European Journal of Pediatrics

, Volume 169, Issue 9, pp 1119–1122

Evidence of Bordetella pertussis infection in vaccinated 1-year-old Danish children

  • Marie-Louise von Linstow
  • Peter Lotko Pontoppidan
  • Carl-Heinz Wirsing von König
  • James D. Cherry
  • Birthe Hogh
Open AccessOriginal Paper

DOI: 10.1007/s00431-010-1192-9

Cite this article as:
von Linstow, M., Pontoppidan, P.L., von König, C.W. et al. Eur J Pediatr (2010) 169: 1119. doi:10.1007/s00431-010-1192-9


We measured IgA and IgG antibodies to pertussis toxin (PT) and filamentous hemagglutinin (FHA) in sera from 203 1-year-old children who had received one to three doses of a monocomponent PT toxoid vaccine. Ten children (5%) had IgA antibody to PT indicating recent infection; seven of these children had received three doses of vaccine. PT IgA responders did not have significantly longer coughing episodes than PT IgA non-responders. Since an IgA antibody response occurs in only ∼50% of infected children, the actual infection rate in our cohort is estimated to ∼10%. The apparent high Bordetella pertussis infection rate in Danish infants suggests that the monocomponent PT toxoid vaccine used in Denmark has limited efficacy against B. pertussis infection. A prospective immunization study comparing a multi-component vaccine with the present monocomponent PT toxoid vaccine should be undertaken.


PertussisPertussis toxinPertussis IgAPertussis epidemiology


Despite high vaccination coverage, pertussis continues to be a major cause of morbidity and mortality in Europe [16]. The clinical spectrum is diverse and is affected by patient age, previous exposure to the organism and immunization history [2, 3, 11]. The heterogeneity in pertussis disease expression makes it an often unrecognized and undiagnosed disease. Pertussis appears epidemically every 2 to 5 years. However, epidemiological data are incomplete, and different reporting procedures suggest that only the tip of the iceberg is evident [2, 3, 11, 16]. Improved disease surveillance and diagnoses are essential to determine the true burden of the disease.

The situation in Denmark is unique in that all children are vaccinated with a domestically produced DTaP (Di-Te-Kik) vaccine in which toxoided pertussis toxin (PT) is the only pertussis component. The PT toxoid vaccine replaced the whole-cell pertussis vaccine in January 1997. The PT toxoid vaccine is reported to provide about 78% protection against notified pertussis after three vaccinations given at 3, 5 and 12 months of age as part of the national child immunization program [9]. Vaccination effectiveness for two doses of pertussis toxoid vaccine in the first year of life is reported to be 59%. In September 2003, a pre-school pertussis booster vaccination at 5 years of age was implemented to reduce transmission to susceptible young children. Infection results in IgA and IgG antibody responses to specific Bordetella pertussis antigens, whereas vaccination results in only an IgG response to these antigens [3, 11].

Diagnosis of pertussis based on clinical symptoms is complicated by a number of factors: the wide spectrum of symptoms and misdiagnosis owing to similarity between symptoms of other infections [2, 3, 11, 16]. A WHO committee in 1991 developed a primary case definition to be used in vaccine efficacy trials: An illness with paroxysmal cough of ≥21 days and either culture-confirmed infection with B. pertussis or serological evidence of infection with B. pertussis or household contact with a case of culture-confirmed pertussis with onset of cough within 28 days before or after onset of cough [21].

In the present study, we investigated whether there was evidence of circulation of B. pertussis in the community. This would provide baseline data on which to assess the epidemiology of B. pertussis and thus direct future use of pertussis vaccines in Denmark.


Study subjects

The study population consisted of healthy children enrolled from the postnatal ward at Hvidovre Hospital, Denmark during a 12-month period from May 2004 to May 2005 [19]. Children were originally enrolled for the study of human metapneumovirus and respiratory syncytial virus infections in infancy. Approximately 20 children were enrolled each month to ensure that the children were sampled equally throughout the year. A total of 242 healthy newborns were enrolled, of whom 217 were followed throughout 1 year.

Study procedures

Children were monitored with detailed health diaries and through monthly home visits until 1 year of age. The study procedures have been previously described in detail [19]. The children were scheduled to receive routine immunizations with D-T-aP-IPV-Hib at 3, 5 and 12 months of age. Blood samples were obtained by venous puncture from 203 of the children at age 12 months and the sera kept at −80°C until further analysis.

Laboratory assays

Twofold dilutions of 50 µl of serum were used for the pertussis ELISA. IgA and IgG antibodies to PT and filamentous hemagglutinin (FHA) were measured by a standardized ELISA procedure and expressed in ELISA units (EU/ml) with respect to reference serum 3 of the Center for Biologics Evaluation and Research/US Food and Drug Administration (CBER/FDA) [20]. The lower levels of detection for the assays were 1.7 EU/ml for IgG-anti-PT, 2.4 EU/ml for IgA-anti PT, 1.8 EU/ml for IgG-anti-FHA and 1.7 EU/ml for IgA-anti-FHA.

Statistical analysis

Antibody concentrations and prevalence were tabulated. For differences in duration in days of coughing episodes and in infants with IgA positive and IgA negative samples, the Mann–Whitney rank sum was used.


At the time of blood sampling, 100% of children had received one dose, 98% had received two doses and 23% had received three doses of the PT toxoid vaccine. Because IgA antibodies are a result of infection and not vaccination, we used their presence as an indicator of infection in the study children. Ten children (4.9%) had IgA antibody to PT, 18 (8.9%) had IgG antibody to FHA, 193 (95.1%) had IgG antibody to PT and 13 (6.4%) had IgA antibody to FHA. Seven of the ten PT IgA responders had received three doses of vaccine and the remaining three PT IgA responders had received two doses at 3 and 5 months of age. The median PT IgG titer for fully vaccinated children was 50 EU/ml vs. 8 EU/ml for children who had only received one or two doses of the PT toxoid vaccine (p < 0.001).

Clinical data on cough were obtained from the health diaries of the study subjects and are illustrated in Table 1. PT IgA responders did not have significantly longer coughing episodes during the first year of life than IgA non-responders (median 11.5 days vs. 10.0 days, p = 0.186). However, two (20%) of IgA responders had cough for more than 21 days compared to 27 (14%) of IgA non-responders (p = >0.05). Mean age at longest coughing episode was 7.5 months. In one PT IgA positive and 20 PT IgA negative children, the longest coughing episode was associated with wheezing, suggesting a viral infection and not B. pertussis infection as the cause of the illnesses. Excluding these 21 children from analysis did not alter the main results (median duration of cough 11 vs. 9 days, p = 0.209). No differences in other symptoms such as fever, rash, diarrhea and vomiting were observed between the groups (data not shown).
Table 1

Duration of longest coughing episode during the first year of life in 203 Danish children related to PT IgA antibody status

Duration of cough

PT IgA pos (n = 10) (%)

PT IgA neg (n = 193) (%)

<7 days

2 (20)

59 (30.6)

7–14 days

4 (40)

89 (46.1)

15–21 days

2 (20)

18 (9.3)

22–28 days

1 (10)

8 (4.1)

29–35 days


11 (5.7)

36–42 days


3 (1.6)

43–49 days

1 (10)

2 (1.0)

>49 days


3 (1.6)


Infection with B. pertussis stimulates both IgA and IgG antibody responses to B. pertussis antigens. In an efficacy trial [12] in Germany, only 120 (52%) of 232 children with pertussis had an IgA response to PT (Heininger and Cherry unpublished data 1998). We found serological evidence of B. pertussis infection (IgA PT antibody) in 5% of our cohort of vaccinated healthy children during their first year of life. Since only 50% of infections result in a PT IgA antibody response, the actual infection rate in our cohort may have been ∼10%. It is of interest that seven of 47 (15%) with three doses of vaccine had a PT IgA antibody response, whereas only three of the 156 (2%) who had less than three doses of vaccine had a PT IgA antibody response. The explanation for this observation is that once a natural infection has occurred, immunization will enhance the PT IgA response. This was observed following the fourth dose in the German efficacy trial mentioned above [12] as well as in a more recent adult vaccine efficacy trial [10]. The presence of IgG and IgA antibodies to FHA in 8.9% and 6.4%, respectively, in the serum of study subjects is also an indicator of B. pertussis infection since the vaccine did not contain this antigen. However, antibody to FHA in contrast to antibody to PT is less specific. Infection with other Bordetella sp. as well as other gram negative bacteria may stimulate an antibody response to FHA [18].

Illnesses with cough are common during infancy. The duration of the most significant cough illness in our study subjects with evidence of B. pertussis infection was not significantly different from the duration in subjects without evidence of B. pertussis infection. This observation suggests that the infections that occurred in the previous vaccinees were clinically mild.

With the exception of the DTaP vaccine (Di-Te-Kik) in use in Denmark, which contains only toxoided PT as the pertussis component, the DTaP vaccines presently in use throughout the world contain toxoided PT as well as 1–4 other B. pertussis antigens (FHA, pertactin [PRN] and fimbriae 2/3 [FIM 2/3]) [3, 11]. The reported pertussis vaccine efficacy in the 1980s and 1990s trials varied considerably based on the case definition used [37, 1115, 17].

The main objection to the WHO primary case definition of pertussis is that it eliminated many laboratory-confirmed clinically mild cases from efficacy calculations in vaccine trials. Because mild cases are more common in vaccinees than in controls, efficacy is inflated. Therefore, vaccine efficacy appears better than it truly is, and less effective vaccines would also seem comparable with their more effective counterparts. Results from a randomized trial of acelluar pertussis vaccines in Stockholm in the 1980s showed that significantly fewer recipients of a two-component vaccine (JNIH-6) were diagnosed as primary or co-primary cases in households than those who received a monocomponent vaccine (JNIH-7) [13]. Regarding the Danish PT toxoid vaccine (Di-Te-Kik), it was used exclusively in the Gothenburg region of Sweden from 1996 until the spring of 1999. The rate of pertussis (in children born between January 1996 and June 1999) between October 1997 and September 2004 was determined for children in the Gothenburg region and the rest of Sweden [1, 8]. The rate of pertussis (mostly vaccine failures) in the Gothenburg region was significantly higher in all children less than 8 years than the rate in the rest of Sweden, where a three component DTaP vaccine was predominantly used.

In conclusion, our data indicate that 5–10% of our vaccinated cohort of healthy children had a B. pertussis infection during the first year of life, demonstrating that B. pertussis is circulating in the community even though few clinical cases were recognized. The high B. pertussis infection rate in Danish infants as well as the surveillance data from Sweden suggest that the PT toxoid vaccine used in Denmark has less than optimal efficacy. A prospective immunization study comparing a multi-component vaccine with the present monocomponent PT toxoid vaccine should be undertaken.

Conflict of interest

The laboratory studies in this paper were supported by an unrestricted grant from Sanofi pasteur. Carl-Heinz Wirsing von König and James D. Cherry have been consultants to Sanofi pasteur and have been participants in the Global Pertussis Initiative which is supported by Sanofi pasteur. Dr. Cherry is a member of the Sanofi pasteur speaker's bureau.

Open Access

This article is distributed under the terms of the Creative Commons Attribution Noncommercial License which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.

Copyright information

© The Author(s) 2010

Authors and Affiliations

  • Marie-Louise von Linstow
    • 1
  • Peter Lotko Pontoppidan
    • 1
  • Carl-Heinz Wirsing von König
    • 2
  • James D. Cherry
    • 3
  • Birthe Hogh
    • 1
  1. 1.Department of Pediatrics, Hvidovre HospitalUniversity of CopenhagenCopenhagenDenmark
  2. 2.Institut für Hygiene und LaboratoriumsmedizinKrefeldGermany
  3. 3.Division of Infectious DiseasesMattel Children’s Hospital UCLALos AngelesUSA