Vaccines Bacterial & Viral

Question 1

How is public health implemented in vaccine development?

Answer 1

Making and administering vaccines depends on quantitative data that tells us if it is emerging, how many people have it, and its course of spread.

With the two groups of meningococcal infections, this is an example where we don’t get cross-protection. This is because the polysaccharides of the two organisms are quite different. So, we need to develop a different vaccine for the specific organisms.

Question 2

Describe how the MenB vaccine came about?

Answer 2

There was a vaccine that covered the groups C, A, W and Y. It was a conjugated (due the fact that infants are not very good at detecting polysaccharides) capsular polysaccharide vaccine.

In 2015, a Men B vaccine was developed, ad it was administered to all new born babies, then secondary shots given at 2 and 4 months, and a booster at 12 months.
There was a catch-up programme for babies born after 1st May 2015. However, other groups remained vulnerable (due to cost-effectiveness, shortage of supply, etc.).

Question 3

What were some issues of the MenB vaccine?

Answer 3

• it was more reactogenic;
• not all serotypes of group B were covered (unlike MenC)
• there was some cross-protection against MenW
• it cost £75 per dose – needed to be £20 for cost effectiveness.
• it had 88% efficacy and strain coverage
• the duration of protection was 10 years

Question 4

Describe the vaccine that was developed to protect against MenW.

Answer 4

There was the emergence of a new highly virulent invasive strain W. It had been increasing since 2009

It was decided to vaccinate risk groups:

• 14 – 18 year olds (school year 13)
• older university entrants (aged 19 - 25)

From spring 2016, it was decided that Men ACWY will replace Men C.

A catch-up programme currently offered to year 9 or 10 + catch –up year 11s.

Question 5

What is the UK immunisation schedule for children/ young people?

Answer 5

Two months: DTaP/ PIV/ Hib/ HepB + PCV + rotavrisu + MenB

Three months: DTaP/ IPV/ Hib/ HepB + rotavirus

Four months: DTaP/ IPV/ Hib/ HepB + PCV + Men B

12 months: Hib/ Meningitis C + MenB

13 months: MMR + PCV

2-8 years: Flu (annual) nasal spray

40-60 months:DTaP/ IPV + MMR (second dose)

12-13 year old girls: HPV vaccine (2 doses, was 3)

13-18 years: Td/ IPV + MenACWY booster

Question 6

Expand on the UK immunisation schedule for children/ young people and how it changed.

Answer 6

HepB was added because there were a lot of children acquiring it during birth from their HepB+ mothers, and it was a burden on the NHS, so a vaccine was introduced to prevent that.

PCV is given in boosting doses.

Rotavirus is a live attenuated viral vaccine. It was thought that you would only need to give attenuated live viral vaccines once, but it was found that they needed to be given twice. Turns out, although the vaccine works, it doesn’t protect children against severe forms of rotavirus.

MMR also needs to be given twice. This is because, ~10% of the people at the age of one year miss out, and because measles is such an infectious disease, there were still pockets of measles breaking out into the community. Thus, a second dose is needed.

Question 7

Describe Haemophilus influenza type B.

Answer 7

It is a paediatric disease - usually affecting 6 month olds - 3 year olds (1/600 would acquire it).
Initially, it is a nasopharyngitis (often starting with viral infection).

It then spreads to an otitis media, sinusitis, bronchitis, pneumonia or sometimes epiglottitis (requiring a tracheotomy, croup.

It can develop into bacteraemia, septic arthritis, and meningitis (60% cases).

It can also develop into neurological disorders (33%) or death (5%) if not vigorously treated.

Question 8

Describe the prevention of Hib meningitis.

Answer 8

The vaccine is very effective (99% of cases are Type B)

Type B - capsule polysaccharide vaccine linked to a conjugate: diphtheria/tetanus toxoids + outer membrane proteins.

Question 9

Describe diphtheria.

Answer 9

It sits in the pharynx and undergoes non-invasive multiplication

The toxin is produced locally but acts at a distance:

• absorbed by lymphatics and has systemic effects, damages heart, kidney, nerves, adrenals
• kills epithelial cells and polymorphs
• has a gelatinous exudate
• ulcer - necrotic exudate - pseudomembrane
• local inflammation, swelling, lymph nodes - leading to Bull Neck
• respiratory obstruction

Question 10

Describe tetanus.

Answer 10

It is caused by Clostridium tetani. These are gram positive rods, and are anaerobic.
Clostridium tetani lives in the soil; it is a spore-forming organism that can survive for years.

It can grow in a wound, and release toxins that have a systemic distribution and has an effect on the nerves.
This is what causes the paralytic excitation of nerves.

Question 11

How does Clostridium tetani cause the paralysis?

Answer 11

The toxins block the release of the neurotransmitters (GABA) at the inhibitory synapse in the CNS.
This results in unopposed excitatory stimuli that gives you this spastic paralysis associated with tetanus.

The vaccine for this disease generated neutralising toxins; if you can neutralise them before they get to the synapses, they can not have their effect.

Question 12

Describe whooping cough and its vaccine.

Answer 12

Whooping cough is also known as pertussis, and it combated by the DTaP vaccine.

It is a multi-toxin disease. It used to be a whole cell vaccine with just killed organisms, but it would give off a lot of toxicity.

Now we use a new low risk acellular vaccine (subunit). It contains outer membrane proteins, an adhesion molecule (adhesin) and the main toxin of the organism (pertussis toxoids).

This blocks the adhesion and neutralises the toxin, taking on an antibody role.
It is very effective.

Question 13

What is the importance of administering the influenza vaccine?

Answer 13

This is mostly used to stop vulnerable people from getting the flu. It is also given to people surrounding them, so that they don’t become carriers and deliver the influenza to them.

Question 14

What is the aim of the influenza programme?

Answer 14

• to protect those who are most at risk of serious illness (such as heart problems, etc.) or death should they develop influenza.
• to reduce the circulation of the virus.

Question 15

Who is administered the influenza programme?

Answer 15

• all those aged 65 years or over
• all those aged 6 months or over in a clinical risk group
• those living in long-stay residential facilities
• those who care for elderly or disabled persons
• household contacts of immunocompromised individuals
• those working within health and social care settings
• those who work in close contact with poultry (as that is where new influenza strains are likely to come from)
• all children 2 – 9 years (most infections and transmission source)

Question 16

What is the implication of the influenza variation?

Answer 16

We need to have neutralising antibodies targeting the surface of the virus (mainly the haemagglutinin).

However, the viruses are constantly changing. This can be through antigenic drift (where they slightly change their serotype over time due to mutations resulting from a high reproduction rate) or through antigenic shift (when two viruses come together and combine to generate a completely new strain of virus).

We need a way to deal with these large numbers of haemagglutinin molecules.

Question 17

Describe the flu vaccine.

Answer 17

Tetravalent vaccines will contain the following viruses:

• A/Michigan/45/2015 as the H1N1-like component (as last year)
• A/Singapore/INFIMH-16-0019/2016 as the H3N2-like component
• B/Colorado/06/2017
• B/Phuket/3073/2013

Effectiveness:

• variable by year/age group
• antigenic drift and shift;
• prior exposure; cross-reacting antibodies
• vaccine production issues

Across all age groups including children - prevented:

52. 4% of flu cases in 2015-16
53. 8% of flu cases in 2016-17

2015-16 - worked less well in the over 65 age group
2016-17 - >65 age – offered little protection

Hence in 2018 – FLUAD vaccine was introduced for >65s ( aTIV) tetravalent Fluad® adjuvant (to make it more effective)

Question 18

What are some symptoms that are presented in pneumococcal infection?

Answer 18

• sinusitis (common)
• invasive pneumococcal disease (bacteramia)
• soft tissue infection (rare)
• arthritis (rare)
• meningitis
• otitis media
• pneumonia
• peritonitis (rare)

Question 19

Who are the immunisation target risk groups of the pneumonia vaccine?

Answer 19

The disease burden for this organism is mainly in children under the age of 1, and people aged over 65.

Thus, the immunization schedule will target these two risk groups.

Question 20

What are the two types of pneumococcal vaccine?

Answer 20

1. Pneumococcal Polysaccharide Vaccine PPV23

2. Pneumococcal Conjugate Vaccine PCV-13V

Question 21

Describe the PPV23 version of the pneumococcal vaccine.

Answer 21

Streptococcus pneumonia is a encapsulated organism, so its vaccine will need to be conjugated.

The virus exists in about 90 different serotypes that circulate in our community. Only about 20-30 of them cause disease, so they are the ones covered by the first pneumonia vaccine.

The vaccine for adults, PPV23, is just the polysaccharides, as they can recognise those antigens.

Question 22

Describe the different types of HPV.

Answer 22

There are over 40 types.

The low risk types (6, 11) can cause genital warts. The high risk types (16, 18) can lead to cancer.

Question 23

Describe HPV.

Answer 23

There are over 40 types.

The low risk types (6, 11) can cause genital warts. The high risk types (16, 18) can lead to cancer.

Cervical cancer kills ~1000 women in the UK each year (~3,000 cases p.a. in UK).

A vaccine against type 16 and 18 was introduced first, to protect women against cervical cancer. However, it can also protect you from getting genital warts, which is a plus.

Question 24

Describe the vaccine against HPV.

Answer 24

There are two licensed vaccines:

• Gardasil: protects against HPV 6,11,16,18 - used now as it covers more
• Cervarix: protects against HPV 16,18

Clinical trials show high efficacy, and it is well tolerated:

• 66% reduction in prevalence high grade pre-cancerous lesions
• 76% reduction in cervical cancer deaths
• will save 400 lives/year

Question 25

How would we immunise a foetus if it is at risk?

Answer 25

We can use the idea of antibodies crossing the placenta to give the foetus immunity to certain viruses by vaccinating the mother.

Question 26

What vaccinations are given to a pregnant women?

Answer 26

1. TdaP/polio - for whooping cough - Boostrix IPV

This was in response to the current UK outbreak of whooping cough. It is given to regnant women to protect their babies before routine immunisation.
It is given at 28 – 32 weeks stage up to 38 weeks.
It was introduced in 2012.

It has an uptake rate of ~ 70%.
Of the 18 babies died of pertussis since 2013, 16 were from non-vaccinated mothers.

2. Flu - mother and baby protection – earlier the better
   Pregnant women account for 13% of all H1N1 flu deaths.
   Most childhood deaths were in <6 month-olds.

The uptake rate was only ~42% in 2015-16; it rose to ~70% 2017 in UK.

Question 27

In 2005, a new policy for the TB immunisation schedule was introduced.

Who was it now administered to?

Answer 27

• all infants (0 - 12 months) living in areas where the incidence of TB
  is 40/100,000 or greater
• all infants (0 - 12 months) with a parent or grandparent who
  was born in a country where the incidence of TB is 40/100,000 or greater
• at risk secondary school children
• previously unvaccinated new immigrants from high prevalence countries for TB