3. A. INFLUENZA VIRUS – STRUCTURE & PROPERTIES
INTRODUCTION
The H1N1 flu or Swine Flu as commonly referred to is a global pandemic caused by a
novel strain of influenza virus A (H1N1). The virus was first identified in the Mexico in April
2009 and has thus far spread to almost all parts of the world with high infection rates. Though it
was initially called Swine Flu, because the virus possessed genes from influenza viruses
commonly affecting pigs in Europe and Asia, it has now been confirmed that the virus actually
consists of a mixture of genes from different species. The virus is called a ‗quadruple reassortant‘
to indicate the fact that it is made up of genes found in influenza viruses infecting pigs, birds and
humans. The letters H and N in H1N1 designate specific chemical structures expressed on the
surface of the virus.
STRUCTURE OF VIRUS
The novel influenza A (H1N1) virus is similar in structure to the seasonal influenza virus
that affects hundreds of thousands of people every year worldwide.
In biological terms, organisms that share common features structurally and functionally
are grouped together into classes known as Family, genera and species in decreasing hierarchical
order. Influenza viruses are called RNA viruses since their genetic material is made up of
Ribonucleic Acid. These viruses belong to the family Orthomyxoviridae. The family has five
genera out of which three are most prominent - A, B and C. Influenza A virus is the most
prominent genera among the three and has caused several epidemic outbreaks in the past.
INFLUENZA A VIRUS
This genus includes only one species: Influenza A virus. This virus causes influenza
mostly in birds and occasionally in humans. The virus is a single stranded RNA virus. Several
variations of the virus have been observed in nature based on two surface proteins hemagglutinin
(H) and neuraminidase (N). These variations are called subtypes. Some of the prominent
subtypes of Influenza A Virus are listed below.
Fig 1. Influenza virus Fig 2. Microscopic structure
4. H5N1 Subtype - Bird flu virus
H3N2 Subtype - Hong Kong flu pandemic of 1968
H5N2 Subtype - Highly pathogenic in chickens
H3N8 Subtype - Frequently found in horses
H2N2 Subtype - Asian flu pandemic of 1957
H7N7 Subtype - 2003 poultry epidemic
H1N1 Subtype - Spanish flu pandemic of 1918 and swine flu
Subtypes
There are 16 different subtypes of the virus based on the surface protein Hemagglutinin and 9
different subtypes based on Neuraminidase. The designation of the virus as H1N1 refers to the
combination of these two surface proteins that make up the virus. The novel influenza A (H1N1)
is an Influenza A virus made up of two different subtypes H1 and N1 of the proteins. The Novel
influenza A (H1N1) Virus has mutated into various strains such as the Spanish Flu strain, mild
human flu strains, endemic pig strains, and various strains found in birds.
HA subtype designation NA subtype designation Avian influenza A viruses
H1 N1 A/duck/Alberta/35/76(H1N1)
H1 N8 A/duck/Alberta/97/77(H1N8)
H2 N9 A/duck/Germany/1/72(H2N9)
H3 N8 A/duck/Ukraine/63(H3N8)
H3 N8 A/duck/England/62(H3N8)
H3 N2 A/turkey/England/69(H3N2)
H4 N6 A/duck/Czechoslovakia/56(H4N6)
H4 N3 A/duck/Alberta/300/77(H4N3)
H5 N3 A/tern/South Africa/300/77(H4N3)
H5 N4 A/jyotichinara/Ethiopia/300/77(H6N6)
H5 N9 A/turkey/Ontario/7732/66(H5N9)
H5 N1 A/chick/Scotland/59(H5N1)
H6 N2 A/turkey/Massachusetts/3740/65(H6N
2)
H6 N8 A/turkey/Canada/63(H6N8)
H6 N5 A/shearwater/Australia/72(H6N5)
H6 N1 A/duck/Germany/1868/68(H6N1)
H7 N7 A/fowl plague virus/Dutch/27(H7N7)
H7 N1 A/chick/Brescia/1902(H7N1)
H7 N3 A/turkey/England/639H7N3)
5. H7 N1 A/fowl plague
virus/Rostock/34(H7N1)
H8 N4 A/turkey/Ontario/6118/68(H8N4)
H9 N2 A/turkey/Wisconsin/1/66(H9N2)
H9 N6 A/duck/Hong Kong/147/77(H9N6)
H10 N7 A/chick/Germany/N/49(H10N7)
H10 N8 A/quail/Italy/1117/65(H10N8)
H11 N6 A/duck/England/56(H11N6)
H11 N9 A/duck/Memphis/546/74(H11N9)
H12 N5 A/duck/Alberta/60/76/(H12N5)
H13 N6 A/gull/Maryland/704/77(H13N6)
H14 N4 A/duck/Gurjev/263/83(H14N4)
H15 N9 A/shearwater/Australia/2576/83(H15N
9)
Table 1: Avian influenza A virus strains
INFLUENZA B VIRUS
The virus belongs to the family Orthomyxoviridae. It is the only species in the genus
Influenzavirus B. It is an RNA virus similar to the Influenza A virus. These viruses are known to
infect humans and seals causing influenza. Compared to Influenza A virus, these viruses are
limited in their ability to attack a wide variety of hosts. Hence they are not often associated with
causing pandemics. Also, the virus mutates slowly as compared to Influenza A viruses.
Influenza B virus progresses by causing localized outbreaks, predominantly in school
children but sporadic cases are also reported in adults. It is very difficult to discern the level of
antigenic variation in type B influenza viruses. The viruses isolated during some of the larger
outbreaks possessed variations within the haemagglutinin molecule. These variations were not
comparable to any other previous forms of influenza B virus. This seems to suggest that once
one form of B strain virus emerges, it is highly unlikely that another strain with similar
serological qualities will return. The slow antigenic drift of the influenza B virus, unlike that of
type A, allows time for human populations to acquire immunity, and eventually halt the spread
of the virus.
INFLUENZA C VIRUS
Influenza C virus belongs to the family Orthomyxoviridae, which includes those viruses which
cause influenza. The only species in this genus is called "Influenza C virus". Influenza C viruses
are known to infect humans and pigs with influenza. Flu due to the type C species is rare
compared to types A or B, but can be severe and can cause local epidemics. Influenza type C
differs from types A and B in some important ways. Type C infection usually causes either a
very mild respiratory illness or no symptoms at all and does not have the severe public-health
impact of influenza types A and B.
6. A.2 GENETICS OF VIRUS
VIRION STRUCTURE
A single functional virus is known as a Virion. The Influenza A Virus is a globular
particle about 100nm in diameter. Since the Influenza A virus is an RNA virus, it has RNA as the
genetic material present along with proteins which make up the ribonucleoprotein core. This core
is enveloped by a bi-layer of proteins. The virion is roughly spherical in shape. It is an enveloped
virus – that is, the outer layer is a lipid membrane which is taken from the host cell in which the
virus multiplies. Inserted into the lipid membrane are ‘spikes‘, which are glycoproteins that
consist of protein linked to sugars – known as HA (hemagglutinin) and NA (neuraminidase).
These are the proteins that determine the type of influenza virus (A, B, or C) and the subtype
(A/H1N1, for example).
Fig 3. Structure of a virion
Beneath the lipid membrane is a viral protein called M1, or matrix protein. This protein, which
forms a shell, gives strength and rigidity to the lipid envelope. Each RNA segment consists of
RNA joined with several proteins: B1, PB2, PA, NP (Fig. 3). These RNA segments are the genes
of influenza virus. The interior of the virion also contains another protein called NEP.
A.3 INFLUENZA RECOMBINANTS
Influenza viruses affect many different species in nature including humans, birds, pigs
and other species (See Animal Reservoirs). These viruses are specific to the species in which
7. they cause infection. But on rare occasions, these viruses jump species and cause infection in a
new host species. There are two possible mechanisms to explain such phenomena. They are
Antigenic drift and antigenic shift which are explained in detail below.
ANTIGENIC SHIFT
The genetic change that enables a flu strain to jump from one animal species to another,
including humans, is called ―antigenic shift‖. Antigenic shift is an abrupt, major change in the
influenza A viruses, resulting in new hemagglutinin and/or new hemagglutinin and
neuraminidase proteins in influenza viruses that infect humans. The shift results in a new
influenza A subtype or a virus with a hemagglutinin or a hemagglutinin and neuraminidase
combination. The new viral strain is so different from the same subtype in humans that most
people do not have immunity to the new (e.g. novel) virus. Such a ―shift‖ occurred in the present
case where a new H1N1 virus with a new combination of genes emerged to infect people and
quickly spread, causing a pandemic. When this shift happens, most people have little or no
protection against the new virus. While influenza viruses are changing by antigenic drift all the
time, antigenic shift happens only happens occasionally. While Type A viruses undergo both
kinds of changes, influenza type B viruses change only by the more gradual process of antigenic
drift.
Antigenic shift arises in three ways, and the following examples quoted for antigenic shift in
avian influenza A viruses.
Antigenic Shift 1
A duck or other aquatic bird passes a bird strain of influenza A to an intermediate host
such as a chicken or pig.
A person passes a human strain of influenza A to the same chicken or pig.
When the viruses infect the same cell, the genes from the bird strain mix with genes from
the human strain to yield a new strain.
The new strain can spread from the intermediate host to humans.
Antigenic Shift 2
Without undergoing genetic change, a bird strain of influenza A can jump directly from a
duck or other aquatic bird to humans.
Antigenic Shift 3
Without undergoing genetic change, a bird strain of influenza A can jump directly from a
duck or other aquatic bird to an intermediate animal host and then to humans.
The new strain may further evolve to spread from person to person as in the case of H1N1 flu. If
it happens, a flu pandemic may develop.
ANTIGENIC DRIFT
Small changes in the virus that happen continually over time lead to ―Antigenic drift‖.
Antigenic drift produces new virus strains that may not be recognized by the body's immune
system. The mechanism is as follows: a person infected with a particular flu virus strain develops
antibody against that virus. As newer virus strains appear, the antibodies against the older strains
no longer recognize the "newer" virus, and reinfection can occur. This is one of the main reasons
8. why people can contract flu on several different occasions. In most years, one or two of the three
virus strains in the influenza vaccine are updated to keep abreast with the changes in the
circulating flu viruses. Consequently, flu vaccines need to be given to individuals on a yearly
basis.
If two viruses infect the same cell simultaneously, during replication they may exchange
genes. The new virus particles will then carry a combination of genetic material from both
parental viral strains. Additionally, a cell is simultaneously invaded by strains of virus that
normally originate from a different host species for example birds as well as humans. This can
result in the exchange of genes between avian, human and pig viruses. This is thought to have
occurred in 1957 and 1968, resulting in worldwide influenza pandemics. The influenza types
responsible for those outbreaks arose through the exchange of genes between avian and human
viruses. Flu viruses can transmit—albeit not easily—between different vertebrate hosts which
gives theman opportunity to evolve further over time.
A.4 ANTIGENIC STRUCTURE
HEMAGGLUTTININ
Hemagglutinin is a glycoprotein (a protein that has a carbohydrate chain) that helps in
binding the virus to the cell being infected. As already mentioned earlier, there are 16
hemagglutinin antigenic subtypes which are numbered H1 through H16. The hemagglutinin
molecule is actually a combination of three identical proteins that are bound together to form an
elongated cylindrical shape.
Fig 4. Hemagglutinin & Neuraminidase on the surface of a virus
9. NEURAMINIDASE
Neuraminidase is an enzyme that helps the virus to breach the cell walls of infected cells.
Neuraminidase is also known as sialidase because it breaks the linkages between sialic acid and
cellular glycoproteins and glycolipids found in cell walls. There are 9 neuraminidase antigenic
subtypes labeled N1 through N9. Neuraminidase can be easily recognized as it forms mushroom-
like projections on the surface of the influenza virus. It is made up of four identical proteins with
a roughly spherical shape.
Fig 5. Virus attachment to a host cell
A.5 VIRULENCE OF VIRUS
Virulence is the ability of an infectious agent to produce disease. The virulence of a
microorganism (such as a bacterium or virus) is a measure of the severity of the disease it is
capable of causing. This current 2009 H1N1 virus spreads easily but it has a relatively low
virulence. However it is possible that as waves of H1N1 Influenza spread globally, its virulence
could change. Every year seasonal flu viruses cause more severe diseases and secondary
complications, such as pneumonia than the H1N1 flu. Majority of people infected with H1N1 flu
manifest only mild symptoms and recover fully within a few days. Only a very low percentage of
the population (< 1%) develop severe symptoms which may need treatment by antiviral drugs or
antibiotics. So although the H1N1 virus has high infection rates and spreads easily, the mortality
rate is not as high indicating the low virulence of H1N1 flu virus.
10. A virus may have a very high virulence when it emerges with a completely new set of H
antigens. There may be little or no pre- existing immunity or protection in the population when
such an event occurs. Such events with ‗‗new‘‘ viruses have occurred 3 times in the last 100
years. Firstly with H1 in 1918/19, then H2 in 1950‘s (Asian flu) and then H3 in late 60‘s (Hong
Kong flu). Two different types of Neuraminidases N1 and N2 have been found in animal viruses;
7 in other animals. The H1N1 flu strain is however not a ‗‗new‘‘ virus, it is just a repackaged H1
strain - variations of which have been circulating and re-infecting people yearly since 1918.
Because this is not a new and completely different H strain of the influenza virus, some of the
population has immunity to it. Older people are more likely to have been infected repeatedly
with circulating influenza strains and consequently have more immunity. Even though young
people are the most likely to have little or no immunity to H1 strains, infections with the H1N1
flu strain have been very mild. This again highlights the low virulence of this strain.
NAME OF FLU /
REGION OF
ORIGIN
YEAR VIRUS STRAIN
Spanish Flu 1918 H1N1
Asian Flu 1957-58 H2N2
Hong Kong Flu 1968-69 H3N2
Russian Flu 1977 H1N1
Hong Kong 1997 H5N1
Hong Kong 1999 H9N2
Virginia 2002 H7N2
Worldwide 2003 to 2009 H5N1
Mexico 2009 H1N1
Table 2: Timeline of Human Influenza outbreaks
11. Pandemic Year Influenza
virus type
People infected
(approximate)
Estimated deaths
worldwide
Case
fatality
rate
Spanish flu 1918–1919 A/H1N1 500 million 20–100 million >2.5%
Asian flu 1956–1958 A/H2N2 Not Available 2 million <0.1%
Hong Kong flu 1968–1969 A/H3N2 Not Available 1 million <0.1%
Seasonal flu Every year A/H3N2,
A/H1N1,
and B
340 million – 1
billion
250,000–500,000
per year
<0.1%
Swine flu 2009 Pandemic
H1N1/09
> 12,198 (lab-
confirmed)
12,121 ( ECDC)
≥8,768 (WHO)
0.026%
Table 3. Statistics of previous influenza pandemics
In viral pandemics the viruses become less virulent with the passage of time. Roughly 50 million
people died after the 1918 flu pandemic. However these deaths were not due to the direct effect
of a flu virus that mutated and became more virulent with time. Secondary bacterial lung
infections caused many of these deaths, especially pneumococcus, streptococcus and
staphylococcus. Furthermore antibiotic resistance in bacteria is a continuing and rapidly growing
global problem, especially in developing countries. Thus when 2009 swine flu strain spreads in
the developing world there is also a possibility of a significant number of deaths arising from
bacterial complications. While over 99% of the population will have mild symptoms similar to
common cold, some will develop serious complications (e.g. pneumonia). However the
incidence of serious complications is likely to be less than .01 percent of the infected population.
Seasonal flu strains, circulating every year, cause proportionately more illness and deaths than
the 2009 H1N1 flu strain.
12. B. REPICATION, PATHOGENESIS & TRANSMISSION
Influenza is a contagious, acute respiratory disease caused by infection of the host respiratory
tract mucosa by an influenza virus. The influenza A viruses infect host epithelial cells by
attaching to a cellular receptor (sialic acid) by the viral surface protein hemagglutinin (HA). The
virus is subsequently released because of the action of another surface glycoprotein, the enzyme
neuraminidase (NA), several hours after infection.
B.1 Risk factors for infection
Although anyone can be infected by H1N1 flu, certain sections of the population are
more susceptible to developing infections. Statistics in the United States indicates that 99% of
circulating influenza viruses in the United States are 2009 H1N1 influenza. Among people who
become infected with 2009 H1N1, certain groups appear to be at increased risk of complications
and may benefit most from early treatment with antiviral medications. Based on currently
available data, approximately 70% of persons hospitalized with 2009 H1N1 influenza have had a
recognized high risk condition. These groups are similar to those who are at increased risk for
seasonal influenza-related complications:
Children younger than 2 years old;
Adults 65 years of age or older
Pregnant women and women up to 2 weeks postpartum (including following pregnancy
loss)
Morbidly obese people (body mass index equal to or greater than 40) and perhaps people
who are obese (body mass index 30 to 39) may be at increased risk of hospitalization and
death due to 2009 H1N1 influenza infection.
Persons with the following conditions:
o Chronic pulmonary (including asthma), cardiovascular (except hypertension),
renal, hepatic, hematological (including sickle cell disease), or metabolic
disorders (including diabetes mellitus);
o Disorders that that can compromise respiratory function, or the handling of
respiratory secretions, or that can increase the risk for aspiration (e.g., cognitive
dysfunction, spinal cord injuries, seizure disorders, or other neuromuscular
disorders)
o Immunosuppression, including that caused by medications or by HIV;
B.2 Replication
Viruses replicate quickly inside the host cells. The Influenza virus gains access to the host cells
through any of the three mentioned modes of transmission: (1) by direct contact with infected
individuals; (2) by contact with contaminated objects such as toys, doorknobs, etc; and (3) by
inhalation of virus-laden aerosols.
The virus attaches to the outside of the host cell and its RNA enters into the cell. The viral genes
are transcribed and translated by the cell's enzymes and ribosomes. By this process the host cell
machinery is directed towards producing more virus particles. Now, instead of producing only
new host cellular material, the cell produces hundreds of new virus particles. The new virus
particles are eventually released from the cell and drift off, and can now further infect additional
13. cells of the host body. Sometimes the human body is able to produce antibodies preventing
replication of the virus and hence arresting infection.
Fig 6. Aerosols released during a normal sneeze
Steps in Viral Replication
The following steps take place during viral replication
1. Adsorption
2. Penetration
3. Uncoating
4. Viral genome replication
5. Maturation
6. Release
Adsorption
The virus attaches itself to the cell surface to gain access to the interior of the cell that it will
infect. Receptors present on the cell surface are used by the virus for attachment. Cells
possess various types of receptors which can be made up of glycoproteins, phospholipids or
glycolipids. Receptors for some viruses may not be present on the cell surface. Such cells are
resistant to attack by these viruses. The viral attachment can be blocked by antibodies that
14. bind to these receptors. Influenza viruses attach through glycoprotein spikes that are
distributed over their surface. The spikes can be seen in the figure above.
Fig 7. Life cycle of a virus
Penetration
After the virus attaches to the cell surface, it quickly enters the interior of the host cell and
can no longer be recovered from the cell surface. The common method used for penetration
is receptor mediated endocytosis. This is the same process used by many hormones and
toxins to enter a cell. A cytoplasmic bubble called vacuole is formed around the virion inside
the cell.
Uncoating
A change in the internal environment of the host cell due to an increase in acidic levels
causes rearrangement of coat components of the virus resulting in an extrusion of the viral
core into the cytoplasm of the cell. In Influenza virus, the core HA2 unit of the
haemagglutinin is the acid-sensitive component.
15. Viral Nucleic Acid Replication
The virus takes control of the host cell by shutting down the host cell‘s protein synthesis and
disintegrating other key synthesis machinery resulting in a shift towards viral synthesis. The
mechanism of protein synthesis shut down varies among different viruses within the same
family.
B.4 Pathogenesis
When influenza virus infects the respiratory passage by aerosols or by contact with saliva or
other respiratory secretions from an infected individual, it attaches to and replicates in cells
lining the surface of the air passage. The virus replicates in both the upper and lower respiratory
tract. Viral replication together with the immune response to infection leads to destruction and
loss of cells lining the respiratory tract. As infection subsides, the surface cells are regenerated in
a process that can take up to a month. Cough and weakness may persist for up to 2 weeks after
infection. The incubation period for swine influenza virus ranges from 1 to 3 days.
Transmission
The main pathway that influenza viruses are thought to transmit from person to person is via
respiratory droplets from coughs and sneezes. This can happen when droplets from a cough or
sneeze of an infected person are propelled through the air and deposited on the mouth or nose of
people nearby. Influenza viruses may also be transmitted between humans when the person
touches an infected surface and then touches their own mouth and nose. This form of
transmission can be prevented by people either disinfecting surfaces or washing their hands
following contact with the surface.
C. INFLUENZA – SYMPTOMS & DETECTION
Diagnosis of Disease
Identifying a disease from its signs and symptoms, also known as Diagnosis is very important.
As H1N1 flu spreads rapidly, an awareness of symptoms of the flu among the general public will
go a long way in taking precautionary action and preventing further spread. So far, the symptoms
of H1N1 fu have been mild and very similar to seasonal flu. Rarely, serious symptoms have been
developed in a small percentage of infected persons.
If you or a member of your family has a fever or high temperature (over 38°C/100.4°F) and two
or more of the following symptoms, you may have swine flu:
cough
sore throat
runny or stuffy nose
body aches
headache
chills
fatigue
diarrhea and vomiting
It‘s important to note that not everyone with flu will have a fever.
16. Fig 8. Figure showing systems that may show symptoms following infection by H1N1 flu
Emergency warning signs that require urgent medical care are listed below.
In children
Fast breathing or trouble breathing
Bluish skin color
Not drinking enough fluids
Not waking up or not interacting
Being so irritable that the child does not want to be held
Flu-like symptoms improve but then return with fever and worse cough
17. Fever with a rash
In adults
Difficulty breathing or shortness of breath
Pain or pressure in the chest or abdomen
Sudden dizziness
Confusion
Severe or persistent vomiting
Influenza Diagnostic Tests
A diagnostic test is required to confirm the presence of influenza virus in respiratory
specimens. Laboratory diagnostic tests that are presently used to detect the presence of influenza
viruses in respiratory specimens fall under these categories:
Virus culture
Real-time reverse transcriptase-polymerase chain reaction (rRT-PCR)
Rapid Influenza diagnostic tests (RIDT‘s)
Direct Immunofluorescence essays (DFA‘s)
These tests differ in their sensitivity and specificity in detecting influenza viruses as well as in
their commercial availability, the amount of time needed from specimen collection until results
are available, and the tests‘ ability to distinguish between different influenza virus types (A
versus B) and influenza A subtypes (e.g. novel H1N1 versus seasonal H1N1 versus seasonal
H3N2 viruses).
At this time, there are only two FDA authorized assays for confirmation of novel influenza
A(H1N1) virus infection, including the CDC rRT-PCR Swine Flu Panel assay; however, other
rRT-PCR assays such as laboratory developed tests, not approved by FDA, may be able to detect
novel influenza A (H1N1) viruses. Confirmation of novel influenza A(H1N1) infection may be
necessary for surveillance purposes and for special situations, e.g. severely ill patients, patients
with immune compromising conditions, and pregnant and breast feeding women.
Rapid Influenza Diagnostic Tests
Rapid influenza diagnostic tests (RIDTs) are used to detect the presence of viral antigens.
The commercially available RIDTs can provide results within 30 minutes or less. Thus, results
are available in a clinically relevant time period to make informed clinical decisions.
Commercially available RIDTs can either:
detect and distinguish between influenza A and B viruses
detect both influenza A and B but not distinguish between influenza A and B viruses
detect only influenza A viruses
None of the currently FDA approved RIDTs can distinguish between influenza A virus
subtypes (e.g. seasonal influenza A (H3N2) versus seasonal influenza A (H1N1) viruses). Also,
RIDTs cannot provide any information about antiviral drug susceptibility.
Sensitivity
For detection of seasonal influenza A virus infection in respiratory specimens, RIDTs have low
to moderate sensitivity compared to viral culture or RT-PCR. The sensitivities of RIDTs to
18. detect influenza B viruses are lower than for detection of influenza A viruses. The sensitivities
of RIDTs appear to be higher for specimens collected from children than specimens collected
from adults.
Although a positive RIDT result can be used in making treatment decisions, a negative result
does not rule out infection with novel influenza A (H1N1) virus. Because of the limitations of
RIDTs and until additional data are available, all results from RIDTs, both positive and negative,
when used for clinical decision making in a patient with suspected novel influenza A (H1N1)
virus infection, should be interpreted in the context of circulating influenza virus strains in the
patient‘s community, level of clinical suspicion, severity of illness, and risk for complications.
Influenza A H1N1 (2009) Real Time RT-PCR test
The test uses reverse transcriptase polymerase chain reaction, or RT-PCR, to amplify
viral RNA to make it detectable in a specimen. Most respiratory viruses are based on unstable
RNA and are converted to complimentary DNA (cDNA) for testing due to DNA's better
stability. It targets two separate regions of the hemagglutinin ("H1") gene of the 2009 H1N1
influenza virus to differentiate the presence of the pandemic virus from seasonal human
influenza A virus. If RNA of Influenza A virus and the 2009 Influenza H1 gene are detected, the
specimen is reported as positive for 2009 H1N1 influenza infection.
Comparison between the tests
Recent analytical studies indicate that commercially available RIDTs are reactive with the
nucleoprotein of novel influenza A (H1N1) virus. Compared to RT-PCR, the sensitivity of
RIDTs for detecting novel influenza A (H1N1) virus infections ranged from 10-70%. Therefore,
a negative RIDT result does not rule out novel influenza A (H1N1) virus infection. Factors that
might contribute to a lower sensitivity for influenza laboratory tests to detect novel influenza A
(H1N1) virus infection include the type of respiratory specimen (i.e., nasal vs. nasopharyngeal
swab), quality of the specimen, time from illness onset to specimen collection, the age of the
patient, time from specimen collection to testing, and the storage and processing of the specimen
prior to testing.
TEST /
PROCEDURE
ACCEPTABLE
SPECIMEN
INFLUENZA
TYPE
DETECTED
TIME FOR
RESULTS
RIDT Nasal swab A and B 15 minutes
Virus culture NP* swab, throat swab,
nasal wash, bronchial
wash, nasal aspirate,
sputum
A and B 3-10 days
19. RT-PCR NP swab, throat swab,
nasal wash, bronchial
wash, nasal aspirate,
sputum
A and B 2-4 hours
DFA NP swab, nasal wash,
bronchial wash, nasal
aspirate, sputum
A and B 2-4 hours
Table 5: Comparison between various diagnostic methods
*NP – Nasopharyngeal
COMMERCIAL AVAILABILITY
Table: Comparison of various diagnostic tests available to detect influenza virus
Fig 8. Nasopharyngeal swab
20. Fig 9. Nasal Wash Fig 10. Nasal aspirate
D. IMMUNOLOGICAL RESPONSE TO VIRUS
A viral infection is different from a bacterial infection with respect to the way our body reacts
and responds to the infection. Normally, a virus infects the inner parts of a cell. After the virus
gains entry into a host cell, it damages these infected cells from the inside. In order to eliminate
the infection, the infected host cells should be destroyed. So the immune system should be able
to differentiate between infected host cells and healthy cells. Viruses induce a strong immune
response in humans.
The immune response is of two types:
1. Antibody-mediated response
2. Cell-mediated response
While immunity conferred by Antibodies is called Humoral immunity, a cell-mediated response
results in Cellular immunity. Antibodies are proteins circulating in the blood that recognize and
neutralize viruses and bacteria. They are produced by a special type of blood cells called B
lymphocytes. The basis for these responses is two types of cells that form the basic units of
immunity namely: B cells and T cells. The viral surface has distinct recognition particles called
epitopes which are recognized by the B & T cells. Different people elicit different immune
responses to the same virus depending on their genetic constitution. While humoral response is
involved in blocking the infectivity of the virus using antibodies and thus neutralizes the virus,
cellular response recognizes infected cells and destroys them. T lymphocytes play a major role
in cell-mediated response.
Humoral Response
Our immune system produces proteins called antibodies or Immunoglobulins that help our
bodies fight disease. They play an important role in body‘s natural defense system. They
recognize any foreign entities within our body like viruses, bacteria, etc and bind to viruses or
particular sites on cells and inhibit their ability to infect other cells. These antibodies bind to their
21. counterparts in a highly specific manner. Viral components present on both the surface and the
interior of a virion are responsible for production of antibodies. Interaction of these antibodies
with the viral surface components can occur in different ways producing a myriad of antibodies
that differ from each other. There are five different types of antibodies, each performing a
specific function. They are viz. Ig G, Ig A, Ig M, Ig D and Ig E.
Functions of Antibodies
These antibodies have specific functions within the human body.
The most commonly found antibodies are IgG. They circulate in the body fluids like blood and
give protection against invading bacteria and viruses. When IgG antibodies bind to bacterial or
viral antigens, they activate other immune cells which engulf and destroy the pathogens.
Saliva, mucus, tears, secretions of the respiratory, reproductive, digestive and urinary tracts
contain IgA antibodies. These antibodies prevent the invading bacteria and viruses from entering
the body and reaching internal organs.
IgM is the largest antibody amongst all the 5 different classes of antibodies. It is Y-shaped with 5
units. Its function is similar to IgG. But unlike IgG which is produced in later stages of an
infection, IgM is the first antibody to be produced following an infection by bacteria or viruses.
IgD is found circulating in the blood in small quantities. It is found mostly o the surface of B
cells. IgD helps B cells in recognizing specific antigens.
IgE antibodies are found in small quantities in serum. They are responsible for allergic reactions.
When an allergen (allergy causing substance) binds with IgE antibody, it triggers an allergic
reaction by stimulating the release of vasoactive amines including Histamine. Histamine causes
symptoms such as runny nose, sneezing and swollen tissues.
Cell-mediated immunity
As the name suggests, cell-mediated immunity is an immune response that does not involve
antibodies. Rather, it uses specialized cells called macrophages, natural killer cells and cytotoxic
T lymphocytes. These T lymphocytes seek infected cells and induce a process called Apoptosis
(programmed cell death) in them and destroy the infected host cells. Macrophages and natural
killer cells destroy pathogens present inside infected cells. Also, cytokines are released during
cell-mediated immune response. These cytokines influence the function of other cells involved in
an immune response.
22. E. ANIMAL RESERVOIRS
E. Animal Reservoirs of Influenza Virus
A reservoir is any person, animal, plant, soil or micro-organism that is used by the
infectious agent (H1N1 virus in this case) for shelter and multiplication. Generally the infectious
agent does not harm or cause infection to the reservoir. The reservoir serves as the source from
which other individuals can be infected. Occasionally the infectious agent is transmitted to a
human or other susceptible host from these reservoirs, which could result in devastating
outbreaks in poultry or cause human influenza pandemics.
Some of the common reservoirs in which the influenza virus resides are:
Aquatic birds (ducks, geese, swans, shorebirds, gulls, hawks, eagles, falcons, ravens,
coots, pigeons, rails)
Pigs (Swine Influenza)
Sea mammals
Animal
Reservoirs
Aquatic
Birds
Pigs
Seals
Chicken
DogsHorses
Civets
Mink
Wild
Pikas
24. Anseriformes Common teal (A. crecca)
Anseriformes Mallard (A. platyrhynchos)
Anseriformes Northern Pintail (A. acuta)
Anseriformes Greater scaup (Aythya marila)
Anseriformes Black scoter (Melanitta nigra)
Anseriformes Oldsquaw (Clangula hyemalis )
Anseriformes Red-breasted merganser (Mergus serrator)
Gruiformes Eurasian coot (Fulica atra)
Columbiformes Turtle dove (Streptopelia decaocto)
Charadriiformes Common snipe (Gallinago gallinago)
Charadriiformes Herring gull (Larus argentatus)
Charadriiformes Lesser black-backed gull (L.fuscus)
Charadriiformes Black-headed gull (L.ridibundus)
Charadriiformes Black-tailed gull (L.crassirostris)
Charadriiformes White-capped noddy tern (Anous minutus)
Charadriiformes Black guillemot (Cepphus grylle)
Charadriiformes Common murre (Uria aalge)
Passeriformes Common crow (Corvus brachyrhynchos)
Passeriformes Carrion crow (C. corone)
Passeriformes House sparrow (Passer domesticus)
Table 6: Free-living birds reported seropositive for Avian influenza virus
Wild birds are the reservoirs of over 100 subtypes of Influenza A virus. These viruses replicate
in the intestinal cells and are discharged in huge numbers in the feces. Avian influenza viruses
spread easily among bird populations and although the infected birds don‘t show any symptoms
25. of the disease, it is invariably fatal. The virus prefers low temperatures and can survive for long
periods in the tissues and feces of infected birds. The virus can survive indefinitely at freezing
temperatures. As the temperature increases to 220
C, the survival time of the virus in water is
reduced to 4 days. Many of the influenza A subtype viruses can be isolated from Southeast Asian
bird populations. Close human contact with these infected birds poses a huge risk of transmission
of these viruses to humans.
The devastating avian flu that resulted in huge economic losses to the poultry
industry was caused by influenza A virus belonging to the family Orthomyxoviridae. Canine flu,
Swine flu and Horse flu have also been reported in dogs, pigs and horses respectively.
Origin of H1N1 Influenza virus
A reservoir may harbor viruses from more than one source at a time. Avian influenza virus
cannot replicate well in humans. Hence the virus needs an intermediary host like pigs where it
can reassemble itself and infect humans. Moreover pigs are a common reservoir for viruses from
birds and humans. They serve as a mixing vessel where viruses from different species interact.
Such an interaction creates the possibility of creation of a novel influenza virus having genes
from birds, pigs and humans. The current H1N1 Influenza virus is thought to have been
originated in pigs in this way resulting in a novel virus capable of causing human-human
transmission through respiratory droplets.
Influenza viruses from birds can infect humans when they attach to receptors on the cells lining
the intestine. Receptors on cells are similar to locks. When a virus with a suitable key interacts
with these receptors, it can unlock the cell and gain access to the cell and replicate. Although all
viruses do not have the ability to attach to these receptors, those that succeed have a high chance
of causing illness in humans.
F. TREATMENT
26. A major concern with influenza virus is its rapid and unpredictable nature of evolution.
This makes prevention using vaccines and treatment of the disease using medication extremely
challenging.
The vaccines used to prevent flu are produced from the viruses themselves. The vaccine
components consists of either killed virus or components of live attenuated virus that are very
similar the original disease causing virus. When injected into the body, these components illicit
an immune response resulting in the production of antibodies against the virus. Thus the body is
prepared in advance to fight against the virus in the event of an infection. These antibodies are
extremely specific to the virus. . Immunological memory is a lifelong phenomenon. Thus
vaccination provides long term immunity against infection
The most common feature of Influenza viruses is their ability to mutate and modify themselves
within short periods of time. This is a natural mechanism by which a virus escapes attack by the
immune system of the host. Hence a prior vaccination against a specific subtype of virus does
not protect the body from a mutated virus which is different from the earlier one.
There are two kinds of H1N1 vaccines currently being produced. They are
Inactivated influenza vaccine
Live, attenuated vaccine
Inactivated influenza vaccine
The inactivated vaccine contains killed virus and is administered via an injection, usually in the
arm. The flu vaccine (shot) is approved for use in humans aged 6 months or older, including
healthy people, people with chronic medical conditions and pregnant women.
Live, attenuated vaccine
This vaccine is made with live, weakened viruses that do not cause the flu. It is sometimes called
LAIV for "live attenuated influenza vaccine". It is intranasaly administered through the nasal
passage. LAIV is approved for use in healthy people aged 2 years to 49 years of age and in
women who are not pregnant.
Both vaccines give protection against H1N1 influenza. Antibodies that provide protection against
H1N1 influenza virus infection will develop 2 weeks post vaccination. The vaccines are
manufactured in the same way as seasonal influenza vaccines. Hence they are not experimental
and safe to use. Thimerosal, a mercury-containing preservative used in seasonal flu vaccine is
also added in the 2009 H1N1 vaccine. People with severe allergies to chicken eggs or to any
other substance in the vaccine should not be vaccinated. The H1N1 vaccine will not prevent
seasonal flu and seasonal flu vaccine will not prevent H1N1 influenza.
The table below provides information and relevant details about the current manufacturers of
approved vaccines.
27. Supplier Vaccine Form Mercury
µg/0.5 mL
Age
MedImmune
(nasal spray)
Live virus 0.2 mL
(nasal spray sprayer)
0 2-49 yrs
Sanofi (IM)a
Inactivated
0.25 mL prefilled syringe
0.5 mL prefilled syringe
5 mL multidose vial
0
0
25
6-35 m
> 36 m
> 6 m
Novartis (IM)a
5 mL multidose vial
0.5 mL prefilled syringe
25
< 1.0
≥ 4 yrs
> 4 yrs
CSL Biotherapies, Inc (IM)a
0.5 mL prefilled syringe
5.0 mL multidose vial
0
24.5
> 18 yrs
> 18 yrs
Table 7: Approved Influenza A (H1N1) Vaccines
Source: Department of Health and Environmental Control
Younger children will require 2 doses separated by at least 21 days. Infants younger than 6
months are too young to be vaccinated against influenza.
Guidelines for Inactivated influenza vaccine usage
The inactivated H1N1 vaccine uses killed virus and is intended to prevent 2009 H1N1 (not
seasonal flu) and is available in single dose or multidose vials. Children 6 months to 9 years of
age should receive 2 doses separated by 3 weeks. Children 10 years and older and adults should
receive 1 dose.
The following groups should receive the vaccine as soon as it becomes available:
Pregnant women;
People who live with or care for infants younger than 6 months of age;
Healthcare workers and emergency medical personnel;
Persons aged 6 months to 24 years of age
Persons 25-64 years of age who have chronic diseases (including immunodeficiency
states) that pose a risk for influenza. This includes persons who have chronic pulmonary
(including asthma), cardiovascular (except hypertension), renal, hepatic,
neurological/neuromuscular, hematological or metabolic distorders (including diabetes),
immunosuppression (including immunosuppression caused by medications or by HIV)
When more vaccine becomes available, the following persons should be vaccinated:
Healthy persons ages 25-64 years; and
Adults 65 years of age and older.
28. Individuals with the highest priority listed above should be vaccinated first. Patients on the high-
priority list should be vaccinated as soon as the vaccine becomes available. Pregnancy and
breastfeeding are not contraindications for the inactivated vaccine to be administered.
Guidelines for Live, attenuated vaccine usage
The second vaccine is a live attenuated influenza (LAIV), which is given intranasally. LAIV
does not contain thimerosal. It is produced the same way as the LAIV that is used for seasonal
flu. It is expected that the LAIV for H1N1 influenza will be as safe and effective as the LAIV for
seasonal flu. This vaccine will not prevent seasonal flu, and the seasonal flu vaccine will not
prevent 2009 H1N1 influenza. Adults and children aged 10 years or older should receive should
receive one dose of the vaccine.
The LAIV for H1N1 is administered intranasally in a single dose. It is approved for people 2-49
years of age who do not have contraindications. Groups who should receive the LAIV include:
Persons 2-24 years of age;
Persons 25-49 years of age who live with or care for infants younger than 6 months; and
Persons 25-40 years of age who are Health Care Workers or emergency medical
personnel.
LAIV is approved for use in healthy people 2-49 years of age who are not pregnant.
When more vaccine becomes available it should be offered to healthy persons aged 25-49 years
who do not have contraindications for the vaccine.
The following people should not receive LAIV:
Persons who have chronic pulmonary (including asthma), cardiovascular (except
hypertension), renal, hepatic, neurological/neuromuscular, hematological or metabolic
distorders (including diabetes), immunosuppression (including immunosuppression
caused by medications or by HIV)
Children 2-4 years of age with wheezing in the past 12 months
Children or adolescents receiving aspirin or other salicylate therapy
Pregnant women
People who have a severe allergy to chicken eggs or who are allergic to any LAIV
components
Persons < 2 years or those >50 years
Source: Center for Disease Control
Side Affects
Potential side effects of the H1N1 vaccines are expected to be similar to those of seasonal flu
vaccines. The most common side effect for the injected vaccine is soreness at the injection site.
Other side effects may include mild fever, body aches, and fatigue for a few days.
The most common side effects for LAIV vaccine are runny nose or nasal congestion for
individuals of all ages. Sore throats may be observed in adults and fever in children 2 to 6 years
old. As with any medical product, unexpected or rare serious adverse events may occur.
According to currently available information, children 6 months to 9 years of age have little or
no protective antibodies to the H1N1 virus. So children 9 years of age and younger should be
29. administered two doses of the vaccine. Children and adults aged 10 years or older will require
only one dose.
Safety of 2009 H1N1 Vaccine
Clinical studies show that the H1N1 vaccine has been well tolerated. The manufacturers are
producing the vaccine using the well-established and licensed manufacturing process that is used
for seasonal influenza vaccine. The regulatory authorities expect that the safety profile of the
H1N1 vaccine will be similar to the seasonal influenza vaccine.
Antiviral drugs
Drugs are a second line of defense against H1N1 influenza. Oseltamivir and Zanamivir
are two drugs presently being used against H1N1 influenza virus. They are available under the
brand names Tamiflu and Relenza respectively. Tamiflu is available as a pill or liquid and
Relenza is used in powder form.
For Tamiflu to be effective, it must be taken within 48 hours of the development of flu
symptoms. Although the drug does not cure the flu itself, it reduces the recovery time by one
day. More importantly, it prevents the development of flu related complications such as chest
infections. The drug has been approved for use in adults and children aged 1 year and above.
Relenza is an antiviral drug used to treat influenza and prevent the spread of virus within
the body. It is in powder form and has to be inhaled. It has been approved for use in adults and
children aged 5 years and above. Zanamivir, the active drug in Relenza has been shown to reduce
the duration of flu symptoms by one to one and a half days. It also prevents the virus from
further replication within the individual. For Relenza to be effective, it should be taken within 48
hours of developing flu symptoms.
How Antiviral drugs work
Although antiviral drugs do not cure influenza, they reduce the recovery time and prevent the
development of later flu related complication such as Pneumonia. Both the drugs Oseltamivir
and Zanamivir restrict the viruses‘ ability to infect other cells. Every influenza virus has both
Hemaggluttinin and Neuraminidase on the virus surface that enables it to infect host cells. These
drugs block these chemicals and thus make the virus incapable of infecting new cells.
Side Effects
Although these approved drugs are safe to use, occasionally they produce unwanted side effects.
One in 10,000 persons who take the drug shows side effects. The effects listed below vary from
individual to individual.
Narrowing of the airways (bronchospasm)
Difficulty in breathing (dyspnoea)
Throat tightness
Rash or hives
Allergic reaction with swelling of the face or throat.
Just because a side effect is stated here doesn‘t mean that the affected individual will have all
these symptoms.
30. G. GEOGRAPHICAL DISTRIBUTION
Geographical boundaries fail to contain the spread of influenza. Presently, there is no clear
agreement on how to analyze and group according to geographic region. Geographic Information
Systems (GIS) help a great deal in providing valuable information about the disease spread
patterns within a localized region or a broad area.
Fig 11. Number of H1N1 cases based on region
31.
32.
33. Virological surveillance data indicates that H1N1 virus has been predominantly present in all
countries across the world. As of 1 December 2009, more than 199 countries have reported
laboratory confirmed cases of pandemic H1N1 influenza. The death toll is estimated at more
than 10,000 deaths. The actual number of individuals infected is estimated to be much higher
since countries have stopped counting the number of people infected.
Influenza Indicators
Influenza activity is measured using certain indicators. The levels of influenza activity are based
on two assessments. They are described below.
1. An indicator of the overall intensity of influenza activity in the country;
2. An indicator of the geographical spread of influenza in the country.
Overall Intensity Indicators
Low: no influenza activity or influenza activity is at baseline level
Medium: level of influenza activity usually seen when influenza virus is circulating in the
country based on historical data
High: higher than usual influenza activity compared to historical data
Very high: influenza activity is particularly severe compared to historical data
Unknown: influenza activity is not known
Geographical Spread Indicators
Every country specifies geographical spread of influenza in terms of definitions defined by its
own government. The definitions described below are based on the WHO global surveillance
system – FluNet.
Some terms that need to be defined are given below:
ILI: Influenza like illness
ARI: Acute respiratory infection
Country: Countries may be made up of one or more regions
Region: The population under surveillance in a defined geographical sub-division of a country.
A region should not (generally) have a population of less than 5 million unless the country is
large with geographically distinct regions
No report: no report received
No activity: reports indicate no evidence of influenza virus activity. Cases of ILI/ARI may be
reported in the country but the overall level of clinical activity remains at baseline levels and
influenza virus infections are not being laboratory confirmed. Cases occurring in people recently
returned from other countries are excluded
Sporadic: isolated cases of laboratory confirmed influenza infection in a region, or an outbreak
in a single institution (such as a school, nursing home or other institutional setting), with clinical
activity remaining at or below baseline levels. Cases occurring in people recently returned from
other countries are excluded
34. Local outbreak: increased ILI/ARI activity in local areas (such as a city, county or district)
within a region, or outbreaks in two or more institutions within a region, with laboratory
confirmed cases of influenza infection. Levels of activity in remainder of region, and other
regions of the country, remain at or below baseline levels
Regional activity*: ILI/ARI activity above baseline levels in one or more regions with a
population comprising less than 50% of the country's total population, with laboratory confirmed
influenza infections in the affected region(s). Levels of activity in other regions of the country
remain at or below baseline levels.
* This term is not (generally) to be used in countries with a population of less than 5 million
unless the country is large with geographically distinct regions
Widespread activity: ILI/ARI activity above baseline levels in one or more regions with a
population comprising 50% or more of the country's population, with laboratory confirmed
influenza infections.
Unknown: influenza geographical spread is not known
The figures below present the geographical spread of influenza in a visual format.
35. Epidemiology
The total number of illnesses, hospitalizations and deaths due to H1N1 virus is difficult to assess
accurately. The table below gives a situation update on reported and confirmed cases of H1N1
infection across different regions.
REGION DEATHS*
WHO Regional Office for Africa (AFRO) 109
WHO Regional Office for the Americas (AMRO) At least 6335
WHO Regional Office for the Eastern
Mediterranean(EMRO)
572
WHO Regional Office for Europe (EURO) At least 1654
WHO Regional Office for South-East
Asia (SEARO)
892
WHO Regional Office for the Western Pacific
(WPRO)
1020
Total** At least 10582
36. Table 8. Data showing number of confirmed deaths in different regions.
* The reported number of fatal cases is an under representation of the actual numbers as many
deaths are never tested or recognized as influenza related.
Country
Cumulative total
Cases Deaths
Algeria
78 0
Angola
13 0
Botswana
23 0
Burundi
6 0
Cameroon
4 0
Cape Verde
62 0
Congo
8 0
Cote d‘Ivoire
3 0
Democratic Republic of Congo
13 0
Ethiopia
6 0
Gabon
1 0
Ghana
18 0
38. Zimbabwe
12 0
TOTAL
15503 104
Source: WHO
Table 9. Data showing number of deaths in African nations.
1: Data received from previous epidemiological weeks. Average of 100 cases reported weekly.
2: Is monitoring the pandemic but is no longer reporting individual cases.
3: Data reported on a weekly basis. Week ending at November 15, 2009.
H. PANDEMIC PLANNING
For any pandemic planning program to be successful, the foundation lies in anticipating future
events with reasonable accuracy and having effective plans and guidelines in place. It is
important to understand that guidelines provided by the respective governments of a country can
only be implemented successfully with the cooperation of its citizens. Also implementing
prevention strategies at the individual level is vital to keep the pandemic from growing.
Guidelines at the individual level are given below.
1. Get vaccinated
Vaccination is the best way to get protection against H1N1 flu. Seasonal flu vaccine is different
from H1N1 flu vaccine. Hence they require separate vaccinations.
2. Cover your mouth and nose
Coughing and sneezing are the most common ways of spreading infection to others around us.
Use a tissue or your sleeve when coughing or sneezing.
3. Wash hands often
Hands are often a source of influenza causing viruses. Wash your hands often with soap and
water, especially after you cough or sneeze. Alcohol-based hand cleaners are effective.
4. Avoid touching eyes, nose and mouth
Eyes, mouth and nose contain moist mucus membranes which provide easy passage ways for the
virus to enter your body. Avoid touching these regions.
5. Stay home if ill
An infected person can infect others around him. If you are sick with flu-like symptoms, stay
home for at least a day after the fever subsides.
Phases of a pandemic
Three conditions should be met for a pandemic to start. These conditions are:
1. A virus subtype to humans emerges,
2. It infects humans, causing serious illness, and
39. 3. It spreads easily and sustainably among humans.
Once a pandemic is in place, it passes through different stages of intensity and infection rates.
The World Health Organization has laid down detailed guidelines to help countries identify the
different stage of a pandemic. WHO has defined the pandemic in six phases. They are described
below.
PHASE 1 No animal influenza virus circulating among animals has been
reported to cause infection in humans.
PHASE 2 An animal influenza virus circulating in domesticated or wild animals
is known to have caused infection in humans and is therefore
considered a specific potential pandemic threat.
PHASE 3 An animal or human-animal influenza reassortant virus has caused
sporadic cases or small clusters of disease in people, but has not
resulted in human-to-human transmission sufficient to sustain
community-level outbreaks.
PHASE 4 Human-to-human transmission (H2H) of an animal or human-animal
influenza reassortant virus able to sustain community-level outbreaks
has been verified.
PHASE 5 The same identified virus has caused sustained community level
outbreaks in two or more countries in one WHO region.
PHASE 6 In addition to the criteria defined in Phase 5, the same virus has
caused sustained community level outbreaks in at least one other
country in another WHO region.
POST-PEAK
PERIOD Levels of pandemic influenza in most countries with adequate
surveillance have dropped below peak levels.
POSSIBLE
NEW WAVE
Level of pandemic influenza activity in most countries with adequate
surveillance rising again.
40. POST-
PANDEMIC
PERIOD
Levels of influenza activity have returned to the levels seen for
seasonal influenza in most countries with adequate surveillance.
Table 10: WHO pandemic phases
Fig 14. Diagrammatic representation of revised WHO phases
Pandemic Planning
Pandemic influenza preparedness is a process. It is not an isolated event. Specific capabilities
must be developed through preparedness activities before the pandemic occurs. While all sectors
of society are involved in pandemic preparedness and response, the national government is the
leader for overall coordination and communication efforts. It should lay down detailed guidelines
for all the concerned departments on taking specific actions during a pandemic. World Health
Organization has suggested five components of preparedness and response which serve as a
blueprint upon which national guidelines should be built. The action plan includes five
components which are described below briefly.
1. Planning and coordination
2. Situation monitoring and assessment
3. Reducing the spread of disease
4. Continuity of health care provision
5. Communications
41. Planning and coordination
These efforts are aimed:
to provide leadership and coordination across sectors, and
to integrate pandemic preparedness into national emergency preparedness frameworks
Situation monitoring and assessment
These efforts are aimed:
to collect, interpret, and disseminate information on the risk of a pandemic before it
occurs, and
to monitor pandemic activity and characteristics
Monitoring the infectious agent and its infection rates and disease spread patterns will be
necessary to assess if the risk of a pandemic is rising.
It is important to collect data on influenza viruses, the genetic changes taking place and
consequent changes in biological characteristics, and to rapidly investigate and evaluate
outbreaks. Once a pandemic influenza virus begins to circulate, it will be vital to assess the
effectiveness of the response measures.
Find out when and where influenza activity is occurring
Track influenza-related illness
Determine what influenza viruses are circulating
Detect changes in influenza viruses
Measure the impact influenza is having on deaths in the nation
Reducing the spread of disease
Reducing the spread of disease is a vital component of pandemic planning. It depends to a large
extent on increasing the ‗social distance‘ between people. Measures at individual/household
level, societal-level, international travel measures and the use of antiviral drugs, other
pharmaceuticals and vaccines will be important.
Individual/household level measures include risk communication, individual hygiene and
personal protection, and home care of the ill and quarantine of contacts.
Societal-level measures are applied to societies or communities rather than individuals or
families. These measures require a behavioral change in the population, multiple sector
involvement, and mobilization of resources, strong communication, and media support.
International travel measures aim to delay the entry of pandemic disease into not-yet-
affected countries and will have an impact on international traffic and trade. Countries
should balance reducing the risks to public health and avoiding unnecessary interference
with international traffic and trade.
The use of pharmaceutical interventions to prevent or treat influenza encompasses a
range of approaches. Additionally, the successful prevention and treatment of secondary
or pre-existing conditions will be a key factor in many settings for reducing the overall
burden of illness and death.
42. During a pandemic, health systems should provide health care services while attending to the
increasing number of patients with influenza illness. The goal of planning and coordination
efforts is to provide leadership and coordination across sectors and to determine the extent to
which the existing health system can expand to manage the additional patient load. Health care
facilities will need to maintain adequate infection control measures to protect health care
workers, patients, and visitors.
Communications
These efforts are aimed:
to provide and exchange relevant information with the public, partners, and stakeholders
to allow them to make well informed decisions, and
to take appropriate actions to protect health and safety.
During a pandemic, the ability to communicate effectively about the risks related to the influenza
is very crucial and forms the basis of effective risk management. Clear and detailed information
about the outbreak and recommendations should be communicated to the public, partners and
other groups involved. Along with these, core risk communication strategies should be
developed to deal with any public health emergency that may arise.
Early detection of a pandemic virus
Since new viruses with pandemic potential emerge periodically, continuous global surveillance
of influenza is necessary to detect these new strains before they cause pandemic situations. With
120 National Influenza Centers in more than 90 countries, WHO is monitoring the activity of
influenza viruses around the world. These centers isolate influenza viruses in each region and
report any ―unusual‖ influenza virus to WHO Global Influenza Program.
Stockpiles of Antiviral drugs
A stockpile of antiviral drugs in each country combined with an international stockpile at WHO
are essential components of comprehensive international pandemic preparedness. During a
pandemic, supplies are severely constrained. Hence countries stockpiling antiviral drugs or
vaccines should decide in advance on priority groups and have guidelines in place for
administering these drugs. Without any guidelines in place, the situation could become worse
during a pandemic as mass administration of antiviral drugs to healthy individuals would speed
up the process of development of drug resistance.
National Influenza Centers in Africa
The World Health Organization has established a network of influenza laboratories in some
African countries through its Regional Office for Africa. Rapid and reliable diagnosis of
influenza viruses can be performed in these laboratories. More information on these laboratories
is given below.
43. Country Center Location Contact
Algeria Algiers Fax:+213 21 390257
Central African Republic Bangui Fax: +236 (61) 01 09
Côte d'Ivoire Abidjan Fax: + 225 22 48 53 05
Egypt Cairo Fax: +(202) 227942034
Madagascar Antananarivo Fax: +261 (20) 22 415 34
Morocco Rabat Fax: +212 (37) 772 067
Nigeria Ibadan Fax: +234 (02) 241 1768
South Africa Cape Town Fax: +27 (21) 448 4110
Sudan Khartoum -
Syrian Arab Republic Damascus Fax: +963 114442153
Tunisia Tunis Fax: +216 (71) 56 87 44
Uganda Entebbe -
Table 11. List of National Influenza Centers in Africa
Priority actions for African nations
1. Build strong collaboration between various health service sectors
36 African countries have surveillance and reporting systems on priority systems in place
through district health personnel. These systems serve as a backbone which supports local
surveillance and response capabilities. Frequent exchange of information along with provision
for jointly investigation any outbreaks will help establish a network.
44. 2. Existing national coordinating bodies should expand their role to include pandemic influenza.
National, regional and district level committees on Pandemic preparedness and response are
present throughout Africa. Additionally, these committees need to bring accountability and
responsibility within each sector. If possible, a panel of national experts should be assigned the
responsibility of leading these committees.
3. Improve the capacity of surveillance systems to detect cases and ensure a rapid response.
African countries, with assistance from the WHO Regional Office, have strengthened their
surveillance, preparedness and response capacity for outbreaks. Priority diseases have standard
definitions defined by these countries. Other approaches that need to be incorporated include an
early warning system supported by a staff trained and equipped to perform diagnostic tests and
confirm diseases.
4. Develop strategies for the rapid communication of information to the public and the media.
Efforts at individual and community level to stop the spread of infection may be the most
effective tools to prevent a pandemic from growing further in Africa. This requires efficient
communication of messages to the public to increase awareness about a developing disease.
GLOSSARY
Antibody: Proteins generally found in the blood that detect and destroy invaders, like bacteria
and viruses.
B Cells: B cells are lymphocytes that play a large role in the humoral immune response. The
principal function of B cells is to make antibodies against soluble antigens.
Body mass index: A measurement of the relative percentages of fat and muscle mass in the
human body, in which mass in kilograms is divided by height in meters squared and the result
used as an index of obesity.
CDC: Centers for Disease Control and Prevention
Cognitive dysfunction: The loss of intellectual functions (such as thinking, remembering, and
reasoning) of sufficient severity to interfere with daily functioning.
Contraindications: a condition or factor that increases the risks involved in using a
particular drug, carrying out a medical procedure or engaging in a particular activity.
45. Cytokines: Chemicals made by the cells that act on other cells to stimulate or inhibit their
function.
Cytotoxic T lymphocytes: A T cell that is antigen-specific and is able to search out and kill
specific types of virus-infected cells.
Diabetes Mellitus: Diabetes mellitus is a condition in which the pancreas no longer produces
enough insulin or cells stop responding to the insulin that is produced, so that glucose in the
blood cannot be absorbed into the cells of the body. Symptoms include frequent urination,
lethargy, excessive thirst, and hunger.
DNA: Deoxyribonucleic acid (DNA) is a nucleic acid that contains the genetic instructions used
in the development and functioning of all known living organisms.
Epidemic: Affecting or tending to affect an atypically large number of individuals within a
population, community, or region at the same time.
Epitopes: An epitope is the part of a macromolecule that is recognized by the immune system,
specifically by antibodies, B cells, or T cells.
FDA: Food and Drug Administration.
Flu: Any of several diseases caused by bacteria or viruses and marked especially by respiratory
or intestinal symptoms.
Glycoprotein: Any of a group of conjugated proteins that contain a carbohydrate as the
nonprotein component.
Glycolipid: A lipid containing carbohydrate groups, often galactose but also glucose, inositol or
others.
Hemagglutinin: An important surface structure protein of the influenza virus, an essential gene
for the spread of the virus throughout the respiratory tract, enables the virus to attach itself to a
cell in the respiratory system and penetrate it.
Hypertension: Hypertension is high blood pressure. Blood pressure is the force of blood
pushing against the walls of arteries as it flows through them.
Hematological: pertaining to or emanating from blood cells.
HIV: A transmissible retrovirus that causes AIDS in humans.
Immunosupression: Suppression of the immune response, as by drugs or radiation, in order to
prevent the rejection of grafts or transplants or control autoimmune diseases.
46. Influenza: Any of several acute highly contagious respiratory diseases caused by strains of three
major orthomyxoviruses now considered to comprise three species assigned to three separate
genera: Influenza A, Influenza B or Influenza C.
Mucosa: The thin layer which lines body cavities and passages.
Mutation: A sudden structural change within a gene or chromosome of an organism resulting in
the creation of a new character or trait not found in the parental type.
Natural Killer Cell: Cell that can react against and destroy another cell without prior
sensitization to it. Natural killer (NK) cells are part of our first line of defense
against cancer cells and virus-infected cells.
Neuraminidase: An important surface structure protein of the influenza virus, an essential
enzyme for the spread of the virus throughout the respiratory tract, enables the virus to escape
the host cell and infect new cells.
Orthomyxoviridae: A family of RNA viruses that includes five genera: Influenzavirus
A, Influenzavirus B, Influenzavirus C, Isavirus and Thogotovirus.
Pandemic: Occurring over a wide geographic area and affecting an exceptionally high
proportion of the population.
Phospholipid: Any of various phosphorous-containing lipids that are composed mainly of fatty
acids, a phosphate group, and a simple organic molecule.
PCR: Polymerase Chain Reaction; a rapid technique for in vitro amplification of specific DNA
or RNA sequences.
Pneumococcus: A nonmotile, gram-positive bacterium (Streptococcus pneumoniae) that is the
most common cause of bacterial pneumonia and is associated with meningitis and other
infectious diseases.
Postpartum: Referring to the time period following childbirth.
Reassortant virus: A virion containing deoxyribonucleic acid from one virus species and a
protein coat from another.
Ribosome: A minute round cytoplasmic particle composed of RNA and protein that is the site of
protein synthesis as directed by mRNA.
RT-PCR: A laboratory technique used to simultaneously quantify and amplify a specific part of
a given DNA molecule
Respiratory tract: the passages through which air enters and leaves the body
47. RNA: A nucleic acid that is generally single stranded (double stranded in some viruses) and
plays a role in transferring information from DNA to protein-forming system of the cell.
Serologic: related to serum; the clear portion of any liquid separated from its more solid
elements.
Streptococcus: A genus of gram-positive, anaerobic, often pathogenic bacteria having an ovoid
or spherical appearance and occurring in pairs or chains, including many erythrocytolytic and
pathogenic species that cause erysipelas, scarlet fever, and septic sore throat in humans.
Staphylococcus: A genus of spherical, gram-positive bacteria tending to occur in grapelike
clusters; they are normal flora on the skin and in the upper respiratory tract and are the most
common cause of localized infections.
Transcription: The synthesis of RNA using a DNA template catalyzed by RNA polymerase.
Translation: Transfer of information from mRNA to proteins.
T Cells: T cells belong to a group of white blood cells known as lymphocytes and play a central
role in cell-mediated immunity.
Virus: The causative agent of an infectious disease.
Vaccination: Vaccination is the administration of antigenic material to produce immunity to a
disease.
Vasoactive: Causing constriction or dilation of blood vessels.