Vaccines Chapter 14 Also see on-line Influenza resource at http://www.influenzareport.com/ir/vaccines.htm The Parents'

1. Vaccines Chapter 14 Also see on-line Influenza resource at http://www.influenzareport.com/ir/vaccines.htm The Parents' Guide to Childhood Immunizations http://www.cdc.gov/nip/publications/Parents-Guide/2005-parents-guide.pdf Self-Test Questions: Intro: both A: 1 – 5, 7, 8 B: 1 - 8 C - G: all Vaccines

2. Edward Jenner and the origin of vaccination Small pox caused by ‘variola virus’ Induced immunity dates to ancient Chinese -- practiced ‘Variolation’ -- brought to England in 1700s -- lead to the ‘Royal experiment’ Jenner discovered protective effect of cow pox -- ‘vaccinia virus’ -- ‘vacca’ Latin for cow - vaccination WHO irradicated small pox in 1970s Vaccines

3. What are different types of immunization? Passive Immunization -- direct transfer of protective antibodies -- no immunological memory Active Immunization -- activation of immune response -- immunological memory Therapeutic Immunization -- treat existing disease Vaccines

4. Passive Immunization to treat Fetal Erythroblastosis Conditions: mother Rh—; father, 1st and 2nd fetuses are Rh+ Rh Immune hemolysis Rhogam Given 24-48 hours after 1st pregnancy Vaccines

5. Active Vaccination: What are some important considerations in the design of vaccines? • Characteristics of pathogen & disease • Intra- vs extra-cellular • short or long incubation • acute or chronic disease • Antigenic stability • route of infection • Characteristics of vaccine • efficacy • appropriate response • booster • safety • stability, cost Vaccines

6. What are the recommended childhood vaccines? Combined vaccines Why are boosters needed? Other vaccines for special needs TB, anthrax, plague, yellow fever, etc Vaccines

7. How effective are vaccines? Vaccine “efficacy” incidence among those administered 1- ------------------------------------------- ------------------------------------------- incidence among those not administered -- e.g., 60% efficacy -- depends upon population, age, etc • Is 100% efficacy necessary? • -- “herd immunity” • Cases per Year Decrease • before inin Cases • (average) 2003 per Year • Diphtheria 175,885 1 99.9% • Hib (<5 yrs old) 20,000 (est.) 259 98.8% • Measles 503,282 56 99.9% • Mumps 152,209 231 99.9% • Pertussis 147,271 11,647 92.1% • Polio (paralytic) 16,316 0 100.0% • Rubella 47,745 7 99.9% • Smallpox 48,164 0 100.0% • Tetanus 1,314 20 98.5% • Sources • CDC. Impact of vaccines universally recommended for children — United States, 1900-1998. • MMWR 8(12):243-8 • CDC. Notice to Readers: Final 2003 Reports of Notifiable Diseases. MMWR 2004;53(30):687 Example efficacies Diphtheria: 87%-96% Tetanus: >90% Oral polio: 90%-100% Mumps/Measles/Rubella: 90%-95% HIV vaccine trials 150 vaccines developed 6 have made it to efficacy testing 2009: 1st with efficacy (31%) [2007 had negative efficacy] Malaria vaccine trial 2011: 45 – 56% Vaccines

8. How are vaccines made? Dead (inactivated) pathogens IPV – Inactivated polio vaccine – ‘Salk’ vaccine [old pertussis of DPT -- Bordetella pertussis] Live attenuated pathogens MMR – measles, mumps, rubella viruses OVP -- oral polio vaccine – ‘Sabin’ vaccine Subunit / Peptide components HBsAG -- Hepititis B surface antigen Flu – purified HA & NA antigens Conjugates(polysaccharides coupled to protein carrier) HiB – Haemophilus influenzae type B PCV – pneumococcal conjugate vaccine Toxoids DTaP -- diphtheria, tetanus toxoids [ + “acellular pertussis” molecular component] Cell cultured virus Remember Adjuvants? -- increase immune response e.g., aluminum hydroxide McGraw-Hill Vaccines Vaccines

9. What are pros and cons of different types of vaccines? Dead (inactivated) pathogens pros may be safer; more stable than attenuated cons weaker cell mediated response; boosters contaminants – pertussis endotoxin in old DPT Live attenuated pathogens pros better cell-mediated response cons reversion -- Sabin polio (Types 1 & 2) infection in immunodeficient patients less stable Molecular components pros No living pathogen present very stable cons fewer epitopes weaker cell mediated response Vaccines

10. Why do we not have vaccines for serious protozoal diseases -- malaria, African sleeping sickness Plasmodium causes Malaria -- Anopholes mosquito is vector Trypanosoma cause ASS -- tsetse fly is vector Complex life cycles Chronic diseases Undergo “Antigenic Shift” Trypanosoma carries ~1000 VSG genes (variant surface glycoprotein) ~1% of parasites shift AG Vaccines

11. Influenza: the disease • Principal virus subtypes -- A & B • Key surface antigens • Hemaglutinin -- HA • Neuraminidase – NA • -- numbered 1,2,3, etc • Causes of seasonality unclear: • Δ antigenicity/ infectiousness • social interactions • environmental conditions • Current circulating forms • H3N2*, H1N1, H1N2, • ~36K deaths • ~200,000 hospitalizations Vaccines

12. Influenza con’t: • Circulating stains vary annually • -- “antigenic drift” • -- vaccine must accommodate • Recent vaccines contain • A -- New Caledonia/20/99 (H1N1) • A -- Wisconsin/67/2005 (H3N2) • B -- Malaysia/2506/2004 • Vaccines types • Injection – inactivated whole virus or • purified HA & NA antigens • Nasal spray “FluMist” • -- cold adapted attenuated • Prepared in eggs • Capacity only ~ 300 x 106 doses Vaccines

13. Pandemic Flu • “Antigenic-Shift” can occur • History • 1918 Spanish Flu (H1N1; 40 mil dead) • 1957 Asian Flu (H2N2; ~1 mil+ dead • 1968 Hong Kong Flu (~0.75 mil dead) • -- AG-shift from H2N2 to H3N2 • Swine Flu 2009 • H1N1 vaccine (influenza A/California/07/2009) • 15 μg HA or • 106.5-107.5 pfu of live attenuated virus • Challenges to vaccination • Development time • Production capacity (use of eggs?) • Distribution • Economics • Vaccination strategy Current spread of H5H1 Vaccines

14. New Vaccination Strategies • DNA vaccines • DNA for an AG injected • -- expressed in cells • Pros • Both arms respond • DNA is very stable • No pathogen involved • Cons • Still experimental • Limited epitopes • Recombinant vectors • e.g., HIV genes in an Adenovirus vector Vaccines