Micro Lecture: Active and Passive Immunity PDF

Summary

This micro lecture presents information on active and passive immunity. It covers different types of vaccines (attenuated, inactivated, toxoid). The lecture notes also include discussions on the mechanisms of each type of immunity and their applications in public health.

Full Transcript

PHARMACEUTICAL MICROBIOLOGY

IMMUNOLOGY.
Active and passive immunity

DR. KASHIF MAROOF
 Active
immunity
Artificiall
Naturally ACTIVE IMMUNITY
y
acquired
acquired
Active immunity occurs when antigens enter the body
and the individual’s immune system actively responds
by producing antibodies and specific lymphocytes. This
exposure to antigens may be unintentional, as when
one becomes ill with a disease, or intentional, when
one is purposely exposed to an antigen.
 NATURALLY ACQUIRED ACTIVE IMMUNITY

 Before vaccines were fully developed, the only way to become immune to
a disease was by suffering the disease and recovering. Thus, such
naturally acquired active immunity follows a bout of illness and occurs in
the “natural” scheme of events.
 However, this is not always the case, because subclinical diseases also
may bring on the immunity. For example, many people have acquired
immunity from subclinical cases of mumps or from subclinical fungal
diseases. So, this active production of antibodies represents the primary
antibody response.
 Memory cells are responsible for the production of antibodies in a
secondary antibody response. The cells remain active for many years and
produce IgG almost immediately upon a subsequent exposure to the same
antigen or pathogen that triggered the primary antibody response.
 ARTIFICIALLY ACQUIRED ACTIVE IMMUNITY

 Artificially acquired active immunity is less risky and represents an
easier way to become immune to an infectious disease. This form of
active immunity develops after the immune system produces
antibodies following an intentional exposure to antigens; that is,
through vaccination. Because the antigens usually are contained in
an immunizing agent, such as an inactivated or toxoid vaccine, the
exposure is called “artificial.”
 VACCINES
 Vaccines are composed of treated microorganisms , chemically
altered toxins, or chemical parts of microorganisms. Such vaccines
work by mimicking a “natural” infection. By exploiting the immune
system’s ability to recognize antigens and respond with antibodies
and lymphocytes, a vaccine triggers a primary antibody response.
However, because the vaccine has been altered in some way, the
pathogen or toxin usually does not trigger the disease and the
person vaccinated does not become ill. Importantly, memory cells
are formed, which now establish active immunity. If the vaccinated
person is exposed to the same antigen at some later time, the
immune system acts swiftly and produces a secondary antibody
response, stopping the infection before it can make the individual
sick. Therefore, the person stays healthy. Vaccines may be
administered by injection, oral consumption, or, as is used for some
TYPES OF VACCINES
 ATTENUATED VACCINES.

 Some microbes can be weakened in the lab such that they should not
cause disease. They are still able to grow or replicate, but attenuated
means they will multiply only at low rates in the body and fail to cause
symptoms of disease. Because the attenuated microbes multiply or
replicate for a period of time within the body, they increase the dose of
antigen to which the immune system will respond. Such vaccines are
the closest to the natural pathogens and, therefore, they generate the
strongest immune response. Often, the person vaccinated will have
lifelong immunity. Also, attenuated organisms can be spread to other
people and reimmunize them, or immunize them for the first time.
ATTENUATED VACCINES.
 ATTENUATED VACCINES.

 Today, there are many viral vaccines that consist of
attenuated viruses. The Sabin oral polio vaccine, as
well as the measles, mumps, and chickenpox
vaccines, contain attenuated viruses.
 To avoid multiple injections of immunizing agents, it
is sometimes advantageous to combine vaccines
into a single-dose vaccine. The measles-mumps-
rubella (MMR) vaccine is one example. In 2005, the
U.S. Food and Drug Administration (FDA) approved a
combination vaccine (Proquad) for children 12
months to 12 years old. This single- dose vaccine
protects against chickenpox, measles, mumps, and
rubella. Making a vaccine with attenuated bacterial
cells is more difficult.
 DOWNSIDE OF ATTENUATED VACCINES

. The downside of attenuated vaccines results from their continued
multiplication. Because the vaccines contain dividing or replicating bacteria or
viruses, there is a remote chance one of them could mutate and revert back
to a virulent form capable of causing disease. Usually a healthy person with a
fully functioning immune system (immunocompetent) clears the infection
without serious consequence. However, individuals with a compromised
immune system, such as patients with AIDS, should not be given attenuated
vaccines, if possible.

 On a global scale, attenuated vaccines may not be the vaccine strategy of
choice. These vaccines require refrigeration to retain their effectiveness,
which could present a problem in many developing nations lacking
widespread refrigeration facilities
 INACTIVATED VACCINES.

 Another strategy for preparing vaccines is to “kill” the
pathogen. These vaccines are relatively easy to produce
because the pathogen is killed by simply using certain
chemicals, heat, or radiation. However, the inactivation
process alters the antigen so it produces a weaker
immune response. The Salk polio vaccine and the hepatitis
A vaccine typify such preparations of inactivated whole
viruses. For protection from diseases like hepatitis A,
booster shots are required to maintain immunity (memory
cells) for long periods of time.
 INACTIVATED VACCINES.
Compared to attenuated vaccines, inactivated
vaccines are safer as they cannot mutate and
therefore cannot cause the disease in a vaccinated
individual. The vaccines can be stored in a freeze-
dried form at room temperature, making them a
vaccine of choice in developing nations. However,
the need for booster shots can be a drawback
when people do not keep up their booster
schedule.
INACTIVATED VACCINES.
 TOXOID VACCINES.
 For some bacterial diseases, such as diphtheria and tetanus, a
bacterial toxin is the main cause of illness. So, a third immunization
strategy is to inactivate these toxins and use them as a vaccine.
Such toxins can be inactivated with formalin, and the resulting
inactivated toxin is called a toxoid. Immunity induced by a toxoid
vaccine allows the body to generate antibodies and memory cells to
recognize the natural toxin, should the individual again come in
contact with it.
 Because toxoid vaccines are inactivated products, booster shots are
necessary. Single-dose vaccines include diphtheria- pertussis-
tetanus vaccine (DPT) and the newer diphtheria-tetanus-acellular
pertussis (DTaP) vaccine. For other vaccines, however, a
combination single-dose vaccine may not be useful because the
antibody response may be lower for the combination than for each
TOXOID VACCINES.
 SECOND GENERATION OF VACCINES

 To minimize the risks of vaccination, second- generation vaccines have been developed
that contain only a fragment of the bacterium or virus. These subunit and conjugate
vaccines generate acquired immunity that lacks a cytotoxic T-cell response.
 SUBUNIT VACCINE

 Unlike the whole agent attenuated or inactivated vaccines,
the strategy for a subunit vaccine is to have the vaccine
contain only those parts or subunits of the antigen that
stimulate a strong immune response. These subunits may be
epitopes. For example, the subunit vaccine for
pneumococcal pneumonia contains 23 different
polysaccharides from the capsules of 23 strains of
Streptococcus pneumoniae.
 Adverse reactions to such subunit vaccines are very rare
because only the important subunits of the antigen are
included in the vaccine. These subunits cannot produce
disease in the person vaccinated.
 CONJUGATE VACCINES

 Conjugate vaccines have a polysaccharide
component, but that sugar is stuck to a
protein or some other carrier so your immune
system will respond to the sugar on the
bacteria better.
 Haemophilus influenzae b (Hib), which is
responsible for a form of child- hood
meningitis, produces an external glycocalyx
coat called a capsule. Since the capsular
polysaccharides by themselves are not
strongly immunogenic, the strategy here is to
conjugate (attach) capsular polysaccharides
to a carrier which will stimulate a strong
immune response. The result is the Hib
vaccine.
 RNA VACCINE

 When an mRNA vaccine is delivered, the RNA material
teaches our body how to make a specific type of protein
that is unique to the virus, but does not make the person
sick. The protein triggers an immune response, which
includes the generation of antibodies that recognize the
protein. That way, if a person is ever exposed to that virus
in the future, the body would like have the tools
(antibodies) to fight against it.
 Pfizer-BioNTech and Moderna COVID-19 vaccines which are
mRNA vaccines.
 PASSIVE IMMUNITY

 Passive immunity develops when antibodies enter the
body from an outside source (in contrast to active
immunity, in which individuals synthesize their own
antibodies).
 Again, the source of antibodies may be unintentional, such
as a fetus receiving antibodies from the mother, or
intentional, such as the transfer of antibodies from one
individual to another.
 NATURALLY ACQUIRED PASSIVE IMMUNITY

 Naturally acquired passive immunity, also called “congenital immunity,”
develops when antibodies pass into the fetal circulation from the mother’s
bloodstream via the placenta and umbilical cord. The process occurs in the
“natural” scheme of events. The maternal IgG antibodies remain with the
child for approximately three to six months after birth and play an important
role during these months of life in providing additional resistance. Certain
antibodies, such as measles antibodies, remain for 12 to 15 months. Maternal
antibodies also pass to the newborn through the first milk, or colostrum, of a
nursing mother as well as during future breast-feedings. In this instance, IgA
is the predominant antibodyalthough IgG and IgM also have been found in the
milk.
 ARTIFICIALLY ACQUIRED PASSIVE IMMUNITY

 Artificially acquired passive immunity arises from the intentional
injection of antibody- rich serum into the patient’s circulation. The
exposure to antibodies is thus “artificial.” In the decades before the
development of antibiotics, such an injection was an important
therapeutic tool for the treatment of disease. The practice still is
used for viral diseases such as Lassa fever and arthropodborne
encephalitis, and for bac- terial diseases in which a toxin is involved.
For example, established cases of botulism, diphtheria, and tetanus
are treated with serum containing their respective antitoxins.
 SERUM RENDERING ARTIFICIALLY ACQUIRED PASSIVE
IMMUNITY.

 Various terms are used for the serum that renders artificially acquired passive
immunity. Antiserum is one such term. Another is hyper-immune serum, which
indicates the serum has a higher-than-normal level of a particular antibody.
 If the serum is used to protect against a disease such as hepatitis A, it is
called prophylactic serum.
 When the serum is used in the therapy of an established disease, it is called
therapeutic serum, and when taken from the blood of a convalescing patient,
physicians refer to it as convalescent serum. Another common term, gamma
globulin, takes its name from the fraction of blood serum in which most
antibodies are found. Gamma globulin usually consists of a pool of sera from
different human donors, and thus contains a mixture of antibodies (usually
IgG), including those for the disease to be treated.
 HERD IMMUNITY

 A population without a vaccination program is vulnerable to disease
epidemics. Many people will suffer from the disease; some may die, while
others could be left with a permanent disability. Even with a vaccination
program, if insufficient numbers of citizens get the vaccination, the pathogen
still can infect those who are not protected. Vaccinations are never meant to
reach 100% of the population. This shortfall is partly due to some people
simply not being vaccinated or because some individuals simply respond
poorly to a vaccine; all such individuals remain susceptible and unprotected.
Still, the lack of 100% vaccination is not seen as a problem as long as most of
the population is immune to an infectious disease. This makes it unlikely a
susceptible person will come in contact with an infected individual. This
phenomenon, called herd (community) immunity, implies that if enough
people in a population are immunized against certain diseases, then it is very
difficult for those diseases to spread.
 HERD IMMUNITY
 Microbiologists and epidemiologists believe that when greater than 85% of the
population is vaccinated (herd immunity threshold), the spread of the disease is
effectively stopped. The rest of the “herd” or population remains susceptible,
which is allowable because it then becomes very hard for pathogens “to find
someone” who isn’t vaccinated. Susceptible individuals are protected from
catching the disease, and if one of these individuals should catch the disease,
there are so many vaccinated people in the “herd” that it is unlikely the person
could easily spread it. Herd immunity can be affected by several factors. One is
the environment. People living in crowded cities are more likely to catch a disease
if they are not vaccinated than non-vaccinated people living in rural areas
because of the constant close contact with other people in the city. Another factor
is the strength of an indi- vidual’s immune system. People whose immune
systems are compromised, either because they currently have a disease or
because of medical treatment (anticancer or antirejection drugs), may not be able
to be immunized. They are at a greater risk of catching the disease to which
others are immunized.