Vaccination Flashcards
Define immunisation
Immunisation is the process of initiating an adaptive immune response ^[B and T cells respond] through the introduction of an antigen into the body.
Describe active immunisation
Active immunisation is the administration of a vaccine that elicits a protective immune response.
- killed or inactivated preparation of a pathogen
- live-attenuated pathogen
- conjugate vaccine
- subunit vaccine
- DNA vaccines
- peptide vaccines
- often requires use of an appropriate adjuvant
Describe passive immunisation
Passive immunisation is the administration of antibodies that provide protection in the recipient
Define vaccination
is the induction of an adaptive immune response to a pathogen via injection of a vaccine.
Define herd immunity
Herd immunity is protection provided to non-vaccinated individuals in a population, due to majority being successfully vaccinated.
Describe the principle of vaccination
Vaccination involves the introduction or exposure of a toxoid/primary antigen challenge to the body. This results in a small primary antibody response (IgM>IgG). Thus on secondary infection or natural infection with the actual toxin/a secondary antigen challenge, a secondary antibody response is generated. This secondary response constitutes acquired immunity (IgG predominant response).
The primary response following acute infection is mainly carried out by naive CD8+ T cells. Once pathogen is cleared a pool of memory T cells remains with rapid response of CTLs following re-exposure to the pathogen.
Discuss the benefits and disadvantages and some examples of passive immunisation
Passive immunisation is the administration of products containing antibody or immune serum.
Previously horse-derived antibodies were used.
Treatments that persist include:
- anti-venom post snake and spider envenomation
- pooled human plasma (Abs directed against multiple pathogens) ^[e.g. for primary immunodeficiency]
- hyperimmune globulin (directed against specific pathogens including varicella zoster virus, RSV, HepB, CMV)
- antitoxins (equine/human origin)
Advantages
- immediate acquisition of antibodies
- in case of anti-venoms or antitoxins: neutralise circulating toxins
Disadvantages
- no immunological memory invoked
- risk of transmission of blood-borne pathogens
- risk of serum sickness or anaphylaxis if repeated administration (equine derived anti-sera)
Describe, provide advantages and disadvantages and some examples of live attentuated vaccines
Active immunisation is the administration of a vaccine that elicits a protective immune response.
- killed or inactivated preparation of a pathogen
- live-attenuated pathogen
- conjugate vaccine
- subunit vaccine
- DNA vaccines
- peptide vaccines
- often requires use of an appropriate adjuvant
Live attenuated vaccines are the most effective of all vaccines.
These contains organisms cultured to reduced pathogenicity.
They retain some of the antigens of the virulent form. Examples include:
- Bacille Calmette-Guerin (BCG) ^[TB], Salmonella typhi
- Measles, mumps, rubella vaccines
- Varicella zoster
- Yellow fever
Advantages
Live, attenuated vaccines confer long lasting immunity: cell mediated, humoral and memory.
Disadvantages
However, there is a risk of restoration of virulence, or reversion, particularly in immunosuppressed or immunodeficient individuals ^[also consideration in vaccinating immunodeficient communities with BCG - IL-12 issue].
Unclear if there is an optimal number of vaccinations as eradication of natural disease occurs.
Discuss inactivated vaccines, some examples, benefits and disadvantages
Killed or inactivated vaccines contain an inactive preparation of a pathogen.
It is less effective than live vaccines i.e. less immunogenic. However, it is more effective if antigen is a protein, and if adjuvant used.
Inactivated vaccines require booster doses to maintain efficacy.
It predominantly generates humoral immunity based on production of neutralising antibodies, with rapid production on re-exposure.
There is a limited cellular immune response due to absence of replicating organisms, and reduced production of secretory IgA.
Examples of inactivated vaccines include polio (Salk), influenza, HepA, rabies, pertussis, cholera.
Advantages
- safety
- easy to produce and store
- less affected by pre-existing antibody (maternal antibody can interfere with the response to immunisation)
#### Disadvantages
- requires boosters
- may not preserve the immunoprotective antigen
- poor induction of T cell immunity (CD8+)
- poor inducers of mucosal immunity
- potential for immune response to tissue antigens derived *from cells to which vaccine is produced (allergy)**
Describe toxoid vaccines
Some bacterial pathogens such as diphtheria and tetanus produce exotoxins.
Toxoid production involves the purification of the exotoxin, followed by inactivation with formaldehyde.
Vaccination with toxoid induces anti-toxoid antibodies capable of binding to, and neutralising the effects of, the exotoxin.
Therefore, the epitope structure of the toxoid must be maintained in order to ensure efficacy.
Describe conjugate vaccines
Encapsulated organisms are an important cause of morbidity and mortality in those under 2 years of age.
This is due to impaired response to polysaccharide antigens in this group.
A solution to this is conjugate vaccines.
These contain polysaccharide antigens conjugated to a carrier protein to which the immune system has already been exposed such as diphtheria, tetanus toxoids or OMPC.
The resultant immune response is T cell dependent and rapid antibody production.
It also significantly reduces morbidity associated with Hib and S. pneumoniae.
- T independent antigen
- cross linking with B cell receptors
- leads to differentiation into plasma cells
- no affinity maturation or memory B cells i.e. can’t mount effective response on re-exposure
- Conjugate vaccine = processing of carrier peptide specific T cells along with polysaccharide specific B cells
- delayed but specific
- class switching, memory, and production of high affinity antibody
- faster and better response on re-exposure
Describe subunit vaccines
Subunit vaccines rely on recombinant DNA technology.
Examples include HepBsAg.
The immunogenicity is compounded due to spontaneous aggregation into virus like particles.
However, failure has been demonstrated in a small group (MHC linked - HLA A1, B8, DR3) ^[receive immunoglobulin therapy].
Another example is the acellular pertussis vaccine, which is a purified subunit vaccine containing defined protein constituents prepared from B. pertussis.
Describe another example of a subunit vaccine
An example is the HPV vaccine.
Virus-like particles or VLPs self-assemble when L1 protein of HPV is produced in isolation.
Vaccines comprise a mixture of types 16, 18, 6, 11; or types 16 and 18 alone.
This vaccine is highly immunogenic, and contain an aluminium salt adjuvant that precipitates VLPs, resulting in a slow release of antigen and monocyte activation ^[macrophages to site of infection that process antigen].
The second HPV vaccine contains monophosphoryl lipid A, which activates the innate immune response via TLR-4.
Both vaccines result in the production of virus-neutralising antibodies.
What are some considerations in designing an effective vaccine?
- should not cause infection in the recipient
- should protect against disease resulting from exposure to the pathogen
- generation of neutralising antibody
- production of an appropriate cell mediated immune response
- acceptable side effect profile
- easy to store and administer
- able to be produced in large quantities and at low cost
Describe the role of adjuvants in vaccination
There is variability in the immunogenicity of proteins or polysaccharides
Adjuvants are substances that have the ability to increase the immune response to an antigen:
- aluminium precipitation with the use of aluminium hydroxide or phosphate
- act as a depot for slow release of the antigen
- recruitment of antigen presenting cells
- signal induction, enhancement of production of stimulatory molecules
Note: RISK of side effects e.g. red and swollen limbs
Examples of adjuvants include:
- aluminium salts most common
- inactivated toxins: cholera and pertussis
- (outdated) cell wall extracts: Complete Freund’s extract: oil and water emulsion containing killed mycobacteria
- bacterial polysaccharides
- bacterial HSPs
Note many adjuvant substances are toxic and are unable to be used in humans.
Innate immunity plays an important role in the facilitation of B cell responses to both thymus dependent and independent antigens.
Many adjuvants provide PAMPs recognised by PRRs.
TLRs are the most important PRRs and recognise specific microbial ligands:
- upregulation of cytokine production
- promotion of DC maturation
- induction of antigen specific T cell responses
Note some TLRs located on cell surface. Some intracellular.
The same pathways that process antigens are utilised to mount an immune response post-immunisation
