European Respiratory Society


As asthma is the most common chronic disease in childhood, much attention is directed towards primary prevention. Here, the clinical effectiveness of a multifaceted educational prevention was studied.

A total of 476 high-risk children were recruited during the prenatal period by general practitioners and randomised to either: 1) a control group, receiving usual care; or 2) an intervention group in which families received instruction from nurses on how to reduce exposure of newborns to mite, pet and food allergens, and passive smoking.

A total of 443 infants were followed-up for 2 yrs. At 2 yrs of age, the intervention group (n = 222) had less asthma-like symptoms, including wheezing, shortness of breath and night-time cough, than the control group (n = 221). No significant differences in total and specific immunoglobulin E were found between the groups. During the first 2 yrs of life, the incidence of asthma-like symptoms was similar in both groups; however, subanalysis revealed a significant reduction in the female, but not in the male, intervention group.

In conclusion, the intervention used in this study was not effective in reducing asthma-like symptoms in high-risk children during the first 2 yrs of life, although it was modestly effective at 2 yrs. Follow-up is necessary to confirm whether the intervention can actually prevent the development of asthma.

Asthma is the most common chronic disease in childhood and it is responsible for a large burden of disease, with huge socio-economic consequences 13. As the prevalence of asthma is still increasing 48, much attention is being directed towards the possibilities for primary prevention. It is generally agreed that asthma is a multifactorial disease, which develops in very early life or even in the uterus 912.

Environmental exposure to allergens and tobacco smoke during pregnancy or in very early life may enhance sensitisation and allergic morbidity, especially in children with a genetic predisposition 13, 14. Several primary prevention trials are currently in progress or will be finished soon, and have recently been reviewed 15. Some trials study the preventive effect of a reduction in a single exposure, such as food allergens 16, or mite and pet allergens 17, 18, or a dual approach of avoidance of food and mite allergens 19, combined with a reduction in passive smoking 20. The study reported here, the Prevention of Asthma in Children (PREVASC) study, differs from the previously cited trials, as eligible cases were recruited from a primary care population in a routine primary care setting. The study uses a multifaceted approach, by investigating the effect of a reduction in both prenatal and postnatal exposure to mite, pet and food allergens, and passive tobacco smoke on the development of asthma in children at high risk, those with at least one first-degree relative with asthma. Through this approach the PREVASC study acknowledges the multifactorial nature of asthma. It brings together the factors that can be addressed in daily primary care. In addition, a comprehensive preventive effect, rather than the effect of a reduction of a single exposure, is assessed. Since airway morbidity is influenced by sex 21, and sex-specific effects of environmental exposure on asthma have been reported recently 22, the clinical effectiveness of the intervention programme was evaluated separately in males and females.


The Ethical Committee of the University Maastricht (Maastricht, The Netherlands) approved the study.

Study population

The PREVASC study is a randomised intervention study carried out in the Dutch primary care setting, investigating the effectiveness of a primary prevention programme of asthma directed towards high-risk families expecting a child. The rationale and design of the PREVASC study have been described previously 14, 23.

In summary, pregnant mothers were recruited by general practitioners (GPs) and midwives during the first two trimesters of their pregnancy when they visited their GP or midwife. In the Dutch healthcare system, all patients are registered with a GP over a long period of time and consult their GP for all their healthcare needs, including pregnancy 24. Mothers were asked for written informed consent when the GP had established that their unborn babies were at high risk from familial occurrence of asthma (asthma in at least the mother, father or sibling(s)). This allowed antenatal identification of those who would subsequently be at increased risk of developing asthma.


The intervention group received standardised instruction from (specially trained) nurses in three home visits: at the start at 4–6 months of pregnancy, at 8 months of pregnancy, and 1–3 weeks after birth. The instruction consisted of recommendations to reduce four main environmental exposures, as follows. 1) Mite allergens by sanitation measures, including daily cleaning of floors in the house, washing bed clothes on a hot cycle (≥60°C), removing textile floor coverings, reducing air humidity by ventilating/airing and heating, using mite-impermeable bedding (mattress, quilt and pillow, and/or sleeping bag) for both parents and infant (Mitecare®; Sanalife BV, Lelystad, The Netherlands). These measures have been shown to be effective in reducing mite allergen levels 14. Parents were informed of these anti-mite measures during the second visit and they were encouraged to apply them before the infant was born and during the first 2 yrs of life. Anti-mite encasings were provided 1 month before birth. 2) Pet allergens by disposing of pets or keeping them outside the house and washing them at least once a month. Instruction on these measures was given during the first visit and repeated in the second and third visits. Parents were asked to start by applying the measure at least 3 months before birth and to continue this during the first 2 yrs of life. The timing of the instruction to apply these two measures was chosen so that a low level of these allergens could be achieved by the time the child was born. 3) Food allergens by breastfeeding the infant during at least the first 6 months of life. If breastfeeding was stopped before a child was 6 months old or if supplementation was necessary, an extensive hydrolysed formula milk (Nutrilon Pepti®; Numico, Zoetermeer, The Netherlands) was prescribed. In addition, it was recommended that the introduction of the first solid food intake was postponed until after 6 months of age. Instruction on these measures was given during the second visit and repeated during the third visit. 4) Passive smoking during pregnancy by maternal abstention from smoking and postnatally by parental abstention from smoking in the first 2 yrs of life. Instruction on these measures was given during the first visit and repeated during the second and third visits.

The control group received usual care provided by the GP. In the guidelines of the Dutch College of General Practitioners on asthma in children 25, preventive measures are recommended only when children are already asthmatic (secondary prevention). Measures to prevent asthma in high-risk infants are currently not part of the guidelines.

Outcome variables

The primary clinical outcome variables were symptoms that might point at a possible development of asthma (referred to as asthma-like symptoms) at any time in the first 2 yrs of life and during the last month of the 2nd year of life (referred to as current symptoms). Symptoms were derived from parental and GP reports.

For measuring the occurrence of asthma-like symptoms in the first 2 yrs of life, questionnaires from the International Study of Asthma and Allergies in Childhood (ISAAC) were used 26, administered at the following ages: 6 months, 1 and 2 yrs. In order to enable comparisons of the results, ISAAC outcomes were brought into line with those used in other primary prevention studies 18. The items studied included: “night-time cough without cold”, “wheezing at least once”, “wheezing with awakening” and “recurrent wheezing” (more than 4 times) at any time in the first 2 yrs of life.

Current asthma-like symptoms included “wheeze”, “shortness of breath” and “night-time coughing”, and were derived from parental reports on these symptoms in the 4 weeks prior to the child's 2nd birthday.

GP reports consisted of prospectively recorded asthma-like symptoms (“wheezing without fever”, “shortness of breath” and “coughing”) observed when the parents consulted the GP when their child was ill during the first 2 yrs of life. In addition, standardised diagnoses (atopic dermatitis, bronchi(oli)tis and pneumonia) were recorded, based on definitions of the International Classification of Health Problems in Primary Care (ICHPPC) 27. As a gold standard for asthma at 0–4 yrs is lacking, asthma diagnosis was based on the Dutch Guideline “Asthma in Children” (further referred to as GP-based diagnosis asthma) 25.

Measurement of IgE

Atopic status was determined at 2 yrs of age by the measurement of total and specific immunoglobulin (Ig)E against mite (Der p1), cat (Fel d1) and dog (Can f1) allergens. Total and specific IgE were determined in heel-prick blood, sampled on filter paper at 2 yrs. Absorbed material was eluted by incubation with phosphate buffered saline (PBS)-T (PBS/Tween-20 (0.1% v/v)) for 16 h under constant rotation. Elutants were separated from filter paper by centrifugation. Determination of total IgE in eluted blood spots was performed as previously described 28 using sepharose-immobilised reagents and 125I-labelled anti-IgE raised in sheep. Test results were expressed in IU per mL (1 IU representing ∼2.4 ng of IgE).

Specific IgE against mite, cat and dog were assessed with a radio-allergosorbent fluorescent immunoassay (RAST).

Measurement of environmental exposures to mite, pet and food allergens, and passive smoking

The effect of the intervention, with respect to mite and pet allergens, was measured by comparing mite, cat and dog allergen levels in three settled dust reservoirs (the living room floor, parental and infant mattresses) at baseline, directly after enrolment (3–5 months before birth) and exactly 1 yr later (7–9 months after birth), in order to avoid seasonal influences in allergen levels 29. At the same time, dust samples were taken in the control group. Dust collecting was performed by research assistants in a standardised manner, by vacuuming (1300-W-vacuum®; Bosch, Rotterdam, The Netherlands) the living room floor (two areas of 1 m2, for 2 min) and the parental and crib mattresses (1 m2, for 2 min) with covers but without sheets. The preparation of dust samples for measurement, and the measurement of Der p1, Fel d1 and Can f1 have been described previously 30. One IU Can f1 corresponds to 1 ng Can f1, whereas 1 mU Fel d1 corresponds to 4 ng Fel d1. The detection limit was 2 ng·g−1 of dust for Der p1, and 1 ng·g−1 of dust for Fel d1 and Can f1. Allergen concentrations were calculated as ng per metre squared vacuumed surface 31.

Data on exposure to food allergens (breastfeeding and/or type of formula feeding) were derived from weekly diary recording and, in the case of the introduction of solid foods, a questionnaire when the child was 6 months old.

Prenatal and postnatal passive smoking were assessed on the basis of a parentally recorded questionnaire when the child was 1 yr old.


As blinding for the intervention measures was not possible, families were allocated to the intervention and control groups by pre-randomisation (randomised consent design, in which both groups were informed about their own trial arm but not about the other 32). To prevent contamination between the intervention group and the control group, the pre-randomisation was performed in clusters, taking into account the post (zip) code of the domicile of the recruited family in combination with the location of the general practice the family attended. Once a general practice was allocated, every family subsequently recruited in that practice was allocated automatically to the same group. In this way, 242 families, recruited in 106 general practices with ∼2.4±3.4 (sd) patients per practice, were allocated to the intervention group; and 234 families, recruited by 146 general practices with ∼1.6±1.8 (sd) patients per practice, were allocated to the control group.


Differences in baseline characteristics and exposures between the intervention and control groups were tested using the Chi-squared test for proportions and the unpaired t-test for normally distributed continuous variables. The dependent variables reported and observed at age 2 yrs included asthma-like morbidity, atopic dermatitis, and total and specific IgE. Some data on the frequency of smoking (23 (10%) and 17 (8%), in the intervention and control groups, respectively) and of breastfeeding (14 (6.3%) and 2 (1%), in the intervention and control groups, respectively) were missing. Therefore, analyses were performed: 1) considering missing data as such (adherers-only analysis); and 2) considering cases with incomplete smoking data as passive smokers and those without breastfeeding data as not being breastfed. Differences in morbidity outcome between the groups were expressed as odds ratios (OR) with 95% confidence intervals (95% CI).

Total IgE data were normally distributed after logarithmic transformation.

In a post hoc analysis, the comparisons between the intervention and control groups were repeated separately for males and females.

As bed-sharing of infants and parents is very common 33, and as children are also exposed to allergens in the living room, the mean of the specific allergen concentrations measured in the parental and crib mattress dust and in the living room dust was calculated for each case, to obtain an overall measure of infant allergen exposure.

As the concentrations of mite, cat and dog allergens in samples of house dust and mattresses were not normally distributed even after logarithmic transformation, their median levels were used for the estimation of the effect of allergen-reducing measures. In addition, to assess the independent effects of the exposure to mite, pets and food allergens, and of passive smoking on the outcome measures, multiple logistic regression analysis was performed. Differences between the groups were tested using the Mann-Whitney U-test and within the groups using the Wilcoxon signed-rank test. A two-sided p-value <0.05 was considered to be significant.


Study population

From 1997–2000, 476 families were recruited, of whom 93% (n = 443) completed the 2-yr study period. Figure 1 shows the trial profile. After 2-yrs' follow-up, 9% (n = 20) in the intervention group and 6% (n = 13) in the control group dropped out, resulting in the participation of 222 families in the intervention group and 221 in the control group. No differences in baseline socio-demographic characteristics were found between the intervention and control groups, either as a whole or within the subgroups of males and females, with the exception of lower mite allergen levels in the control group (table 1). Significantly more intervention families than control families enrolled in the autumn/winter: 182 (82%) versus 152 (69%), p = 0.001. Baseline mite allergen levels were found to be lower in the control group than in the intervention group, and this was also the case when analysed within the male and female groups (table 1).

Fig. 1—

Trial profile of the Prevention of Asthma in Children (PREVASC) study after recruitment.

View this table:
Table. 1—

Demographic and other baseline characteristics of the control and intervention groups stratified for sex

After 2-yrs' follow-up, some data on applied intervention measures were missing. However, they were equally divided between the intervention and control groups. There were no indications for a selective item nonresponse (data not shown).

The effect of the intervention programme on exposure

The effect of the intervention programme on exposure to food allergens and passive smoking is shown in figure 2, and to mite and pet allergens in figure 3.

Fig. 2—

Effectiveness of the Prevention of Asthma in Children (PREVASC) intervention programme on a) feeding practice in the first 6 months of life and b) tobacco smoking. ▓: intervention group (n = 222); ▪: control group (n = 221). Ever: at least 1 week. ***: p<0.001, using Pearson's Chi-squared test.

Fig. 3—

Effectiveness of the Prevention of Asthma in Children (PREVASC) programme on exposure to mite and pet allergens. Median overall concentrations of a) mite, b) cat and c) dog allergens in dust samples of living room, parental and infant mattresses at baseline (t0) and 1 yr later (t1) for the intervention group (▓) and the control group (▪). ***: p = 0.001, intervention versus control group after the intervention (t1), using Mann-Whitney U-test.

Infants in the intervention group, when compared to the control group, were considerably more exclusively breastfed and/or received more hypoallergenic bottle feeds. The intervention group received their first solid food less frequently before they were 6 months old when compared with the control group. Prenatal and postnatal exposure to smoking were equal for the intervention and the control groups.

One year after baseline measurements, mite, cat and dog allergen concentrations were significantly lower in the intervention group than in the control group (fig. 3). The same results were found within the male and female groups (data not shown).

Clinical effectiveness

Parentally reported and GP-based symptoms and diagnoses

Table 2 shows the frequencies of the asthma-like symptoms in the intervention and control groups, and their risk estimates with 95% CI. No differences were found between the groups for parentally reported and GP-observed asthma-like symptoms during the first 2 yrs. The same held for the GP-based diagnosis of asthma. Parentally reported current asthma-like symptoms occurred significantly less in the intervention group compared with the control group (table 2).

View this table:
Table. 2—

Occurrence of asthma-like symptoms and allergic morbidity at 0–2 yrs and at 2 yrs in the intervention and control groups

When analysed for females and males separately, both asthma-like symptoms in the first 2 yrs of life, as well as current symptoms, occurred significantly less among females in the intervention group than in the female control group, whereas there was no difference amongst males. This was the case for parentally reported symptoms during the first 2 yrs of life or current symptoms (fig. 4), as well as for GP-observed symptoms (fig. 5). In the female intervention group, GP diagnosis of asthma tended to be less frequently present (p = 0.08) compared with the female control group, whereas among males this was not the case.

Fig. 4—

Occurrence of parentally reported asthma-like symptoms in ISAAC questionnaire and weekly diary for male and female children in the intervention (▓) and control (▪) groups: a) recurrent (≥1 episode within 4 weeks prior to 2nd birthday) wheeze 0–2 yr; b) ≥1 wheeze with awakening 0–2 yrs; c) current wheeze; d) current shortness of breath; and e) current nightly coughing. #: p = 0.04; : p = 0.03.

Fig. 5—

Occurrence of asthma-like symptoms in the first 2 yrs of life as diagnosed by the general practitioners for male and female children in the intervention (▓) and control (▪) groups: a) wheezing without fever; b) shortness of breath; c) coughing; and d) diagnosis of asthma. **: p = 0.01; #: p = 0.02; : p = 0.08.

Serum IgE levels

The mean serum concentration of total IgE was similar for the intervention and control groups (table 3). In addition, mite-, cat- and dog-specific IgE were similar in both groups. Separate subanalysis of the outcomes for males and females revealed that females in the intervention group tended to be less sensitised against mites, whereas the opposite was observed in the male group, although the differences did not reach statistical significance (p = 0.09; table 3).

View this table:
Table. 3—

Serum total and specific immunoglobulin (Ig)E for mite, cat and dog at age 2 yrs in the intervention and control groups stratified for sex

When the analyses on the association between asthma-like and atopic morbidity were repeated, assuming that the children with missing data on smoking and breastfeeding behaviour were exposed to passive smoke and were not breastfed, respectively, the results did not change essentially (data not shown).

Relationship between exposure and asthma-like morbidity

Table 4 shows the ORs for asthma-like symptoms for the group as a whole (the intervention and control group together) in relation to exposure to mite, cat, dog and food allergens, and passive smoking, adjusted for each other in a multiple logistic regression analysis. Being breastfed (≥1 week) from birth decreased the risk of current asthma-like symptoms at 2 yrs. Abstinence from maternal smoking reduced the risk of recurrent wheeze and of current wheeze at 2 yrs. Low mite levels significantly decreased the risk of current wheezing and shortness of breath.

View this table:
Table. 4—

Associations of exposure to mite, cat, dog and food allergens, and passive smoking with parentally reported symptoms without group allocation


The PREVASC study is the first study in a primary care environment to investigate the clinical effectiveness of a multifaceted approach aimed to prevent the development of asthma in high-risk children.

The results of this study indicate that the intervention was able to reduce exposure to mite, pet and food allergens, but not to passive smoking. Despite this reduction, there was no effect on either parentally reported or GP-observed symptoms during first 2 yrs of life, nor on total and specific IgE at 2 yrs. However, asthma-like symptoms at the end of the 2nd yr were less frequently reported in the intervention group. Moreover, the decrease appeared to be more pronounced in and mainly confined to the females in the intervention group.

The intervention might have caused the differences in symptoms at the end of the 2nd yr, but other explanations for the reported decrease in current asthmatic symptoms also have to be considered. A major limitation is the fact that most of the environmental exposure-reducing measures, including breastfeeding, weaning practices, procuring pets and smoking, cannot be blindly executed. All birth cohort intervention studies experience this problem 17, 20. Therefore, reporting bias cannot be excluded as an explanation for the decrease in asthma-like symptoms in the intervention group at age 2 yrs. Parents in the intervention group are aware of the applied intervention and might expect their children to have a reduced asthma-like morbidity, whereas in the control group no such “placebo” effect is to be expected. GPs in the intervention group were also not blinded for the intervention, and this could have influenced their interpretation of the observed symptoms and their diagnostic labelling. However, it was found that both the parents and GPs allocated to the intervention group reported and classified asthma-like symptoms less frequently in the female children than in the male children, and it is unlikely that a reporting bias is influenced by sex.

Several randomised intervention studies have reported results on various clinical symptoms at age 1 17, 20, 34, 2 18, 35, 3 36, 4 37 and 8 yrs 19. When the results of intervention studies are compared, it has to be kept in mind that comparison is hampered, as the studies differ in defining high-risk cases, the applied intervention(s) and the definition of outcomes. In the Manchester Allergy and Asthma Study (nacMAAS) study 36, 38, stringent anti-mite measures were provided in the homes of expecting atopic parents, where the mothers had to be at least sensitised for mite, cat or dog allergens, as shown by skin testing, but who had no cats or dogs. A significant reduction of (reported) severe wheeze with breathlessness and with exertion at age 1 yr was found 38, as well as a better specific airway resistance in the intervention group at 3 yrs 36. The Prevention and Incidence of Asthma and Mite Allergy (PIAMA study) 18 recruited pregnant females at high risk on the basis of a reported personal history of asthma, hay fever or reported allergy for house dust, mite or pet allergens. Anti-mite covers for crib and parental mattresses and pillows were provided. At 2 yrs, only a slight but significant reduction in reported night-time cough without a cold was reported, whereas the other (ISAAC) outcomes were not significantly different. The small improvement in the PIAMA study was attributed by the authors to pre-existent low mite levels. However, in the PREVASC study, low mite levels at baseline were also found. In contrast to the PIAMA study, the data presented here show a more pronounced effect of the intervention at 2 yrs, not only on night-time cough but also on other asthma-like symptoms, which might be explained by the multifaceted approach used in the PREVASC study. The Isle of Wight study 19 defined high-risk cases when allergy in at least two first-degree relatives or in one first-degree relative with an elevated cord blood IgE was present. A dual preventive approach was used, i.e. encasement of the crib mattress (not the parental mattress) and maternal avoidance of food allergens during lactation. At age 8 yrs, the intervention group was found to be at a significantly reduced risk for wheeze in the past year, nocturnal cough and mite sensitisation; however, the numbers were small because of the relatively high drop-out rate 19. A Canadian intervention study 39, 40 had a university hospital-based setting, used comparable inclusion criteria and also carried out a multifaceted intervention like the PREVASC study. In their study, the clinical outcome (probable or possible asthma diagnosed by paediatric allergists) at age 2 yrs was significantly (significance one-sided tested) less present in the intervention group (16%) than in the control group (23%) 40. A comparable difference was found in GP-diagnosed asthma in the PREVASC study, although this difference, tested two-sided, did not reach statistical significance.

The Childhood Asthma Prevention (CAPS) study 41 focused on mite allergen avoidance and/or supplementation with omega-3 fatty acids. The mite intervention was associated with lower use of oral steroids but not with wheeze, serum IgE, atopy or doctor-diagnosed asthma. However, the diet intervention resulted in a lower parentally reported prevalence of wheeze during the first 18 months.

In this study, no significant effect of the intervention was found on the incidence of specific IgE against mite, cat and dog allergen at age 2 yrs. In addition, the Canadian study 40, the PIAMA 18, the CAPS study 41 and the Study of Prevention of Allergy in Children in Europe (SPACE) 35 all found no effect of the intervention on mite sensitisation at age 2 yrs, while the nacMAAS study reported that the stringent mite avoidance regime was associated with an increased risk 36. One explanation for this might be that the intervention was started too late, as sensitisation might already have occurred in utero 42, 43.

In the present study, it was shown that it is possible to reduce exposure to mite, pet and food allergens, but not to passive smoking. The main reduction in mite levels was attained in mattress dust by the use of anti-mite encasings. In general, low pre-intervention levels of mite and pet allergens were found at baseline, probably as a result of (already) successful efforts of asthmatic families to achieve a low-allergen environment, as reported previously 44. In spite of the pre-existent low mite level, infants with mite allergen levels below the median had a reduced risk of current asthma-like symptoms when compared to infants exposed to levels above the median.

Multiple logistic regression analyses of the relationship between exposure and asthma-like (wheezing) symptoms revealed that exposure to mite and food allergens, and passive smoking contributed, independently of each other, to asthma-like symptoms, confirming that asthma is a multifactorial disease. A reduction of a single exposure seems to be less effective, as is supported by recent reports. A large observational birth cohort study 45 in Sweden analysed the effect of living in agreement with three prevailing preventive measures: avoidance of maternal smoking, breastfeeding the infant and reduction of home dampness. Children of families who had applied all three measures had less wheeze and asthma than children of families who executed only two measures. The studies might explain why avoidance of a single exposure has only marginal or no effects when other exposures are still existing, as might have been the case in other prevention studies 18, 35. In tertiary prevention of asthma intervention studies 46, focusing on a reduction of multiple environmental exposures has shown promising results, whereas the results of clinical trials targeting only one allergen were disappointing 47, 48. These studies and the current findings are a plea in favour of pursuing a multifaceted approach with respect to the prevention of asthma.

In contrast to most other intervention studies, the PREVASC study was designed to work in primary care, by approximating regular primary care circumstances as well as possible. This is important if and when the intervention, once proven to be effective to prevent asthma, becomes part of regular primary care. As has been shown in the PREVASC study, GPs and midwives were able to identify high-risk cases during routine consultation in early pregnancy. The intervention can be initiated in primary care, as was done in the research setting and executed with the help of practice nurses and/or well-baby clinics.

In a post hoc analysis, it was observed that the clinical effect of the intervention was mainly confined to females in the intervention group. To the current authors' knowledge, this is the first intervention study reporting that sex might modify the effect of reduction of environmental exposure on symptoms. The difference between the male and female groups was striking, and very consistent for almost all outcomes derived from three sources, which makes chance as an explanation less likely. For specific IgE, a nonsignificant trend for a sex-specific intervention effect was also observed. However, post hoc analyses do not allow conclusions to be drawn, but only present the possibility of the modification by sex as a suggestive hypothesis. So far, the results permit a speculative explanation of a possible effect modification by sex, although there is support in the literature for this interesting observation. Airway physiology and pathology during the whole life span, starting in the intrauterine period, is subjected to the influence of sex and might be under hormonal control, as reviewed by Becklake and Kauffmann 21. Airways of male infants are smaller than those of female infants, resulting in a lower lung function of young males 49. Studies report that symptoms induced by environmental exposure are influenced by sex. When exposed to passive tobacco smoking in utero, lung function of young males with asthma is lower than of young females with asthma 50. Pet-owning females are more susceptible to asthma when they also smoke 22. Lung function in females, if sensitised by cat and pollen allergens, is more affected than in males 51. The production of IgE is also influenced by sex, as the concentration of total serum IgE was higher in the males than the females. On the basis of these observations, one might hypothesise that, given the different reactions of the male and female immune systems to environmental exposure, males and females might also react differently to a reduction in relevant exposures. Sex-specific effects of the intervention should be evaluated in further (prospective) research, and it would be interesting if all ongoing cohort studies included information specifying whether a sex difference can be detected.

In conclusion, no effect of a multifaceted intervention programme was found on asthma-like symptoms in high-risk children during their first 2 yrs of life and atopic sensitisation at age 2 yrs. However, a small effect was observed on the symptoms at the end of their 2nd yr of life. Further follow-up is necessary to determine whether the intervention measures can actually prevent the development of asthma.


The PREVASC study is a joint project of the Depts of General Practice of the University of Maastricht and the Radboud University of Nijmegen. The authors would like to thank the GPs allied to these departments and the participating midwives for recruiting eligible families. The authors are grateful to all families who readily participated in the project. The authors would also like to thank: the research assistants, I. van Beerendonck and K. Manders; the data managers, J. Pisters and K. Coolen; the statistical adviser, J. Sijbrandij; the nurses, who visited and instructed the participating families, C. Brink, K. van der Meer, M. Rovers, T. Jeijsman, I. Schaap, M. Terhaar and E. de Vree; and the PREVASC secretary, A. Spaninks. The authors thank Numico NV (Zoetermeer, The Netherlands) for the supply of Nutrilon pepti® and Sanalife (Lelystad, The Netherlands) for the supply of the house dust mite impermeable covers (Mitecare®) and bedding. They would also like to thank N. van der Maas of Skiltec B.V., Beek, The Netherlands, for his linguistic comments and suggestions.

  • Received June 8, 2004.
  • Accepted December 7, 2004.


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