From: Related terms: Download as PDF Set alert About this page D. Reid, D. Goldberg, in , 2012 Herd immunity Herd immunity is an important element in the balance between the host population and the micro-organism, and represents the degree to which the community is susceptible or not to an infectious disease as a result of members of the population having acquired active immunity from either previous infection or prophylactic immunization (see p. 731 ).
Herd immunity can be measured: 1 Indirectly from the age distribution and incidence pattern of the disease if it is clinically distinct and reasonably common.
This is an insensitive and inadequate method for infections that manifest subclinically.
2 Directly from assessments of immunity in defined population groups by antibody surveys (sero-epidemiology) or skin tests; these may show ‘immunity gaps’ and provide an early warning of susceptibility in the population.
Although it may be difficult to interpret the data in absolute terms of immunity and susceptibility, the observations can be standardized to reveal trends and differences between various defined population groups in place and time.
The decision whether to introduce herd immunity artificially by immunization against a particular disease will depend on several epidemiological principles.
• The disease must carry a substantial risk.
• The risk of contracting the disease must be considerable.
• The vaccine must be effective.
The effectiveness and safety of immunization programmes are monitored by observing the expected and actual effects of such programmes on disease transmission patterns in the community by appropriate epidemiological techniques.
URL: https://www.sciencedirect.com/science/article/pii/B9780702040894000822 Paolo Giorgi Rossi, Francesca Carozzi, in , 2019 Vaccination of boys Herd immunity is the main driver for the proposal of universal vaccination, that is, including boys and girls.
With growing evidence of the involvement of HPV in a relevant proportion of head and neck cancers, in particular oropharynx ( Plummer et al., 2016 ), it has become clear that the burden of vaccine-preventable disease in males is not negligible ( de Martel et al., 2017 ).
The vaccine has proven to be effective also on precancerous lesions of genital mucosae in males ( Palefsky et al., 2011 ).
Nevertheless, most models still predict that the largest benefit of vaccinating boys is the indirect effect on cervical cancer in women due to the reduction of circulating virus and to establishing of herd immunity faster ( Brisson et al., 2011 ).
The opportunity and cost effectiveness of vaccinating boys is still under debate, with the extreme heterogeneity of policies adopted in industrialized countries reflecting this uncertainty.
Given the very high incidence of HPV-related cancers in males having sex with males, there is consensus that vaccinating this group is opportune ( Markowitz et al., 2014 ; Kirby, 2015 ; Sauvageau and Dufour-Turbis, 2016 ), even though implementing effective strategies to target high-risk populations without indirectly fostering discrimination or stigmatization is challenging.
URL: https://www.sciencedirect.com/science/article/pii/B9780128012383651383 Catherine J. Luke, ... Kanta Subbarao, in , 2013 Herd immunity and indirect protection from LAIV Herd immunity is defined as the proportion of persons with immunity in a given population, 180 and the indirect protection afforded by this immunity to the unimmunized segment of the population is defined as the herd effect .
Herd immunity has been demonstrated for infectious diseases of viral and bacterial etiology, and it is widely accepted that this phenomenon occurs with influenza.
181 Despite the facts that influenza vaccine policy in the United States has been focused on the immunization of persons aged 65 years and older and that vaccination rates increased from 31% to 67% between 1989 and 1997, influenza epidemics still cause widespread morbidity and mortality in this age group.
181–183 Several lines of evidence suggest that widespread immunization of otherwise healthy populations may result in interruption of transmission of influenza and thereby may indirectly protect those in high-risk groups.
For example, vaccination of health care workers was associated with reduced morbidity and mortality from influenza among nursing home residents, 184–188 and health care workers now constitute a priority group for influenza vaccination in the United States.
169 Widespread vaccination of schoolchildren has also been proposed as a measure to reduce the burden of influenza in the community, because children are important vectors for the spread of influenza.
The ability to modify the course of an influenza outbreak by vaccination of schoolchildren has been demonstrated in several studies.
A vaccination rate of 86% in schoolchildren in Tecumseh, Michigan, with a monovalent inactivated vaccine, resulted in a three-fold reduction in the excess attack rate for the community from influenza compared with a neighboring community in which schoolchildren were not vaccinated.
189 A clear difference was observed in the rates of school absenteeism between the communities, and there was evidence that protection was not limited to children of school age.
In Japan, vaccination of schoolchildren was mandatory between 1977 and 1987.
In 1987, the laws were relaxed, and parents could decide whether or not their children received vaccine.
In 1994, vaccination rates fell to low levels amid doubts about the effectiveness of the program.
In an analysis of all-cause mortality and death attributed to influenza and of vaccination rates from Japan and from the United States between 1949 and 1998, Reichert and colleagues found that excess mortality rates, predominantly in older persons, dropped significantly in Japan with initiation of the vaccination program for schoolchildren, from rates 3 to 4 times those in the United States to rates similar to the United States.
190 Excess mortality rates in Japan increased with discontinuation of the vaccination program for schoolchildren.
From a practical standpoint, LAIV could be an extremely effective method to achieve herd immunity if high vaccination rates with an efficacious vaccine are achieved in schoolchildren and influenza transmission to other segments of the community is interrupted.
Large numbers of children could be vaccinated in a short period of time, and intranasal administration is preferred over injection of inactivated vaccine.
There is evidence from several studies that this is an effective approach.
A study conducted in the 1990s demonstrated that vaccination of schoolchildren with either inactivated or Russian LAIV resulted in significant protection.
In schools where the children received LAIV, vaccination rates and illness among staff and unvaccinated children were inversely correlated, suggesting reduction of transmission as a result of vaccination.
Such a correlation was not seen in the schools where children received inactivated vaccine or in schools where children received placebo.
191 There are several studies in a community in central Texas that report both direct and indirect protection against ILI afforded by vaccination of children.
In these studies, age-specific rates of MAARI during the influenza season in intervention communities, where children received LAIV, were compared with rates in comparison communities, where children did not receive vaccine.
Vaccination of approximately 20% to 25% of children, 1.5 to 18 years of age, in intervention communities resulted in indirect protection of 8% to 18% against MAARI in adults older than 35 years.
This small effect may translate into a substantial effect at the population level.
Moreover, the size of this effect may be diluted from use of clinical rather than laboratory endpoints.
192 In another study, significant protection against laboratory-confirmed influenza illness and pneumonia and influenza events was observed in the children who received LAIV, but not in those who received TIV.
Indirect effectiveness against MAARI was observed in 5- to 11-year-old children and in 35- to 44-year-old adults.
193 In a third study, 194 when schoolchildren were vaccinated with LAIV against antigenically mismatched influenza viruses, significant indirect protection from influenza was observed in all age groups, with the exception of those aged 12 to 17 years.
Combined virologic surveillance and MAARI visit data suggested that a single dose of LAIV provided better protection against influenza than TIV.
King and colleagues reported a small pilot study followed by a larger, multistate, school-based immunization intervention study using LAIV.
195, 196 In the pilot study, 195 significant (45% to 70%) relative reductions in fever or respiratory illness–related outcomes including physician visits by adults, physician visits by children, prescription or other medicines purchased by household members, and family schooldays and workdays missed, were observed for intervention ("target") school households compared with control school households.
In the larger trial, intervention school households reported significantly fewer ILI-related doctor or clinic visits for children; fewer episodes of fever plus cough or sore throat in children and adults; lower ILI-related prescription, over-the-counter, and herbal medication use for ILI; lower absenteeism rates for elementary and high-school students; and fewer missed workdays for adults caring for their own ILI or for others during the peak influenza week.
Relative reductions across these outcomes ranged from 25% to 40%, again confirming indirect as well as direct benefit.
Limitations of this study included the lack of placebo groups and the use of questionnaires for reporting of ILI.
In summary, a large body of data demonstrates the effectiveness of vaccination of schoolchildren for the control of influenza in communities, from both direct and indirect effects of immunization.
Both LAIV and TIV are highly efficacious against influenza in children, and a mechanism to explain how LAIV could afford better indirect protection is not clear.
The data from these studies support the widespread vaccination of schoolchildren as a means of reducing morbidity and mortality in other high-risk members of communities.
URL: https://www.sciencedirect.com/science/article/pii/B9781455700905000276 In , 2012 Summary • Herd immunity forms the theoretical basis for mass vaccination programs.
• In the twentieth century, mass vaccination programs were highly successful in eradicating childhood diseases such as diphtheria, pertussis, and tetanus.
• Vaccines administered by the subcutaneous or intramuscular route prevent dissemination of bacteria or viruses to multiple organs but may not prevent infection.
• Vaccines that are administered by the intranasal route prevent both infection and dissemination of bacteria or viruses.
• Bacterial antigens used in vaccines are usually stable.
• Viral antigens often change as a consequence of antigenic drift, antigenic shift, or genetic reassortment.
URL: https://www.sciencedirect.com/science/article/pii/B9780323069472100252 JOHN P. FOX, LILA R. ELVEBACK, in , 1975 In 1971, we discussed herd immunity and its relevance to immunization practices ( 1 ), using applications of the Reed-Frost epidemic model ( 2 ), and of a stochastic simulation model for a community of families ( 3 ) to illustrate the basic concepts.
This presentation draws heavily on our previous discussion * but also will consider how these concepts of herd immunity relate to some important current immunization problems.
Epidemic potential and median epidemic size under various conditions in a randomly mixing population when one case is introduced Average No.
Susceptible Contact Rate Total With Sus-ceptibles Probability of no spread (P NS ) Computer simulation of 100 epidemics a Set No.
N N-S/N S O p pN p S o (1-p) S o No.
with one case Median Size 1 400 0 400 b .005 2 2 .14 14 315 10,000 96 400 .005 50 2 .14 14 315 2 2,000 96 80 .020 40 1.6 .20 18 40 10,000 96 400 .004 40 1.6 .20 17 244 3 2,000 96 80 .005 10 0.4 .67 64 1 10,000 96.
400 .005 50 2.0 .14 13 315 4 5,000 96 200 .005 25 1.0 .37 41 2 5,000 96 200 .010 50 2.0 .14 12 157 5 1,000 60 400 .004 4 1.6 .20 17 244 2,000 80 400 .002 4 0.8 .45 45 1 6 2,000 80 400 .005 10 2.0 .14 13 315 2,000 96 80 .005 10 0.4 .67 64 1 a Simulation using stochastic properties of the Reed-Frost model b Underlining indicates pair of characteristics held constant Table 2 .
Distribution by size of 100 simulated epidemics among 100 susceptible children in a community of families, play groups, and a nursery school a Within-Group No.
of epidemics with indicated numbers of cases No.
of cases Mixing Group Contact Rate 1 2 3 4–9 10–39 40–79 Median Maximum Community .002 82 15 2 1 – – 1 4 Community .002 Families .005 22 18 34 25 1 3 16 Community .002 Families .005 11 6 26 46 2 – 4 33 Play Groups .100 Community .002 Families .005 Play Groups .100 23 4 – – – 73 45 73 Nursery School .100 a The 100 susceptible children and the initial case were in 62 families with 1 to 3 children (mean 1.6) and in 24 play groups with up to 10 children (mean 4.2).
The case was in a 3-child family and a 5-child play group and did not attend nursery school although his 2 siblings were among the 40 susceptibles who did attend.
URL: https://www.sciencedirect.com/science/article/pii/B9780125220507500204 Paul E.M. Fine, ... W. John Edmunds, in , 2018 Case Reproduction Numbers We can approach this herd immunity concept from an alternative, and equally informative, perspective.
If an infection is to persist, each infected individual must, on average, transmit the agent to at least one other individual.
If not, incidence will decline and the infection will disappear progressively from the population.
The number, or distribution, of actual onward transmissions per case thus describes the spread of an infection in a population, and it is a function of four things: (1) the duration of infectiousness; (2) the likelihood of transmission per “contact” between infectious and susceptible individuals; (3) the rate and pattern of contact between members of the host population; and (4) the proportion susceptible in the host population.
Its value under any set of circumstances is known as the reproduction number of the infection, by analogy with standard demographic measures (the average number of progeny per individual per generation).
This average number of actual transmissions should be at a maximum if all members of the host population are susceptible—in which circumstance it is known as a basic reproduction number ( R 0 ) , defined formally as the average number of transmissions expected from a single primary case introduced into a totally susceptible population.
14,15 This definition can be translated directly into the mass action formulation ( Eq.
1 ) by setting C t = 1 and S t = T , to represent the single case introduced into a fully susceptible population.
The number of secondary cases, C t + 1 , is then equivalent, by definition, to the basic reproduction number ( R 0 ): [Eq.
4] C t + 1 = T × r = R 0 This basic reproduction number describes the maximal spreading potential of an infection in a population.
Continuing with the example in Fig.
77.3 , the introduction of a single primary case into the population of T = 100,000 susceptible persons should lead to 10 secondary cases ( C t +1 = 100,000 × 0.0001 = 10 = R 0 ).
Table 77.2 shows examples of numerical values of this statistic that are applicable to different infections and derived by methods described later.
77.5A is an illustration of the concept.
If immune individuals are present in a population, then some of the contacts of infectious individuals will be with these immune persons, and hence will fail to lead to transmission.
As a result, the average number of actual infection transmissions per case will be less than the basic case reproduction number, and this has been defined as the net, or actual, or effective, reproduction number ( R n ).
13,14 The actual number of transmissions ( R n ) should be equivalent to the basic case reproduction number ( R 0 ) times the proportion susceptible in the population ( S ): [Eq.
5] R n = R 0 × S By this expression, if the proportion susceptible ( S ) were equal to the reciprocal of the basic reproduction number of the infection (1 / R 0 ), the average number of transmissions per case ( R n ) should be 1, and thus incidence should remain constant over time.
77.5B illustrates this, and it once again leads us directly to the herd immunity threshold ( H ).
Because the proportion immune is just the complement of the proportion susceptible ( H = 1 − S ), we have [Eq.
6] H = 1 − 1 / R 0 = ( R 0 − 1 ) / R 0 The same expression can also be derived just by combining Eqs.
As long as the proportion immune is maintained above this threshold, incidence should decrease, ultimately to the point of eradication of the infection from the population.
77.6 shows the relationship graphically, which shows the implications for persistence or decline of an infection depending on its basic reproduction number and the proportion of immune persons in the population.
1,13,16 URL: https://www.sciencedirect.com/science/article/pii/B9780323357616000778 Emmanuel Vidor, Stanley A. Plotkin, in , 2013 Herd immunity The best evidence for a herd immunity effect of IPV is the experience in the United States where IPV was introduced into routine use in 1955 and was replaced by OPV in 1962.
A sharp drop in the numbers of cases of paralytic and nonparalytic polio was evident during the years 1955 to 1962 ( Figure 27-5 ).
The apparent reduction in the number of cases observed exceeded the expectation based on the percentage of children vaccinated ( Figure 27-6 ).
214 More specific regional data were published that suggested a greater than expected reduction in polio cases.
215 The second example of herd immunity comes from the Netherlands where vaccination is refused by a religious community that is well dispersed throughout the country, although IPV is routinely administered to the rest of the population.
Two outbreaks of polio have occurred in this religious group, one caused by type 1 virus in 1978 (110 cases) and the second by type 3 virus from 1992 to 1993 (71 cases).
Despite the wide circulation of the virus in this community, there was only one case of polio in other Dutch communities.
Approximately 400,000 unvaccinated individuals not belonging to this religious community also remained unaffected.
216–220, 270 The virulent viruses also spread to similar religious groups in North America, but cases only resulted from the 1978 outbreak.
221–223 Oostvogel et al 224 did an analysis of the circulating viruses in schools affected by the outbreak from 1992 to 1993.
Proof of recent type 3 infection was found in 59.5% of the unvaccinated children and in 22.2% of the vaccinated children.
The evidence for herd immunity comes from countries where oral-to-oral transmission was probably the dominant mode of interhuman poliovirus transmission.
It is less clear if IPV is able to induce herd immunity in countries where the fecal-to-oral route is thought to be the primary role in transmission.
URL: https://www.sciencedirect.com/science/article/pii/B9781455700905000343 RICHARD C. ROSATTE, ... DAVID H. JOHNSTON, in , 2007 10.2 Bait density Control ultimately depends on establishing herd immunity through animals taking baits and sero-converting.
Hence, bait density must correlate with animal density in some positive fashion ( Rosatte and Lawson, 2001 ).
This includes the density of all bait-consuming species, not just the target vector.
Non-target species, such as opossum ( Didelphis virginiana ), may consume a considerable proportion of baits intended for raccoons.
In urban habitats, raccoon density may be extremely high, e.g.
in Washington DC raccoon density was 67–333/km 2 ( Riley et al., 1998 ).
High bait densities will be required to reach a substantial portion of the population.
In Scarborough, Ontario, where raccoon density ranged from 37 to 94/km 2 ( Broadfoot et al.
, 2001 ), raccoon acceptance of baits was 74% when bait density was 200/km 2 ( Rosatte and Lawson, 2001 ).
(1998) used fishmeal polymer V-RG baits at a density 64/km 2 in the Cape May area of New Jersey to control raccoon rabies during 1992–1994.
Tetracycline was detected in 73% of the sampled raccoons and 61% of the raccoons tested seroconverted ( Roscoe et al., 1998 ).
In Newfoundland, under severe winter snowconditions, Whitney et al.
(2005) eradicated an invading epizootic of arctic-strain rabies in red fox using a density of 35 baits/km 2 and, in France, Vuillaume et al.
(1998) distributed vaccine baits at fox dens at a density of 11.4 baits/den.
Given the wide variation in results in a small number of trials, it is necessary in planning ORVPs to consider other factors, such as the methods of vaccine placement, timing of vaccination, spatial variations in animal density and bait design ( Table 18.1 ) ( Bachmann et al., 1990 ; Robbins et al., 1998 ; Olson et al., 2000 ; Rupprecht et al., 2004 ).
Baiting success guidelines derived from counts of tetracycline biomarker lines in teeth of carnivore vector species Species (location) a Sample (n) (year class) Total tetracycline biomarker (%+) Median (range), tetracycline biomarker lines/(+) animal Baiting success, guideline (Type) Red fox (NL) b 25 (1st year class) 66 6.3 (1–11) BSG, Type 1 Coyote (TX) c 117 (1st year) 82 3.3(1–8) BSG, Type 1 Red fox (ON) d 210 (all years) 70 2.8 (1–28) BSG, Type 2 Red fox (DE-Rügen) e 28 (all years) 75 2.5 (1–7) BSG, Type 2 Red fox (CZ) f 19 210 (all years) 78 2.0 BSG, Type 2 Raccoon (NY) g 207 (all years) 73 2.0 (1–9) BSG, Type 2 Raccoon (OH) h 22 (1st year) 76 1.5(1–6) BSG, Type 2 Gray fox (TX) c 141 (1st year) 36 2.1 (1–5) BSG, Type 3 a NL = Newfoundland, TX = Texas, ON = Ontario, DE = Deutschland, CZ = Czech Republic, OH = Ohio; b Whitney et al.
(2005) ; d Johnston and Voigt (1982) ; e Müller et al.
(unpublished); f Matouch and Vitasek (2005) ; g Bigler and Lein (2001) ; h Nohrenberg, USDA(unpublished).
URL: https://www.sciencedirect.com/science/article/pii/B9780123693662500208 David S. Stephens, Michael A. Apicella, in , 2015 Herd Immunity and Introduction Strategies Protection against the bacterial meningitis pathogens through herd immunity is a remarkable, powerful, and unanticipated effect of bacterial polysaccharide-protein conjugate vaccines.
35 Herd immunity can account for approximately one half of their effectiveness at preventing disease and has significantly enhanced their cost-effectiveness.
It is an important strategy for vaccine introduction, implementation, and evaluation.
As noted, in 1999 to 2000 the meningococcal serogroup C conjugate vaccines were introduced in the United Kingdom as a broad catch-up campaign for those younger than 19 years of age, reduced nasopharyngeal carriage of serogroup C in adolescents more than 75%, and created herd immunity that has persisted for more than a decade.
413,417 The explanation for this remarkable herd immunity effect is the low R 0 (basic reproduction number, or the average number of secondary infectious cases that are produced by a single index case in completely susceptible population), estimated at 1.3, for meningococcal disease providing herd immunity with 17% to 26% vaccine coverage of the population.
35 ,434 In contrast, measles, mumps, pertussis, polio, and rubella have an R 0 greater than 5 and require much higher thresholds (i.e., >80% for herd immunity).
427 The immunologic basis of mucosal (herd) immunity with conjugate vaccines remains unclear.
Generation of capsule-specific mucosal immunoglobulins, transudation of high-avidity serum IgG to mucosal surfaces, and Th17-induced immunity via macrophage clearance have been proposed.
35 Cost-effectiveness, measured as a quality-adjusted life-year (QALY) score, is increasingly becoming an important consideration of vaccine recommendations in public health.
419 Using standard cost-effectiveness methods, a recent analysis estimated a routine infant meningococcal vaccination program was approximately $647,000 per QALY saved compared with the $157,000 per QALY saved with the two-dose adolescent vaccination program at the current price of $90 a dose.
The ACIP concluded that routine infant meningococcal vaccination with HibMenCY was not cost-effective at this time.
433 URL: https://www.sciencedirect.com/science/article/pii/B9781455748013002137 Recommended publications: Journal Journal Reference work • 2008 Journal We use cookies to help provide and enhance our service and tailor content and ads.
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