Evidence and control: meningococcal disease

1. Evidence and control: meningococcal disease

2. Public health policy in UK • Cases and contacts • bp to case before admission • rif or cipro to case and close contacts • vaccinate close contacts if A,C,W135,Y • give out information • outbreaks: 2 or more cases in a school, wider public health action • http://www.hpa.org.uk/cdph/issues/CDPHVol5/no3/ • Meningococcal_Guidelines.pdf

3. Pre-admission antibiotics and mortality • Systematic review • Oral antibiotics (n=5) RR 0.17 (0.07 - 0.43) • Parenteral antibiotics (n=12) • marked heterogeneity • unable to estimate RR

4. Parenteral pre-admission antibiotics and mortality

5. Relationship between risk ratio and proportion of treated cases

6. What doers it all mean? • Confounding by severity • inadequate stratification to deal with confounding in observational studies of physician behaviour need RCT • Effect modification • true harm in severe subset, true benefit for most

7. Carriage eradication in close contacts • high risk in close contacts (RR >500, AR 1 in 200 – 1 in 300) • highest in first 24 hours • case infectious for very short period (<24hours) before illness • may continue to be carrier afterwards • asymptomatic carriers infectious for 1-2 years • risk to close contacts likely from carrier among close contacts • policy of carriage eradication should also prevent disease in newly acquired carrier

8. Antibiotics to households Risk reduction 1-30 days after index case

9. Antibiotics to households Risk reduction 1-30 days after index case Risk ratio [95% CI] CDC 1976 Samuelsson 2000 6.14 Scholten 1993 0.11 [0.02, 0.58] Overall Risk Ratio 0 1 2 3

10. Measure of effect • NNT = 1/RD = 1/(Ie – Iue) = 1000/4.6 = 218 95%CI 150-367

11. Interval between 1st and 2nd cases in clusters

12. Vaccination low effectiveness in preventing illness among contacts, as risk is highest early on, before vaccination can generate immunity • so, for prevention in Europe we rely mainly on antibiotics for close contacts • Our aim is for primary prevention through vaccination

13. Polysaccharide vaccines • A,C, W135, Y • Produced from purified PS antigens from capsule of organism (Nm) • No immunological memory, short term protection • Antibody response is age dependent • Low efficacy in infants (especially C)

14. Conjugate vaccines • Monovalent (C, A) and quadrivalent ACW135Y • PS antigen attached to carrier protein (e.g. TT, CRM-197) • T cell dependent response • Immunological memory and prolonged protection • Good response in young infants • but may need booster

15. Serogroup B and C cases 1998 – 2005England and Wales Men C campaign

16. Vaccine efficacy to four years by catch-up cohort and time (England)

17. Herd immunity effect • Conjugate vaccines shown to reduce carriage • 70% reduction in carriage of serogroup C meningococci one year after vaccination in teenagers • should lead to indirect protection in unvaccinated • Reduced attack rates in unvaccinated before and 2 years after MenC programme • In <20 year olds, attack rate reduced by 67% (52-77%) • Followed by decline in >20 year olds (not included in vaccination programme)

18. Serogroup C cases by age group 1998-2005 Men C campaign

19. What’s next? Group B vaccines • Group B polysaccharide not immunogenic • Outer membrane proteins generate serosubtype specific immunity (New Zealand) • Modified capsular polysaccharide with conjugation to a protein carrier (non starter) • Genome “mining” for vaccine candidates -recombinant subunit proteins or outer membrane vesicles (Chiron) • Neisseria lactamica vaccine (on trial)