Direct methods: culture of bacteria
Method used to propagate microorganisms by allowing them to grow in predetermined culture media
under controlled laboratory conditions (e.g. temperature, air supply, light, pH).
Depends on culture of microorganism mainly on solid nutrient media (agar plates) to produce colonies.
A colony is composed of thousands of bacteria growing on the surface that originate from a single cell.
Types of medium:
Defined medium: if the exact chemical composition is known.
Enrichment medium: contains some component that permits the
growth of specific types or species of bacteria, usually because they
alone can utilize the component from their environment.
Selective medium: Culture media designed to support the growth of
only specific microorganisms (e.g. selection done by adding antibiotics
or lacking amino acids).
Differential medium: Distinguishes closely related microorganism
growing on the same media on a difference in the colony appearance
due to the presence of certain dyes or chemicals in the media.
Direct methods: culture of viruses
Propagation requires cell cultures as viruses only replicate in living cells.
Cells that support viral replication are called permissive.
Multiplicity of infection (MOI) refers to the number of virions that are added per cell
during infection.
A virus-infected cell can show dramatic changes in appearance or cytopathic effects
(CPE) such as cell rounding and detachment from surface, cell fusion (syncytia) or
inclusion bodies.
Direct methods: culture of viruses
Propagation requires cell cultures as viruses only replicate in living cells.
Cells that support viral replication are called permissive.
Multiplicity of infection (MOI) refers to the number of virions that are added per cell
during infection.
A virus-infected cell can show dramatic changes in appearance or cytopathic effects
(CPE) such as cell rounding and detachment from surface, cell fusion (syncytia) or
inclusion bodies.

A B C

Monolayer of healthy cells Infected cells showing CPE
Direct methods: microscopy
Microscopy and molecular techniques based on detection of nucleic acids provide a
rapid indication of microbial infection in a matter of hours.

Used either with wet or fixed samples
Can be used in combination with stains.
Can study bacteria morphology and staining
characteristics.
Used to determine virus-induced CPE. To see virus
morphology electron microscopy is needed.
Direct methods: microscopy
Microscopy and molecular techniques based on detection of nucleic acids provide a
rapid indication of microbial infection in a matter of hours.

Used either with wet or fixed samples
Can be used in combination with stains.
Can study bacteria morphology and staining
characteristics.
Used to determine virus-induced CPE. To see virus
morphology electron microscopy is needed.
Direct methods: microscopy
Microscopy and molecular techniques based on detection of nucleic acids provide a
rapid indication of microbial infection in a matter of hours.

Used either with wet or fixed samples
Can be used in combination with stains.
Can study bacteria morphology and staining
characteristics.
Used to determine virus-induced CPE. To see virus
morphology electron microscopy is needed.
Direct methods: detection of nucleic acids
Molecular tests can detect the presence
of bacterial and viral DNA or RNA in a
patient specimen. Labelled probe
Sample
Can be used to detect organisms that are
slow or difficult to grow in the laboratory,
antibiotic resistance genes or virulence
factors.
Very sensitive and specific.

Two main types:
Hybridisation techniques with
nucleic acid probes Fully complementary strands bind strongly
Direct methods: detection of nucleic acids
Molecular tests can detect the presence
of bacterial and viral DNA or RNA in a
patient specimen. Labelled probe
Sample
Can be used to detect organisms that are
slow or difficult to grow in the laboratory,
antibiotic resistance genes or virulence
factors.
Very sensitive and specific.

Two main types:
Hybridisation techniques with
nucleic acid probes Fully complementary strands bind strongly
Direct methods: detection of nucleic acids
Molecular tests can detect the presence of bacterial and viral DNA or RNA
in a patient specimen.
Can be used to detect organisms that are slow or difficult to grow in the
laboratory, antibiotic resistance genes or virulence factors.
Very sensitive and specific.
Two main types:
Hybridisation techniques with Original DNA to be
replicated
nucleic acid probes (template)

Polymerase chain reaction (PCR) dNTPs

Primer
Indirect methods: serological tests
Determine the presence of antibodies in serum or microbial antigens in tissue or body fluids.

Titre refers to antibody concentration in the sample and
is associated with the number of times one can dilute a
sample and still detect the antibody.
Indirect methods: serological tests
Determine the presence of antibodies in serum or microbial antigens in tissue or body fluids.

Titre refers to antibody concentration in the sample and
is associated with the number of times one can dilute a
sample and still detect the antibody.
Paired sera samples need to be collected during acute
phase (5-7 days after onset of symptoms) and
convalescence phase of infection (after 2-4 weeks).
At least a four-fold rise in specific antibody titre between
acute and convalescent samples (seroconversion) must
be found for a diagnosis to be made.
Presence of IgM but not IgG antibodies can be an
indication of current active infection.
Do not distinguish between previous or current infection.
Serological methods are retrospective.
Indirect methods: serological tests
Determine the presence of antibodies in serum or microbial antigens in tissue or body fluids.

Titre refers to antibody concentration in the sample and
is associated with the number of times one can dilute a
sample and still detect the antibody.
Paired sera samples need to be collected during acute
phase (5-7 days after onset of symptoms) and
convalescence phase of infection (after 2-4 weeks).
At least a four-fold rise in specific antibody titre between
acute and convalescent samples (seroconversion) must
be found for a diagnosis to be made.
Presence of IgM but not IgG antibodies can be an
indication of current active infection.
Do not distinguish between previous or current infection.
Serological methods are retrospective.
 Direct vs indirect methods
Method Advantages Disadvantages
Culture Confirms presence of organism Can take long
Organism is multiplied and can be used Organism need to be capable of growing
for additional testing in vitro
Microscopy Quick and easy preliminary results Not very specific

Detection of nucleic acids Results available within hours Previous knowledge of DNA sequence
Very sensitive and specific needed
Serological tests Not limited to blood serum (other body Long length of time required to obtain
fluids also suitable) paired sera
Well established, inexpensive and easy Specific antibodies not always available
to perform Not suitable for agents that produce
Can be used for multiple sample clinical disease before the appearance of
analysis at a time antibodies
Some conditions may not produce
detectable antibodies
Prone to false positive results due to
antigenic cross-reactivity between
related agents
Strategies to treat infection
Selective toxicity
Antimicrobial agents need to inhibit the growth of the
Penicillium colony microbe while doing minimal damage to the patient.
Achieved by exploiting the differences between the
metabolism and structure of microorganisms and the
human cells they infect.
Compared to the number of drugs available to treat
bacterial infection, the number of antiviral drugs is
very small viral replication is intimately linked to
normal cellular functions so selective toxicity is
difficult to obtain.
Antimicrobial agents can be natural products (e.g.
antibiotics from fungal sources) or synthetic if they
are chemically designed in the lab.
Antibacterial agents
Type of antimicrobial drug used in the treatment and prevention of
bacterial infections.
They may either kill (bactericidal) or inhibit the growth of bacteria
(bacteriostatic)
May be classified as either broad spectrum or narrow spectrum
depending on how many types of microorganism are naturally
susceptible to their action
Also classified depending on their chemical structure and site of action:
Molecules that inhibit cell wall synthesis
Molecules that inhibit the function of the bacterial plasma
membrane
Molecules that inhibit the synthesis of nucleic acids
Molecules that inhibit the synthesis of proteins
Antibacterial agents
Major targets of common antibacterial agents Principle of action
Cell wall synthesis The cell wall is rich in
peptidoglycans, a compound unique
to bacteria.

Plasma membrane Injure plasma membrane by disrupting
function membrane potential.
Some target specifically the LPS within
Gram-negative outer membranes.

Nucleic acid Block bacterial enzymes or metabolic
synthesis pathways that produce essential
precursors needed for DNA and mRNA
synthesis
Protein synthesis Exploit the differences between
eukaryotic and prokaryotic
ribosomal proteins, RNAs and
associated enzymes
Antiviral agents
Major steps targeted by common antiviral agents Principle of action

Attachment and entry Inhibit fusion of viral envelope or
attachment to receptor

Nucleic acid Molecules that target viral DNA and
synthesis RNA polymerases

Assembly and budding Inhibit viral proteins needed for
virion maturation and/or release
Antimicrobial drug resistance
Antimicrobial resistance is the ability of a microorganism to survive and multiply in the
presence of an antimicrobial agent that would normally inhibit or kill this particular kind
of organism.

Bacterial resistance strategies:
By preventing drug from reaching its target by reducing its ability to penetrate
the cell
By inactivation of drug via modification or degradation
By expulsion of the drug from the cell via general or specific efflux pumps
By modification of the drug’s target site within the bacteria
Antimicrobial drug resistance
Antimicrobial resistance is the ability of a microorganism to survive and multiply in the
presence of an antimicrobial agent that would normally inhibit or kill this particular kind
of organism.

Viral resistance strategies:
Results from spontaneous mutations in the viral genome during viral
replication
Mutations are within the target of the antiviral drug
The error-prone polymerase enzyme in RNA viruses cause these viruses to
develop resistance more frequently than DNA viruses
Special concern during extended therapy for chronic infections (e.g. HIV, HBV
and HCV)
Combination therapy with more than one agent is commonly used to delay
appearance of resistance
Prevention of disease transmission
Immunological memory
First exposure Clonal Memory cells are long- Second Stronger and more rapid
to antigen expansion lived, continue to exposure to response
reproduce antigen

Effector cells carry out
immediate response; short lived

Primary response Secondary response
 Types of adaptive immunity

ADAPTIVE IMMUNITY

ACTIVE PASSIVE

NATURAL ARTIFICIAL NATURAL ARTIFICIAL
Exposure to infectious agent Vaccination Maternal antibodies Injected Antibodies
Artificial passive immunisation
Immunity is transferred by administration of antibodies to a non immune individual.
Used when there is no time to wait for the development of active immunity, or when
no effective active vaccine exists.
The antibodies used can be either of human origin or produced in animals
Artificial active immunisation
Immunity develops after the immune system encounters an
antigen and is the basis for VACCINATION.
Thus, vaccination is exposing a person to material that is
antigenic but NOT pathogenic, inducing adaptive immunity and
memory.
At the population level, the success of a vaccination programme
depends on herd immunity.
Herd immunity: in contagious diseases that are transmitted
from individual to individual, chains of infection are likely to be
disrupted when large numbers of a population are immune or
less susceptible to the disease.
The proportion of the population required to be immune to
reach herd immunity depends on a number of factors and it’s
different for each disease.
Requirements of an effective vaccine
Safe, with no or few side effects – it must not cause disease!!
Give long lasting, appropriate protection against the natural form of the pathogen
Stimulate both a humoral and cell-mediated immune response and the production
of memory cells.
Low in cost
Stable with long shelf life and no special storage requirements
Easy to administer