Eradication of Vaccine-Preventable Diseases

Hinman, Alan R.

doi:10.1146/annurev.publhealth.20.1.211

Cited by 89 publications

(43 citation statements)

References 22 publications

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“…13,14 Elimination of measles, mumps and rubella is a feasible but costly objective because it requires achieving and maintaining a high prevalence of protected individuals. 2,4,15 The re-emergence of measles in Europe made it impossible to achieve measles elimination by the year 2010, and raised the possibility that infected Europeans could spread the disease to poor countries where vaccination rates are low. The global eradication of measles is more difficult than for other infectious diseases due its higher herd prevalence of protected individuals necessary to block its transmission.…”

Section: Discussionmentioning

confidence: 99%

Evaluation of the establishment of herd immunity in the population by means of serological surveys and vaccination coverage

Plans-Rubió

2012

Human Vaccines & Immunotherapeutics

121

104

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Section: Discussionmentioning

confidence: 99%

Evaluation of the establishment of herd immunity in the population by means of serological surveys and vaccination coverage

Plans-Rubió

2012

Human Vaccines & Immunotherapeutics

121

104

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“…Smallpox was eradicated with live vaccinia virus, and a live attenuated poliovirus vaccine has been at the core of the polio eradication campaign (17). Worldwide measles virus (MV) vaccination prevents an estimated 80 million cases and 4.5 million deaths annually (45) with minimal severe adverse effects, on average less than 10 in 1 million doses (34).…”

mentioning

confidence: 99%

A Vectored Measles Virus Induces Hepatitis B Surface Antigen Antibodies While Protecting Macaques against Measles Virus Challenge

Valle

Devaux

Hodge

et al. 2007

J Virol

105

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Vaccines based on live viruses can be highly effective and easy to produce and deliver. Smallpox was eradicated with live vaccinia virus, and a live attenuated poliovirus vaccine has been at the core of the polio eradication campaign (17). Worldwide measles virus (MV) vaccination prevents an estimated 80 million cases and 4.5 million deaths annually (45) with minimal severe adverse effects, on average less than 10 in 1 million doses (34). With the currently recommended vaccination scheme, the first dose of vaccine given at 10 to 12 months of age confers long-lasting immunity to 95% of vaccinees (16). The second dose, given to 6-year-olds, raises the conversion rate to nearly 100%, eliminating primary vaccine failures (45). The two-dose strategy has been credited with elimination of indigenous measles in several countries (9), and the live attenuated MV vaccine is considered to be one of the safest and most cost-effective health tools available (28).MV is a nonsegmented negative-strand RNA virus replicating in the cytoplasm. Vaccine safety and efficacy are sustained by lack of recombination, lack of a DNA replication phase, established vaccine production methods, and effective distribution networks (2, 50). A reverse genetic system (37) allows generation of recombinant MV expressing heterologous proteins, including those of other pathogens (48). For this, coding regions are inserted between duplicated MV-specific gene start and gene end motifs that direct transcription by the viral RNAdependent RNA polymerase. These expression cassettes are named additional transcription units (ATUs). The genomic location of an ATU determines the amount of protein expressed due to the sequential attenuation of transcription at gene ends (6,18).Work towards developing recombinant MV with additional vaccine specificities has begun: genes from hepatitis B virus (HBV) (43), simian and human immunodeficiency viruses (24, 52), mumps virus (50), and West Nile virus (10) have been inserted into different positions in the MV genome and thus expressed at different levels. The immunogenicities of vectored MVs and, in one case, their vaccine efficacies have been characterized in rodent and primate animal models. An MV-based candidate vaccine protected interferon (IFN) receptor-deficient mice against West Nile virus challenge (10).The widely used HBV vaccine is based on Saccharomyces cerevisiae-expressed small surface antigen (hepatitis B surface antigen [HBsAg]) and has a three-dose schedule (22). This vaccine provides enduring and protective immunity, but compliance with this regimen is often low, and a long-desired global immunization is not in sight. To facilitate HBV eradication, alternatives have been proposed, including a two-dose scheme (1, 4). Replicating HBsAg-expressing viral vectors have also been generated: vaccinia virus (27, 44)-, varicellazoster virus (20, 42)-, adenovirus (25)-, and MV-based vectors (43) produce HBsAg to high levels and elicit protective antiHBsAg antibodies in animal models.

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“…1 Vaccination is one of the most effective disease prevention strategies when implemented properly across all sections of the at-risk population. Immunization against a disease is achieved only if a potent vaccine in administered.…”

mentioning

confidence: 99%

Evaluation of the Cold-Chain for Oral Polio Vaccine in a Rural District of India

Samant¹,

Lanjewar²,

Parker³

et al. 2007

Public Health Rep

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Eradication of Vaccine-Preventable Diseases

Cited by 89 publications

References 22 publications

Evaluation of the establishment of herd immunity in the population by means of serological surveys and vaccination coverage

Evaluation of the establishment of herd immunity in the population by means of serological surveys and vaccination coverage

A Vectored Measles Virus Induces Hepatitis B Surface Antigen Antibodies While Protecting Macaques against Measles Virus Challenge

Evaluation of the Cold-Chain for Oral Polio Vaccine in a Rural District of India

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